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Communication

The Xanthomonas RaxH-RaxR Two-Component Regulatory System Is Orthologous to the Zinc-Responsive Pseudomonas ColS-ColR System

1
Department of Microbiology & Molecular Genetics, University of California, Davis, CA 95616, USA
2
Department of Plant Pathology and Genome Center, University of California, Davis, CA 95616, USA
*
Author to whom correspondence should be addressed.
Microorganisms 2021, 9(7), 1458; https://doi.org/10.3390/microorganisms9071458
Submission received: 4 June 2021 / Revised: 30 June 2021 / Accepted: 2 July 2021 / Published: 7 July 2021

Abstract

:
Genome sequence comparisons to infer likely gene functions require accurate ortholog assignments. In Pseudomonas spp., the sensor-regulator ColS-ColR two-component regulatory system responds to zinc and other metals to control certain membrane-related functions, including lipid A remodeling. In Xanthomonas spp., three different two-component regulatory systems, RaxH-RaxR, VgrS-VgrR, and DetS-DetR, have been denoted as ColS-ColR in several different genome annotations and publications. To clarify these assignments, we compared the sensor periplasmic domain sequences and found that those from Pseudomonas ColS and Xanthomonas RaxH share a similar size as well as the location of a Glu-X-X-Glu metal ion-binding motif. Furthermore, we determined that three genes adjacent to raxRH are predicted to encode enzymes that remodel the lipid A component of lipopolysaccharide. The modifications catalyzed by lipid A phosphoethanolamine transferase (EptA) and lipid A 1-phosphatase (LpxE) previously were detected in lipid A from multiple Xanthomonas spp. The third gene encodes a predicted lipid A glycosyl transferase (ArnT). Together, these results indicate that the Xanthomonas RaxH-RaxR system is orthologous to the Pseudomonas ColS-ColR system that regulates lipid A remodeling. To avoid future confusion, we recommend that the terms ColS and ColR no longer be applied to Xanthomonas spp., and that the Vgr, Rax, and Det designations be used instead.

1. Introduction

Diverse Xanthomonas species and pathovars cause serious diseases in most plants [1,2]. One example is X. oryzae pv. oryzae (Xoo), which causes significant rice crop losses in Asia and Africa [3]. Resistance to Xoo is conferred by the rice XA21 receptor kinase [4], which activates innate immune responses upon binding the Xoo RaxX (required for activation of XA21 component X) protein [5]. RaxX is a secreted sulfopeptide similar to the plant PSY sulfopeptide growth hormone [6,7], and is synthesized by some but not all Xanthomonas spp. [8].
Xoo proteins required specifically for RaxX processing and secretion are encoded by the raxX-raxSTAB gene cluster [5,9,10,11] (Figure 1). These genes are adjacent to a seven-gene cluster including the raxHR genes [12], which encode the sensor histidine kinase and response regulator proteins, respectively, of a two-component regulatory system [12,13]. Phosphoryl transfer from a sensor to its cognate response regulator increases DNA binding in order to control target gene transcription initiation [14,15,16]. Truncated soluble RaxH protein rapidly autophosphorylates and catalyzes efficient phosphoryl-transfer to RaxR protein in vitro [13] as expected for a cognate two-component regulatory pair [17]. To date, the RaxR protein has not been demonstrated to bind DNA or activate transcription.
Pseudomonas spp. encode the ColS-ColR two-component regulatory system, identified initially in P. fluorescens as required for root colonization through controlling functions that remodel LPS (lipopolysaccharide) [18,19]. In Xanthomonas spp., three separate two-component regulatory pairs have been denoted as ColS-ColR in several different published genome sequences [20,21,22,23,24,25,26] and research papers [27,28,29,30]. Separately, each of these Xanthomonas ColS-ColR-like pairs has been assigned unique symbols based on experimental analysis: RaxH-RaxR [12], VgrS-VgrR (virulence and growth regulator) [31], and DetS-DetR (detoxifying) [32].
In Xoo, the RaxH-RaxR pair may play a role in setting the level of RaxX synthesis, processing, or secretion through a mechanism not yet determined [12]. In Xoo, Xanthomonas campestris pv. campestris (Xcc), and X. citri (Xac), the VgrS-VgrR pair controls virulence, the hypersensitive response, environmental stress tolerance, and growth with limited iron [27,28,29,31]. The DetR response regulator is required for virulence in Xoo [32] but not in Xcc [27]. Unlike Pseudomonas ColS-ColR, neither VgrS-VgrR nor DetS-DetR has been implicated in the control of lipid A remodeling enzyme synthesis.
Orthologs are genes derived from the most recent common ancestor of the lineages being considered [33], and orthologous gene products generally perform similar functions [34,35]. To advance understanding of the raxRH and adjacent genes (Figure 1), we determined their orthologous relationships with genes of known function from other genera. These determinations generated two conclusions: first, that the Xanthomonas RaxH-RaxR pair is orthologous to the Pseudomonas ColS-ColR pair, which regulates lipid A remodeling enzyme synthesis in response to excess Zn2+ [36,37]; second, that the Xanthomonas genes denoted here as eptA, lpxE, and arnT likely encode enzymes that remodel lipid A in response to cell envelope stress. These results suggest that the Xanthomonas RaxH-RaxR two-component system regulates expression of the arnT-lpxE-eptA gene cluster encoding lipid A remodeling enzymes.

2. Materials and Methods

2.1. Sequence Analyses

The BLAST programs [38,39] were used for database searches and for determining reciprocal best hits. Nucleotide and deduced amino acid sequences were edited and analyzed with the programs EditSeq™ and MegAlign™ (version 14.1.0), DNASTAR, Madison, WI, USA. The Integrated Microbial Genomes interface [40] was used to compare genome segments from different species in order to analyze genome neighborhoods.
Xanthomonas genes described here in detail are from Xoo strain PXO99A (GenBank accession NC_010717.2) except as noted otherwise. Genes, locus tags and accession numbers are presented in Table S1.

2.2. Ortholog Identification

Orthologous genes were identified initially by analyzing their predicted amino acid sequences for reciprocal BLASTP best hits [34,35] using default parameters for database BLASTP searches [41] (expect = 10; word size = 6; matrix = BLOSUM62; gap costs = existence 11, extension 1; no compositional adjustments). Initial searches focused on comparisons between genes from Xoo and from Pseudomonas aeruginosa, a well-annotated close relative [42]. Other species and genera were examined as needed. Candidate orthologous pairs were then evaluated to ensure that they have similar lengths, that sequence similarity extends throughout most of their lengths, and that they have similar domain compositions. Candidates were further examined for the presence of conserved and functionally-important residues and for genome neighborhood.
Pairwise comparisons generated for Table 1 were performed with the pairwise BLASTP function using default parameters (expect = 0.05; word size = 3; matrix = BLOSUM62; gap costs = existence 11, extension 1; conditional compositional score matrix adjustment).

2.3. Predicted Transmembrane Helices

Sequences were evaluated in the TMHMM Server v. 2.0 accessed through the Danish Technical University (http://www.cbs.dtu.dk/services/TMHMM/, accessed on 14 April 2021). Predictions were refined by manual adjustment as necessary.

3. Results

3.1. The gcvP-minCDE Region in the Xoo Strain PXO99A Genome

The raxX-raxSTAB gene cluster apparently has been gained and lost multiple times during Xanthomonas speciation [8]. In all cases identified [8], this cluster is located in the same genome neighborhood, between the gcvP gene encoding a subunit of glycine dehydrogenase [43] on one side, and the minCDE operon encoding proteins required for cell division [44] on the other (Figure 1). The gene denoted as “mfsX” is predicted to encode a major facilitator subfamily permease [8]. The eptA, lpxE, and arnT genes are predicted to encode enzymes involved in lipid A remodeling, as described below (Section 3.3, Section 3.4 and Section 3.5).
The ace gene, identified first in Xac, encodes a dipeptidyl-carboxypeptidase homologous to mammalian ACE (angiotensin converting enzyme). Xac ACE enzyme efficiently digests mammalian ACE substrates such as angiotensin [45], although the authentic substrate(s) and physiological function(s) for bacterial ACE are not known. ace gene homologs are distributed throughout diverse bacterial phyla [45], and gene neighborhoods are not conserved across different genera (not shown).
The raxR-raxH and lpxE-eptA gene pairs have overlapping termination and initiation codons (ATGTCTAA and ATGA, respectively). Such overlaps indicate that the two gene products function together [46]. Otherwise, the raxR-arnT intergenic region is 218 nt, the arnT-lpxE intergenic region is 99 nt, and the eptA-ace intergenic region is 111 nt (Figure 1).

3.2. Evidence That Xanthomonas RaxH-RaxR and Pseudomonas ColS-ColR Are Orthologous Pairs

The two-component regulatory systems considered here all resemble the model EnvZ-OmpR pair that controls outer membrane porin synthesis in Escherichia coli [17,47]. In EnvZ-OmpR-type systems, the sensor protein comprises an amino-terminal periplasmic signal input domain and a carboxyl-terminal cytoplasmic transmitter module with histidine autokinase activity. The response regulator protein has amino-terminal phospho-accepting receiver and carboxyl-terminal DNA-binding domains. About 11 distinct OmpR-type response regulators [48] are conserved across different Xanthomonas spp. [49,50]. Of these, three cognate sensors have EnvZ-type transmitter sequences (HPK2 family [51]): RaxH, VgrS, and DetS. All three sensors also have been denoted as ColS (see Introduction), based on sequence similarities across the transmitter domains.
Three criteria indicate that the Xanthomonas RaxH-RaxR pair is orthologous to the Pseudomonas ColS-ColR pair [34,35]. First, the RaxH and Pseudomonas ColS periplasmic domain sequences display virtually identical size and predicted topology, even though they share only 20% identical residues (Figure 2 and Figure S1). The other two candidate ColS orthologs (VgrS and DetS) are predicted to adopt similar topologies, but their periplasmic domain sequences are different lengths (Figure 2 and not shown).
It should be noted that relatively low sequence identity between orthologous sensor periplasmic domains is typical. For example, the PhoQ sensors from P. aeruginosa [52] and Xoo [53] share only 25% sequence identity between the periplasmic domains, in contrast to 42% between the transmitter domains and 56% between the corresponding PhoP response regulators (alignments not shown).
Second, the ColS sequence includes the critical metal ion-binding ExxE (Glu-X-X-Glu) motif, just proximal to the second transmembrane helix, which is required for responses to Fe3+, Zn2+ and other metal ions [36]. This motif is at the same position in RaxH (Figure 2 and Figure S1), whereas the VgrS Fe3+-binding ExxE motif [54] is in the middle of the periplasmic domain sequence (Figure 2). (The DetS periplasmic domain sequence does not contain an ExxE motif.) For comparison, Figure 2 depicts periplasmic domains from two other ExxE motif-containing sensors, Salmonella enterica PmrB, which signals in response to excess Fe3+ or Al3+ [55], and P. aeruginosa BqsS, which signals in response to excess Fe2+ [56].
Remarkably, the RaxH sequence also includes a second ExxE motif, just distal to the first transmembrane helix, that is not conserved in ColS sequences (Figure 2 and Figure S1). In this respect, the RaxH sequence is similar to that of PmrB [55] (Figure 2). These differences in ExxE motif numbers and locations imply differences in binding specificity and/or affinities for different metal ions.
The third criterion for assigning RaxH-RaxR and ColS-ColR as orthologous pairs comes from analyzing genome neighborhoods [35]. Both the Xanthomonas raxRH and Pseudomonas colRS genes are adjacent to the divergently transcribed lpxE ortholog (Section 3.6, below). These neighborhoods differ in that the Pseudomonas eptA and arnT genes are elsewhere in the genome. Nonetheless, in P. aeruginosa and P. putida, the ColS-ColR pair activates expression of the eptA [37] and predicted lpxE genes [36,57], and represses expression of the arnT-containing arnB operon [37], all in response to excess Zn2+. Accordingly, the Xanthomonas eptA-lpxE-arnT cluster immediately adjacent to the raxRH genes suggests independently that RaxH-RaxR and ColS-ColR control similar physiological functions [35].

3.3. The Xanthomonas eptA Gene Is Predicted to Encode Lipid A Phosphoethanolamine Transferase

Section 3.3, Section 3.4 and Section 3.5 concern the genes eptA, lpxE, and arnT, predicted to encode lipid A remodeling enzymes and to be regulated by the RaxH-RaxR two-component system.
LPS consists of the membrane anchor lipid A connected through a core oligosaccharide to the polymorphic O antigen polysaccharide [58,59,60]. Lipid A in many gram-negative genera (including Xanthomonas) is an acylated β-1′,6-linked glucosamine disaccharide bis-phosphate [61,62,63,64] (Figure 3A). The phosphates at positions 1 and 4′ are bridged by Mg2+ ions, providing one of the LPS lateral interactions necessary to form the characteristic tight permeability barrier [60,65].
As the outer membrane’s external surface, LPS confers unique permeability properties while also providing targets for bacteriophage attachment, host pattern recognition, and antimicrobial peptides. Accordingly, LPS structures can be remodeled not only by changing the O antigen but also through modifications to the core oligosaccharide and lipid A components [58,59,60]. Lipid A remodeling enzyme synthesis is induced by certain disruptive envelope stresses, including cation imbalance and cationic antimicrobial peptides.
One widespread modification is catalyzed by lipid A phosphoethanolamine transferase (EptA enzyme), which acts in the periplasm to transfer phosphoethanolamine (P-EtN) from phosphatidylethanolamine to positions 1 and/or 4′ on the lipid A disaccharide [58] (Figure 3B). The Xoo putative EptA sequence shares ca. 40% identity over most of its length with the orthologous P. aeruginosa EptA sequence (Table 1). Sequence alignments (not shown) reveal that the Xoo putative EptA sequence includes critical residues identified in N. meningitidis EptA [66]: Glu-240, Thr-280, Asp-452 and His-453 (Glu-253, Thr-293, Asp-463 and His-464 in Xoo EptA), which form the Zn2+-binding active site, and disulfides formed by Cys residue pairs at positions 276–286, 327–331, 348–353, 402–410, and 499–540 (287–297, 338–342, 359–364, 413–421, and 510–549 in Xoo EptA).
Lipid A from wild-type Xanthomonas campestris pv. campestris (Xcc) has undetectable EtN [63], whereas lipid A from a nonpathogenic rfaX mutant displays nonstoichiometric substitution with EtN at positions 1 and/or 4′ on the lipid A disaccharide [67]. The rfaX lesion generates LPS with a severely truncated core oligosaccharide, and so the resulting outer membrane disruption likely induces EptA synthesis [67]. Lipid A with linked EtN also has been detected in X. campestris pv. pruni [68], Xac [61], and Xoo [62], although not in X. fragariae [68] or X. translucens pv. translucens [64]. These results provide evidence that the Xoo putative EptA enzyme is synthesized and active (Figure 3).

3.4. The Xanthomonas lpxE Gene Is Predicted to Encode Lipid A 1-phosphatase

A second lipid A remodeling reaction is catalyzed by lipid A 1-phosphatase (LpxE enzyme), which functions in the periplasm [69,70] (Figure 3C). The Xoo putative LpxE sequence shares ca. 40% identity with the orthologous P. aeruginosa putative LpxE sequence (Table 1). These sequences share similar predicted membrane topology with the Rhizobium etli LpxE sequence [69,70], each having six predicted transmembrane helices delimiting three periplasmic segments and four cytoplasmic segments (alignments not shown). Neither the structure nor the active site for LpxE enzyme has been determined. However, the Xoo putative LptE sequence includes several residues conserved in R. etli LpxE thought to be important for catalysis [69]: Lys-123, Pro-131, Pro-155, Gly-157, His-158 and His-197 (Lys-127, Pro-135, Pro-164, Gly-166, His-167, and His-213 in Xoo LpxE).
Some LpxE homologs have phosphatase activity on substrates other than lipid A [69,70]. Three lines of evidence support the hypothesis that the Xoo putative LpxE enzyme is lipid A 1-phosphatase. First, Helicobactri pylori EptA and LpxE enzymes are expressed from the eptA-lpxE operon [71], revealing a shared genome neighborhood. Recall that the Xoo lpxE and eptA genes overlap, indicating likely translational coupling (Figure 1; Section 3.1, above).
Second, this genetic association reflects functional association, as H. pylori LpxE removes the lipid A 1-phosphate before EptA adds P-EtN, thereby forming a monophosphoethanolamine (P-EtN) moiety [72] (Figure 3C,D). In many other studied genera, P-EtN is added to the existing phosphate group, thereby forming a pyrophosphoethanolamine (PP-EtN) moiety [58,60] (Figure 3B). Strikingly, lipid A from Xac is a mixture wherein some molecules contain two PP-EtN moieties and others contain one PP-EtN and one P-EtN [61], providing evidence that Xac lipid A has been dephosphorylated in some cases before P-EtN addition.
Third, H. pylori and R. etli both synthesize dephospho-lipid A through LpxE (and LpxF) activities [73,74]. Some lipid A molecules from X. campestris pv. pruni are dephosphorylated [68], providing evidence that the Xanthomonas putative LpxE enzyme is synthesized and active (Figure 3). In H. pylori and R. etli, LpxE-dependent lipid A 1-dephosphorylation confers some resistance to antimicrobial peptides [71,75], although higher-level resistance requires LpxF-dependent lipid A 4′-dephosphorylation as well [73,74].

3.5. The Xanthomonas arnT Gene Is Predicted to Encode Lipid A Glycosyl Transferase

A third lipid A remodeling reaction is catalyzed by lipid A glycosyl transferase (ArnT enzyme), which functions in the periplasm to transfer 4-amino-4-deoxy-L-arabinose (Ara4N) from its undecaprenyl phosphate carrier to the phosphate at either end of the lipid A disaccharide [58,59,60]. The enzyme comprises an amino-terminal domain with 13 transmembrane helices and a carboxyl-terminal periplasmic domain whose sequence is poorly-conserved [76,77]. The Xoo putative ArnT sequence shares ca. 30% identity with the orthologous P. aeruginosa ArnT sequence over the amino-terminal half (Table 1), similar to other ArnT sequence comparisons [76,77]. Sequence alignments (not shown) reveal that the Xoo putative ArnT sequence includes critical residues identified in Cupriavidus metallidurans ArnT [76]: Glu-84, Lys-85, Arg-270 and Tyr-345 (Glu-70, Lys-71, Arg-264 and Tyr-335 in Xoo ArnT), all involved in coordinating the phosphate group of the undecaprenyl carrier, and the ion pairs Asp-55/Arg-58 and Asp-158/Lys-203 (Asp-41/Arg-44 and Asp-144/Lys-185 in Xoo ArnT), which orient the lipid A phosphate for catalysis.
ArnT enzyme first was identified and characterized in enterobacteria, where it is expressed from the arnBCADTEF operon [55]. Besides arnT, the remaining six arn genes encode enzymes that synthesize and translocate the Ara4N-undecaprenyl phosphate sugar donor for ArnT catalysis [78]. However, in some other species, the ArnT enzyme instead transfers galactosamine, glucosamine, or glucose [79,80,81]. For example, Francisella novicida encodes two homologs of the enterobacterial arnC gene, encoding undecaprenyl phosphate sugar transferase that instead are specific for galactosamine (FlmF2) or glucose (FlmF1) [82].
The enzyme responsible for making the putative undecaprenyl phosphate sugar substrate for Xanthomonas ArnT enzyme is not clear. At least two genes, both unlinked to the gcvP-minCDE cluster, potentially encode ArnC-like enzymes. Gene PXO_RS22265 encodes a protein ca. 30% identical to P. aeruginosa ArnC, although it is only about two-thirds as long (Table 1). This gene is in a cluster between PXO_RS22260, which encodes a predicted sugar-nucleotide epimerase, and PXO_RS22270, which encodes a ca. 100 residue protein homologous to a biochemically-uncharacterized amino-terminal domain in the LpxB lipid A-disaccharide synthase from Chlamydia and related genera (accession WP_009873791.1). Indeed, PXO_RS22265 and PXO_RS22270 homologs are linked to arnT genes in other species (Section 3.6 below), suggesting that they encode functions involved in lipid A remodeling. However, these genes also are present in species, such as clade 1 Xanthomonas spp., for which we did not identify an arnT ortholog (Section 3.6 below). Separately, gene PXO_RS14680 encodes a protein ca. 37% identical to the F. novicida FlmF1 and FlmF2 sequences (Table 1). However, the adjacent gene PXO_RS14685 encodes an enzyme likely involved in peptidoglycan biosynthesis, so the PXO_RS14680-encoded protein may function in this process instead.
Thus, it is plausible that the Xanthomonas ArnT enzyme catalyzes transfer of a sugar other than Ara4N to lipid A. Nevertheless, to our knowledge, the only reported modifications to Xanthomonas lipid A disaccharide phosphates are the dephosphorylation and the P-EtN and PP-EtN moieties described above. Accordingly, predicted function(s) for the Xoo putative ArnT enzyme are unspecified. Perhaps lipid A analysis from cultures grown under different conditions will identify a plausible ArnT-dependent modification.

3.6. raxRH Gene Neighborhoods in Members of the Order Xanthomonadales (Lysobacterales)

Expanding on our prior analysis [8], we compared the gcvP-minCDE regions across the range of Xanthomonas spp. There were 31 correctly-named Xanthomonas spp. as of 20 May 2021 [83]. We used the Integrated Microbial Genomes platform [40] to examine 41 genomes, with each correctly-named Xanthomonas species included at least once, to determine their raxRH gene neighborhoods (Table S2). The gcvP-minCDE region is virtually identical in each case (not shown), with two exceptions. First, some strains have the raxX-raxSTAB gene cluster between genes gcvP and “mfsX” (Figure 1), whereas others do not [8] (Table S2). Second, the relatively small number of strains from clade 1 [1,2] (Table S2) specifically lack only the arnT gene (Figure S2).
This phylogenetic distribution indicates that the complete gcvP-minCDE region (excepting the raxX-raxSTAB gene cluster [8]) was not acquired recently through lateral gene transfer [84]. A separate, relatively simple criterion to examine this point is provided by the G+C percentage, which often differs in laterally transferred genes [84]. In Xoo PXO99A, the G+C percentage is relatively constant across the gcvP-minCDE region (including the raxX-raxSTAB genes) and close to the median value for the entire genome: 63.7% (Figure S3).
Next, we used BLAST to search for homologs of the Xoo PXO99A RaxH periplasmic domain sequence in other species from the order Xanthomonadales (renamed as Lysobacterales [83]). This search identified sequences from a variety of genera in the family Xanthomonadaceae (renamed as Lysobacteraceae [83]) and two genera from the family Rhodanobacteraceae (Table S1). The alignment of representative RaxH periplasmic domain sequences (Figure S1) shows that all share an overall length, predicted membrane topology, and conserved sequence features with Xoo RaxH. Notably, however, the TM2-proximal ExxE motif is not fully conserved, with the first Glu replaced by Gln, His, or Thr in some sequences (Figure S1 and not shown).
Finally, we examined raxRH gene neighborhoods for these and related strains. In each case, the raxRH genes are adjacent to one or another combination of the arnT, lpxE, and eptA genes, reinforcing the association of the RaxH-RaxR two-component regulatory system with functions for LPS remodeling (Figure S2).

4. Discussion

4.1. RaxH-RaxR and ColS-ColR Are Orthologous Two-Component Regulatory System Pairs

Sequence comparisons between different phylogenetic groups can provide indispensable guidance for predicting gene functions. However, useful predictions depend upon accurate ortholog assignments [34,35]. Otherwise, genes with the same designations might be considered to have the same functions in different genera, potentially obscuring meaningful differences.
The ColS-ColR two-component regulatory system in Pseudomonas spp. responds to metal ions such as Zn2+ to control genes whose products remodel lipid A [18,19,36,37,57]. In Xanthomonas spp., the designation ColS-ColR has often [27,28,29,30] but not always [49,54,85] been applied to the VgrS-VgrR two-component regulatory system that controls a variety of virulence-related functions. However, evidence presented here suggests that the Xanthomonas RaxH and RaxR proteins are the true orthologs of ColS and ColR. Therefore, conflating Xanthomonas VgrS-VgrR with Pseudomonas ColS-ColR is potentially misleading, especially since the two regulatory systems appear to control different functions.
Although the RaxH and ColS sequences share overall similarities, they may have potential functional differences, for example in the number of ExxE motifs (Figure S1). Therefore, we recommend that the ColS and ColR designations no longer be applied to Xanthomonas two-component regulatory systems, and that the appropriate Rax, Vgr, and Det designations be used instead.

4.2. Two-Component Regulatory Systems Regulate Lipid A Remodeling

In other species, lipid A remodeling enzyme synthesis is controlled both directly and indirectly by multiple two-component regulatory systems. For example, S. enterica eptA and arnT gene expression is activated indirectly by the PhoQ-PhoP pair in response to limiting Mg2+, and directly by the PmrB-PmrA pair in response to excess Fe3+ [55]. P. aeruginosa regulation is more complex, with five two-component regulatory systems to control lipid A remodeling enzyme synthesis in response to limiting Mg2+ (PhoQ-PhoP and PmrB-PmrA), excess Zn2+ (ColS-ColR), and antimicrobial peptides (CprS-CprR, ParS-ParR, and PmrB-PmrA) [86] found.
In comparison to S. enterica and P. aeruginosa, Xanthomonas spp. encode a distinct subset of two-component regulatory systems implicated in lipid A remodeling. The PhoQ-PhoP two-component regulatory system is encoded by all three genera [53,86], emphasizing its central role in the response to limiting Mg2+ [87]. By contrast, the PmrB-PmrA and RaxH-RaxR (ColS-ColR orthologs) pairs are absent from Xanthomonas spp. and S. enterica, respectively, and the CprS-CprR and ParS-ParR pairs are absent from both [31,50]. Thus, conservation of RaxH-RaxR (ColS-ColR orthologs) plus PhoQ-PhoP implies that lipid A regulation in Xanthomonas spp. comprises a subset of the complex P. aeruginosa network.
The RaxH-RaxR pair was characterized and named in the context of raxSTAB operon expression [12]. Nevertheless, Rax phenotypes conferred by raxH and raxR null alleles are subtle, at least under the conditions studied, and potentially result from indirect effects. Better understanding of Xanthomonas two-component regulatory networks is necessary to define the relationship between the RaxH-RaxR pair and raxX-raxSTAB regulation.

4.3. Phenotypes Resulting from EptA-, LpxE-, and ArnT-Catalyzed Lipid A Remodeling

The outer membrane permeability barrier depends on strong lateral interactions between LPS molecules, mediated in large part by Mg2+ or Ca2+ ions that bridge phosphates in adjacent lipid A molecules [65]. In the mammalian pathogen S. enterica, limiting Mg2+ encountered during infection [88] induces EptA and ArnT synthesis for lipid A remodeling [55]. The resulting positively charged moieties counteract the phosphate negative charge partially (EtN) or fully (Ara4N), thereby reducing the Mg2+ dependence for LPS function [65]. By influencing LPS lateral interactions, different types of lipid A remodeling differentially affect the outer membrane structure, resilience, and permeability [65].
Lipid A remodeling confers two additional phenotypes, cation resistance and immune evasion [60]. First, LPS remodeled with EtN and/or Ara4N is more resistant to diverse toxic cations, including metals such as Fe3+ and antimicrobial peptides such as polymyxins [55]. EtN-mediated resistance to antimicrobial peptides is relatively weak compared to that conferred by Ara4N in both S. enterica [89] and P. aeruginosa [37,90], reflecting differences in molecular mass (EtN = 61 Da; Ara4N = 149 Da) and degrees of negative charge compensation [65]. Further variation comes from using PP-EtN vs P-EtN (Figure 3B vs. Figure 3D) or sugars other than Ara4N [79,80]. Plants also synthesize cationic antimicrobial peptides, and at least one of these induces ArnT synthesis in P. aeruginosa [91].
The second lipid A remodeling phenotype concerns interactions between LPS and host innate immune systems. In mammals, lipid A binds the TLR4/MD2 (Toll-like receptor 4/myeloid differentiation factor 2) complex that controls innate immune responses to lipid A [92,93]. Binding involves both the fatty acyl chains and the phosphates, and so remodeled lipid A forms are recognized poorly by the TLR4/MD2 complex [94]. Notably, modifications involving phosphates 1 and 4′ influence TLR4/MD2 recognition and signaling [73,81,95,96,97], and appear to help host cells differentiate between pathogenic and commensal species [98].
Plant receptors for LPS molecules are yet to be identified. The Arabidopsis thaliana LORE receptor-like kinase, previously suggested to detect lipid A [99], instead responds to co-purified medium-chain 3-hydroxy fatty acid metabolites [100]. Nevertheless, plant recognition of LPS is a prominent feature of the innate response to bacteria [63,99,101]. Although plant-associated bacteria remodel their lipid A upon exposure to antimicrobial peptides [91], specific roles for lipid A and its remodeling are not defined. Xanthomonas spp. provide relatively simple models to evaluate roles for lipid A and its remodeling in a broad range of bacterium-plant contexts.

Supplementary Materials

The following are available online at https://www.mdpi.com/article/10.3390/microorganisms9071458/s1, Figure S1, Periplasmic domains from select RaxH and ColS sequences; Figure S2, raxRH gene neighborhoods in members of the order Lysobacterales (formerly Xanthomonadales); Figure S3, Percent G+C across the gcvP-minCDE region in Xoo PXO99A; Table S1, Locus tags and accession numbers; Table S2, Genome sequences used for gene neighborhood analysis.

Author Contributions

Analysis, V.S.; writing—original draft preparation, V.S.; writing—review and editing, P.C.R.; funding acquisition, P.C.R. Both authors have read and agreed to the published version of the manuscript.

Funding

This study was supported by Public Health Service grant GM122968 to P.C.R. from the National Institute of General Medical Sciences.

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

All data are presented in the paper.

Acknowledgments

We thank Anna Joe and Saul Burdman for commenting on the manuscript. We are grateful to our laboratory colleagues for their interest, thoughtful discussion and support.

Conflicts of Interest

The authors declare no conflict of interest. The funders had no role in the design of the study; in the collection, analyses, or interpretation of data; in the writing of the manuscript, or in the decision to publish the results.

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Figure 1. Genes in the Xoo strain PXO99A gcvP-minCDE region. Drawn to scale. Gene symbols are eptA, phosphoethanolamine transferase (dark red); lpxE, lipid A 1-phosphatase (red); arnT, sugar-undecaprenyl phosphate transferase (orange); raxR (dark blue); raxH (light blue). Other gene symbols are described in the text. The raxX-raxSTAB gene cluster is between gcvP and “mfxS” only in certain Xanthomonas species (Table S1). Small open reading frames with unknown function are not shown. See text for references.
Figure 1. Genes in the Xoo strain PXO99A gcvP-minCDE region. Drawn to scale. Gene symbols are eptA, phosphoethanolamine transferase (dark red); lpxE, lipid A 1-phosphatase (red); arnT, sugar-undecaprenyl phosphate transferase (orange); raxR (dark blue); raxH (light blue). Other gene symbols are described in the text. The raxX-raxSTAB gene cluster is between gcvP and “mfxS” only in certain Xanthomonas species (Table S1). Small open reading frames with unknown function are not shown. See text for references.
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Figure 2. Periplasmic domain schematic structures for selected sensor proteins. Drawn to scale. The amino-terminal sequences are illustrated through the second of two transmembrane (TM) helices, shown as gray filled boxes. Numbers show positions of specific residues. The conserved ExxE motifs are shown as red-filled boxes, with the corresponding sequences above. The variant HxxE motif in ColS is shown as a white box. The blue line under the Xcc VgrS periplasmic domain shows the extent of a conserved sequence substitution in the Xoo sequence that removes the ExxE motif. Sen, Salmonella enterica LT2, Xoo, Xanthomonas oryzae pv. oryzae PXO99A, Ppu, Pseudomonas pudita KT2440, Pae, Pseudomonas aeruginosa PAO1, Xcc, Xanthomonas campestris pv. campestris 8004. See text for references.
Figure 2. Periplasmic domain schematic structures for selected sensor proteins. Drawn to scale. The amino-terminal sequences are illustrated through the second of two transmembrane (TM) helices, shown as gray filled boxes. Numbers show positions of specific residues. The conserved ExxE motifs are shown as red-filled boxes, with the corresponding sequences above. The variant HxxE motif in ColS is shown as a white box. The blue line under the Xcc VgrS periplasmic domain shows the extent of a conserved sequence substitution in the Xoo sequence that removes the ExxE motif. Sen, Salmonella enterica LT2, Xoo, Xanthomonas oryzae pv. oryzae PXO99A, Ppu, Pseudomonas pudita KT2440, Pae, Pseudomonas aeruginosa PAO1, Xcc, Xanthomonas campestris pv. campestris 8004. See text for references.
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Figure 3. EptA (phosphoethanolamine transferase) and LpxE (lipid A 1-phosphatase) activities. (A) Lipid A schematic structure. The glucosamine disaccharide is decorated with six fatty acyl chains, the core oligosaccharide that ligates the polymorphic O-antigen (O-Ag) polysaccharide, and phosphate esters at positions 1 and 4’. (B) EptA enzyme adds phosphoethanolamine (P-EtN) to form a pyrophosphoethanolamine moiety. Only one glucosamine from the lipid A disaccharide is shown, but the same reaction also can occur at the 4’ position. (C) LpxE enzyme removes phosphate-1. (D) EptA enzyme adds P-EtN to form a phosphoethanolamine moiety. See text for references.
Figure 3. EptA (phosphoethanolamine transferase) and LpxE (lipid A 1-phosphatase) activities. (A) Lipid A schematic structure. The glucosamine disaccharide is decorated with six fatty acyl chains, the core oligosaccharide that ligates the polymorphic O-antigen (O-Ag) polysaccharide, and phosphate esters at positions 1 and 4’. (B) EptA enzyme adds phosphoethanolamine (P-EtN) to form a pyrophosphoethanolamine moiety. Only one glucosamine from the lipid A disaccharide is shown, but the same reaction also can occur at the 4’ position. (C) LpxE enzyme removes phosphate-1. (D) EptA enzyme adds P-EtN to form a phosphoethanolamine moiety. See text for references.
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Table 1. Ortholog sequence identity and coverage in pairwise alignments.
Table 1. Ortholog sequence identity and coverage in pairwise alignments.
Symbol 1Query 2LengthFromToCoverSubjectIdentityGaps
EptAXoo5562455696%Pae45%1%
Pae567654495%Xoo45%1%
Xoo5562254995%Nmb38%1%
Nmb544754098%Xoo38%2%
LpxEXoo2544725180%Pae33%1%
Pae2641623282%Xoo33%2%
Xoo25410716924%Ret29%7%
Ret24410321546%Xoo32%11%
ArnTXoo5773033653%Pae31%8%
Pae5494034556%Xoo32%8%
ArnC 3Xoo240621286%Pae30%2%
Pae339921460%Xoo30%2%
FlmF1 4Xoo3481732087%Fno38%0%
Fno314931296%Xoo38%0%
1 Locus tags and accession numbers are in Table S1. 2 Fno, Francisella novicida U112; Nmb, Neisseria meningitidis MC58; Ret, Rhizobium etli (leguminosarum) CFN42; Pae, Pseudomonas aeruginosa PAO1; Xoo, Xanthomonas oryzae pv. oryzae PXO99A. 3 Xoo gene PXO_RS22265. 4 Xoo gene PXO_RS14680.
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Stewart, V.; Ronald, P.C. The Xanthomonas RaxH-RaxR Two-Component Regulatory System Is Orthologous to the Zinc-Responsive Pseudomonas ColS-ColR System. Microorganisms 2021, 9, 1458. https://doi.org/10.3390/microorganisms9071458

AMA Style

Stewart V, Ronald PC. The Xanthomonas RaxH-RaxR Two-Component Regulatory System Is Orthologous to the Zinc-Responsive Pseudomonas ColS-ColR System. Microorganisms. 2021; 9(7):1458. https://doi.org/10.3390/microorganisms9071458

Chicago/Turabian Style

Stewart, Valley, and Pamela C. Ronald. 2021. "The Xanthomonas RaxH-RaxR Two-Component Regulatory System Is Orthologous to the Zinc-Responsive Pseudomonas ColS-ColR System" Microorganisms 9, no. 7: 1458. https://doi.org/10.3390/microorganisms9071458

APA Style

Stewart, V., & Ronald, P. C. (2021). The Xanthomonas RaxH-RaxR Two-Component Regulatory System Is Orthologous to the Zinc-Responsive Pseudomonas ColS-ColR System. Microorganisms, 9(7), 1458. https://doi.org/10.3390/microorganisms9071458

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