Next Article in Journal
Soil Nitrate Nitrogen Content and Grain Yields of Organically Grown Cereals as Affected by a Strip Tillage and Forage Legume Intercropping
Next Article in Special Issue
Application of Native or Exotic Arbuscular Mycorrhizal Fungi Complexes and Monospecific Isolates from Saline Semi-Arid Mediterranean Ecosystems Improved Phoenix dactylifera’s Growth and Mitigated Salt Stress Negative Effects
Previous Article in Journal
Seed Treatment with Biostimulants Extracted from Weeping Willow (Salix babylonica) Enhances Early Maize Growth
Previous Article in Special Issue
Regulation of Botrytis cinerea Infection and Gene Expression in Cut Roses by Using Nano Silver and Salicylic Acid
 
 
Search for Articles:
Title / Keyword
Author / Affiliation / Email
Journal
Article Type
 
 
Advanced Search
 
Section
Special Issue
Volume
Issue
Number
Page
 
Journals
Plants
Volume 10
Issue 7
10.3390/plants10071451
plants-logo
Submit to this Journal Review for this Journal Propose a Special Issue
Article Menu

Article Menu

share Share announcement Help format_quote Cite question_answer Discuss in SciProfiles thumb_up
...
Endorse textsms
...
Comment
first_page
settings
Order Article Reprints
Font Type:
Arial Georgia Verdana
Font Size:
Aa Aa Aa
Line Spacing:
Column Width:
Background:
Review

Protein Carbonylation: Emerging Roles in Plant Redox Biology and Future Prospects

by
Adesola J. Tola
,
Amal Jaballi
and
Tagnon D. Missihoun
*
Groupe de Recherche en Biologie Végétale (GRBV), Department of Chemistry, Biochemistry and Physics, Université du Québec à Trois-Rivières, 3351 boul. des Forges, Trois-Rivières, QC G9A 5H7, Canada
*
Author to whom correspondence should be addressed.
Plants 2021, 10(7), 1451; https://doi.org/10.3390/plants10071451
Submission received: 28 May 2021 / Revised: 26 June 2021 / Accepted: 9 July 2021 / Published: 15 July 2021
(This article belongs to the Special Issue Plant Cell Signalling under Stress)
Browse Figures
Versions Notes

Abstract

:
Plants are sessile in nature and they perceive and react to environmental stresses such as abiotic and biotic factors. These induce a change in the cellular homeostasis of reactive oxygen species (ROS). ROS are known to react with cellular components, including DNA, lipids, and proteins, and to interfere with hormone signaling via several post-translational modifications (PTMs). Protein carbonylation (PC) is a non-enzymatic and irreversible PTM induced by ROS. The non-enzymatic feature of the carbonylation reaction has slowed the efforts to identify functions regulated by PC in plants. Yet, in prokaryotic and animal cells, studies have shown the relevance of protein carbonylation as a signal transduction mechanism in physiological processes including hydrogen peroxide sensing, cell proliferation and survival, ferroptosis, and antioxidant response. In this review, we provide a detailed update on the most recent findings pertaining to the role of PC and its implications in various physiological processes in plants. By leveraging the progress made in bacteria and animals, we highlight the main challenges in studying the impacts of carbonylation on protein functions in vivo and the knowledge gap in plants. Inspired by the success stories in animal sciences, we then suggest a few approaches that could be undertaken to overcome these challenges in plant research. Overall, this review describes the state of protein carbonylation research in plants and proposes new research avenues on the link between protein carbonylation and plant redox biology.

1. Introduction

Plants are sessile in nature and they perceive and react to the abiotic and biotic factors prevailing in their growth environment. Mechanistically, most environmental factors, such as high or low temperature, high light, drought, UV/X-ray irradiation, soil salinity, and nutrient deficiencies, induce a change in the cellular homeostasis of reactive oxygen species (ROS). The most reactive ROS include hydrogen peroxide (H2O2), the superoxide radical anion (O2•−), singlet oxygen (1O2), and the hydroxyl radical (HO). ROS have different, short half-lives and they are endogenously produced during aerobic metabolism in plants. However, under stressful conditions, plants generate an enormous amount of ROS in their chloroplasts, peroxisomes, mitochondria and apoplasts. Although the enzymes that generate or process the ROS are well-known and found in nearly all taxa, how ROS encode the message from the environment is still elusive in plants. High intracellular levels of ROS are known to trigger the oxidation of diverse cellular components, including lipids, DNA, and proteins, and to contribute to cell and organismal ageing and death. Research findings from the last two decades have also shown that ROS act as signal molecules that control the expression of several plant genes involved in growth and development [1]. So far, well-known ROS signaling mechanisms in plants involve the direct oxidation of key cysteine residues in target proteins. ROS-mediated modification of proteins occurs through various post-translational modifications (PTMs), including the formation of intra- or intermolecular disulphide bonds between two cysteine residues (S-sulfhydration, glutathionylation), or one cysteine and nitric oxide or hydrogen sulfide (S-nitrosylation, persulfidation), and the oxidation reaction of H2O2 with the cysteine thiolate anion, leading to the formation of cysteine sulfenic acid (−SOH), sulfinic acid (−SO2H), and sulfonic acid (−SO3H) [2,3,4]. These modifications may activate or deactivate the target proteins or lead to their release from an interacting protein partner. ROS have also appeared to achieve their biological functions through the carbonylation of certain proteins [2]. In this case, ROS were shown to introduce carbonyl groups into the side chains of Lys, Pro, and Thr via the Fenton reaction or prompt the peroxidation of membrane lipids, which generate α,β-unsaturated aldehydes. These lipid-derived aldehydes then form carbonyl adducts on the side chains of Cys, His, and Lys in proteins in a non-enzymatic process [5]. Carbonylated proteins have been found at all the stages of the plant life cycle. In comparison to the animal models and to other ROS-mediated PTMs, little is known about their role in the regulation of gene expression and during plant growth and development [5,6]. Exogenous application of α,β-unsaturated aldehydes was found to trigger the expression of several genes implicated in growth and defense response in humans, animal models, and plants [7,8,9,10]; furthermore, a few studies have pointed to the role of protein carbonylation in diverse plant physiological processes [11,12,13,14]. Many proteins were carbonylated in Arabidopsis thaliana seeds during germination but these seeds successfully grew into highly vigorous seedlings and young plants, thus indicating a role for protein carbonylation in seed dormancy release and germination [11]. Like protein ubiquitinylation, carbonylation triggers proteasome-mediated degradation of proteins [15]. However, unlike protein ubiquitinylation or phosphorylation, protein carbonylation cannot be undone. Although recent genetic studies pointed to the transduction of ROS and phytohormone signals by protein carbonylation [16,17,18,19], it is still unclear how cells would control protein carbonylation in time and space similarly to ubiquitinylation or phosphorylation. The non-enzymatic feature of the carbonylation reaction and the fact that various endogenous lipid peroxidation-derived molecules can form adducts on proteins (see below) have considerably slowed the efforts to identify the functions regulated by protein carbonylation in plants.
In this review, we first describe the most common types of stress-derived ROS, the sites of their production in the cell, and the various PTMs that they trigger. Second, we focus on ROS-mediated protein carbonylation and the biological effects of this in selected prokaryotes and eukaryotes species. We discuss key aspects that need more attention in future investigations in plant species. These include the potential role of protein carbonylation in seed development and germination, protein quality control and proteome homeostasis, the crosstalk with other ROS-mediated protein modifications, hormone signaling, and the specificity of carbonylation targets. Finally, one important challenge in protein carbonylation research is the detection of carbonylated proteins by mass spectrometry. Based on examples of successful characterization of carbonyl adducts and their biological effects in bacteria and human cells, we present a few strategies that could also be implemented to bring progress in the field of plant research.

2. ROS: Diversity, Reactivity, and Sites of Production in Plants

ROS are partially reduced or excited forms of atmospheric oxygen with various levels of reactivity (Figure 1A,B) [20]. They are inevitable products of aerobic metabolism generated in the mitochondria of mammalian cells and non-photosynthesizing plant cells (Figure 1A). However, the main sources of ROS in photosynthesizing plant cells are the peroxisomes and the chloroplasts [21]. Diverse species of ROS can be derived from the transfer of sufficient energy capable of reversing the spin on unpaired electrons and thus producing 1O2 or during a sequential single-electron reduction pathway of molecular oxygen to produce O2•−, H2O2 or HO [22]. Under stress conditions, such as pathogen attacks, diseases, toxicity, and nutrient deficiencies, ROS production generally plummets and leads to oxidative modifications of macromolecules such as carbohydrates, unsaturated fatty acids, DNA, and proteins. Despite their potential toxicity, ROS also regulate several biological processes [21,23,24,25]. The most reactive and studied ROS in the biological systems include O2•−, H2O2, HO, and 1O2.

2.1. ROS Diversity and Reactivity

2.1.1. Singlet oxygen (1O2)

Singlet oxygen is non-radical molecular oxygen that possesses one unpaired electron in the π* orbital as a result of rapid decay of the free radical oxygen state with two unpaired electron states (non-radical) [22]. 1O2 is a short-lived molecule with a half-life of about 1–4 µs and can diffuse within a small diffusion range of 30 nm. It can potentially cause damage to lipids and proteins and induce cell death [26,27]. In plants, singlet oxygen is largely produced in the photosystem II (PS II) reaction center by photodynamic activation of the ground state oxygen that reacts with triplet chlorophyll [28]. Chloroplasts are thus the main site for 1O2 production and several carotenoid-dependent quenching systems can minimize the production of singlet oxygen, which dissipates as heat from excess light energy [29]. When carotenoid-dependent quenching becomes insufficient, excess 1O2 further triggers lipid peroxidation, which is essentially the main cause of stress-induced damage [27]. Despite its toxicity, singlet oxygen signaling is one of the important regulatory mechanisms of cell fate and gene expression [30,31].

2.1.2. Superoxide Anion (O2•−)

There are various means through which superoxides are formed in a living system. The superoxide anion (O2•−) can be generated as a byproduct of aerobic metabolism during the sequential single-electron reduction pathway of molecular oxygen. Enzymes like xanthine oxidase and NAD(P)H oxidase carry out an electron reduction of molecular oxygen to form superoxide [32]. Since O2•− has moderate reactivity and a short half-life (1–4 µs) [33,34], it is less aggressive than singlet oxygen and can further be reduced to H2O2 through singlet valency reduction or dismutation by superoxide dismutases (SODs).

2.1.3. Hydrogen Peroxide (H2O2)

H2O2 lives longer than superoxide and has a half-life of about 1000 µs or more [35]. In plants, H2O2 is known to be a double-edged sword. At low cellular concentrations, it controls several vital physiological processes, whereas, at a high concentrations, it becomes harmful by causing oxidative damages to DNA and proteins [36].

2.1.4. Hydroxyl Radical (HO)

The hydroxyl radical is small, water-soluble, highly mobile, and well-known as the most reactive species of activated oxygen. It has a single unpaired electron with the shortest half-life of 1 µs [37,38] and, as a consequence, it is quick to irreversibly modify DNA, RNA, lipids, and proteins [39,40,41]. Hydroxyl radicals are formed from the non-enzymatic reaction of H2O2 in a process called the Fenton reaction (Figure 1A), where reduced metals, including Cu2+ or Fe2+, provide the electron to reduce H2O2 to the hydroxyl radical. There are no efficient enzymatic systems to scavenge toxic HO and excessive accumulation promotes programmed cell death [42]. The steady-state level of HO in the cell likely depends on the availability of H2O2 and metal ions and the rate of occurrence of the Fenton reaction and the Haber–Weiss reaction. Iron plays a significant role in the Fenton reaction in biological systems and is mostly present in its oxidized form (Fe3+). Only a small fraction of the iron pool exists in the oxidized form (Fe2+) and participates in the Fenton reaction. The Fenton reaction may be further enhanced by the Haber–Weiss reaction which generates Fe2+ from Fe3+ stored in ferritins [43] (Figure 1B).

2.2. ROS Production Sites in Plants

Studies have shown that an estimated 1–2% of oxygen consumption in plants results in the synthesis of ROS in different subcellular organelles, including mitochondria [44], chloroplasts [45], peroxisomes [46], apoplasts, and other possible compartments containing proteins and/or molecules with high redox potential as ROS synthetic sites (Figure 1A) [47,48].

2.2.1. Chloroplasts

Chloroplasts are the major sites for ROS production in plants under illumination [45]. During photosynthesis, O2•− and H2O2 are produced via the PS I [49] and the 1O2 in the PS II [50]. Singlet oxygen (1O2) is generated constitutively in illuminated chloroplasts and its synthesis is importantly enhanced under high or excess light or heat and short or suboptimal temperature stress conditions, which also limit CO2 fixation [51,52]. This results in the overloading of the electron transport chain (ETC), which eventually causes the leakage of an electron from ferredoxin to molecular oxygen to form superoxides (O2•−) and damaging the Fe-S cluster in the PSI [53]. This process is known as PSI photo-inhibition or the Mehler reaction. Superoxide dismutases present in the chloroplast convert O2•− to H2O2 while ascorbate peroxidase and glutathione (GSH) peroxidase scavenge H2O2 back to water [54,55]. The Mehler reaction is thus integrated into the so-called water–water cycle, which may further enhance O2•− production to H2O2 production.

2.2.2. Mitochondria

In plants, ROS generation also takes place in the respiratory chain of the mitochondria at complex I (NADH dehydrogenase) and complex III (cytochrome b/c1 complex), which harbor electrons with adequate energy to reduce molecular oxygen to O2•− [44,56]. O2•− is produced from the single electron leak from complex I and III onto O2 in the ubiquinone. O2•− is then scavenged by matrix-localized manganese superoxide dismutase to H2O2 and O2 [57]. About 1–5% of the oxygen used in the mitochondria results in the production of H2O2 that may subsequently be converted to HO via the Fenton reaction [58]. Under the normal respiratory conditions, ROS produced by chloroplasts and peroxisomes are more important than those produced in mitochondria. However, under stress conditions, ROS production in mitochondria is significantly enhanced and may lead to the activation of programmed cell death [59].

2.2.3. Peroxisomes

Peroxisomes represent an additional site for O2•− and H2O2 production apart from the chloroplasts and mitochondria. O2•− are generated in the peroxisome matrix during the oxidation of xanthine to hypoxanthine and uric acid by xanthine oxidase or in the peroxisomal membrane during fatty acid beta-oxidation [46] and re-oxidation of NADH to yield NAD+ [60]. The concentration of H2O2 is two times higher in the peroxisomes than in chloroplasts and 50 times higher than in the mitochondria, partly due to photorespiration [61]. H2O2 is primarily produced in the peroxisomes by glycolate oxidase that catalyzes the oxidation of glycolate to glyoxylate in green tissues with the use of O2 as an electron donor [62,63]. Fatty acid β-oxidation, dismutation of O2•− radicals, and enzymatic reactions catalyzed by flavin oxidases are other sources of H2O2 in the peroxisomes [64].

2.2.4. Apoplasts (Plasma Membrane and the Cell Wall)

ROS are also produced in the apoplast, the compartment between the plasma membrane and the cell wall. The plasma membrane-localized NADPH oxidases are a major source of O2•−. Plant NADPH oxidases are homologs of mammalian respiratory burst oxidase homologs (RBOHs), and they possess an apoplastic oxidase domain that produces O2•− in the apoplast [65]. O2•− generated in the apoplast is subsequently converted to H2O2 by plasma membrane-localized superoxide dismutase [66]. Besides NADPH oxidase apoplasts, ROS are also produced through some enzymes present in the plant cell wall, including class III peroxidases, amine oxidases, lipoxygenases, and quinone reductase [67].

3. Common ROS-Mediated Post-Translational Modification (PTMs)

Despite their potential toxicity, ROS fulfill numerous biological functions in plants, mostly by modifying lipids and proteins. In this section, we describe the most common ROS-mediated post-translational modifications and protein carbonylation.
ROS can introduce covalent bonds into proteins by directly oxidizing amino acids (Cys residues) or create carbonyl groups in the side chains of certain amino acids [68,69,70]. The latter is termed protein carbonylation (Figure 2). Direct modification of proteins by ROS include nitrosylation or nitration of tyrosine residues, carbonylation of specific amino acids, formation of disulphide crosslinks, glycoxidation adducts, and glutathionylation, whereas indirect modification of a protein by ROS is prominently due to the conjugation of proteins to the breakdown products of lipid peroxidation [71] (Figure 2A). The accumulation of ROS in biological systems can result in either of these modifications, and they can be reversible or irreversible, interconnected, and influence each other [72] (Figure 2B).

3.1. Methionine Oxidation

Methionine oxidation is a reversible modification that occurs when the sulfur atom of methionine is oxidized to sulfoxide. Small heat shock proteins found in the chloroplasts are inactivated by sulfoxidation of methionine but reactivated by its reduction. The reduction is catalyzed by peptide methionine sulfoxide reductase using thioredoxin as a reductant [73]. Reports have suggested that methionine residues found in some peripherals act as endogenous antioxidants, protecting the active site and other sensitive domains in the protein while quenching ROS [74]. Reversible methionine sulfoxidation is deemed an important regulatory mechanism [75]. Further oxidation of methionine to sulfonic is irreversible and damaging to proteins [76].

3.2. Cysteinylation (Cysteine Oxidation) and Glutathionylation

Cysteine is readily oxidized by 1O2 and HO to form a disulfide bond (R1-S-S-R2, cystine) and this represents an important regulatory mechanism of the metabolism [77]. Initial oxidation of Cys by H2O2 typically leads to sulfenic acid, which can then form a mixed disulfide bond with GSH or a disulfide bond with other thiols. Further oxidation of sulfenic acid results in the formation of sulfinic acid and sulfonic acid. The sulfinic acid group may be reduced by a sulfiredoxin enzyme in mitochondria or peroxiredoxins in the chloroplast [78]. Glutathionylation involves the transfer of GSH, a tripeptide (Glu-Cys-Gly) available in plant cells in millimolar concentrations, to thiol groups in proteins. GSH can also form a mixed disulphide bridge with an accessible free thiol on a protein, a reaction termed protein S-glutathionylation. Several plant enzymes, typically proteins in the mitochondria, chloroplast, and the cytosol, have been proved to undergo glutathionylation [79].

3.3. Nitrosylation

This modification involves the covalent attachment of a nitrosyl radical (NO) to a cysteine thiol group. NO is a lipophilic gas produced during abiotic stress and is recognized as an important regulator and signaling molecule in plants [80,81,82,83]. The thiol group in proteins (and glutathione) interacts with NO derivatives and results in a range of products, including disulfides and sulfenic, sulfinic, and sulfonic acids, as well as S-nitrosothiols [84]. The most well-known NO•− derivative is peroxynitrite (ONOO), which is a product of the condensation reaction of NO with O2•−. However, NO does not cause S-nitrosylation by itself but does so through the involvement of S-nitrosothiols [85].

3.4. Persulfidation

Persulfidation has been proposed to derive from the interaction of H2S with cysteine sulfenic acid formed by H2O2 and to prevent further oxidation to sulfinic acids (RSO3H) [86]. Persulfides can then return to thiols through the action of the thioredoxin system. Recently, Aroca et al. proposed that signaling by H2S occurs by protein persulfidation through the covalent addition of thiol groups to form persulfides (R-SSHs) [87,88]. Their studies revealed that protein persulfidation can be reversed by the reducing agent dithiothreitol in vitro and can thus serve to modulate protein activities and enzymes involved in the maintenance of ROS homeostasis and redox balance [88]. More recently, Shen et al. reported on how ABA stimulates the persulfidation of L-cysteine desulfhydrase 1 (DES), an endogenous H2S-metabolizing enzyme. In their findings, DES was activated by ABA through auto-persulfidation at Cys44 and Cys205, which led to the transient overproduction of H2S in an Arabidopsis guard cell. A sustainable level of H2S accumulation triggered persulfidation of NADPH oxidase respiratory burst oxidase homolog protein D (RBOHD) at Cys825 and Cys892 to potentiate ROS generation. Consequently, these processes initiate a negative feedback loop that helps to fine-tune guard-cell redox homeostasis and ABA signaling [89].

4. Details of Protein Carbonylation

4.1. Direct and Indirect Reactions of Protein Carbonylation

Protein carbonylation is an irreversible PTM that involves the introduction of aldehyde and ketone carbonyl groups into the side chains of certain amino acids [90]. It represents the most frequent and irreversible chemical modification that affects protein [91]. The chemistry of protein carbonylation is complex due to the different biomolecules that are involved, including lipid and sugar derivatives. Wong et al. proposed two major types of protein carbonylation, primary protein carbonylation and secondary protein carbonylation, to reflect how the modification occurs [92] (Figure 3). Primary protein carbonylation involves metal-catalyzed oxidation (MCO) of the side chains of Lys, Pro, and Thr residues, leading to aldehyde or ketone formation [93,94]. Primary protein carbonylation may also occur, although to a much lesser extent, through α-amidation pathways or glutamyl side chains, which leads to the synthesis of peptides with the α-keto derivative at the N-terminal [13,95]. Metal-catalyzed oxidation is one common mechanism of protein carbonylation in a biological cell [96,97,98]. It is triggered by HO derived from the Fenton reaction between Fe2+ (or divalent metal ions) and H2O2 in any part of the cell [99] (Figure 1B). The hydroxyl radical reacts with side chains of Lys, Pro, Arg, Thr, and sometimes Trp to cleave them and form carbonyl groups. This results in the formation of aminoadipic semialdehyde from Lys, glutamic semialdehyde from Pro and Arg, and 2-amino-3-ketobutyric acid from Thr, respectively [100].
Secondary protein carbonylation involves the addition of reactive carbonyl species (RCS) to the side chains of Cys, His, and Lys (Figure 3). RCS are electrophilic compounds that are referred to as reactive electrophile species (RES) in the literature. They are generated by the peroxidation of membrane polyunsaturated fatty acids (PUFAs; linoleic acid, linolenic acid, and arachidonic acid), particularly in the mitochondria and chloroplasts [14,30,76]. The RCS belong to different chemical classes, as summarized in Table 1: α,β-unsaturated aldehydes (4-hydroxynonenal (4-HNE) and acrolein (ACR)), keto-aldehydes (4-oxo-nonenal), isoketals, dia-aldehydes (malondialdehydes (MDA) and glyoxal), and cyclopentanones [101]. Protein and nucleic acids are the main targets of RCS and their interaction with RCS mainly occurs through Michael adduction or Schiff-base formation [101]. Examples of RES species frequently involved in protein carbonylation include 2-propenal (acrolein), 4-HNE, and malondialdehydes (MDA) [102,103,104]. A large number of carbonylated proteins have been detected and quantified in plants and non-plant species using different techniques (see below) [92,104,105,106,107].
Overall, increased protein carbonylation is associated with an increase in the cellular ROS levels under stress conditions, making carbonylated proteins a good indicator of cellular oxidative stress. It is noteworthy that carbonylated proteins are also found in unstressed cells under optimal growth conditions. This points to the involvement of protein carbonylation in cell physiological processes required for growth and maintenance. Proteomic studies have revealed that protein carbonylation is not uniform across the proteome and some proteins are more sensitive than others to carbonylation [5,108]. The pattern of protein carbonylation in Arabidopsis thaliana (the flowering plant) differs from that in non-photosynthetic eukaryotes. Carbonylation of proteins first increases with age (the same as other species) but declines drastically before the transition from the vegetative to the reproductive phase and independently of senescence [5]. This contrasts with the situation in animals, where increased protein carbonyls are observed with ageing. These observations indicate that protein carbonylation may serve different purposes in plants and animals.

4.2. The Fates of Carbonylated Proteins

Carbonylation by RCS increases the hydrophobicity of proteins, which often become partially unfolded. As a consequence, protein carbonylation usually deactivates the protein function [15]. Studies have shown that carbonylated proteins are degraded by the proteasome system [15,116,117] (Figure 3). Hence, carbonylated proteins were deemed a marker for proteolysis. In contrast to ubiquitinylated proteins that are degraded by the 26S proteasome system, the degradation of carbonylated proteins only requires the 20S proteasome system [118]. It should be noted that the steady-state level of carbonylated proteins depends not only on their formation but also on their degradation. Therefore, increased carbonyl levels may also stem from a dysfunctional proteasome system. When proteins are heavily carbonylated, they tend to accumulate as cytotoxic aggregates due to their increased hydrophobicity. Such aggregates are linked to age-related diseases in humans and to the clogging of the proteasome system [13].
The turnover of the cellular proteome is also mediated by autophagy, and autophagy mutants displayed delayed growth compared to the wild type [119,120,121]. Interestingly, RNAi-AtATG18a transgenic lines of Arabidopsis that were impaired in autophagy were found to accumulate significant levels of carbonylated proteins compared to the wild type [122,123]. These findings indicate that autophagy also serves to degrade carbonylated proteins in plants, but the mechanism that recognizes and directs the carbonylated proteins to the autophagosome remains to be elucidated. In yeast and mammals, p62 and NBR1 (neighbor of BRCA1) act as cargo receptors to target protein aggregates derived from extensive ubiquitination in order to achieve degradation by selective autophagy [124]. A hybrid protein of p62 and NBR1 has also been identified, which mediates ubiquitin-dependent selective autophagy in plants [125,126]. It is still unclear whether protein carbonylation represents a posttranslational modification sufficient to target proteins to the autophagosome. If not, the cargo receptor that recognizes carbonylated proteins remains to be uncovered. This would improve our understanding of the relevance of protein carbonylation under normal growth conditions.

5. Importance of Protein Carbonylation in Seed After-Ripening and Germination

Fresh seeds of most temperate species are dormant and will not germinate at harvest. Seed after-ripening refers to the period in which seeds are air-dried and stored. It is associated with dormancy release and allows synchronized and faster seed germination later, although seed after-ripening and loss of dormancy have been shown to be two distinct physiological processes [127,128]. Dormancy release by environmental cues allows seed germination. Though many proteins were carbonylated in Arabidopsis thaliana seeds during germination, seeds successfully grew into highly vigorous seedlings and young plants, thus indicating a role for protein carbonylation in seed dormancy release and germination [11]. Protein carbonylation could be involved in the transitions from seed dormancy to seed germination and ageing [6]. Parallel to ROS increase, protein carbonylation during seed storage was shown to alleviate dormancy in sunflower and Arabidopsis [129,130]. Reactive oxygen species produced by the NADPH oxidase AtrbohB in Arabidopsis during after-ripening induced protein carbonylation events in the seeds of the Brassicaceae model species Lepidium sativum and A. thaliana [131]. Consistently, the mutation of the NADPH oxidase genes AtRbohB and AtRbohD in Arabidopsis reduced protein carbonylation and increased seed dormancy [131]. Furthermore, natural ageing of seeds or controlled heating of seeds to mimic natural seed ageing led to abundant carbonylated proteins and complete loss of germination in rice and Arabidopsis [132]. This suggests a balance between the beneficial effect of protein carbonylation in breaking seed dormancy and the adverse effect on seed viability. It remains unclear how such a balance is achieved and what determines the specificity of protein carbonylation during seed after-ripening and germination.

6. Importance of Protein Carbonylation in Proteome Remodeling under Nutrient Starvation and Stress Conditions

Protein degradation represents a key cellular process that assures a healthy proteome and helps recycle amino acids during nutrient starvation or stress. As we know, the level of carbonylated proteins rises in stressed cells. Prolonged abiotic stress often results in nutrient starvation, the stress in plants causing a significant overlap between stress-induced genes and sugar starvation-responsive genes [133,134]. Extended dark-induced sucrose starvation is associated with an increase of genes involved in proteolysis [135,136,137,138]. The increased level of carbonylated proteins under stress, therefore, coincides with a rise of proteolysis, which provides cells with amino acids for respiration. This suggests that protein carbonylation could be relevant to proteolysis associated with cell growth and maintenance, particularly under stress. Indeed, nutrient starvation resulted in increased protein carbonylation in a sub-population of an E. coli culture [139,140]. E. coli cells deficient in proteolysis accumulated a high level of carbonylated proteins, indicating that carbonylated proteins are targeted for proteolysis [141]. Similarly, serum starvation of two cancer cell lines, A549 and PC3, was found to increase the levels of carbonylated proteins revealed by a benzocoumarin hydrazine in vivo labeling probe [142]. Carbon starvation was also found to increase protein carbonylation and the activity of the 20S proteasome in maize root tips [143]. Hence, like ubiquitination, protein carbonylation appears as an effective way of remodeling the cellular proteome, particularly under stress conditions that challenge energy metabolism. With regard to this, oxidative stress often causes the carbonylation and deactivation of glycolytic and citric acid cycle enzymes and, accordingly, bacteria and animal cells respond to oxidative stress with about a 50% decrease in intracellular ATP levels [144,145]. Under this condition, cells must rely on ATP-independent processes to counteract stress and recycle oxidized proteins. Low intracellular ATP levels were found to decrease the 26S proteasome levels but to increase 20S proteasome levels [146]. In contrast to ubiquitylation-dependent degradation by the 26S proteasome, protein carbonylation does not require ATP and enzymes. The degradation of carbonylated proteins by the 20S proteasome system constitutes an energy-efficient way to quickly provide amino acid building blocks for growth [96,147,148].
Protein carbonylation is traditionally deemed damaging to cells, but recent studies in mammals and bacteria indicate that the oxidation of certain proteins turns them into chaperones, which direct other proteins to the 20S proteasome system [148]. Several proteins, including members of the heat shock protein 70 families, were found to turn into ATP-independent chaperones that refold proteins or direct them to the proteasome system [148]. The chaperone Hsp70 was shown to be essential for the stabilization of the 19S particle and the reassembly of the 26S proteasome system [117], whereas low levels of Hsp90 led to the disassembly of the 26S proteasome and the increase of the 20S particles [149]. Both the Hsp70 and HSP90 proteins are frequently identified as being carbonylated in bacteria, animal, and plant species [150]. Their carbonylation results in the destabilization of the 26S proteasome and increased 20S proteasome particles that are required for degrading oxidized proteome [118,143]. The 26S proteasome is heavily dependent on ATP, whereas the 20S is not but becomes particularly essential for the cells under stress conditions [151]. An impairment of the 26S proteasome system has been associated with an increase of 20S particle levels in plants [152]. Arabidopsis plants deficient in the 26S proteasome system showed increased activity of the 20S system and were more resistant to treatments that promote protein oxidation [152]. An increase in the 20S proteasome contributed to enhancing oxidative stress tolerance in plants [153]. This antagonistic regulation of the 26S and 20S proteasome across bacteria, animals, and plants likely assures the maintenance of a healthy proteome under both normal and stress conditions. Overall, the rise of protein carbonylation might serve to maintain protein turnover in a context of low ATP and contribute to oxidative stress tolerance. This is particularly relevant in scenarios of short-term stress where the concomitant expression of ROS- and RCS-detoxification enzymes quickly help the plant overcome the stress.

7. Protein Carbonylation Serves as a Signal Transduction Mechanism in Bacteria and Mammalian Cells

Signal transduction is a process that converts one form of a signal into another type within cells. ROS serve as the second messenger for signal transduction processes; however, their molecular targets have not been fully identified [76]. Studies in prokaryotes and humans have demonstrated the involvement of protein carbonylation as an ROS signal transduction mechanism. To illustrate our point, we have chosen to describe only a few examples before focusing on current evidence in plants.

7.1. Carbonylation of the Transcription Repressor PerR Facilitates H2O2 Sensing and the Expression of Oxidative Response Genes in Prokaryotes

Bacteria adapt to an elevated level of ROS by increasing the expression of detoxifying enzymes and repair proteins. The main ROS detoxification enzymes in bacteria include catalases, catalase/peroxidases, alkyl hydroperoxide reductase (AhpR), peroxiredoxins, superoxide dismutases, and the organic hydroperoxide resistance protein (Ohr) [154,155,156,157]. In B. subtilis, iron derepresses oxidative stress genes via PerR, a transcription factor related to the ferric-uptake repressor (Fur) family of the metalloproteins [158]. PerR was shown to mediate H2O2- and metal-dependent induction of the genes katA (catalase), ahpCF (alkyl hydroperoxide reductase), mrgA (nonspecific DNA-binding protein), and hemAXCDBL (heme biosynthesis operon) [159,160]. The mechanism of H2O2 sensing is thought to be mediated by a typical protein thiol (redox-active cysteine) [154,161,162,163]. Indeed, several transcription factors have been identified in bacteria, yeast, and mammals, which use the reversible oxidation of cysteine to sense H2O2 [76,124,162]. However, Lee and Helmann have revealed that H2O2 sensing occurs by metal-catalyzed oxidation of PerR and leads to the expression of oxidative defense genes (Figure 4A). PerR is a zinc-binding protein with a regulatory site that coordinates either Fe2+ or Mn2+ metal ions. There are two His residues present in the transcription factor PerR of B. subtilis, which coordinate with Fe. Upon exposure of PerR to a low level of H2O2 (˂10 µM), one or both His residues become oxidized, presumably by the hydroxyl radical generated by the Fenton reaction involving the bound iron [164]. This causes the loss of the DNA binding activity of PerR and the derepression of the PerR regulon-encoding enzymes katA, ahpCF, mrgA, and hemAXCDBL (heme biosynthesis operon) [159,160]. Hence, in the presence of iron (Fe2+), PerR mediates strong induction of the PerR regulon in response to H2O2 (Figure 4A). PerR represents the major regulator of the peroxide-induced stress response in both Gram-positive and Gram-negative bacteria and its carbonylation constitutes a widespread mechanism of ROS and peroxide sensing in the procaryotes [162].

7.2. In Animals: Mammalian Cell

Numerous cases in which protein carbonylation mediates ROS signaling have been reported in animal cells [165]. Endothelin-1 (ET-1) is a potent vasoconstrictor and a mitogen of smooth muscle cells of the pulmonary artery [166,167,168]. ET-1 is activated by receptors ETA or ETB, which can induce the proliferation of pulmonary artery smooth muscle cells through the production of ROS [169,170,171]. In an animal model of pulmonary hypertension, the expression of endothelin-1 was high and further progression of the disease was blocked by endothelin-1 receptor antagonists [172,173]. ET-1 induces ROS through NAD(P)H oxidase, and antioxidants were found to block endothelin-1-induced proliferation of the smooth muscle cells in the fetal bovine pulmonary artery [169,170]. The idea that protein carbonylation might play a role in ET-1 signaling arose is based upon observations that low concentrations of H2O2 (500 nM) could induce protein carbonylation and that ET-1 triggered protein carbonyl as early as 5–10 minutes in cultured bovine pulmonary artery smooth muscle cells [168,174]. When pulmonary artery smooth muscle cells were pre-treated with ET-1 receptor antagonists, hydrogen peroxide scavengers, or an iron chelator (deferoxamine), subsequent treatment with ET-1 was found to promote protein carbonylation in an ET-1-receptor- and Fenton reaction-dependent manner [168,174]. Annexin A1 was identified as one prominently carbonylated protein in response to ET-1 using 2D-PAGE and mass spectrometry. Annexin A1 inhibits cell growth and promotes apoptosis but its carbonylation and subsequent degradation in response to ET-1 led to cell proliferation [174] (Figure 4B). These findings demonstrate that metal-catalyzed protein carbonylation could be promoted in response to ligand–receptor interactions.
Similarly, the regulation of phase II antioxidant enzyme expression by the nuclear factor (erythroid-derived 2)-like 2 (NRF2)–Kelch-like ECH-associated 1 (KEAP1) pathway involves protein carbonylation [175]. KEAP1 is a Cullin3 ubiquitin ligase complex adaptor protein. Under physiological conditions, KEAP1 binds to NRF2 in the cytoplasm and sequesters it from the nucleus by targeting it for degradation by the proteasome system. In response to oxidative stress, KEAP1 is modified with HNE (reactive carbonyl species) through carbonylation at critical cysteine residues (Cys273 and Cys288); this releases NRF2 that translocates into the nucleus where it forms a dimer with a variety of nuclear factors, including MAF and NRF1 [176]. This complex binds to the antioxidant response element (ARE), which triggers the expression of the antioxidant responsive genes. Fang and Holmgren also reported that when thioredoxin (TRX) became carbonylated with HNE, this modified the structure of TRX at the vicinal thiol groups of TRX (Cys32 and Cys35) and triggered the release of apoptosis signaling-regulatory kinase 1 (ASK1) from the complex in which it was sequestered. This facilitates its autophosphorylation at Thr813, Thr838, and Thr842 and subsequent activation [177]. Additionally, TRX can be carbonylated at Cys72, a residue distal to the catalytic site resulting in TRX inactivation, but this did not trigger the release of ASK1. Activation of ASK1 triggers a cascade of phosphorylation of SEK and c-Jun N-terminal kinase (JNK), leading to nuclear factor-kβ activation [178] and the development of insulin resistance [165,179,180]. These signaling events illustrate a negative feedback loop in which lipid peroxidation-induced protein carbonylation transduces the ROS signal to allow the expression of antioxidant response genes and phase II metabolic enzymes in response to oxidative stress.
Plants 10 01451 g004 550
Figure 4. Examples of the implication of protein carbonylation in ROS signaling in prokaryotes and humans. (A) Bacilius subtilis uses metal-catalyzed oxidation of PerR for H2O2 and peroxides sensing. The transcription factor PerR possesses two His residues that bind to Fe. Exposure of PerR to a low level of H2O2 is sufficient to trigger one or both His residues’ oxidation, presumably via the Fenton reaction that involves the bound iron. This causes the loss of the DNA binding activity of PerR and the derepression of the PerR regulon-encoding enzymes, such as the genes katA (catalase), mrgA (nonspecific DNA-binding protein), hemAXCDBL (heme biosynthesis operon), Fur (iron uptake regulator), and ZosA (zinc-transporting ATPase), acting to detoxifying peroxides. The induced katA (catalase) removes the hydrogen peroxide to water, whereas Fur suppresses the iron intake. (B) Mammalian annexin A1 undergoes carbonylation as a signal transduction mechanism in response to endothelin-1 (ET-1) treatment to promote cell proliferation and apoptosis. ET-1 is known as a potent vasoconstrictor and a mitogen of pulmonary artery smooth muscle cells. ET-1 activates the proliferation of pulmonary artery smooth muscle cells through the production of ROS. ROS trigger metal-catalyzed oxidation of annexin A1 in response to ET-1 treatment. The carbonylation of annexin A1 and its subsequent degradation of promote cell proliferation and survival. The figures are based on data from the literature [154,157,158,159,160,162,163,164,168,169,170,171,172,173].
Figure 4. Examples of the implication of protein carbonylation in ROS signaling in prokaryotes and humans. (A) Bacilius subtilis uses metal-catalyzed oxidation of PerR for H2O2 and peroxides sensing. The transcription factor PerR possesses two His residues that bind to Fe. Exposure of PerR to a low level of H2O2 is sufficient to trigger one or both His residues’ oxidation, presumably via the Fenton reaction that involves the bound iron. This causes the loss of the DNA binding activity of PerR and the derepression of the PerR regulon-encoding enzymes, such as the genes katA (catalase), mrgA (nonspecific DNA-binding protein), hemAXCDBL (heme biosynthesis operon), Fur (iron uptake regulator), and ZosA (zinc-transporting ATPase), acting to detoxifying peroxides. The induced katA (catalase) removes the hydrogen peroxide to water, whereas Fur suppresses the iron intake. (B) Mammalian annexin A1 undergoes carbonylation as a signal transduction mechanism in response to endothelin-1 (ET-1) treatment to promote cell proliferation and apoptosis. ET-1 is known as a potent vasoconstrictor and a mitogen of pulmonary artery smooth muscle cells. ET-1 activates the proliferation of pulmonary artery smooth muscle cells through the production of ROS. ROS trigger metal-catalyzed oxidation of annexin A1 in response to ET-1 treatment. The carbonylation of annexin A1 and its subsequent degradation of promote cell proliferation and survival. The figures are based on data from the literature [154,157,158,159,160,162,163,164,168,169,170,171,172,173].
Plants 10 01451 g004

8. The Implication of Protein Carbonylation in Phytohormone Signaling Pathways

The phytohormone abscisic acid (ABA) is known to induce the production of ROS by NAD(P)H oxidases AtrbohD and AtrbohF located on the plasma membrane in the Arabidopsis guard cells. ROS-induced lipid peroxidation products, including MDA and HNE, are commonly identified as RES or RCS as a result of the presence of an electrophilic α,β-unsaturated carbonyl group [14,30]. Islam et al. demonstrated that RCS function downstream of H2O2 production in ABA signaling for stomatal closure in guard cells using transgenic tobacco plants overexpressing 2-alkenal reductase [18]. In the epidermal tissue treated with ABA, RCS levels increased within 30 min and remained high up to 120 min. Both ABA and H2O2 induced the production of RCS [18]. Treatment of the epidermal tissues with either 50 µM ABA or 1 mM of H2O2 significantly increased the level of acrolein and HNE content. The application of the RCS scavengers carnosine (1 mM) and pyridoxamine (0.5 mM) did not affect the ABA-induced H2O2 production but inhibited the ABA and H2O2-induced stomatal closure [181].
Similar to ABA-induced stomatal closure, the production of ROS by NAD(P)H oxidases is also required by MeJA-induced stomatal closure in A. thaliana guard cells [182,183,184,185,186]. As with ABA, the application of MeJA induced the accumulation of RCS such as acrolein and HNE in WT tobacco plants, thus implicating RCS in MeJA-induced stomatal closure [19]. A study by Akter and colleagues revealed that stomatal closure induced by MeJA is accompanied by depletion in the level of intracellular GSH found in Arabidopsis guard cells [187], but no effect of GSH was found in MeJA-induced ROS production [188]. GSH is thus required downstream of ROS. Consistently, RCS production triggered by MeJA induced GSH depletion in guard cells [19], indicating that RCS targets likely lie downstream of H2O2 production by RbohD and RbohF proteins in the guard cells.
The calcium ion plays a key role as a second messenger in ABA signaling and ABA-induced stomatal closure in the guard cell [189,190,191]. An elevation of cytosolic free Ca2+ concentration ([Ca2+]cyt) was also associated with methyl jasmonate (MeJA)-induced stomatal closure in guard cells [186]. The activation of Ca2+ permeable cation channels in the plasma membrane triggers the elevation of the cytosolic free Ca2+ concentration through Ca2+ influx from the apoplast and the intracellular stores [182,183,192]. H2O2 activates Ca2+-permeable cation (Ica) channels to trigger the elevation of the [Ca2+]cyt level in the guard cells [182]. The activation of the Ica channels was enhanced in the GSH-depleted mutant cad2–1 [193], indicating that GSH negatively controls H2O2-mediated Ica channel activation in Arabidopsis. Exogenous application of the RCS acrolein was more effective at raising the level of [Ca2+]cyt and inducing stomatal closure than exogenous H2O2 application [181]. Similarly, RCS-mediated [Ca2+]cyt increase was negatively regulated by GSH [19]. These suggest that GSH acts downstream of H2O2 and RCS most likely by scavenging RCS to prevent them from reacting with protein targets. Collectively, the findings generated over the last decade by Mano’s group position RCS as signal mediators downstream of H2O2 production by RBOHs and upstream of the elicitation of the Ca2+ signal in Arabidopsis guard cells for both ABA- and MeJA-mediated stomatal closure (Figure 5). Treatment of guard cells with 100 µM acrolein and HNE induced stomata closure incrementally for 4 h. Interestingly, the stomata closure could be reversed when replacing the bathing solution with one without acrolein or HNE [181]. These observations further point to an increased turnover rate of the proteins targeted by RCS, given that protein carbonylation is irreversible.
ROS are also known to control several developmental processes, including leaf expansion and xylem differentiation, adventitious root formation, and root hair development [194,195,196,197]. The involvement of ROS specifically in lateral root (LR) formation was reported in soybean [198], rice [199], and Phaseolus vulgaris [200]. In these studies, H2O2 was found to accumulate at the initiation sites where the lateral root emerged from. Several reports suggested that the LR formation might be modulated by the interaction between auxin and ROS signals, with auxin stimulus inducing the production of ROS through the activation of RBOHs in the LR-forming regions. Treatment of Arabidopsis roots with auxin triggered the accumulation of H2O2 through RBOHs and promoted lateral root formation, whereas RBOH-deficient mutants produce fewer LRs than the wild type in Arabidopsis [172,201,202,203,204]. Despite these findings, the mechanism of action of ROS in auxin signaling for LR emergence was still unclear until recently. By investigating this mechanism, Biswas and colleagues established that RCS derived from ROS mediate auxin signaling to promote lateral root formation [16]. The levels of RCS, including acrolein, HNE, and crotonaldehyde, were elevated before the formation of LRs in Arabidopsis following auxin treatment, and supplementation of the carbonyl scavenger carnosine suppressed auxin-induced LR formation (both in numbers and density) [16]. The action of the RCS to promote LR formation depended on the presence of auxin receptors (TIR1 or AFB2) and promoted the degradation of Aux/IAA proteins. RCS likely further auxin signaling by triggering the degradation of negative regulators of the auxin signaling pathways via protein carbonylation. A summary of the recent findings pointing to hormone signal transduction by protein carbonylation in plants is provided in Table 2.

9. Crosstalk Between Carbonylation and Other PTMs

Cys residues are primary targets for ROS-mediated PTMs. As described above, Cys residues can undergo nitrosylation, glutathionylation, persulfidation, and direct oxidation to sulfenic, sulfinic, or sulfonic acid derivatives. These PTMs on Cys are associated with diverse biological effects [2]. Since Cys is also a substrate for carbonylation, it is very likely that carbonylation interferes positively or negatively with these biological effects, particularly at the onset of stress and in the early events of stress signaling in plants and non-plant species. The carbonylation of Keap1 by RCS alters the adaptor function of Keap1 and prevents the ubiquitination of its specific partner NRF2 [123,205]. Mitogen-activated protein kinases (MAPKs) form an important group of proteins that relay intracellular and extracellular signals via a cascade of protein phosphorylation in eukaryotic cells. Reactive carbonyl species were found to modify MAPKs to interfere with their signaling functions [206,207]. Crosstalk between protein carbonylation and protein nitrosylation has also been reported [6]. The analysis of the proteome of citrus plants (Citrus aurantium L.) exposed to salt stress revealed an important overlap between the carbonylated proteins and the nitrosylated proteins after pretreatment with H2O2 and sodium nitroprusside, respectively [208]. Sodium nitroprusside is a donor of ˙NO required for protein nitrosylation. Interestingly, H2O2 and SNP pre-treatments before salinity stress lowered the levels of both carbonylated proteins and S-nitrosylated proteins, indicating crosstalk between H2O2 and ˙NO signaling pathways [208,209]. The irreversible carbonylation of proteins may thus prevent reversible PTMs, such as S-nitrosylation and phosphorylation, from occurring or vice versa. This is supported by observations in animals and the effects of NO and HCN in alleviating protein oxidation in seeds [11,129,180,210,211]. Besides Cys, carbonylation at Lys residues influences the effects of acetylation, methylation, mono- and polyubiquitination, and SUMOylation of proteins. Histones are lysine- and arginine-rich proteins that regulate chromatin structure and gene expression. Treatment of RKO cells with either 4-HNE or 4-oxo-2-nonenal resulted in the carbonylation of histones at Lys and His residues [212]. Complementary tests in vitro revealed that pre-treatment of H3/H4 tetramers inhibited nucleosome assembly similarly to lysine acetylation. Combined histone acetylation and carbonylation may thus enhance gene activation in the cell. So far, crosstalk between histone protein carbonylation and histone acetylation or phosphorylation has yet to be demonstrated in plants. Progress brought about by studies in animals show that much remains to be known in plants concerning the importance of protein carbonylation in ROS, hormone signaling, and their crosstalk.

10. Target Specificity in Protein Carbonylation

The answer to the question concerning specificity in protein carbonylation has long been sought. Despite being nonenzymatic, protein carbonylation appears to bear some substrate specificity according to the hundreds of studies in several prokaryote and eukaryote species [150]. Enzymes are the most frequent targets identified in various species, probably because of the enhanced nucleophilic reactivity of the residues in their active sites, namely Cys, His, and Lys. Besides enzymes, heat shock proteins and cytoskeleton proteins are often identified among carbonylated proteins [150,213]. Several orthologous or conserved enzymes and proteins have been found to be carbonylated similarly across species and kingdoms. A long list of such enzymes and proteins found in Escherichia coli, rats, humans, and plants has been drawn up and constitutes a solid case in favor of the specificity of protein carbonylation [150]. However, how can one predict such specificity? From the analysis of carbonylated E. coli proteins and bovine serum albumin (BSA) by mass spectrometry, Maisonneuve et al. identified small peptide regions called RKPT-enriched regions containing several carbonylated residues. Based on these regions and surrounding residues, they developed a computer model (available at http://www.lcb.cnrs-mrs.fr/CSPD/, accessed on 27 May 2021) capable of predicting sites and proteins more susceptible to carbonylation in E. coli [97]. The model, however, could only predict direct carbonylation products in E. coli and failed to detect carbonylated proteins found in A. thaliana and yeast. To overcome these limitations, another bioinformatics tool, named CarSPred, was developed later to predict carbonylation in the human proteome [214]. Interestingly, these studies and several others agreed upon the fact that RKPT-enriched regions in proteins are hot spots of protein carbonylation in several species [214,215,216,217]. A similar or better bioinformatics tool is still lacking for plants. An important step toward closing this gap is to further improve carbonylated proteome sequencing and develop new approaches to identify modified residues unequivocally (see below).

11. Challenges and Approaches for Studying the Roles of Protein Carbonylation in Plants: Lessons from Studies in Mammalians

Protein carbonylation is irreversible in most cases and carbonylated proteins can remain in the cell for more than 4 h before degradation [218]. Several techniques have been developed over the last two decades to analyze the profile of protein carbonylation or to identify the carbonylated proteins within the cellular proteome. These methods range from Western blot analyses to mass spectrometry-based protein sequencing. For a Western blot analysis, carbonylated proteins are first labeled with a carbonyl-reactive compound, most commonly 2,4-dinitrophenylhydrazine (DNPH), prior to the separation by electrophoresis and then revealed using anti-DNP antibodies. DNPH reacts with the aldehyde or ketone carbonyl group and forms hydrazone derivatives (DNP), thus enabling spectrophotometric or antibody detection [219,220].
The aldehyde reactive probe (ARP; N′-aminooxymethylcarbonylhydrazino D- biotin), a biotinylated hydroxylamine compound that forms an oxime derivative with the carbonyl group found in oxidatively modified proteins, is also frequently used [221,222]. A comprehensive description of the existing methods has been undertaken in previous studies [150,223]. For mass spectrometry analysis, an enrichment step of carbonylated proteins is often required, as for most PTM analyses [17,93,108,224,225,226,227]. A major drawback of this approach though is the impossibility of revealing the sites of the modification and quantifying the number of carbonylated proteins, particularly when the modified peptide is not found and sequenced. Moreover, diverse RCS are generated in the cell, the majority of which are unknown, and therefore the exact mass adducts brought by the RCS cannot be determined precisely and accounted for in the mass search analysis. Although a few hits can be found based on the known mass of the commonly found RCS in the cells (HNE, MDA, acrolein), this approach still under-samples the carbonylated proteome. This is as well as the fact that the mere identification of the carbonylated proteins does not suffice to conclude about the biological effect of the modification in vivo. However, because of the enrichment step during the sample preparation, the approach still provides a list of putative carbonylated proteins that can be further examined by top-down proteomics. Pioneer and recent studies in mammal and plant cells adopted this strategy and were successful in validating the biological effects of the carbonylation of candidate targets identified in a first screening [225,228,229,230]. A more robust strategy to identify the site of modification consists of profiling the carbonylated proteins based on their affinity to a given RCS. This approach, called affinity-based proteome profiling (ABBP), has been successfully used in mammal cells to identify cysteines that are highly reactive to RCS [231,232,233]. Genuine targets of protein carbonylation in vivo have been identified using this method and the biological effects of the modification in gene signaling were successfully characterized thereafter by site-directed mutagenesis and mutant analysis [231,232]. Probes that are blind to the nature of the target amino acid residues have also been developed to identify residues other than Cys [234]. We are currently unaware of the use of these probes with plant samples. Furthermore, one critical research challenge relates to the confounding feature of protein carbonylation—in other words, how can we distinguish potential physiological effects of protein carbonylation (protein quality control and recycling, crosstalk, and signaling) from the fatality of severe oxidative stress where an unavoidable surge of protein carbonylation leads to protein aggregation and cell death? A targeted proteomics approach could help. More knowledge needs to be accumulated on single proteins to build up a global understanding of the effects of their carbonylation on the biological functions known for them. Another powerful approach that allows the probing of protein carbonylation in vivo has been developed for mammals [215,235]. Due to the proven efficacy and robustness of these chemical and genetics tools, they could also be used in plants to bring progress in the field.

12. Conclusion and Future Perspectives

Redox biology has gained much attention in plant science over the last two decades. The traditional view of ROS as deleterious compounds has evolved into the acknowledgment of the importance of ROS in plant physiology, growth, and development [236,237,238]. ROS-mediated PTMs have emerged as signal transduction mechanisms that relay environmental stress and hormone cues toward and within the cell. Of these PTMs, the importance of protein carbonylation in redox biology has begun to surface through pioneering studies in plants and the recent findings on its implication in ABA, auxin, and JA signaling pathways [13,76,239,240,241,242,243]. The proteins targeted by carbonylation for the transduction of these hormone signals have yet to be identified. In contrast to protein ubiquitination and phosphorylation, it is still unknown how protein carbonylation is controlled and what other physiological processes are related to it. Moreover, diverse RCS are produced in the cell and likely have different effects depending on their chemical nature and the proteins that they modify [244]. As a consequence, the identification of the RCS responsible for the modification in vivo remains challenging, as the timing, the location, and the nature of the RCS mediating the modification can vary. However, a combined approach involving screening for reactivity using arbitrary RCS substrates followed by targeted characterization, as well as the use of ion mobility spectrometry, may be helpful [105,234]. For signaling, a target protein must have a high affinity with the RCS and be able to translate the RCS signal into a downstream protein via other modifications. For a target protein, the ratio of the carbonylated forms to the non-carbonylated form is often unclear. As pointed out by Poganik et al. [245], the carbonylation of a protein involved in ROS or hormone signaling pathways is likely to have a dominant effect even when only a small fraction of the pool of the target protein is carbonylated. We are very hopeful that the next few years will witness ground-breaking findings and answers to these questions about the importance of protein carbonylation in plant redox biology.
The analysis and summary of the findings provided in this review revealed the emerging role of protein carbonylation in protein quality control, protein homeostasis, and hormone signaling. As in prokaryotes and eukaryotes, these functions of protein carbonylation could also be explored in plant research and redox biology. The findings could then be used in biotechnology to mitigate the effects of environmental stress on crops.

Author Contributions

Writing—Original Draft Preparation, A.J.T. and T.D.M.; Writing—Review & Editing A.J., A.J.T. and T.D.M. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the Natural Sciences and Engineering Research Council of Canada (NSERC), Discovery Grant Program, grant number DGECR-2019-00304. A.J. received the Mitacs Globalink Graduate Fellowship. A.J.T. and A.J. thank UQTR for their financial support through the Universalis Causa and the UQTR Foundation scholarships respectively.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

No new data were created or analyzed in this study. Data sharing is not applicable to this article.

Acknowledgments

In this section, you can acknowledge any support given which is not covered by the author contribution or funding sections. This may include administrative and technical support, or donations in kind (e.g., materials used for experiments).

Conflicts of Interest

The authors declare no conflict of interest.

References

  1. Mittler, R. ROS Are Good. Trends Plant Sci. 2017, 22, 11–19. [Google Scholar] [CrossRef] [Green Version]
  2. Friso, G.; Van Wijk, K.J. Posttranslational protein modifications in plant metabolism. Plant Physiol. 2015, 169, 1469–1487. [Google Scholar] [CrossRef] [Green Version]
  3. Waszczak, C.; Akter, S.; Eeckhout, D.; Persiau, G.; Wahni, K.; Bodra, N.; Van Molle, I.; De Smet, B.; Vertommen, D.; Gevaert, K.; et al. Sulfenome mining in Arabidopsis thaliana. Proc. Natl. Acad. Sci. USA 2014, 111, 11545–11550. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  4. Waszczak, C.; Carmody, M.; Kangasjärvi, J. Reactive Oxygen Species in Plant Signaling. Annu. Rev. Plant Biol. 2018, 69, 209–236. [Google Scholar] [CrossRef] [Green Version]
  5. Johansson, E.; Olsson, O.; Nyström, T. Progression and specificity of protein oxidation in the life cycle of Arabidopsis thaliana. J. Biol. Chem. 2004, 279, 22204–22208. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  6. Lounifi, I.; Arc, E.; Molassiotis, A.; Job, D.; Rajjou, L.; Tanou, G. Interplay between protein carbonylation and nitrosylation in plants. Proteomics 2013, 13, 568–578. [Google Scholar] [CrossRef]
  7. Ayala, A.; Muñoz, M.F.; Argüelles, S. Lipid peroxidation: Production, metabolism, and signaling mechanisms of malondialdehyde and 4-hydroxy-2-nonenal. Oxid. Med. Cell. Longev. 2014, 2014, 360438. [Google Scholar] [CrossRef]
  8. Scott, W.; Sattler, E.; Mè Ne-Saffrané, L.; Farmer, E.E.; Krischke, M.; Mueller, M.J.; Dellapenna, D. Nonenzymatic Lipid Peroxidation Reprograms Gene Expression and Activates Defense Markers in Arabidopsis Tocopherol-Deficient Mutants. Plant Cell 2006, 18, 3706–3720. [Google Scholar] [CrossRef] [Green Version]
  9. Weber, H.; Chételat, A.; Reymond, P.; Farmer, E.E. Selective and powerful stress gene expression in Arabidopsis in response to malondialdehyde. Plant J. 2004, 37, 877–888. [Google Scholar] [CrossRef]
  10. Dueckershoff, K.; Mueller, S.; Mueller, M.J.; Reinders, J. Impact of cyclopentenone-oxylipins on the proteome of Arabidopsis thaliana. BBA Proteins Proteom. 2008, 1784, 1975–1985. [Google Scholar] [CrossRef]
  11. Job, C.; Rajjou, L.; Lovigny, Y.; Belghazi, M.; Job, D. Patterns of Protein Oxidation in Arabidopsis Seeds and during Germination. Plant Physiol. 2005, 138, 790–802. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  12. Liu, X.-L.; Yu, H.-D.; Guan, Y.; Li, J.-K.; Guo, F.-Q. Carbonylation and loss-of-function analyses of SBPase reveal its metabolic interface role in oxidative stress, carbon assimilation, and multiple aspects of growth and development in Arabidopsis. Mol. Plant 2012, 5, 1082–1099. [Google Scholar] [CrossRef] [Green Version]
  13. Nystrom, T. Role of oxidative carbonylation in protein quality control and senescence. EMBO J 2005, 24, 1311–1317. [Google Scholar] [CrossRef] [PubMed]
  14. Mène-Saffrané, L.; Davoine, C.; Stolz, S.; Majcherczyk, P.; Farmer, E.E. Genetic removal of tri-unsaturated fatty acids suppresses developmental and molecular phenotypes of an Arabidopsis tocopherol-deficient mutant: Whole-body mapping of malondialdehyde pools in a complex eukaryote. J. Biol. Chem. 2007, 282, 35749–35756. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  15. Levine, R.L. Carbonyl modified proteins in cellular regulation, aging, and disease. Free Radic. Biol. Med. 2002, 32, 790–796. [Google Scholar] [CrossRef]
  16. Biswas, M.S.; Fukaki, H.; Mori, I.C.; Nakahara, K.; Mano, J. Reactive oxygen species and reactive carbonyl species constitute a feed-forward loop in auxin signaling for lateral root formation. Plant J. 2019, 100, 536–548. [Google Scholar] [CrossRef]
  17. Biswas, S.; Mano, J. Lipid peroxide-derived short-chain carbonyls mediate hydrogen peroxide-induced and salt-induced programmed cell death in plants. Plant Physiol. 2015, 168, 885–898. [Google Scholar] [CrossRef] [Green Version]
  18. Islam, M.M.; Ye, W.; Matsushima, D.; Munemasa, S.; Okuma, E.; Nakamura, Y.; Biswas, M.S.; Mano, J.; Murata, Y. Reactive carbonyl species mediate ABA signaling in guard cells. Plant Cell Physiol. 2016, 57, 2552–2563. [Google Scholar] [CrossRef] [Green Version]
  19. Islam, M.M.; Ye, W.; Akter, F.; Rhaman, M.S.; Matsushima, D.; Munemasa, S.; Okuma, E.; Nakamura, Y.; Biswas, M.S.; Mano, J.; et al. Reactive Carbonyl Species Mediate Methyl Jasmonate-Induced Stomatal Closure. Plant Cell Physiol. 2020, 61, 1788–1797. [Google Scholar] [CrossRef]
  20. Halliwell, B.; Gutteridge, J.M. Free Radicals in Biology and Medicine; Oxford University Press: Oxford, UK, 1990; Volume 58. [Google Scholar]
  21. Foyer, C.H.; Noctor, G. Redox sensing and signalling associated with reactive oxygen in chloroplasts, peroxisomes and mitochondria. Physiol. Plant. 2003, 119, 355–364. [Google Scholar] [CrossRef] [Green Version]
  22. Halliwell, B. Reactive Species and Antioxidants. Redox Biology Is a Fundamental Theme of Aerobic Life. Plant Physiol. 2006, 141, 312–322. [Google Scholar] [CrossRef] [Green Version]
  23. König, J.; Jung, T.; Grune, T. Protein Carbonylation in Aging and Senescence. Protein Carbonylation Princ. Anal. Biol. Implic. 2017, 272–290. [Google Scholar] [CrossRef]
  24. Mignolet-Spruyt, L.; Xu, E.; Idänheimo, N.; Hoeberichts, F.A.; Mühlenbock, P.; Brosché, M.; Van Breusegem, F.; Kangasjärvi, J. Spreading the news: Subcellular and organellar reactive oxygen species production and signalling. J. Exp. Bot. 2016, 67, 3831–3844. [Google Scholar] [CrossRef] [Green Version]
  25. Vaahtera, L.; Brosché, M.; Wrzaczek, M.; Kangasjärvi, J. Specificity in ROS signaling and transcript signatures. Antioxid. Redox Signal. 2014, 21, 1422–1441. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  26. Davies, M.J. Reactive species formed on proteins exposed to singlet oxygen. Photochem. Photobiol. Sci. 2004, 3, 17–25. [Google Scholar] [CrossRef]
  27. Triantaphylidès, C.; Krischke, M.; Hoeberichts, F.A.; Ksas, B.; Gresser, G.; Havaux, M.; Van Breusegem, F.; Mueller, M.J. Singlet oxygen is the major reactive oxygen species involved in photooxidative damage to plants. Plant Physiol. 2008, 148, 960–968. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  28. Fischer, B.B.; Hideg, É.; Krieger-Liszkay, A. Production, detection, and signaling of singlet oxygen in photosynthetic organisms. Antioxid. Redox Signal. 2013, 18, 2145–2162. [Google Scholar] [CrossRef] [PubMed]
  29. Ruban, A.V.; Johnson, M.P.; Duffy, C.D.P. The photoprotective molecular switch in the photosystem II antenna. Biochim. Biophys. Acta Bioenerg. 2012, 1817, 167–181. [Google Scholar] [CrossRef] [Green Version]
  30. Farmer, E.E.; Mueller, M.J. ROS-Mediated Lipid Peroxidation and RES-Activated Signaling. Annu. Rev. Plant Biol. 2013, 64, 429–450. [Google Scholar] [CrossRef] [PubMed]
  31. Havaux, M. Carotenoid oxidation products as stress signals in plants. Plant J. 2014, 79, 597–606. [Google Scholar] [CrossRef] [PubMed]
  32. Fridovich, I. Superoxide anion radical (O2−·), superoxide dismutases, and related matters. J. Biol. Chem. 1997, 272, 18515–18517. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  33. Egorov, S.Y.; Kamalov, V.F.; Koroteev, N.I.; Krasnovsky, A.A.; Toleutaev, B.N.; Zinukov, S.V. Rise and decay kinetics of photosensitized singlet oxygen luminescence in water. Measurements with nanosecond time-correlated single photon counting technique. Chem. Phys. Lett. 1989, 163, 421–424. [Google Scholar] [CrossRef]
  34. Skovsen, E.; Snyder, J.W.; Lambert, J.D.C.; Ogilby, P.R. Lifetime and diffusion of singlet oxygen in a cell. J. Phys. Chem. B 2005, 109, 8570–8573. [Google Scholar] [CrossRef] [PubMed]
  35. Henzler, T.; Steudle, E. Transport and metabolic degradation of hydrogen peroxide in Chara corallina: Model calculations and measurements with the pressure probe suggest transport of H2O2 across water channels. J. Exp. Bot. 2000, 51, 2053–2066. [Google Scholar] [CrossRef] [Green Version]
  36. Mittler, R.; Berkowitz, G. Hydrogen peroxide, a messenger with too many roles? Redox Rep. 2001, 6, 69–72. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  37. Haber, F.; Weiss, J.; Seph, J.O.; Eiss, W. The Catalytic Decom position o f Hydrogen Peroxide by Iron Salts. Proc. R. Soc. Lond. Ser. A Math. Phys. Sci. 1934, 147, 332–351. [Google Scholar]
  38. Kehrer, J.P. The Haber-Weiss reaction and mechanisms of toxicity. Toxicology 2000, 149, 43–50. [Google Scholar] [CrossRef]
  39. Halliwell, B.; Gutteridge, J.M.C.; Aruoma, O.I. The deoxyribose method: A simple “test-tube” assay for determination of rate constants for reactions of hydroxyl radicals. Anal. Biochem. 1987, 165, 215–219. [Google Scholar] [CrossRef]
  40. Betteridge, D.J. What is oxidative stress? Metabolism 2000, 49, 3–8. [Google Scholar] [CrossRef]
  41. Carter, R. Oxygen: The Molecule that made the World. JRSM 2003, 96, 46–47. [Google Scholar] [CrossRef] [Green Version]
  42. Das, K.; Roychoudhury, A. Reactive oxygen species (ROS) and response of antioxidants as ROS-scavengers during environmental stress in plants. Front. Environ. Sci. 2014, 2, 1–13. [Google Scholar] [CrossRef] [Green Version]
  43. Harrison, P.M.; Bauminger, E.R.; Hechel, D.; Hodson, N.W.; Nowik, I.; Treffry, A.; Yewdall, S.J. Mechanism of Fe(II) oxidation and core formation in ferritin. In Progress in Iron Research; Hershko, C., Konijn, A.M., Aisen, P., Eds.; Advances in Experimental Medicine and Biology; Springer: Boston, MA, USA, 1994; Volume 356, pp. 1–12. [Google Scholar] [CrossRef]
  44. Sweetlove, L.J.; Heazlewood, J.L.; Herald, V.; Holtzapffel, R.; Day, D.A.; Leaver, C.J.; Millar, A.H. The impact of oxidative stress on Arabidopsis mitochondria. Plant J. 2002, 32, 891–904. [Google Scholar] [CrossRef]
  45. Asada, K. Production and Scavenging of Reactive Oxygen Species in Chloroplasts and Their Functions. Plant Physiol. 2006, 141, 391–396. [Google Scholar] [CrossRef] [Green Version]
  46. Corpas, F.J.; Barroso, J.B.; Palma, J.M.; Rodriguez-Ruiz, M. Plant peroxisomes: A nitro-oxidative cocktail. Redox Biol. 2017, 11, 535–542. [Google Scholar] [CrossRef]
  47. Daudi, A.; Cheng, Z.; O’brien, J.A.; Mammarella, N.; Khan, S.; Ausubel, F.M.; Paul Bolwell, G. The Apoplastic Oxidative Burst Peroxidase in Arabidopsis Is a Major Component of Pattern-Triggered Immunity. Plant Cell 2012, 24, 275–287. [Google Scholar] [CrossRef] [Green Version]
  48. Qi, J.; Wang, J.; Gong, Z.; Zhou, J.M. Apoplastic ROS signaling in plant immunity. Curr. Opin. Plant Biol. 2017, 38, 92–100. [Google Scholar] [CrossRef] [PubMed]
  49. Asada, K.; Kiso, K.; Yoshikawa, K. Univalent reduction of molecular oxygen by spinach chloroplasts on illumination. J. Biol. Chem. 1974, 249, 2175–2181. [Google Scholar] [CrossRef]
  50. Telfer, A.; Bishop, S.M.; Phillips, D.; Barber, J. Isolated Photosynthetic Reaction Center of Photosystem II as a Sensitizer for the Formation of Singlet Oxygen. J. Biol. Chem. 1994, 269, 13244–13253. [Google Scholar] [CrossRef]
  51. Triantaphylidès, C.; Havaux, M. Singlet oxygen in plants: Production, detoxification and signaling. Trends Plant Sci. 2009, 14, 219–228. [Google Scholar] [CrossRef]
  52. Pospíšil, P. Production of reactive oxygen species by photosystem II as a response to light and temperature stress. Front. Plant Sci. 2016, 7, 1950. [Google Scholar] [CrossRef] [PubMed]
  53. Mehler, A.H. Studies on reactions of illuminated chloroplasts. II. Stimulation and inhibition of the reaction with molecular oxygen. Arch. Biochem. Biophys. 1951, 34, 339–351. [Google Scholar] [CrossRef]
  54. Asada, K.; Allen, J.; Foyer, C.H.; Matthijs, H.C.P. The water-water cycle as alternative photon and electron sinks. Philos. Trans. R. Soc. B Biol. Sci. 2000, 355, 1419–1431. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  55. Chang, C.C.C.; Šlesak, I.; Jordá, L.; Sotnikov, A.; Melzer, M.; Miszalski, Z.; Mullineaux, P.M.; Parker, J.E.; Karpińska, B.; Karpiñski, S. Arabidopsis chloroplastic glutathione peroxidases play a role in cross talk between photooxidative stress and immune responses. Plant Physiol. 2009, 150, 670–683. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  56. Møller, I.M. Plant mitochondria and oxidative stress: Electron transport, NADPH turnover, and metabolism of reactive oxygen species. Annu. Rev. Plant Biol. 2001, 52, 561–591. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  57. Cvetkovska, M.; Alber, N.A.; Vanlerberghe, G.C. The signaling role of a mitochondrial superoxide burst during stress. Plant Signal. Behav. 2013, 8, e22749. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  58. Popov, V.N.; Simonian, R.A.; Skulachev, V.P.; Starkov, A.A. Inhibition of the alternative oxidase stimulates H2O2 production in plant mitochondria. FEBS Lett. 1997, 415, 87–90. [Google Scholar] [CrossRef] [Green Version]
  59. Petrov, V.; Hille, J.; Mueller-Roeber, B.; Gechev, T.S. ROS-mediated abiotic stress-induced programmed cell death in plants. Front. Plant Sci. 2015, 6, 69. [Google Scholar] [CrossRef] [Green Version]
  60. Del Rio, L.A.; Fernandez, V.M.; Ruperez, F.L.; Sandalio, L.M.; Palma, J.M. NADH Induces the Generation of Superoxide Radicals in Leaf Peroxisomes’. Plant Physiol. 1989, 89, 728–731. [Google Scholar] [CrossRef] [Green Version]
  61. Foyer, C.H.; Bloom, A.J.; Queval, G.; Noctor, G. Photorespiratory metabolism: Genes, mutants, energetics, and redox signaling. Annu. Rev. Plant Biol. 2009, 60, 455–484. [Google Scholar] [CrossRef]
  62. del Río, L.A.; Palma, J.M.; Sandalio, L.M.; Corpas, F.J.; Pastori, G.M.; Bueno, P. Peroxisomes as a source of superoxide and hydrogen peroxide in stressed plants Superoxide dismutases (SODs) and superoxide radicals in peroxisomes Metabolism of activated oxygen in leaf peroxisomes from stressed plants. Biochem. Soc. Trans. 1996, 24, 434–438. [Google Scholar]
  63. Xu, H.; Zhang, J.; Zeng, J.; Jiang, L.; Liu, E.; Peng, C.; He, Z.; Peng, X. Inducible antisense suppression of glycolate oxidase reveals its strong regulation over photosynthesis in rice. J. Exp. Bot. 2009, 60, 1799–1809. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  64. del Río, L.A.; Corpas, F.J.; Sandalio, L.M.; Palma, J.M.; Gómez, M.; Barroso, J.B. Reactive oxygen species, antioxidant systems and nitric oxide in peroxisomes. J. Exp. Bot. 2002, 53, 1255–1272. [Google Scholar] [CrossRef] [PubMed]
  65. Marino, D.; Dunand, C.; Puppo, A.; Pauly, N. A burst of plant NADPH oxidases. Trends Plant Sci. 2012, 17, 9–15. [Google Scholar] [CrossRef] [PubMed]
  66. Karpinska, B.; Karlsson, M.; Schinkel, H.; Streller, S.; Süss, K.-H.; Melzer, M.; Wingsle, G. A Novel Superoxide Dismutase with a High Isoelectric Point in Higher Plants. Expression, Regulation, and Protein Localization. Plant Physiol. 2001, 126, 1668–1677. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  67. Camejo, D.; Guzm, A.; Moreno, A. Reactive oxygen species, essential molecules, during plantepathogen interactions. Plant Physiol. Biochem. 2016, 103, 10–23. [Google Scholar] [CrossRef]
  68. Berlett, B.S.; Stadtman, E.R. Protein Oxidation in Aging, Disease, and Oxidative Stress. J. Biol. Chem. 1997, 272, 20313–20316. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  69. Dean, R.T.; Fu, S.; Stocker, R.; Davies, M.J. Biochemistry and pathology of radical-mediated protein oxidation. Biochem. J. 1997, 324, 1–18. [Google Scholar] [CrossRef] [Green Version]
  70. Rhoads, D.M.; Umbach, A.L.; Subbaiah, C.C.; Siedow, J.N. Mitochondrial Reactive Oxygen Species. Contribution to Oxidative Stress and Interorganellar Signaling. Plant Physiol. 2006, 141, 357–366. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  71. Davies, M.J. The oxidative environment and protein damage. Biochim. Biophys. Acta Proteins Proteom. 2005, 1703, 93–109. [Google Scholar] [CrossRef]
  72. Ghezzi, P.; Bonetto, V. Redox proteomics: Identification of oxidatively modified proteins. Proteomics 2003, 3, 1145–1153. [Google Scholar] [CrossRef]
  73. Gustavsson, N.; Kokke, B.P.; Härndahl, U.; Silow, M.; Bechtold, U.; Poghosyan, Z.; Murphy, D.; Boelens, W.C.; Sundby, C. A peptide methionine sulfoxide reductase highly expressed in photosynthetic tissue in Arabidopsis thaliana can protect the chaperone-like activity of a chloroplast-localized small heat shock protein. Plant J. 2002, 29, 545–553. [Google Scholar] [CrossRef] [PubMed]
  74. Levine, R.L.; Mosoni, L.; Berlett, B.S.; Stadtman, E.R. Methionine residues as endogenous antioxidants in proteins. Proc. Natl. Acad. Sci. USA 1996, 93, 15036–15040. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  75. Smirnoff, N.; Cumbes, Q.J. Hydroxyl radical scavenging activity of compatible solutes. Phytochemistry 1989, 28, 1057–1060. [Google Scholar] [CrossRef]
  76. Møller, I.M.; Jensen, P.E.; Hansson, A. Oxidative modifications to cellular components in plants. Annu. Rev. Plant Biol. 2007, 58, 459–481. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  77. Buchanan-Wollaston, V.; Page, T.; Harrison, E.; Breeze, E.; Pyung, O.L.; Hong, G.N.; Lin, J.F.; Wu, S.H.; Swidzinski, J.; Ishizaki, K.; et al. Comparative transcriptome analysis reveals significant differences in gene expression and signalling pathways between developmental and dark/starvation-induced senescence in Arabidopsis. Plant J. 2005, 42, 567–585. [Google Scholar] [CrossRef]
  78. Rey, P.; Bécuwe, N.; Barrault, M.B.; Rumeau, D.; Havaux, M.; Biteau, B.; Toledano, M.B. The Arabidopsis thaliana sulfiredoxin is a plastidic cysteine-sulfinic acid reductase involved in the photooxidative stress response. Plant J. 2007, 49, 505–514. [Google Scholar] [CrossRef]
  79. Zaffagnini, M.; Bedhomme, M.; Groni, H.; Marchand, C.H.; Puppo, C.; Gontero, B.; Cassier-Chauvat, C.; Decottignies, P.; Lemaire, S.D. Glutathionylation in the Photosynthetic Model Organism Chlamydomonas reinhardtii: A Proteomic Survey. Mol. Cell. Proteom. 2012, 11, M111.014142. [Google Scholar] [CrossRef] [Green Version]
  80. Yu, M.; Lamattina, L.; Spoel, S.H.; Loake, G.J. Nitric oxide function in plant biology: A redox cue in deconvolution. New Phytol. 2014, 202, 1142–1156. [Google Scholar] [CrossRef]
  81. Navrot, N.; Finnie, C.; Svensson, B. Plant redox proteomics. J. Proteom. 2011, 74, 1450–1462. [Google Scholar] [CrossRef] [PubMed]
  82. Wang, Y.; Loake, G.J.; Chu, C.; Levine, A. Cross-talk of nitric oxide and reactive oxygen species in plant programed cell death. Front. Plant Sci. 2013, 4, 314. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  83. Trapet, P.; Kulik, A.; Lamotte, O.; Jeandroz, S.; Bourque, S.; Nicolas-Francès, V.; Rosnoblet, C.; Besson-Bard, A.; Wendehenne, D. NO signaling in plant immunity: A tale of messengers. Phytochemistry 2015, 112, 72–79. [Google Scholar] [CrossRef] [PubMed]
  84. Costa, N.J.; Dahm, C.C.; Hurrell, F.; Taylor, E.R.; Murphy, M.P. Interactions of Mitochondrial Thiols with Nitric Oxide. Antioxid. Redox Signal. 2003, 5, 291–305. [Google Scholar] [CrossRef]
  85. Dahm, C.C.; Moore, K.; Murphy, M.P. Persistent S-nitrosation of complex I and other mitochondrial membrane proteins by S-nitrosothiols but not nitric oxide or peroxynitrite: Implications for the interaction of nitric oxide with mitochondria. J. Biol. Chem. 2006, 281, 10056–10065. [Google Scholar] [CrossRef] [Green Version]
  86. Cuevasanta, E.; Lange, M.; Bonanata, J.; Laura Coitiñ, E.; Ferrer-Sueta, G.; Filipovic, M.R.; Alvarez, B. Reaction of Hydrogen Sulfide with Disulfide and Sulfenic Acid to Form the Strongly Nucleophilic Persulfide. J. Biol. Chem. 2015, 290, 26866–26880. [Google Scholar] [CrossRef] [Green Version]
  87. Aroca, A.; Schneider, M.; Scheibe, R.; Gotor, C.; Romero, L.C. Hydrogen Sulfide Regulates the Cytosolic/Nuclear Partitioning of Glyceraldehyde-3-Phosphate Dehydrogenase by Enhancing its Nuclear Localization. Plant Cell Physiol. 2017, 58, 983–992. [Google Scholar] [CrossRef]
  88. Aroca, A.; Gotor, C.; Romero, L.C. Hydrogen Sulfide Signaling in Plants: Emerging Roles of Protein Persulfidation. Front. Plant Sci. 2018, 9, 1369. [Google Scholar] [CrossRef] [Green Version]
  89. Shen, J.; Zhang, J.; Zhou, M.; Zhou, H.; Cui, B.; Gotor, C.; Romero, L.C.; Fu, L.; Yang, J.; Foyer, C.H.; et al. Persulfidation-based modification of cysteine desulfhydrase and the NADPH oxidase RBOHD controls guard cell abscisic acid signaling. Plant Cell 2020, 32, 1000–1017. [Google Scholar] [CrossRef] [PubMed]
  90. Stadtman, E.R. Metal ion-catalyzed oxidation of proteins: Biochemical mechanism and biological consequences. Free Radic. Biol. Med. 1990, 9, 315–325. [Google Scholar] [CrossRef] [Green Version]
  91. Colombo, G.; Clerici, M.; Garavaglia, M.E.; Giustarini, D.; Rossi, R.; Milzani, A.; Dalle-Donne, I. A step-by-step protocol for assaying protein carbonylation in biological samples. J. Chromatogr. B Anal. Technol. Biomed. Life Sci. 2016, 1019, 178–190. [Google Scholar] [CrossRef] [PubMed]
  92. Wong, C.; Suzuki, Y. Protein Carbonylation Signaling in Pulmonary Hypertension. Am. Thorac. Soc. Int. Conf. 2009, A2482. [Google Scholar] [CrossRef]
  93. Fedorova, M. Diversity of Protein Carbonylation Pathways. Protein Carbonylation 2017, 48–82. [Google Scholar] [CrossRef]
  94. Biswas, M.S.; Terada, R.; Mano, J. Inactivation of carbonyl-detoxifying enzymes by H2O2 is a trigger to increase carbonyl load for initiating programmed cell death in plants. Antioxidants 2020, 9, 141. [Google Scholar] [CrossRef] [Green Version]
  95. Requena, J.R.; Levine, R.L.; Stadtman, E.R. Recent advances in the analysis of oxidized proteins Review Article. Amino Acids 2003, 25, 221–226. [Google Scholar] [CrossRef] [PubMed]
  96. Jung, T.; Höhn, A.; Grune, T. The proteasome and the degradation of oxidized proteins: Part II—Protein oxidation and proteasomal degradation. Redox Biol. 2014, 2, 99–104. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  97. Maisonneuve, E.; Ducret, A.; Khoueiry, P.; Lignon, S.; Longhi, S.; Talla, E.; Dukan, S. Rules governing selective protein carbonylation. PLoS ONE 2009, 4, e7269. [Google Scholar] [CrossRef]
  98. Møller, I.M.; Rogowska-Wrzesinska, A.; Rao, R.S.P. Protein carbonylation and metal-catalyzed protein oxidation in a cellular perspective. J. Proteom. 2011, 74, 2228–2242. [Google Scholar] [CrossRef]
  99. Valentine, J.S.; Gralla, E.B. Introduction: Reactive Oxygen Species Special Feature. Proc. Natl. Acad. Sci. USA 2008, 105, 8178. [Google Scholar] [CrossRef] [Green Version]
  100. Requena, J.R.; Groth, D.; Legname, G.; Stadtman, E.R.; Prusiner, S.B.; Levine, R.L. Copper-catalyzed oxidation of the recombinant SHa(29-231) prion protein. Proc. Natl. Acad. Sci. USA 2001, 98, 7170–7175. [Google Scholar] [CrossRef] [Green Version]
  101. Aldini, G.; Dalle-Donne, I.; Facino, R.M.; Milzani, A.; Carini, M. Intervention strategies to inhibit protein carbonylation by lipoxidation-derived reactive carbonyls. Med. Res. Rev. 2007, 27, 817–868. [Google Scholar] [CrossRef] [PubMed]
  102. Perluigi, M.; Coccia, R.; Allan Butterfield, D. 4-hydroxy-2-nonenal, a reactive product of lipid peroxidation, and neurodegenerative diseases: A toxic combination illuminated by redox proteomics studies. Antioxidants Redox Signal. 2012, 17, 1590–1609. [Google Scholar] [CrossRef] [Green Version]
  103. West, J.D.; Marnett, L.J. Endogenous reactive intermediates as modulators of cell signaling and cell death. Chem. Res. Toxicol. 2006, 19, 173–194. [Google Scholar] [CrossRef]
  104. Mano, J. Reactive carbonyl species: Their production from lipid peroxides, action in environmental stress, and the detoxification mechanism. Plant Physiol. Biochem. 2012, 59, 90–97. [Google Scholar] [CrossRef] [PubMed]
  105. Milic, I.; Kipping, M.; Hoffmann, R.; Fedorova, M. Separation and characterization of oxidized isomeric lipid-peptide adducts by ion mobility mass spectrometry. J. Mass Spectrom. 2015, 50, 1386–1392. [Google Scholar] [CrossRef] [PubMed]
  106. Rogowska-Wrzesinska, A.; Wojdyla, K.; Nedić, O.; Baron, C.P.; Griffiths, H.R. Analysis of protein carbonylation—Pitfalls and promise in commonly used methods. Free Radic. Res. 2014, 48, 1145–1162. [Google Scholar] [CrossRef] [Green Version]
  107. Mano, J.; Tokushige, K.; Mizoguchi, H.; Fujii, H.; Khorobrykh, S. Accumulation of lipid peroxide-derived, toxic α, β-unsaturated aldehydes (E)-2-pentenal, acrolein and (E)-2-hexenal in leaves under photoinhibitory illumination. Plant Biotechnol. 2010, 27, 193–197. [Google Scholar] [CrossRef] [Green Version]
  108. Kristensen, B.K.; Askerlund, P.; Bykova, N.V.; Egsgaard, H.; Møller, I.M. Identification of oxidised proteins in the matrix of rice leaf mitochondria by immunoprecipitation and two-dimensional liquid chromatography-tandem mass spectrometry. Phytochemistry 2004, 65, 1839–1851. [Google Scholar] [CrossRef]
  109. Aldini, G.; Carini, M.; Yeum, K.-J.; Vistoli, G. Novel molecular approaches for improving enzymatic and nonenzymatic detoxification of 4-hydroxynonenal: Toward the discovery of a novel class of bioactive compounds. Free Radic. Biol. Med. 2014, 69, 145–156. [Google Scholar] [CrossRef]
  110. Chen, Z.H.; Niki, E. 4-Hydroxynonenal (4-HNE) has been widely accepted as an inducer of oxidative stress. Is this the whole truth about it or can 4-HNE also exert protective effects? IUBMB Life 2006, 58, 372–373. [Google Scholar] [CrossRef] [PubMed]
  111. Guéraud, F.; Atalay, M.; Bresgen, N.; Cipak, A.; Eckl, P.M.; Huc, L.; Jouanin, I.; Siems, W.; Uchida, K. Chemistry and biochemistry of lipid peroxidation products. Free Radic. Res. 2010, 44, 1098–1124. [Google Scholar] [CrossRef]
  112. Roede, J.R.; Jones, D.P. Reactive Species and Mitochondrial Dysfunction: Mechanistic Significance of 4-Hydroxynonenal. Environ. Mol. Mutagen. 2010, 51, 380. [Google Scholar] [CrossRef] [Green Version]
  113. Zhao, Y.; Miriyala, S.; Miao, L.; Mitov, M.; Schnell, D.; Dhar, S.; Cai, J.; Klein, J.; Sultana, R.; Butterfield, D.; et al. Redox proteomic identification of HNE-bound mitochondrial proteins in cardiac tissues reveals a systemic effect on energy metabolism after doxorubicin treatment. Free. Radic. Biol. Med. 2014, 72, 55–65. [Google Scholar] [CrossRef] [Green Version]
  114. Traverso, N.; Menini, S.; Maineri, E.P.; Patriarca, S.; Odetti, P.; Cottalasso, D.; Marinari, U.M.; Pronzato, M.A. Malondialdehyde, a Lipoperoxidation-Derived Damage To Proteins. America 2004, 59, 890–895. [Google Scholar] [CrossRef] [Green Version]
  115. Pizzimenti, S.; Ciamporcero, E.; Daga, M.; Pettazzoni, P.; Arcaro, A.; Cetrangolo, G.; Minelli, R.; Dianzani, C.; Lepore, A.; Gentile, F.; et al. Interaction of aldehydes derived from lipid peroxidation and membrane proteins. Front. Physiol. 2013, 4, 242. [Google Scholar] [CrossRef] [Green Version]
  116. Levine, R.L.; Oliver, C.N.; Fulks, R.M.; Stadtman, E.R. Turnover of bacterial glutamine synthetase: Oxidative inactivation precedes proteolysis. Proc. Natl. Acad. Sci. USA 1981, 78, 2120–2124. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  117. Grune, T.; Catalgol, B.; Licht, A.; Ermak, G.; Pickering, A.M.; Ngo, J.K.; Davies, K.J.A. HSP70 mediates dissociation and reassociation of the 26S proteasome during adaptation to oxidative stress. Free Radic. Biol. Med. 2011, 51, 1355–1364. [Google Scholar] [CrossRef] [Green Version]
  118. Gili, B.-N.; Sharon, M. Regulating the 20S Proteasome Ubiquitin-Independent Degradation Pathway. Biomolecules 2014, 4, 862–884. [Google Scholar] [CrossRef] [Green Version]
  119. Yu, F.; Xie, Q. Non-26S Proteasome Endomembrane Trafficking Pathways in ABA Signaling. Trends Plant Sci. 2017, 22, 976–985. [Google Scholar] [CrossRef]
  120. Signorelli, S.; Tarkowski, Ł.P.; Van Den Ende, W.; Bassham, D.C. Linking Autophagy to Abiotic and Biotic Stress Responses. Trends Plant Sci. 2019, 24, 413–430. [Google Scholar] [CrossRef] [Green Version]
  121. Avin-Wittenberg, T.; Bajdzienko, K.; Wittenberg, G.; Alseekh, S.; Tohge, T.; Bock, R.; Giavalisco, P.; Fernie, A.R. Global Analysis of the Role of Autophagy in Cellular Metabolism and Energy Homeostasis in Arabidopsis Seedlings under Carbon Starvation. Plant Cell 2015, 27, 306–322. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  122. Xiong, Y.; Contento, A.L.; Bassham, D.C. Disruption of Autophagy Results in Constitutive Oxidative Stress in Arabidopsis. Autophagy 2007, 3, 257–258. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  123. Rachakonda, G.; Xiong, Y.; Sekhar, K.R.; Stamer, S.L.; Liebler, D.C.; Freeman, M.L. Covalent Modification at Cys151 Dissociates the Electrophile Sensor Keap1 from the Ubiquitin Ligase CUL3. Chem. Res. Toxicol. 2008, 21, 705–710. [Google Scholar] [CrossRef] [Green Version]
  124. Farré, J.-C.; Subramani, S. Mechanistic insights into selective autophagy pathways: Lessons from yeast. Nat. Rev. Mol. Cell Biol. 2016, 17, 537–552. [Google Scholar] [CrossRef] [PubMed]
  125. Svenning, S.; Lamark, T.; Krause, K.; Johansen, T. Plant NBR1 is a selective autophagy substrate and a functional hybrid of the mammalian autophagic adapters NBR1 and p62/SQSTM1. Autophagy 2011, 7, 993–1010. [Google Scholar] [CrossRef] [PubMed]
  126. Zhou, J.; Wang, J.; Cheng, Y.; Chi, Y.-J.; Fan, B. NBR1-Mediated Selective Autophagy Targets Insoluble Ubiquitinated Protein Aggregates in Plant Stress Responses. PLoS Genet. 2013, 9, 1003196. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  127. Carrera, E.; Holman, T.; Medhurst, A.; Dietrich, D.; Footitt, S.; Theodoulou, F.L.; Holdsworth, M.J. Seed after-ripening is a discrete developmental pathway associated with specific gene networks in Arabidopsis. Plant J. 2008, 53, 214–224. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  128. Holdsworth, M.J.; Bentsink, L.; Soppe, W.J.J. Molecular networks regulating Arabidopsis seed maturation, after-ripening, dormancy and germination. New Phytol. 2008, 179, 33–54. [Google Scholar] [CrossRef] [Green Version]
  129. Oracz, K.; Bouteau, H.E.M.; Farrant, J.M.; Cooper, K.; Belghazi, M.; Job, C.; Job, D.; Corbineau, F.; Bailly, C. ROS production and protein oxidation as a novel mechanism for seed dormancy alleviation. Plant J. 2007, 50, 452–465. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  130. Leymarie, J.; Vitkauskaité, G.; Hoang, H.H.; Gendreau, E.; Chazoule, V.; Meimoun, P.; Corbineau, F.; El-Maarouf-Bouteau, H.; Bailly, C. Role of Reactive Oxygen Species in the Regulation of Arabidopsis Seed Dormancy. Plant Cell Physiol. 2012, 53, 96–106. [Google Scholar] [CrossRef] [Green Version]
  131. Müller, K.; Carstens, A.C.; Linkies, A.; Torres, M.A.; Leubner-Metzger, G. The NADPH-oxidase AtrbohB plays a role in Arabidopsis seed after-ripening. New Phytol. 2009, 184, 885–897. [Google Scholar] [CrossRef] [Green Version]
  132. Tesnier, K.; Strookman-Donkers, H.M.; Pijlen, J.G.V.; Geest, A.V.D.; Bino, R.; Groot, S. A controlled deterioration test for Arabidopsis thaliana reveals genetic variation in seed quality. Seed Sci. Technol. 2002, 30, 149–166. [Google Scholar]
  133. Skirycz, A.; De Bodt, S.; Obata, T.; De Clercq, I.; Claeys, H.; De Rycke, R.; Andriankaja, M.; Van Aken, O.; Van Breusegem, F.; Fernie, A.R.; et al. Developmental Stage Specificity and the Role of Mitochondrial Metabolism in the Response of Arabidopsis Leaves to Prolonged Mild Osmotic Stress. Plant Physiol. 2010, 152, 226–244. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  134. Seki, M.; Umezawa, T.; Urano, K.; Shinozaki, K. Regulatory metabolic networks in drought stress responses. Curr. Opin. Plant Biol. 2007, 10, 296–302. [Google Scholar] [CrossRef]
  135. Contento, A.L.; Kim, S.J.; Bassham, D.C. Transcriptome profiling of the response of arabidopsis suspension culture cells to Suc starvation. Plant Physiol. 2004, 135, 2330–2347. [Google Scholar] [CrossRef] [Green Version]
  136. Buchanan, B.B.; Balmer, Y. Redox regulation: A broadening horizon. Annu. Rev. Plant Biol. 2005, 56, 187–220. [Google Scholar] [CrossRef]
  137. Ishizaki, K.; Larson, T.R.; Schauer, N.; Fernie, A.R.; Graham, I.A.; Leaver, C.J. The critical role of Arabidopsis electron-transfer flavoprotein:ubiquinone oxidoreductase during dark-induced starvation. Plant Cell 2005, 17, 2587–2600. [Google Scholar] [CrossRef] [Green Version]
  138. Brouquisse, R.; Gaudillère, J.P.; Raymond, P. Induction of a carbon-starvation-related proteolysis in whole maize plants submitted to light/dark cycles and to extended darkness. Plant Physiol. 1998, 117, 1281–1291. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  139. Desnues, B.; Cuny, C.; Grégori, G.; Dukan, S.; Aguilaniu, H.; Nyström, T. Differential oxidative damage and expression of stress defence regulons in culturable and non-culturable Escherichia coli cells. EMBO Rep. 2003, 4, 400–404. [Google Scholar] [CrossRef] [Green Version]
  140. Noda, Y.; Berlett, B.S.; Stadtman, E.R.; Aponte, A.; Morgan, M.; Shen, R.F. Identification of enzymes and regulatory proteins in Escherichia coli that are oxidized under nitrogen, carbon, or phosphate starvation. Proc. Natl. Acad. Sci. USA 2007, 104, 18456–18460. [Google Scholar] [CrossRef] [Green Version]
  141. Fredriksson, Å.; Ballesteros, M.; Dukan, S.; Nyström, T. Defense against Protein Carbonylation by DnaK/DnaJ and Proteases of the Heat Shock Regulon. J. Bacteriol. 2005, 187, 4207–4213. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  142. Mukherjee, K.; Chio, T.I.; Gu, H.; Banerjee, A.; Sorrentino, A.M.; Sackett, D.L.; Bane, S.L. Benzocoumarin Hydrazine: A Large Stokes Shift Fluorogenic Sensor for Detecting Carbonyls in Isolated Biomolecules and in Live Cells. ACS Sens. 2017, 2, 128–134. [Google Scholar] [CrossRef]
  143. Basset, G.; Raymond, P.; Malek, L.; Brouquisse, R. Changes in the expression and the enzymic properties of the 20S proteasome in sugar-starved maize roots. Evidence for an in vivo oxidation of the proteasome. Plant Physiol. 2002, 128, 1149–1162. [Google Scholar] [CrossRef] [Green Version]
  144. Kumsta, C.; Thamsen, M.; Jakob, U. Effects of Oxidative Stress on Behavior, Physiology, and the Redox Thiol Proteome of Caenorhabditis elegans. Antioxid. Redox Signal. 2011, 14, 1023–1037. [Google Scholar] [CrossRef] [Green Version]
  145. Winter, J.; Linke, K.; Jatzek, A.; Jakob, U. Severe oxidative stress causes inactivation of DnaK and activation of the redox-regulated chaperone Hsp33. Mol. Cell 2005, 17, 381–392. [Google Scholar] [CrossRef]
  146. Huang, Q.; Wang, H.; Perry, S.W.; Figueiredo-Pereira, M.E. Negative Regulation of 26S Proteasome Stability via Calpain-mediated Cleavage of Rpn10 Subunit upon Mitochondrial Dysfunction in Neurons *. J. Biol. Chem. 2013, 288, 12161–12174. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  147. Shringarpure, R.; Grune, T.; Mehlhase, J.; Davies, K.J.A. Ubiquitin conjugation is not required for the degradation of oxidized proteins by proteasome. J. Biol. Chem. 2003, 278, 311–318. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  148. Reichmann, D.; Voth, W.; Jakob, U. Maintaining a Healthy Proteome during Oxidative Stress. Mol. Cell 2018, 69, 203–213. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  149. Imai, J.; Maruya, M.; Yashiroda, H.; Yahara, I.; Tanaka, K. The molecular chaperone Hsp90 plays a role in the assembly and maintenance of the 26S proteasome. EMBO J. 2003, 22, 3557–3567. [Google Scholar] [CrossRef] [Green Version]
  150. Cabiscol, E.; Tamarit, J.; Ros, J. Protein carbonylation: Proteomics, specificity and relevance to aging. Mass Spectrom. Rev. 2014, 33, 21–48. [Google Scholar] [CrossRef] [PubMed]
  151. Deshmukh, F.K.; Yaffe, D.; Olshina, M.A.; Gili, B.-N.; Sharon, M. The Contribution of the 20S Proteasome to Proteostasis. Biomolecules 2019, 9, 190. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  152. Kurepa, J.; Toh-E, A.; Smalle, J.A. 26S proteasome regulatory particle mutants have increased oxidative stress tolerance. Plant J. 2008, 53, 102–114. [Google Scholar] [CrossRef] [PubMed]
  153. Kurepa, J.; Wang, S.; Li, Y.; Smalle, J. Proteasome regulation, plant growth and stress tolerance. Plant Signal. Behav. 2009, 4, 924–927. [Google Scholar] [CrossRef] [Green Version]
  154. Mongkolsuk, S.; Helmann, J.D. Regulation of inducible peroxide stress responses. Mol. Microbiol. 2002, 45, 9–15. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  155. Storz, G.; Imlay, J.A. Oxidative stress. Curr. Opin. Microbiol. 1999, 2, 188–194. [Google Scholar] [CrossRef]
  156. Carmel-Harel, O.; Storz, G. Roles of the Glutathione- and Thioredoxin-Dependent Reduction Systems in the Escherichia Coli and Saccharomyces Cerevisiae Responses to Oxidative Stress. Annu. Rev. Microbiol. 2000, 54, 439–461. [Google Scholar] [CrossRef]
  157. Zheng, M.; Storz, G. Redox sensing by prokaryotic transcription factors. Biochem. Pharmacol. 2000, 59, 1–6. [Google Scholar] [CrossRef]
  158. Helmann, J.D.; Wu, M.F.W.; Gaballa, A.; Kobel, P.A.; Morshedi, M.M.; Fawcett, P.; Paddon, C. The global transcriptional response of Bacillus subtilis to peroxide stress is coordinated by three transcription factors. J. Bacteriol. 2003, 185, 243–253. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  159. Bsat, N.; Herbig, A.; Casillas-Martinez, L.; Setlow, P.; Helmann, J.D. Bacillus subtilis contains multiple Fur homologues: Identification of the iron uptake (Fur) and peroxide regulon (PerR) repressors. Mol. Microbiol. 1998, 29, 189–198. [Google Scholar] [CrossRef] [PubMed]
  160. Chen, L.; Keramati, L.; Helmann, J.D. Coordinate regulation of Bacillus subtilis peroxide stress genes by hydrogen peroxide and metal ions. Proc. Natl. Acad. Sci. USA 1995, 92, 8190–8194. [Google Scholar] [CrossRef] [Green Version]
  161. Kiley, P.J.; Storz, G. Exploiting Thiol Modifications. PLoS Biol. 2004, 2, e400. [Google Scholar] [CrossRef]
  162. Herbig, A.F.; Helmann, J.D. Roles of metal ions and hydrogen peroxide in modulating the interaction of the Bacillus subtilis PerR peroxide regulon repressor with operator DNA. Mol. Microbiol. 2001, 41, 849–859. [Google Scholar] [CrossRef]
  163. Ortiz de Orué Lucana, D.; Wedderhoff, I.; Groves, M.R. ROS-Mediated Signalling in Bacteria: Zinc-Containing Cys-X-X-Cys Redox Centres and Iron-Based Oxidative Stress. J. Signal Transduct. 2012, 2012, 1–9. [Google Scholar] [CrossRef] [Green Version]
  164. Lee, J.W.; Helmann, J.D. The PerR transcription factor senses H2O2 by metal-catalysed histidine oxidation. Nature 2006, 440, 363–367. [Google Scholar] [CrossRef] [PubMed]
  165. Curtis, J.M.; Hahn, W.S.; Long, E.K.; Burrill, J.S.; Arriaga, E.A.; Bernlohr, D.A. Protein carbonylation and metabolic control systems. Trends Endocrinol. Metab. 2012, 23, 399–406. [Google Scholar] [CrossRef] [Green Version]
  166. Hassoun, P.M.; Thappa, V.; Landman, M.J.; Fanburg, B.L. Endothelin 1: Mitogenic Activity on Pulmonary Artery Smooth Muscle Cells and Release from Hypoxic Endothelial Cells. Proc. Soc. Exp. Biol. Med. 1992, 199, 165–170. [Google Scholar] [CrossRef] [PubMed]
  167. Janakidevi, K.; Fisher, M.A.; Del Vecchio, P.J.; Tiruppathi, C.; Figge, J.; Malik, A.B. Endothelin-1 stimulates DNA synthesis and proliferation of pulmonary artery smooth muscle cells. Am. J. Physiol. Cell Physiol. 1992, 263, C1295–C1301. [Google Scholar] [CrossRef]
  168. Wong, C.M.; Marcocci, L.; Liu, L.; Suzuki, Y.J. Cell signaling by protein carbonylation and decarbonylation. Antioxidants Redox Signal. 2010, 12, 393–404. [Google Scholar] [CrossRef] [Green Version]
  169. Wedgwood, S.; Black, S.M. Role of Reactive Oxygen Species in Vascular Remodeling Associated with Pulmonary Hypertension. Antioxidants Redox Signal. 2003, 5, 759–769. [Google Scholar] [CrossRef]
  170. Wedgwood, S.; Dettman, R.W.; Black, S.M. ET-1 stimulates pulmonary arterial smooth muscle cell proliferation via induction of reactive oxygen species. Am. J. Physiol. Lung Cell. Mol. Physiol. 2001, 281, L1058–L1067. [Google Scholar] [CrossRef] [Green Version]
  171. Davie, N.; Haleen, S.J.; Upton, P.D.; Polak, J.M.; Yacoub, M.H.; Morrell, N.W.; Wharton, J. ETA and ETB receptors modulate the proliferation of human pulmonary artery smooth muscle cells. Am. J. Respir. Crit. Care Med. 2002, 165, 398–405. [Google Scholar] [CrossRef]
  172. Miyauchi, T.; Yorikane, R.; Sakai, S.; Sakurai, T.; Okada, M.; Nishikibe, M.; Yano, M.; Yamaguchi, I.; Sugishita, Y.; Goto, K. Contribution of endogenous endothelin-1 to the progression of cardiopulmonary alterations in rats with monocrotaline-induced pulmonary hypertension. Circ. Res. 1993, 73, 887–897. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  173. Zamora, M.R.; Stelzner, T.J.; Webb, S.; Panos, R.J.; Ruff, L.J.; Dempsey, E.C. Overexpression of endothelin-1 and enhanced growth of pulmonary artery smooth muscle cells from fawn-hooded rats. Am. J. Physiol. Lung Cell. Mol. Physiol. 1996, 270, L101–L109. [Google Scholar] [CrossRef] [PubMed]
  174. Wong, C.M.; Cheema, A.K.; Zhang, L.; Suzuki, Y.J. Protein carbonylation as a novel mechanism in redox signaling. Circ. Res. 2008, 102, 310–318. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  175. Zhu, H.; Jia, Z.; Zhang, L.; Yamamoto, M.; Misra, H.P.; Trush, M.A.; Li, Y. Antioxidants and Phase 2 Enzymes in Macrophages: Regulation by Nrf2 Signaling and Protection Against Oxidative and Electrophilic Stress. Exp. Biol. Med. 2008, 233, 463–474. [Google Scholar] [CrossRef]
  176. McMahon, M.; Itoh, K.; Yamamoto, M.; Hayes, J.D. Keap1-dependent proteasomal degradation of transcription factor Nrf2 contributes to the negative regulation of antioxidant response element-driven gene expression. J. Biol. Chem. 2003, 278, 21592–21600. [Google Scholar] [CrossRef] [Green Version]
  177. Fang, J.; Holmgren, A. Inhibition of thioredoxin and thioredoxin reductase by 4-hydroxy-2-nonenal in vitro and in vivo. J. Am. Chem. Soc. 2006, 128, 1879–1885. [Google Scholar] [CrossRef]
  178. Sharma, R.; Sharma, A.; Dwivedi, S.; Zimniak, P.; Awasthi, S.; Awasthi, Y.C. 4-Hydroxynonenal self-limits Fas-mediated DISC-independent apoptosis by promoting export of Daxx from the nucleus to the cytosol and its binding to Fas. Biochemistry 2008, 47, 143–156. [Google Scholar] [CrossRef] [Green Version]
  179. Fujino, G.; Noguchi, T.; Matsuzawa, A.; Yamauchi, S.; Saitoh, M.; Takeda, K.; Ichijo, H. Thioredoxin and TRAF Family Proteins Regulate Reactive Oxygen Species-Dependent Activation of ASK1 through Reciprocal Modulation of the N-Terminal Homophilic Interaction of ASK1. Mol. Cell. Biol. 2007, 27, 8152–8163. [Google Scholar] [CrossRef] [Green Version]
  180. Bai, X.; Yang, L.; Tian, M.; Chen, J.; Shi, J. Nitric Oxide Enhances Desiccation Tolerance of Recalcitrant Antiaris toxicaria Seeds via Protein S-Nitrosylation and Carbonylation. PLoS ONE 2011, 6, 20714. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  181. Islam, M.M.; Ye, W.; Matsushima, D.; Rhaman, M.S.; Munemasa, S.; Okuma, E.; Nakamura, Y.; Biswas, M.S.; Mano, J.; Murata, Y. Reactive carbonyl species function as signal mediators downstream of H2O2 production and regulate [Ca2+]cyt elevation in ABA signal pathway in Arabidopsis guard cells. Plant Cell Physiol. 2019, 60, 1146–1159. [Google Scholar] [CrossRef]
  182. Pel, Z.M.; Murata, Y.; Benning, G.; Thomine, S.; Klüsener, B.; Allen, G.J.; Grill, E.; Schroeder, J.I. Calcium channels activated by hydrogen peroxide mediate abscisic acid signalling in guard cells. Nature 2000, 406, 731–734. [Google Scholar] [CrossRef]
  183. Kwak, J.M.; Mori, I.C.; Pei, Z.M.; Leonhard, N.; Angel Torres, M.; Dangl, J.L.; Bloom, R.E.; Bodde, S.; Jones, J.D.G.; Schroeder, J.I. NADPH oxidase AtrbohD and AtrbohF genes function in ROS-dependent ABA signaling in arabidopsis. EMBO J. 2003, 22, 2623–2633. [Google Scholar] [CrossRef]
  184. Suhita, D.; Raghavendra, A.S.; Kwak, J.M.; Vavasseur, A. Cytoplasmic alkalization precedes reactive oxygen species production during methyl jasmonate- and abscisic acid-induced stomatal closure. Plant Physiol. 2004, 134, 1536–1545. [Google Scholar] [CrossRef] [Green Version]
  185. Munemasa, S.; Oda, K.; Watanabe-Sugimoto, M.; Nakamura, Y.; Shimoishi, Y.; Murata, Y. The coronatine-insensitive 1 mutation reveals the hormonal signaling interaction between abscisic acid and methyl jasmonate in Arabidopsis guard cells. Specific impairment of ion channel activation and second messenger production. Plant Physiol. 2007, 143, 1398–1407. [Google Scholar] [CrossRef] [Green Version]
  186. Islam, M.M.; Hossain, M.A.; Jannat, R.; Munemasa, S.; Nakamura, Y.; Mori, I.C.; Murata, Y. Cytosolic alkalization and cytosolic calcium oscillation in Arabidopsis guard cells Response to ABA and MeJA. Plant Cell Physiol. 2010, 51, 1721–1730. [Google Scholar] [CrossRef]
  187. Akter, N.; Sobahan, M.A.; Uraji, M.; Ye, W.; Hossain, M.A.; Mori, I.C.; Nakamura, Y.; Murata, Y. Effects of depletion of glutathione on abscisic acidand methyl jasmonate-induced stomatal closure in arabidopsis thaliana. Biosci. Biotechnol. Biochem. 2012, 76, 2032–2037. [Google Scholar] [CrossRef] [Green Version]
  188. Akter, N.; Okuma, E.; Sobahan, M.A.; Uraji, M.; Munemasa, S.; Nakamura, Y.; Mori, I.C.; Murata, Y. Negative Regulation of Methyl Jasmonate-Induced Stomatal Closure by Glutathione in Arabidopsis. J. Plant Growth Regul. 2013, 32, 208–215. [Google Scholar] [CrossRef]
  189. McAinsh, M.R.; Brownlee, C.; Hetherington, A.M. Abscisic acid-induced elevation of guard cell cytosolic Ca2+ precedes stomatal closure. Nature 1990, 343, 186–188. [Google Scholar] [CrossRef] [Green Version]
  190. McAinsh, M.R.; Brownlee, C.; Hetherington, A.M. Visualizing Changes in Cytosolic-Free Ca2+ during the Response of Stomatal Guard Cells to Abscisic Acid. Plant Cell 1992, 4, 1113–1122. [Google Scholar] [CrossRef]
  191. Staxén, I.; Pical, C.; Montgomery, L.T.; Gray, J.E.; Hetherington, A.M.; Mcainsh, M.R. Abscisic acid induces oscillations in guard-cell cytosolic free calcium that involve phosphoinositide-specific phospholipase C. Proc. Natl. Acad. Sci. USA 1999, 96, 1779–1784. [Google Scholar] [CrossRef] [Green Version]
  192. Murata, Y.; Pei, Z.-M.; Mori, I.C.; Schroeder, J. Abscisic Acid Activation of Plasma Membrane Ca2+ Channels in Guard Cells Requires Cytosolic NAD(P)H and Is Differentially Disrupted Upstream and Downstream of Reactive Oxygen Species Production in abi1-1 and abi2-1 Protein Phosphatase 2C Mutants. Plant Cell 2001, 13, 2513–2523. [Google Scholar] [CrossRef] [Green Version]
  193. Munemasa, S.; Muroyama, D.; Nagahashi, H.; Nakamura, Y.; Mori, I.C.; Murata, Y. Regulation of reactive oxygen species-mediated abscisic acid signaling in guard cells and drought tolerance by glutathione. Front. Plant Sci. 2013, 4, 472. [Google Scholar] [CrossRef] [Green Version]
  194. Rodríguez, A.A.; Grunberg, K.A.; Taleisnik, E.L. Reactive oxygen species in the elongation zone of maize leaves are necessary for leaf extension. Plant Physiol. 2002, 129, 1627–1632. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  195. Ros Barceló, A. Xylem parenchyma cells deliver the H2O2 necessary for lignification in differentiating xylem vessels. Planta 2005, 220, 747–756. [Google Scholar] [CrossRef]
  196. Li, S.; Xue, L.; Xu, S.; Feng, H.; An, L. Hydrogen peroxide involvement in formation and development of adventitious roots in cucumber. Plant Growth Regul. 2007, 52, 173–180. [Google Scholar] [CrossRef]
  197. Foreman, J.; Demidchik, V.; Bothwell, J.H.F.; Mylona, P.; Miedema, H.; Angel Torres, M.; Linstead, P.; Costa, S.; Brownlee, C.; Jones, J.D.G.; et al. Reactive oxygen species produced by NADPH oxidase regulate plant cell growth. Nature 2003, 422, 442–446. [Google Scholar] [CrossRef]
  198. Su, G.-X.; Zhang, W.-H.; Liu, Y.-L. Involvement of Hydrogen Peroxide Generated by Polyamine Oxidative Degradation in the Development of Lateral Roots in Soybean. J. Integr. Plant Biol. 2006, 48, 426–432. [Google Scholar] [CrossRef]
  199. Chen, Y.H.; Chao, Y.Y.; Hsu, Y.Y.; Kao, C.H. Heme oxygenase is involved in H2O2-induced lateral root formation in apocynin-treated rice. Plant Cell Rep. 2013, 32, 219–226. [Google Scholar] [CrossRef]
  200. Montillet, J.-L.; Leonhardt, N.; Mondy, S.; Tranchimand, S.; Rumeau, D.; Boudsocq, M.; Garcia, A.V.; Douki, T.; Bigeard, J.; Laurière, C.; et al. An Abscisic Acid-Independent Oxylipin Pathway Controls Stomatal Closure and Immune Defense in Arabidopsis. PLoS Biol. 2013, 11, e1001513. [Google Scholar] [CrossRef] [Green Version]
  201. Li, N.; Sun, L.; Zhang, L.; Song, Y.; Hu, P.; Li, C.; Hao, F.S. AtrbohD and AtrbohF negatively regulate lateral root development by changing the localized accumulation of superoxide in primary roots of Arabidopsis. Planta 2015, 241, 591–602. [Google Scholar] [CrossRef]
  202. Orman-Ligeza, B.; Parizot, B.; de Rycke, R.; Fernandez, A.; Himschoot, E.; van Breusegem, F.; Bennett, M.J.; Périlleux, C.; Beeckman, T.; Draye, X. RBOH-mediated ROS production facilitates lateral root emergence in Arabidopsis. Development 2016, 143, 3328–3339. [Google Scholar] [CrossRef] [Green Version]
  203. Kim, M.; McLoughlin, F.; Basha, E.; Vierling, E. Assessing Plant Tolerance to Acute Heat Stress. Bio-Protocol 2017, 7, 1–12. [Google Scholar] [CrossRef]
  204. Ma, F.; Wang, L.; Li, J.; Samma, M.K.; Xie, Y.; Wang, R.; Wang, J.; Zhang, J.; Shen, W. Interaction between HY1 and H2O2 in auxin-induced lateral root formation in Arabidopsis. Plant Mol. Biol. 2014, 85, 49–61. [Google Scholar] [CrossRef] [PubMed]
  205. Yamamoto, T.; Suzuki, T.; Kobayashi, A.; Wakabayashi, J.; Maher, J.; Motohashi, H.; Yamamoto, M. Physiological Significance of Reactive Cysteine Residues of Keap1 in Determining Nrf2 Activity. Mol. Cell. Biol. 2008, 28, 2758–2770. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  206. Zhang, H.; Liu, H.; Iles, K.E.; Liu, R.M.; Postlethwait, E.M.; Laperche, Y.; Forman, H.J. 4-Hydroxynonenal induces rat γ-glutamyl transpeptidase through mitogen-activated protein kinase-mediated electrophile response element/nuclear factor erythroid 2-related factor 2 signaling. Am. J. Respir. Cell Mol. Biol. 2006, 34, 174–181. [Google Scholar] [CrossRef] [Green Version]
  207. Rudolph, T.K.; Freeman, B.A. Transduction of Redox Signaling by Electrophile-Protein Reactions. Sci. Signal. 2009, 2, re7. [Google Scholar] [CrossRef] [Green Version]
  208. Tanou, G.; Job, C.; Rajjou, L.; Arc, E.; Belghazi, M.; Diamantidis, G.; Molassiotis, A.; Job, D. Proteomics reveals the overlapping roles of hydrogen peroxide and nitric oxide in the acclimation of citrus plants to salinity. Plant J. 2009, 60, 795–804. [Google Scholar] [CrossRef]
  209. Tanou, G.; Filippou, P.; Belghazi, M.; Job, D.; Diamantidis, G.; Fotopoulos, V.; Molassiotis, A. Oxidative and nitrosative-based signaling and associated post-translational modifications orchestrate the acclimation of citrus plants to salinity stress. Plant J. 2012, 72, 585–599. [Google Scholar] [CrossRef]
  210. Kakizawa, S.; Shibazaki, M.; Mori, N. Protein oxidation inhibits NO-mediated signaling pathway for synaptic plasticity. Neurobiol. Aging 2012, 33, 535–545. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  211. Krasuska, U.; Ciacka, K.; Ebska, K.D.; Bogatek, R.; Gniazdowska, A. Dormancy alleviation by NO or HCN leading to decline of protein carbonylation levels in apple (Malus domestica Borkh.) embryos. J. Plant Physiol. 2014, 171, 1132–1141. [Google Scholar] [CrossRef]
  212. Galligan, J.J.; Rose, K.L.; Beavers, W.N.; Hill, S.; Tallman, K.A.; Tansey, W.P.; Marnett, L.J. Stable Histone Adduction by 4-Oxo-2-nonenal: A Potential Link between Oxidative Stress and Epigenetics. J. Am. Chem. Soc. 2014, 136, 11864–11866. [Google Scholar] [CrossRef] [Green Version]
  213. Chavez, J.D.; Wu, J.; Bisson, W.; Maier, C.S. Site-specific proteomic analysis of lipoxidation adducts in cardiac mitochondria reveals chemical diversity of 2-alkenal adduction. J. Proteom. 2011, 74, 2417–2429. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  214. Lv, H.; Han, J.; Liu, J.; Zheng, J.; Liu, R. CarSPred: A Computational Tool for Predicting Carbonylation Sites of Human Proteins. PLoS ONE 2014, 9, 111478. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  215. Weng, S.L.; Huang, K.Y.; Kaunang, F.J.; Huang, C.H.; Kao, H.J.; Chang, T.H.; Wang, H.Y.; Lu, J.J.; Lee, T.Y. Investigation and identification of protein carbonylation sites based on position-specific amino acid composition and physicochemical features. BMC Bioinform. 2017, 18, 66. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  216. Prasad Rao, R.S.; Zhang, N.; Xu, D.; MaxMoøller, I. CarbonylDB: A curated data-resource of protein carbonylation sites. Bioinformatics 2018, 34, 2518–2520. [Google Scholar] [CrossRef]
  217. Shyama Prasad Rao, R.; Møller, I.M. Pattern of occurrence and occupancy of carbonylation sites in proteins. Proteomics 2011, 11, 4166–4173. [Google Scholar] [CrossRef]
  218. Yang, J.; Tallman, K.A.; Porter, N.A.; Liebler, D.C. Quantitative chemoproteomics for site-specific analysis of protein alkylation by 4-hydroxy-2-nonenal in cells. Anal. Chem. 2015, 87, 2535–2541. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  219. Levine, R.L.; Williams, J.A.; Stadtman, E.P.; Shacter, E. Carbonyl assays for determination of oxidatively modified proteins. Methods Enzymol. 1994, 233, 346–357. [Google Scholar] [CrossRef] [PubMed]
  220. Reznick, A.Z.; Packer, L. Oxidative damage to proteins: Spectrophotometric method for carbonyl assay. Methods Enzymol. 1994, 233, 357–363. [Google Scholar] [CrossRef]
  221. Chavez, J.; Wu, J.; Han, B.; Chung, W.G.; Maier, C.S. New role for an old probe: Affinity labeling of oxylipid protein conjugates by N′-aminooxymethylcarbonylhydrazino D-biotin. Anal. Chem. 2006, 78, 6847–6854. [Google Scholar] [CrossRef]
  222. Madian, A.G.; Regnier, F.E. Proteomic Identification of Carbonylated Proteins and Their Oxidation Sites. J. Proteome Res. 2010, 9, 3766–3780. [Google Scholar] [CrossRef] [Green Version]
  223. Carini, M.; Aldini, G.; Facino, R.M. Mass spectrometry for detection of 4-hydroxy-trans-2-nonenal (HNE) adducts with peptides and proteins. Mass Spectrom. Rev. 2004, 23, 281–305. [Google Scholar] [CrossRef]
  224. Bollineni, R.C.; Hoffmann, R.; Fedorova, M. Identification of protein carbonylation sites by two-dimensional liquid chromatography in combination with MALDI- and ESI-MS. J. Proteom. 2011, 74, 2338–2350. [Google Scholar] [CrossRef]
  225. Tzeng, S.C.; Maier, C.S. Label-free proteomics assisted by affinity enrichment for elucidating the chemical reactivity of the liver mitochondrial proteome toward adduction by the lipid electrophile 4-hydroxy-2-nonenal (HNE). Front. Chem. 2016, 4, 2. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  226. Matamoros, M.A.; Kim, A.; Peñuelas, M.; Ihling, C.; Griesser, E.; Hoffmann, R.; Fedorova, M.; Frolov, A.; Becana, M. Protein carbonylation and glycation in legume nodules. Plant Physiol. 2018, 177, 1510–1528. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  227. Yin, G.; Xin, X.; Fu, S.; An, M.; Wu, S.; Chen, X.; Zhang, J.; He, J.; Whelan, J.; Lu, X. Proteomic and carbonylation profile analysis at the critical node of seed ageing in Oryza sativa. Sci. Rep. 2017, 7, 1–12. [Google Scholar] [CrossRef] [PubMed]
  228. Arnett, D.; Quillin, A.; Geldenhuys, W.J.; Menze, M.A.; Konkle, M. 4-Hydroxynonenal and 4-Oxononenal Differentially Bind to the Redox Sensor MitoNEET. Chem. Res. Toxicol. 2019, 32, 977–981. [Google Scholar] [CrossRef]
  229. Han, B.; Hare, M.; Wickramasekara, S.; Fang, Y.; Maier, C.S. A comparative ‘bottom up’ proteomics strategy for the site-specific identification and quantification of protein modifications by electrophilic lipids. J. Proteom. 2012, 75, 5724–5733. [Google Scholar] [CrossRef] [Green Version]
  230. Codreanu, S.G.; Ullery, J.C.; Zhu, J.; Tallman, K.A.; Beavers, W.N.; Porter, N.A.; Marnett, L.J.; Zhang, B.; Liebler, D.C. Alkylation Damage by Lipid Electrophiles Targets Functional Protein Systems. Mol. Cell. Proteom. 2014, 13, 849–859. [Google Scholar] [CrossRef] [Green Version]
  231. Weerapana, E.; Wang, C.; Simon, G.M.; Richter, F.; Khare, S.; Dillon, M.B.D.; Bachovchin, D.A.; Mowen, K.; Baker, D.; Cravatt, B.F. Quantitative reactivity profiling predicts functional cysteines in proteomes. Nature 2010, 468, 790–795. [Google Scholar] [CrossRef] [Green Version]
  232. Wang, C.; Weerapana, E.; Blewett, M.M.; Cravatt, B.F. A chemoproteomic platform to quantitatively map targets of lipid-derived electrophiles. Nat. Methods 2014, 11, 79–85. [Google Scholar] [CrossRef] [Green Version]
  233. Matthews, M.L.; He, L.; Horning, B.D.; Olson, E.J.; Correia, B.E.; Yates, J.R.; Dawson, P.E.; Cravatt, B.F. Chemoproteomic profiling and discovery of protein electrophiles in human cells. Nat. Chem. 2017, 9, 234–243. [Google Scholar] [CrossRef] [Green Version]
  234. Chen, Y.; Liu, Y.; Lan, T.; Qin, W.; Zhu, Y.; Qin, K.; Gao, J.; Wang, H.; Hou, X.; Chen, N.; et al. Quantitative Profiling of Protein Carbonylations in Ferroptosis by an Aniline-Derived Probe. J. Am. Chem. Soc. 2018, 140, 4712–4720. [Google Scholar] [CrossRef] [Green Version]
  235. Parvez, S.; Long, M.J.C.; Lin, H.Y.; Zhao, Y.; Haegele, J.A.; Pham, V.N.; Lee, D.K.; Aye, Y. T-REX on-demand redox targeting in live cells. Nat. Protoc. 2016, 11, 2328–2356. [Google Scholar] [CrossRef] [Green Version]
  236. Schmidt, R.; Schippers, J.H.M. ROS-mediated redox signaling during cell differentiation in plants. Biochim. Biophys. Acta Gen. Subj. 2015, 1850, 1497–1508. [Google Scholar] [CrossRef]
  237. Wrzaczek, M.; Brosché, M.; Kangasjä Rvi, J. ROS signaling loops-production, perception, regulation. Curr. Opin. Plant Biol. 2013, 16, 575–582. [Google Scholar] [CrossRef] [PubMed]
  238. Smirnoff, N.; Arnaud, D. Hydrogen peroxide metabolism and functions in plants. New Phytol. 2019, 221, 1197–1214. [Google Scholar] [CrossRef] [PubMed]
  239. Mueller, S.; Hilbert, B.; Dueckershoff, K.; Roitsch, T.; Krischke, M.; Mueller, M.J.; Berger, S. General detoxification and stress responses are mediated by oxidized lipids through TGA transcription factors in arabidopsis. Plant Cell 2008, 20, 768–785. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  240. Mueller, M.J.; Berger, S. Reactive electrophilic oxylipins: Pattern recognition and signalling. Phytochemistry 2009, 70, 1511–1521. [Google Scholar] [CrossRef] [PubMed]
  241. Ichi Mano, J.; Biswas, M.S.; Sugimoto, K. Reactive Carbonyl Species: A Missing Link in ROS Signaling. Plants 2019, 8, 391. [Google Scholar] [CrossRef] [Green Version]
  242. Vollenweider, S.; Weber, H.; Stolz, S.; Chételat, A.; Farmer, E.E. Fatty acid ketodienes and fatty acid ketotrienes: Michael addition acceptors that accumulate in wounded and diseased Arabidopsis leaves. Plant J. 2000, 24, 467–476. [Google Scholar] [CrossRef]
  243. Améras, E.; Stolz, S.; Vollenweider, S.; Reymond, P.; Mène-Saffrané, L.; Farmer, E.E. Reactive electrophile species activate defense gene expression in Arabidopsis. Plant J. 2003, 34, 205–216. [Google Scholar] [CrossRef] [PubMed]
  244. Winger, A.M.; Taylor, N.L.; Heazlewood, J.L.; Day, D.A.; Millar, A.H. The Cytotoxic Lipid Peroxidation Product 4-Hydroxy-2-nonenal Covalently Modifies a Selective Range of Proteins Linked to Respiratory Function in Plant Mitochondria. J. Biol. Chem. 2007, 282, 37436–37447. [Google Scholar] [CrossRef] [PubMed] [Green Version]
  245. Poganik, J.R.; Long, M.J.C.; Aye, Y. Getting the Message? Native Reactive Electrophiles Pass Two Out of Three Thresholds to be Bona Fide Signaling Mediators. BioEssays 2018, 40, 1700240. [Google Scholar] [CrossRef] [PubMed]
Plants 10 01451 g001 550
Figure 1. Environmental stress and ROS production in plants. (A) ROS are produced in the chloroplasts, mitochondria, peroxisomes, plasma membrane, cell walls, and apoplasts under normal growth conditions. However, environmental stresses exacerbate their production and may lead to oxidative stress. (B) The Fenton reaction and Haber–Weiss reaction. ROS are partially reduced or activated forms of molecular oxygen. About 1–5% of molecular oxygen consumed by plants leads to ROS generation. The different forms of ROS include superoxide radicals, singlet oxygen, hydrogen peroxide, perhydroxyl, and hydroxyl radicals.
Figure 1. Environmental stress and ROS production in plants. (A) ROS are produced in the chloroplasts, mitochondria, peroxisomes, plasma membrane, cell walls, and apoplasts under normal growth conditions. However, environmental stresses exacerbate their production and may lead to oxidative stress. (B) The Fenton reaction and Haber–Weiss reaction. ROS are partially reduced or activated forms of molecular oxygen. About 1–5% of molecular oxygen consumed by plants leads to ROS generation. The different forms of ROS include superoxide radicals, singlet oxygen, hydrogen peroxide, perhydroxyl, and hydroxyl radicals.
Plants 10 01451 g001
Plants 10 01451 g002 550
Figure 2. Overview of ROS-mediated post-translational modifications. (A) Most common ROS-mediated PTMs. The thiol groups of Cys and Met are prominently modified by ROS. The modifications include nitrosylation, cysteinylation, glutathionylation, methionine oxidation, persulfidation, and protein carbonylation. (B) Framework model of ROS-mediated PTMs in cell signaling in response to environmental stress in plants.
Figure 2. Overview of ROS-mediated post-translational modifications. (A) Most common ROS-mediated PTMs. The thiol groups of Cys and Met are prominently modified by ROS. The modifications include nitrosylation, cysteinylation, glutathionylation, methionine oxidation, persulfidation, and protein carbonylation. (B) Framework model of ROS-mediated PTMs in cell signaling in response to environmental stress in plants.
Plants 10 01451 g002
Plants 10 01451 g003 550
Figure 3. The reactions of protein carbonylation and the fates of carbonylated proteins. Metal-catalyzed oxidation of the side chains of Arg, Thr, Pro, and Lys and addition of lipid peroxidation-derived RCS to the side chains of Cys, His, and Lys represent the two types of protein carbonylation in plants and result in carbonylated proteins. The fates of carbonylated proteins. The carbonylated proteins may lose their activity, change their initial conformation, or aggregate. They are subsequently degraded by the 20S proteasome system. The biological relevance of these changes is further discussed in the text.
Figure 3. The reactions of protein carbonylation and the fates of carbonylated proteins. Metal-catalyzed oxidation of the side chains of Arg, Thr, Pro, and Lys and addition of lipid peroxidation-derived RCS to the side chains of Cys, His, and Lys represent the two types of protein carbonylation in plants and result in carbonylated proteins. The fates of carbonylated proteins. The carbonylated proteins may lose their activity, change their initial conformation, or aggregate. They are subsequently degraded by the 20S proteasome system. The biological relevance of these changes is further discussed in the text.
Plants 10 01451 g003
Plants 10 01451 g005 550
Figure 5. A model of RCS-mediated carbonylation processes in the hormonal signaling pathway in guard cells. ABA or MeJA induced the production of ROS by NAD(P)H oxidases (RbohD and RbohF) located on the plasma membrane in the guard cells. The RCS derived from the oxidation of membrane lipids by ROS trigger the activation of Ca2+-permeable cation channels in the plasma membrane, which initiates the elevation of the cytosolic free Ca2+ concentration through Ca2+ influx from the apoplast and the intracellular stores. RCS likely induce the carbonylation of an unknown protein target upstream of the calcium channels. CPK6 is a positive regulator of ABA- or MeJA-induced stomatal closure, whereas CDPK6, an isozyme of CPK6, is responsible for the regulation of Ica channels in ABA- or MeJA-induced stomatal closure. The increase in cytosolic Ca2+ is sensed by CDPKs and CPK6 and results in the activation of the S-type anion channels and stomatal closure. GSH is a negative regulator of ABA or MeJA signaling in the guard cell-induced stomatal closure by depletion of intracellular levels of GSH. This model is based on the previous studies from the literature [18,19,181,187,188,190,191,193].
Figure 5. A model of RCS-mediated carbonylation processes in the hormonal signaling pathway in guard cells. ABA or MeJA induced the production of ROS by NAD(P)H oxidases (RbohD and RbohF) located on the plasma membrane in the guard cells. The RCS derived from the oxidation of membrane lipids by ROS trigger the activation of Ca2+-permeable cation channels in the plasma membrane, which initiates the elevation of the cytosolic free Ca2+ concentration through Ca2+ influx from the apoplast and the intracellular stores. RCS likely induce the carbonylation of an unknown protein target upstream of the calcium channels. CPK6 is a positive regulator of ABA- or MeJA-induced stomatal closure, whereas CDPK6, an isozyme of CPK6, is responsible for the regulation of Ica channels in ABA- or MeJA-induced stomatal closure. The increase in cytosolic Ca2+ is sensed by CDPKs and CPK6 and results in the activation of the S-type anion channels and stomatal closure. GSH is a negative regulator of ABA or MeJA signaling in the guard cell-induced stomatal closure by depletion of intracellular levels of GSH. This model is based on the previous studies from the literature [18,19,181,187,188,190,191,193].
Plants 10 01451 g005
Table
Table 1. Reactive carbonyl species (RCS) frequently implicated in protein carbonylation-mediated gene signaling.
Table 1. Reactive carbonyl species (RCS) frequently implicated in protein carbonylation-mediated gene signaling.
Lipid Peroxide-Derived Reactive
Carbonyl Species		Predominant PUFAsPreference of Amino Acids for ModificationType of Reaction with Amino AcidsReferences
4-Hydroxy-(E)-2-nonenal (4-HNE)Linoleic acid
(LA: 18:2ω-6)
Arachidonic acid (AA: 20:4, ω-6)		Cys >> His > LysMichael addition [108,109,110,111,112,113]
Malondialdehyde (MDA)Arachidonic acid (AA: 20:4, ω-6)Lys >> His > ArgMichael addition [7,113,114]
AcroleinLinoleic acid
(LA: 18:2ω-6)		Cys >> His > LysMichael addition or Schiff-base formation[108,115]
4-Oxo-nonenal (4-ONE)Linoleic acid
(LA: 18:2ω-6)
Arachidonic acid (AA: 20:4, ω-6)		Lys >> Cys > His > ArgSchiff-base formation[110,113]
Table
Table 2. Summary of RCS-mediated protein carbonylation in plants.
Table 2. Summary of RCS-mediated protein carbonylation in plants.
Hormonal SignalingPhysiological ProcessesForms of RCS InvolvedReferences
Auxin signalingLateral root formationHNE, acrolein, crotonaldehyde, butyraldehyde[16]
ABA signalingStomatal closureHNE, MDA[17,18,183]
MeJA signalingStomatal closureHNE, MDA[19]
Publisher’s Note: MDPI stays neutral with regard to jurisdictional claims in published maps and institutional affiliations.

Share and Cite

MDPI and ACS Style

Tola, A.J.; Jaballi, A.; Missihoun, T.D. Protein Carbonylation: Emerging Roles in Plant Redox Biology and Future Prospects. Plants 2021, 10, 1451. https://doi.org/10.3390/plants10071451

AMA Style

Tola AJ, Jaballi A, Missihoun TD. Protein Carbonylation: Emerging Roles in Plant Redox Biology and Future Prospects. Plants. 2021; 10(7):1451. https://doi.org/10.3390/plants10071451

Chicago/Turabian Style

Tola, Adesola J., Amal Jaballi, and Tagnon D. Missihoun. 2021. "Protein Carbonylation: Emerging Roles in Plant Redox Biology and Future Prospects" Plants 10, no. 7: 1451. https://doi.org/10.3390/plants10071451

APA Style

Tola, A. J., Jaballi, A., & Missihoun, T. D. (2021). Protein Carbonylation: Emerging Roles in Plant Redox Biology and Future Prospects. Plants, 10(7), 1451. https://doi.org/10.3390/plants10071451

Note that from the first issue of 2016, this journal uses article numbers instead of page numbers. See further details here.

Article Metrics

Back to TopTop