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Article

The Light- and Jasmonic Acid-Induced AaMYB108-like Positive Regulates the Initiation of Glandular Secretory Trichome in Artemisia annua L.

Frontiers Science Center for Transformative Molecules, Joint International Research Laboratory of Metabolic and Developmental Sciences, Plant Biotechnology Research Center, Fudan-SJTU Nottingham Plant Biotechnology R&D Center, School of Agriculture and Biology, Shanghai Jiao Tong University, Shanghai 200240, China
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Authors to whom correspondence should be addressed.
Int. J. Mol. Sci. 2023, 24(16), 12929; https://doi.org/10.3390/ijms241612929
Submission received: 31 July 2023 / Revised: 15 August 2023 / Accepted: 17 August 2023 / Published: 18 August 2023
(This article belongs to the Section Molecular Plant Sciences)

Abstract

:
The plant Artemisia annua L. is famous for producing “artemisinin”, which is an essential component in the treatment of malaria. The glandular secretory trichomes (GSTs) on the leaves of A. annua secrete and store artemisinin. Previous research has demonstrated that raising GST density can effectively raise artemisinin content. However, the molecular mechanism of GST initiation is not fully understood yet. In this study, we identified an MYB transcription factor, the AaMYB108-like, which is co-induced by light and jasmonic acid, and positively regulates glandular secretory trichome initiation in A. annua. Overexpression of the AaMYB108-like gene in A. annua increased GST density and enhanced the artemisinin content, whereas anti-sense of the AaMYB108-like gene resulted in the reduction in GST density and artemisinin content. Further experiments demonstrated that the AaMYB108-like gene could form a complex with AaHD8 to promote the expression of downstream AaHD1, resulting in the initiation of GST. Taken together, the AaMYB108-like gene is a positive regulator induced by light and jasmonic acid for GST initiation in A. annua.

1. Introduction

Malaria is a global health problem with a high-risk population of more than 3 billion people, mainly in Southeast Asia and Africa [1,2]. Artemisinin combination therapy (ACT) is the only effective malaria treatment recognized by the World Health Organization [3]. Artemisinin is a sesquiterpenoid isolated from the traditional Chinese medicine Artemisia annua, which is mainly synthesized and stored in the peltate glandular secretory trichome on the surface of A. annua leaves [4,5]. In wild-type A. annua, the artemisinin content is only 0.1–1.0% of the dry weight; therefore, research on the biosynthesis pathway of artemisinin and the development of glandular secretory trichome is important to improve the content of artemisinin in A. annua [6].
As a specialized metabolite, the biosynthetic pathway of artemisinin has been fully resolved [6]. Studies surrounding the transcriptional regulation of four key artemisinin enzymes, ADS, CYP71AV1, DBR2, and ALDH1, have become a hot topic in recent years. Researchers have achieved many results in the study of transcription factors promoting artemisinin biosynthesis. AaERF1, AaERF2, and AaTAR1, all belonging to the AP2/ERF transcription factor family, enhance artemisinin biosynthesis by promoting the expression of ADS, CYP71AV1, and DBR2 [7,8,9]. Artemisinin biosynthesis is regulated by several phytohormones. Jasmonic acid and abscisic acid have been found to promote artemisinin biosynthesis. bZIP transcription factor AabZIP1 is regulated by ABA to promote artemisinin biosynthesis [10]. AaORA and AaGSW1 (GLANDULAR TRICHOME-SPECIFIC WRKY 1) are transcription factors that are induced by both jasmonic acid and abscisic acid. AaORA is a positive regulator of artemisinin synthesis, and AaGSW1 not only promotes CYP71AV1 expression directly but also promotes artemisinin biosynthesis indirectly through AaORA [8,11]. AaTCP15 can form a complex with AaORA and thus promote the expression of downstream genes [12]. Light signals, as the most important signals for plants in nature, have profound effects on plant growth, development, and specialized metabolism [13,14,15,16]. It was found that light signaling can co-regulate artemisinin synthesis with jasmonic acid signaling. The WRKY family transcription factor, AaWRKY9, is co-induced by light and jasmonic acid to promote artemisinin biosynthesis [17]. AaMYB108 reveals a light-dependent molecular mechanism of jasmonic acid-promoted artemisinin biosynthesis through interactions with AaGSW1 and AaCOP1 at the protein level [18].
The glandular secretory trichome on the surface of A. annua leaves is the main site of artemisinin biosynthesis and storage; therefore, increasing the density of the glandular secretory trichome is important to increase artemisinin content [19]. The HD-ZIP family transcription factors, AaHD1 and AaHD8, are positive regulators of A. annua glandular secretory trichome initiation. AaHD8 directly binds to the promoter of AaHD1 to promote the expression of AaHD1, thereby promoting the initiation of glandular secretory trichomes [20,21]. The HD-ZIP family is considered to be the main module of glandular secretory trichome development in A. annua. Other families of transcription factors have also been found to promote the initiation of A. annua glandular secretory trichomes. The MYB transcription factor AaMYB16 forms a complex with AaHD1 to promote the expression of downstream genes [22]. ERF family transcription factor, AaWIN1, is a positive regulator of glandular secretory trichome initiation [23]. AaSPL9 can directly regulate the expression of HD1 and thus promote the initiation of glandular secretory trichomes [24].
MYB family transcription factors play important roles in plant development and metabolism. Transcriptome analysis of co-treatment with light and jasmonic acids revealed that MYB family transcription factors were involved in the process of regulation of artemisinin biosynthesis by light and jasmonic acids in A. annua seedlings [4]. AaMYB108 is the core factor integrating light and jasmonic acid signaling to regulate artemisinin biosynthesis in A. annua [18]. There is evidence that homologs of AaMYB108 are present in A. annua, and it is interesting to study the function of AaMYB108 homologs.
According to previous studies, glandular trichome initiation is also regulated by hormones and light, but the molecular mechanism by which light and hormones co-regulate glandular secretory trichome development in A. annua is unclear. In this study, we identified an MYB transcription factor, the AaMYB108-like gene, as a positive regulator of the initiation of glandular secretory trichomes. The AaMYB108-like gene was co-induced by light and jasmonic acid. Overexpression of the AaMYB108-like gene increased glandular secretory trichome density, and thus the AaMYB108-like gene is a positive regulator of glandular secretory trichome development in A. annua. Further experiments demonstrated that the AaMYB108-like gene could form a complex with AaHD8 to promote the expression of downstream AaHD1 and, thus, the initiation of GST. Taken together, we identified an MYB transcription factor that is co-induced by light and jasmonic acid, which could promote artemisinin accumulation by positively regulating the GST density in A. annua leaves.

2. Results

2.1. Identification of the AaMYB108-like Gene from A. annua

AaMYB108 is a positive regulator of artemisinin biosynthesis that is co-induced by light and jasmonic acid. We found the homolog gene of AaMYB108 by sequence analysis, Aannua01621S233630, which is named the AaMYB108-like gene (Figure 1A). We further investigated whether the AaMYB108-like gene is involved in artemisinin synthesis and glandular secretory trichome development. By gene cloning, we obtained a gene with a coding sequence (CDS) length of 960 bp, encoding 319 amino acids. The amino acid sequence comparison revealed that the AaMYB108-like gene was 60% homologous to AaMYB108 (Figure 1B).

2.2. Co-Induction of AaMYB108-like Gene Expression by Light and Jasmonic Acid

To further characterize the AaMYB108-like gene, we examined the effects of light and jasmonic acid on its expression. We used 100 µM of exogenous methyl jasmonate (MJ) for wild-type A. annua seedlings and analysis of the quantitative real-time PCR (qRT-PCR) results revealed that AaMYB108-like gene expression was induced by jasmonic acid (Figure 2A). Similarly, we subjected wild-type A. annua seedlings to light and dark treatments, and the qRT-PCR results showed that light could induce the expression of the AaMYB108-like gene (Figure 2B). According to the above experimental results, the AaMYB108-like gene is an MYB family transcription factor induced by both light and jasmonic acid.

2.3. Expression Pattern of the AaMYB108-like Gene

According to the transcriptome data of the various tissues in A. annua, glandular trichomes are where the AaMYB108-like gene is highly expressed. QRT-PCR research was carried out to look into the AaMYB108-like gene expression patterns in both space and time. The AaMYB108-like gene had the highest expression in glandular trichomes in various tissues, according to the results of the qRT-PCR study (Figure 3A).
In order to more clearly illustrate the expression pattern of the AaMYB108-like gene, we transformed wild-type (WT) A. annua with 1391Z-proMYB108-like-GUS (-glucuronidase), where expression of the GUS reporter is driven by the 1878-base pair (bp) promoter sequence of the AaMYB108-like gene. Histochemical GUS staining of the 1391Z-proMYB108-like-GUS transgenic lines revealed GUS activity, particularly in the glandular secretory trichomes (GST) of early leaves and stems (Figure 3B). The expression pattern of the GUS reporter and the detected expression patterns by qRT-PCR exhibited a good correlation. In summary, the AaMYB108-like gene is a transcription factor that is highly expressed in A. annua glandular trichomes.

2.4. Subcellular Localization of the AaMYB108-like Gene

We created a pHB-AaMYB108-like-YFP (yellow fluorescent protein) fusion construct and transiently expressed it in Nicotiana benthamiana leaves in order to further investigate the subcellular location of the AaMYB108-like gene (Figure 4). We discovered via fluorescence microscopy that the YFP signals were very strong in the nucleus. According to these findings, the AaMYB108-like protein is localized to the nucleus, which is consistent with its function as a transcription factor.

2.5. Overexpressing AaMYB108-like Gene Increased GST Density in A. annua

Transgenic A. annua plants were created in order to investigate the function of the AaMYB108-like gene. After PCR detection, we obtained 17 AaMYB108-like overexpression lines and 14 anti-AaMYB108-like lines. Following the transgenic test, three AaMYB108-like overexpression lines and three anti-AaMYB108-like lines were chosen for phenotype analysis. Firstly, the leaves of AaMYB108-like transgenic plants were collected for artemisinin extraction, and the content of artemisinin in the leaves was determined by HPLC. The results of the HPLC assay showed that overexpression of the AaMYB108-like gene increased the artemisinin content compared to wild-type A. annua, while the interference expression of the AaMYB108-like gene decreased the artemisinin content (Figure 5A). When the expression of key enzymes in AaMYB108-like transgenic plants was examined, it was found that the expression of the four key enzymes of artemisinin biosynthesis did not show a trend consistent with the artemisinin content (Figure 5B,C).
Considering that the increase in the number of GST of A. annua can cause an increase in artemisinin content, the GST on the leaf surface of AaMYB108-like transgenic plants were observed in this study. Surprisingly, in lines overexpressing the AaMYB108-like gene, the density of GST on the surface of leaves rose by at least 60% (Figure 5D,E).

2.6. The AaMYB108-like Gene Interacts with AaHD8 to Promote AaHD1 Expression

To investigate the molecular mechanism by which the AaMYB108-like gene promotes glandular secretory trichome initiation, we used a yeast two-hybrid assay first. The results show that the AaMYB108-like gene interacts with AaHD8 (Figure 6A), a reported positive regulator of glandular secretory trichome initiation, which promotes downstream AaHD1 expression. Subsequently, we used a Dual-LUC assay to confirm that the interaction of the AaMYB108-like gene with AaHD8 could enhance the activation of AaHD8 for AaHD1 (Figure 6B). We also examined the expression of AaHD1 in AaMYB108-like transgenic plants and found that overexpression of the AaMYB108-like gene increased the expression of AaHD1 (Figure 6C). Therefore, we can conclude that the AaMYB108-like gene forms a complex with AaHD8 to promote the expression of the downstream gene AaHD1 and thus promote glandular secretory trichome initiation.

3. Discussion

Based on these results, the AaMYB108-like gene is a positive regulator that promotes glandular trichomes initiation in A. annua. The functions of transcription factors are usually diverse. According to the analysis of the AaMYB108-like gene expression pattern, we can speculate that the AaMYB108-like gene may be associated with flower development. Overexpression of the AaMYB108-like gene can increase the density of glandular trichomes, ultimately leading to the overaccumulation of artemisinin. This suggests that increasing the density of glandular trichomes is an effective strategy to increase the content of artemisinin. Light and jasmonic acid regulate the initiation of glandular trichomes via the AaMYB108-like gene in A. annua, suggesting that glandular trichomes initiation is a complex process. Interaction between the AaMYB108-like gene and AaHD1 explains the molecular mechanism by which the AaMYB108-like gene regulates glandular trichomes initiation; however, the regulatory network for glandular trichomes initiation and development remains unclear in A. annua.
The study of increasing the active ingredients of medicinal plants has become a desirable topic in the field of plant-specialized metabolism research. Although the exogenous application of plant growth regulators and ploidy breeding are used successfully to increase the contents of specialized metabolites in medicinal plants, genetic engineering has been demonstrated to be another effective approach [25,26,27,28,29,30,31]. For example, overexpression of the biosynthetic pathway genes or downregulation of the competitive branching pathway by anti-sense or RNAi technologies can improve the production of important metabolites such as artemisinin in A. annua [32,33,34,35], vinblastine in Catharanthus roseus [36], scopolamine in Atropa belladonna [37], and tropane alkaloids in Hyoscyamus niger [38]. Along with the large amount of omics data generated and the development of the regulatory network of important specialized metabolites from medicinal plant species [39,40], a range of transcription factors belonging to various families, including MYB [41], AP2/ERF [42], MYC [43], bZIP [44], WRKY [45], YABBY [46,47], TCP [48], NAC [49], SPL [50], MADS-box [51], and bHLH [52,53] have been identified and demonstrated to have positive functions for elevating the accumulation of various specialized metabolites such as artemisinin, showing their promising application values for the trait improvement in medicinal plants.
Plant glandular trichomes are known as plant factories because of their richness in natural chemical products. Therefore, increasing the density of glandular trichomes is an effective means to obtain high-content varieties. The molecular mechanism of glandular hair initiation and development remains to be studied, and no structural genes related to glandular hair initiation have been reported. In the case of A. annua, the study of glandular trichome initiation is also of great importance. After years of research, a regulatory network of glandular trichome initiation has been formed with HD-ZIP and MYB transcription factors as the core factors [45]. Summarizing past studies, we can find that the development of plant glandular trichomes is regulated by both hormones and light. JA, Gibberellic Acid (GA), ABA, and other plant hormones have been reported to regulate glandular trichome initiation [21,24]. However, the molecular mechanisms by which light and plant hormones jointly regulate glandular trichome initiation are not clear. On this basis, we found that the AaMYB108-like gene was regulated by light and jasmonic acid and further elucidated the molecular mechanisms by which light and jasmonic acid regulate glandular trichome initiation. Our study provides new ideas for exploring the molecular mechanisms of glandular trichome development. It is easy to see from our study that increasing the density of glandular trichomes can effectively increase the content of artemisinin. Our research provides new ideas for obtaining high-content varieties in production.

4. Materials and Methods

4.1. Plant Materials and Growth Conditions

The A. annua used in this investigation was “Huhao 1”, which was created in Shanghai following years of selection and was taken from Chongqing, China [6]. Plantlets of A. annua and Nicotiana benthamiana were planted in a glasshouse with a photoperiod of 16 h:8 h, light:dark, and 25 °C. All the plants were cultivated with a mixture of vermiculite and nutrient soil.

4.2. Treatment of Light, Dark and MJ

For later usage, seedlings of wild-type A. annua that were 14 days old and at the same growth stage were chosen. Half (10 pots, 4 plants per pot) were kept under continuous illumination and half (10 pots) were transferred to completely dark conditions. Leaves were sampled at 0 h and 3 h during treatment and frozen in liquid nitrogen for RNA extraction. For jasmonic acid treatment, 14-day-old A. annua seedlings with the same growth status were treated with methyl jasmonate (MJ) of 100 μmol/L, then sampled at 0 h, 1 h, 3 h, and 6 h after spraying treatment.

4.3. Isolation of Glandular Trichomes

Flower buds (20 g) were mixed with 0.5 mm glass beads (50 g) and extraction buffer (250 mL). The mixture was shaken thoroughly for 1 min; then, the process was repeated three times. The mixture was sequentially passed through 350 μm, 105 μm, and 20 μm nylon sieves to isolate the glass beads and tissue fragments. Glandular trichomes were collected on the 20 μm nylon sieves and were washed by buffer at least eight times. Tissues and glandular trichomes were stored and disposed of in ice.

4.4. RNA Extraction and RT-qPCR

Total RNA was extracted from each sample using the RNAprep Pure Plant Kit (Tiangen, Beijing, China) according to the manufacturer’s instructions in order to analyze the expression patterns of the AaMYB108-like gene in various tissues (root, stem, young leaf (YL), old leaf (OL), buds, flower, shoot, and trichome). PrimeScript™ RT Master Mix was used to create first-strand cDNA for qRT-PCR from whole RNA (TaKaRa, Shiga, Japan). TB Green® Premix EX Taq™ II was used to conduct QRT-PCR analyses (Takara, Japan). For each analysis, three technical and biological replicates were duplicated. Actin was chosen as the reference or control. All primers used are listed in Table S1.

4.5. Subcellular Localization

To create a pHB-AaMYB108-like-YFP fusion protein, the open reading frame (ORF) of the AaMYB108-like gene was amplified using KOD (Thermococcus kodakaraensis KOD1) plus DNA polymerase and then cloned into the plant expression vector pHB-YFP. The plasmid was then introduced into the Agrobacterium tumefaciens strain GV3101 for transient expression in N. benthamiana leaves, with pHB-YFP serving as the negative control. Confocal laser microscopy was used to study the fluorescent signals of N. benthamiana leaves after 48 h of low light (Leica TCS SP5-II).

4.6. Transformation of Artemisia annua

Using KOD plus DNA polymerase (Toyobo, Osaka, Japan), the 960 bp full-length cDNA of the AaMYB108-like gene was amplified before being cloned into the pHB vector. In order to genetically transform the A. tumefaciens strain EHA105 into A. annua for further investigation, the constructed pHB-AaMYB108-like gene was added [54]. A. annua seeds were first planted on germination medium MS0, and they were then grown at 24 °C to 26 °C with a 16 h light cycle and an 8 h dark cycle (8000 lux). After two weeks, the seedlings’ leaves were harvested, cut into 0.5-cm-diameter discs, and co-cultivated with the A. tumefaciens strain EHA105 for three days at 25 °C. As soon as the leaves were moved to the selective medium MS1 (MS0 + 2.5 mg/L N6-benzoyladenine + 0.3 mg/L naphthalene-1-acetic acid + 50 mg/L hygromycin + 250 mg/L carbenicillin), we chose the antibiotic-resistant plantlets and subcultured them three times before moving them to the rooting medium MS2 (12 MS0 + 250 mg/L carbenicillin). Eventually, the rooted plantlets were transplanted to soil pots in the growth chamber after 1 month.

4.7. GUS Expression in 1391Z-proMYB108-like-GUS Transgenic A. annua Plants

To create 1391Z-proAaMYB108-like-GUS plants, the 1878 bp promoter region of the AaMYB108-like gene upstream of the initiation codon was found in the genomes of A. annua. The promoter of the AaMYB108-like gene was cloned and inserted into the pCambia1391Z vector with the GUS reporter. For the transformation of A. annua plants, the recombinant plasmids were converted into A. tumefaciens strain EHA105. As previously mentioned, GUS staining was carried out [55]. Observation of the sample was conducted with an optical microscope, adjusted to a 10× eyepiece and 20× objective. GUS activity appeared blue in the field of view.

4.8. Artemisinin Content Measurement

A. annua leaves that were 4 months old were collected and dried in an oven at 50 °C. After that, leaves were powdered, and 0.1 g of that powder were extracted twice with 2 mL of methanol using ultrasonic for 30 min at a temperature of 55 °C. The supernatants were filtered through nitrocellulose (0.22 m) after centrifuging 12,000× g for 10 min. Using high-performance liquid chromatography (HPLC), the artemisinin’s components were examined [56]. The filtrates were analyzed by the Waters Alliance 2695 HPLC system coupled with a Waters 2420 ELSD detector (Milford, MA, USA). The HPLC conditions were set as described previously [8]. The standard of artemisinin was purchased from Sigma, and the standards of dihydroartemisinic acid were obtained from Guangzhou Honsea Sunshine Bio Science and Technology Co., Ltd. (Guangzhou, Guangdong, China). All samples were measured three times for technical replications.

4.9. Bimolecular Fluorescence Complementation Assays

For bimolecular fluorescence complementation (BiFC) assays, the open reading frame of the AaMYB108-like gene was cloned into the pxy106-nYFP vector, and the full-length coding region of AaHD8 was inserted into the pxy104-cYFP vector. The recombinant plasmids and the empty vectors were transferred into GV3101. Subsequently, combinations of the plasmids were co-transformed into N. benthamiana leaves. Confocal laser microscopy (Leica TCS SP5-II) was used to observe the YFP signals.

4.10. Yeast Two-Hybrid (Y2H) Assays

To create the pGADT7-AaMYB108-like gene, the whole coding sequence of the AaMYB108-like gene was cloned and placed into the pGADT7 vector. AaHD8 were then introduced into the pGBKT7 vector. Negative controls included the usage of the empty pGADT7 and pGBKT7 vectors. The recombinant plasmid combinations were added to yeast stain AH109. In SD/-Leu/-Trp (DDO) agar medium plates, the positive clones were grown. These plates were then switched over to SD/-Leu/-Trp/-His (TDO) and SD/-Leu/-Trp/-His/-Ade (QDO) medium plates. After three days, the outcomes were observed.

4.11. Dual-LUC (Dual-Luciferase Reporter) Assay

The PHB-AaMYB108-like gene and pHB-AaHD8 were transformed into A. tumefaciens strain GV3101 to act as an effector, and the pHB empty vector was used as a negative control. The promoter of AaHD1 was cloned into a pGREEN II 0800 vector as a reporter and transformed into A. tumefaciens strain GV3101 with the help of the helper plasmid pSoup 19. For the purpose of transforming 4-week-old tobacco leaves, the effectors and reporters were combined in a 9:1 volume ratio [57]. After 48 h of low light incubation, N. benthamiana’s invaded leaves were discovered utilizing the Dual-Luciferase Reporter Assay System (Promega, Madison, WI, USA). The relative LUC/REN ratios were utilized to reflect the activity of the promoter after the activity of LUC was normalized to the activity of REN. Four biological repeats were performed for each sample.

5. Conclusions

Our study identified a positive regulator promoting glandular trichomes initiation by bioinformatics analysis in A. annua. The expression of the AaMYB108-like gene was co-induced by light and jasmonic acid, and it was highly expressed in glandular trichomes. AaMYB108-like transgenic experiments showed that overexpression of the AaMYB108-like gene promoted glandular trichomes initiation in A. annua. The interaction between the AaMYB108-like gene and AaHD1 explains the molecular mechanism by which the AaMYB108-like gene regulates glandular trichomes initiation. Based on our results, we can conclude that the AaMYB108-like gene is a positive regulator of glandular trichomes initiation induced by both light and jasmonic acid. The initiation and development of plant glandular trichomes is a complex process that deserves more in-depth study.

Supplementary Materials

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/ijms241612929/s1.

Author Contributions

H.L. and K.T. designed the project. H.L., W.H., X.Y. (Xinghao Yao), X.Y. (Xin Yan) and X.W. performed most of the experiments. B.P., Y.Z., J.S., X.H., Q.M., L.L. and K.T. analyzed the data and discussed the article. H.L. wrote the manuscript. All authors contributed to the article and approved the submitted version. All authors have read and agreed to the published version of the manuscript.

Funding

This research was funded by the National Natural Science Foundation of China (82274047 and 31770327), the National Key R&D Program of China (2018YFA0900600), and the Bill and Melinda Gates Foundation (OPP1199872 and INV-027291). And The APC was funded by the Bill and Melinda Gates Foundation (OPP1199872 and INV-027291).

Institutional Review Board Statement

Not applicable.

Informed Consent Statement

Not applicable.

Data Availability Statement

The datasets presented in this study can be found in online repositories. The names of the repository/repositories and accession number(s) can be found in the article/Supplementary Material.

Acknowledgments

This work was supported, in whole or in part, by the National Natural Science Foundation of China (82274047 and 31770327), the National Key R&D Program of China (2018YFA0900600), and the Bill and Melinda Gates Foundation (OPP1199872 and INV-027291). Under the grant conditions of the Foundation, a Creative Commons Attribution 4.0 Generic License has already been assigned to the Author Accepted Manuscript version that might arise from this submission. We also want to thank the Instrumental Analysis Center of Shanghai Jiao Tong University for the metabolite analysis.

Conflicts of Interest

The authors declare no conflict of interest.

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Figure 1. Phylogenetic analysis of AaMYB108-like gene. (A) The protein sequence alignment of AaMYB108-like gene and AaMYB108. Candidate genes marked by red frame. (B) Phylogenetic analysis was performed using MYB family proteins from A. annua. The tree presented here is a neighbor-joining tree based on amino acid sequence alignment and constructed using the program MEGA. Black highlights are identical amino acid sequences. Every 10 amino acids are marked with an asterisk “*”.
Figure 1. Phylogenetic analysis of AaMYB108-like gene. (A) The protein sequence alignment of AaMYB108-like gene and AaMYB108. Candidate genes marked by red frame. (B) Phylogenetic analysis was performed using MYB family proteins from A. annua. The tree presented here is a neighbor-joining tree based on amino acid sequence alignment and constructed using the program MEGA. Black highlights are identical amino acid sequences. Every 10 amino acids are marked with an asterisk “*”.
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Figure 2. Co-induction of AaMYB108-like gene expression by light and jasmonic acid in A. annua. (A) Relative expression of the AaMYB108-like gene in response to methyl jasmonate (MJ, 100 μM) by RT-qPCR. Data values are means ± SD (n = 3). (B) Light could induce the expression of the AaMYB108-like gene. Data values are means ± SD (n = 3). (C) Dark treatment decreased AaMYB108-like expression. Data values are means ± SD (n = 3).
Figure 2. Co-induction of AaMYB108-like gene expression by light and jasmonic acid in A. annua. (A) Relative expression of the AaMYB108-like gene in response to methyl jasmonate (MJ, 100 μM) by RT-qPCR. Data values are means ± SD (n = 3). (B) Light could induce the expression of the AaMYB108-like gene. Data values are means ± SD (n = 3). (C) Dark treatment decreased AaMYB108-like expression. Data values are means ± SD (n = 3).
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Figure 3. Expression pattern of the AaMYB108-like gene. (A) Relative expression levels of the AaMYB108-like gene in different tissues. Data values are means ± SD (n = 3). (B) β-Glucuronidase expression of 1391-proAaMYB108-like-GUS transgenic A.annua plants. Bars: 100 μm.
Figure 3. Expression pattern of the AaMYB108-like gene. (A) Relative expression levels of the AaMYB108-like gene in different tissues. Data values are means ± SD (n = 3). (B) β-Glucuronidase expression of 1391-proAaMYB108-like-GUS transgenic A.annua plants. Bars: 100 μm.
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Figure 4. The subcellular localization of the AaMYB108-like gene in leaves of N. benthamiana. Yellow, yellow fluorescent protein (YFP). Bars: 50 μm.
Figure 4. The subcellular localization of the AaMYB108-like gene in leaves of N. benthamiana. Yellow, yellow fluorescent protein (YFP). Bars: 50 μm.
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Figure 5. The AaMYB108-like gene is a positive regulator of glandular secretory trichome initiation in A. annua. (A) High-performance liquid chromatography (HPLC) analysis of the artemisinin content (mg.g−1 DW) in transgenic A. annua plants. (B,C) Expression of key enzyme genes in AaMYB108-like overexpression transgenic plants. (D) The glandular secretory trichomes on the adaxial side of mature leaves derived from wild-type (WT) plants, OE-AaMYB108-like transgenic A. annua plants, and anti-sense-AaMYB108-like transgenic A. annua plants (bars: 200 mm). (E) Glandular secretory trichomes density of mature leaves derived from WT and AaMYB108-like transgenic plants. All data are presented as means ± SD (n = 3) ** p < 0.01; Student’s t-test.
Figure 5. The AaMYB108-like gene is a positive regulator of glandular secretory trichome initiation in A. annua. (A) High-performance liquid chromatography (HPLC) analysis of the artemisinin content (mg.g−1 DW) in transgenic A. annua plants. (B,C) Expression of key enzyme genes in AaMYB108-like overexpression transgenic plants. (D) The glandular secretory trichomes on the adaxial side of mature leaves derived from wild-type (WT) plants, OE-AaMYB108-like transgenic A. annua plants, and anti-sense-AaMYB108-like transgenic A. annua plants (bars: 200 mm). (E) Glandular secretory trichomes density of mature leaves derived from WT and AaMYB108-like transgenic plants. All data are presented as means ± SD (n = 3) ** p < 0.01; Student’s t-test.
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Figure 6. The AaMYB108-like gene interacts with AaHD8 to promote AaHD1 expression. (A) Bimolecular fluorescence complementation assay between the AaMYB108-like gene and AaHD8. Yellow, yellow fluorescent protein (YFP). Bars: 50 μm. (B) Y2H analysis of AaMYB108-like gene interaction with AaHD8. (C) Dual-LUC assays performed in N. benthamiana leaves of co-expressing AaMYB108-like and AaHD8 genes. (D) Expression of AaHD1 in AaMYB108-like transgenic plants. All data are presented as means ± SD (n = 3) ** p < 0.01; Student’s t-test.
Figure 6. The AaMYB108-like gene interacts with AaHD8 to promote AaHD1 expression. (A) Bimolecular fluorescence complementation assay between the AaMYB108-like gene and AaHD8. Yellow, yellow fluorescent protein (YFP). Bars: 50 μm. (B) Y2H analysis of AaMYB108-like gene interaction with AaHD8. (C) Dual-LUC assays performed in N. benthamiana leaves of co-expressing AaMYB108-like and AaHD8 genes. (D) Expression of AaHD1 in AaMYB108-like transgenic plants. All data are presented as means ± SD (n = 3) ** p < 0.01; Student’s t-test.
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Liu, H.; He, W.; Yao, X.; Yan, X.; Wang, X.; Peng, B.; Zhang, Y.; Shao, J.; Hu, X.; Miao, Q.; et al. The Light- and Jasmonic Acid-Induced AaMYB108-like Positive Regulates the Initiation of Glandular Secretory Trichome in Artemisia annua L. Int. J. Mol. Sci. 2023, 24, 12929. https://doi.org/10.3390/ijms241612929

AMA Style

Liu H, He W, Yao X, Yan X, Wang X, Peng B, Zhang Y, Shao J, Hu X, Miao Q, et al. The Light- and Jasmonic Acid-Induced AaMYB108-like Positive Regulates the Initiation of Glandular Secretory Trichome in Artemisia annua L. International Journal of Molecular Sciences. 2023; 24(16):12929. https://doi.org/10.3390/ijms241612929

Chicago/Turabian Style

Liu, Hang, Weizhi He, Xinghao Yao, Xin Yan, Xiuyun Wang, Bowen Peng, Yaojie Zhang, Jin Shao, Xinyi Hu, Qing Miao, and et al. 2023. "The Light- and Jasmonic Acid-Induced AaMYB108-like Positive Regulates the Initiation of Glandular Secretory Trichome in Artemisia annua L." International Journal of Molecular Sciences 24, no. 16: 12929. https://doi.org/10.3390/ijms241612929

APA Style

Liu, H., He, W., Yao, X., Yan, X., Wang, X., Peng, B., Zhang, Y., Shao, J., Hu, X., Miao, Q., Li, L., & Tang, K. (2023). The Light- and Jasmonic Acid-Induced AaMYB108-like Positive Regulates the Initiation of Glandular Secretory Trichome in Artemisia annua L. International Journal of Molecular Sciences, 24(16), 12929. https://doi.org/10.3390/ijms241612929

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