Identification and knockout of rhamnose synthase CiRHM1 enhances accumulation of flavone aglycones in chrysanthemum flower

IF 10.1 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY
Chang Luo, Jiayi Luo, Mingzheng Han, Zhenzhen Song, Yahui Sun, Yaqin Wang, Yafei Zhao, Conglin Huang, Junping Gao, Bo Hong, Chao Ma
{"title":"Identification and knockout of rhamnose synthase CiRHM1 enhances accumulation of flavone aglycones in chrysanthemum flower","authors":"Chang Luo, Jiayi Luo, Mingzheng Han, Zhenzhen Song, Yahui Sun, Yaqin Wang, Yafei Zhao, Conglin Huang, Junping Gao, Bo Hong, Chao Ma","doi":"10.1111/pbi.14556","DOIUrl":null,"url":null,"abstract":"<p>Flavonoids play critical roles in plant adaptation to environmental changes and are valuable medicinal resources (Chagas <i>et al</i>., <span>2022</span>). Flavonoids are predominantly found in glycosylated forms, which exhibit increased structural complexity, solubility and stability. However, the aglycone forms of flavonoids exhibit greater antioxidant capacity and bioavailability (Xie <i>et al</i>., <span>2022</span>). Enhancing the content of flavonoid aglycones in crops can improve their nutritional value and health benefits for humans.</p>\n<p>In plants, UDP-rhamnose serves as a key sugar donor in flavonoid glycosylation, synthesized from UDP-glucose via the enzyme rhamnose synthase (RHM). In Arabidopsis (<i>Arabidopsis thaliana</i>), mutations in the <i>RHM1</i> lead to significant reduction in rhamnosylated flavonols (Saffer and Irish, <span>2018</span>). However, as Arabidopsis lacks flavone synthase and flavones, the impacts of UDP-rhamnose on flavone aglycone or glycoside biosynthesis are unknown.</p>\n<p><i>Chrysanthemum indicum</i>, a notable medicinal plant, has been used in traditional Chinese medicine for over 2000 years (He <i>et al</i>., <span>2016</span>). The dried flowers of <i>C. indicum</i>, known as ‘Yejuhua’ in the <i>Pharmacopoeia of the People's Republic of China</i> (2020 edition), are recognized for their anti-inflammatory, antioxidant, antimicrobial, anticancer and immunomodulatory properties (Xie <i>et al</i>., <span>2012</span>). These pharmaceutical effects are largely attributed to the high flavone content, particularly compounds like apigenin, luteolin and their derivatives (Shao <i>et al</i>., <span>2020</span>). Previous studies have shown significant variations in morphology and metabolic composition among different eco-geographic populations (ecotypes) of <i>C. indicum</i> in China, influencing their medicinal and nutritional value (Fang <i>et al</i>., <span>2012</span>).</p>\n<p>To explore the natural variation of flavones in <i>C. indicum</i>, we collected ecotypes from various regions across China, and quantified the major bioactive flavone, apigenin, in the flowers using ultra-performance liquid chromatography–tandem mass spectrometry (UPLC–MS). A metabolite-based genome-wide association study (mGWAS) was performed on 72 ecotypes exhibiting distinct apigenin content (Figure 1a; Dataset S1). The association analysis showed that the natural variation in apigenin content across these ecotypes was governed by two loci located on chromosomes 2 and 9 (Figure 1b–c). Within the locus on chromosome 2, we identified a <i>TREHALOSE-6-PHOSPHATE SYNTHASE1</i> gene (<i>CiTPS1</i>, Cse_sc000461.1_g010.1) and <i>CiRHM1</i> (Cse_sc000461.1_g020.1) (Figure 1b; Table S1). Collinearity analysis indicated that the <i>TPS1-RHM1</i> gene cluster is conserved among dicotyledonous plants (Figure S1). RNA-seq of 18 ecotypes showed that the expression of <i>CiRHM1</i> was negatively correlated with apigenin content (Figure 1d, Table S2), while <i>CiTPS1</i> expression displayed no correlation (Figure S2a, Table S2). Furthermore, we identified one paralog of <i>CiRHM1</i> located on chromosome 6 of <i>C. indicum</i> genome, named <i>CiRHM1-like</i> (Cse_sc005633.1_g060.1, Figure S3), whose expression showed a lower correlation with apigenin content compared to <i>CiRHM1</i> (Figure S2b). Therefore, <i>CiRHM1</i> was selected as a candidate gene for further functional analysis. Subsequent investigation identified the SNP (LG02: 36801176) located within the intron of <i>CiRHM1</i> (Table S1). Ecotypes with the homozygous T/T genotype at this SNP exhibited significantly higher apigenin content compared to those with the G/G genotype (Figure 1e).</p>\n<figure><picture>\n<source media=\"(min-width: 1650px)\" srcset=\"/cms/asset/7a5c1709-09ce-4be5-a426-e65c384d91f0/pbi14556-fig-0001-m.jpg\"/><img alt=\"Details are in the caption following the image\" data-lg-src=\"/cms/asset/7a5c1709-09ce-4be5-a426-e65c384d91f0/pbi14556-fig-0001-m.jpg\" loading=\"lazy\" src=\"/cms/asset/5cbee751-c5aa-4938-a3c6-c77b46f6e9e3/pbi14556-fig-0001-m.png\" title=\"Details are in the caption following the image\"/></picture><figcaption>\n<div><strong>Figure 1<span style=\"font-weight:normal\"></span></strong><div>Open in figure viewer<i aria-hidden=\"true\"></i><span>PowerPoint</span></div>\n</div>\n<div><i>CiRHM1</i> influences flavone aglycone content in <i>C. indicum</i>. (a) Frequency distribution of apigenin content across 72 <i>C. indicum</i> ecotypes. Classes of apigenin content are shown on the <i>x</i>-axis, and the corresponding counts of ecotypes are shown on the <i>y</i>-axis. (b) Manhattan plots displaying GWAS signals for SNPs associated with apigenin content. (c) Q–Q plot illustrating the GWAS results for apigenin. (d) Correlation analysis between the expression levels of <i>CiRHM1</i> and apigenin content. (e) Boxplot demonstrating significant associations between apigenin content and the SNP LG02:36801176. (f) Genotyping of <i>Cirhm1</i> mutants. (g) Phenotypes of WT and <i>Cirhm1</i> mutants. (h) Plant height measurements of WT and <i>Cirhm1</i> mutants. (i) Rhamnose and UDP-glucose contents in the flowers of WT and <i>Cirhm1</i> mutants. (j) Flavone aglycone content in the flowers of WT and <i>Cirhm1</i> mutants. Data are presented as mean ± SD from three biological replicates. Statistical significance between WT and <i>Cirhm1</i> mutants was determined using Student's <i>t</i>-test (*<i>P</i> &lt; 0.05, **<i>P</i> &lt; 0.01, ***<i>P</i> &lt; 0.001 and ****<i>P</i> &lt; 0.0001).</div>\n</figcaption>\n</figure>\n<p>We knocked out <i>CiRHM1</i> in <i>C. indicum</i> using our CRISPR/Cas9 gene editing platform (Liu <i>et al</i>., <span>2023</span>). Two single-guide RNAs (sgRNAs) were designed to specifically target the first exon of the <i>CiRHM1</i> gene, and two <i>Cirhm1</i> mutants were generated (Figure 1f). RT-qPCR results showed that knocking out <i>CiRHM1</i> significantly reduced its expression in <i>Cirhm1</i> mutants, while the expression levels of other RHM family genes remained unchanged (Figure S4). Although no significant differences in flowering were observed between the wild-type (WT) and mutants, the mutant plants exhibited reduced height compared to the WT (Figure 1g,h).</p>\n<p>We analysed the sugar profiles of flowers from both WT and <i>Cirhm1</i> mutants (Dataset S2). The results showed a significant decrease in L-rhamnose and UDP-rhamnose levels in <i>Cirhm1</i> mutants compared to WT (Figure 1i), confirming the role of CiRHM1 as a rhamnose synthase. Consistently, the levels of trehalose, glucose and sucrose were significantly higher in the flowers of <i>Cirhm1</i> mutants than in WT (Figure S5).</p>\n<p>Next, we measured the flavonoid content in the flowers of WT and <i>Cirhm1</i> mutants (Dataset S3). Flavone rhamnoside levels were significantly reduced in both <i>Cirhm1</i> mutants (Figure S6). In contrast, the content of flavone aglycones, including apigenin, luteolin, norwogonin, diosmetin and hispidulin, was significantly higher in <i>Cirhm1</i> mutants compared to WT (Figure 1j). Additionally, levels of flavone glucosides, such as apigenin 7-glucoside, luteolin 7-glucoside, genistein 7-glucoside and wogonin 7-O-glucuronide, were also elevated in <i>Cirhm1</i> mutants compared to WT (Figure S7).</p>\n<p>In summary, our study demonstrates that CiRHM1 influences flavone aglycone content in <i>C. indicum</i>. Furthermore, we developed novel germplasm of <i>C. indicum</i> with enhanced flavone aglycone content through genome editing.</p>","PeriodicalId":221,"journal":{"name":"Plant Biotechnology Journal","volume":"1 1","pages":""},"PeriodicalIF":10.1000,"publicationDate":"2024-12-15","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":null,"platform":"Semanticscholar","paperid":null,"PeriodicalName":"Plant Biotechnology Journal","FirstCategoryId":"5","ListUrlMain":"https://doi.org/10.1111/pbi.14556","RegionNum":1,"RegionCategory":"生物学","ArticlePicture":[],"TitleCN":null,"AbstractTextCN":null,"PMCID":null,"EPubDate":"","PubModel":"","JCR":"Q1","JCRName":"BIOTECHNOLOGY & APPLIED MICROBIOLOGY","Score":null,"Total":0}
引用次数: 0

Abstract

Flavonoids play critical roles in plant adaptation to environmental changes and are valuable medicinal resources (Chagas et al., 2022). Flavonoids are predominantly found in glycosylated forms, which exhibit increased structural complexity, solubility and stability. However, the aglycone forms of flavonoids exhibit greater antioxidant capacity and bioavailability (Xie et al., 2022). Enhancing the content of flavonoid aglycones in crops can improve their nutritional value and health benefits for humans.

In plants, UDP-rhamnose serves as a key sugar donor in flavonoid glycosylation, synthesized from UDP-glucose via the enzyme rhamnose synthase (RHM). In Arabidopsis (Arabidopsis thaliana), mutations in the RHM1 lead to significant reduction in rhamnosylated flavonols (Saffer and Irish, 2018). However, as Arabidopsis lacks flavone synthase and flavones, the impacts of UDP-rhamnose on flavone aglycone or glycoside biosynthesis are unknown.

Chrysanthemum indicum, a notable medicinal plant, has been used in traditional Chinese medicine for over 2000 years (He et al., 2016). The dried flowers of C. indicum, known as ‘Yejuhua’ in the Pharmacopoeia of the People's Republic of China (2020 edition), are recognized for their anti-inflammatory, antioxidant, antimicrobial, anticancer and immunomodulatory properties (Xie et al., 2012). These pharmaceutical effects are largely attributed to the high flavone content, particularly compounds like apigenin, luteolin and their derivatives (Shao et al., 2020). Previous studies have shown significant variations in morphology and metabolic composition among different eco-geographic populations (ecotypes) of C. indicum in China, influencing their medicinal and nutritional value (Fang et al., 2012).

To explore the natural variation of flavones in C. indicum, we collected ecotypes from various regions across China, and quantified the major bioactive flavone, apigenin, in the flowers using ultra-performance liquid chromatography–tandem mass spectrometry (UPLC–MS). A metabolite-based genome-wide association study (mGWAS) was performed on 72 ecotypes exhibiting distinct apigenin content (Figure 1a; Dataset S1). The association analysis showed that the natural variation in apigenin content across these ecotypes was governed by two loci located on chromosomes 2 and 9 (Figure 1b–c). Within the locus on chromosome 2, we identified a TREHALOSE-6-PHOSPHATE SYNTHASE1 gene (CiTPS1, Cse_sc000461.1_g010.1) and CiRHM1 (Cse_sc000461.1_g020.1) (Figure 1b; Table S1). Collinearity analysis indicated that the TPS1-RHM1 gene cluster is conserved among dicotyledonous plants (Figure S1). RNA-seq of 18 ecotypes showed that the expression of CiRHM1 was negatively correlated with apigenin content (Figure 1d, Table S2), while CiTPS1 expression displayed no correlation (Figure S2a, Table S2). Furthermore, we identified one paralog of CiRHM1 located on chromosome 6 of C. indicum genome, named CiRHM1-like (Cse_sc005633.1_g060.1, Figure S3), whose expression showed a lower correlation with apigenin content compared to CiRHM1 (Figure S2b). Therefore, CiRHM1 was selected as a candidate gene for further functional analysis. Subsequent investigation identified the SNP (LG02: 36801176) located within the intron of CiRHM1 (Table S1). Ecotypes with the homozygous T/T genotype at this SNP exhibited significantly higher apigenin content compared to those with the G/G genotype (Figure 1e).

Abstract Image
Figure 1
Open in figure viewerPowerPoint
CiRHM1 influences flavone aglycone content in C. indicum. (a) Frequency distribution of apigenin content across 72 C. indicum ecotypes. Classes of apigenin content are shown on the x-axis, and the corresponding counts of ecotypes are shown on the y-axis. (b) Manhattan plots displaying GWAS signals for SNPs associated with apigenin content. (c) Q–Q plot illustrating the GWAS results for apigenin. (d) Correlation analysis between the expression levels of CiRHM1 and apigenin content. (e) Boxplot demonstrating significant associations between apigenin content and the SNP LG02:36801176. (f) Genotyping of Cirhm1 mutants. (g) Phenotypes of WT and Cirhm1 mutants. (h) Plant height measurements of WT and Cirhm1 mutants. (i) Rhamnose and UDP-glucose contents in the flowers of WT and Cirhm1 mutants. (j) Flavone aglycone content in the flowers of WT and Cirhm1 mutants. Data are presented as mean ± SD from three biological replicates. Statistical significance between WT and Cirhm1 mutants was determined using Student's t-test (*P < 0.05, **P < 0.01, ***P < 0.001 and ****P < 0.0001).

We knocked out CiRHM1 in C. indicum using our CRISPR/Cas9 gene editing platform (Liu et al., 2023). Two single-guide RNAs (sgRNAs) were designed to specifically target the first exon of the CiRHM1 gene, and two Cirhm1 mutants were generated (Figure 1f). RT-qPCR results showed that knocking out CiRHM1 significantly reduced its expression in Cirhm1 mutants, while the expression levels of other RHM family genes remained unchanged (Figure S4). Although no significant differences in flowering were observed between the wild-type (WT) and mutants, the mutant plants exhibited reduced height compared to the WT (Figure 1g,h).

We analysed the sugar profiles of flowers from both WT and Cirhm1 mutants (Dataset S2). The results showed a significant decrease in L-rhamnose and UDP-rhamnose levels in Cirhm1 mutants compared to WT (Figure 1i), confirming the role of CiRHM1 as a rhamnose synthase. Consistently, the levels of trehalose, glucose and sucrose were significantly higher in the flowers of Cirhm1 mutants than in WT (Figure S5).

Next, we measured the flavonoid content in the flowers of WT and Cirhm1 mutants (Dataset S3). Flavone rhamnoside levels were significantly reduced in both Cirhm1 mutants (Figure S6). In contrast, the content of flavone aglycones, including apigenin, luteolin, norwogonin, diosmetin and hispidulin, was significantly higher in Cirhm1 mutants compared to WT (Figure 1j). Additionally, levels of flavone glucosides, such as apigenin 7-glucoside, luteolin 7-glucoside, genistein 7-glucoside and wogonin 7-O-glucuronide, were also elevated in Cirhm1 mutants compared to WT (Figure S7).

In summary, our study demonstrates that CiRHM1 influences flavone aglycone content in C. indicum. Furthermore, we developed novel germplasm of C. indicum with enhanced flavone aglycone content through genome editing.

鼠李糖合成酶 CiRHM1 的鉴定和基因敲除可促进菊花中黄酮苷的积累
类黄酮在植物适应环境变化方面发挥着关键作用,也是宝贵的药用资源(Chagas 等人,2022 年)。黄酮类化合物主要以糖基化形式存在,糖基化形式的黄酮类化合物具有更高的结构复杂性、溶解性和稳定性。然而,苷元形式的类黄酮具有更强的抗氧化能力和生物利用率(Xie 等人,2022 年)。在植物中,UDP-鼠李糖是类黄酮糖基化过程中的关键供糖体,通过鼠李糖合成酶(RHM)由 UDP-葡萄糖合成。在拟南芥(Arabidopsis thaliana)中,RHM1的突变会导致鼠李糖基化的黄酮醇显著减少(Saffer 和 Irish,2018 年)。然而,由于拟南芥缺乏黄酮合成酶和黄酮,UDP-鼠李糖对黄酮苷元或苷元生物合成的影响尚不清楚。菊花(Chrysanthemum indicum)是一种著名的药用植物,用于传统中药已有 2000 多年的历史(He 等人,2016 年)。菊花的干花在《中华人民共和国药典》(2020 年版)中被称为 "叶菊花",其抗炎、抗氧化、抗菌、抗癌和免疫调节特性已得到公认(Xie 等人,2012 年)。这些药效主要归功于黄酮含量高,特别是芹菜素、木犀草素及其衍生物等化合物(Shao 等人,2020 年)。之前的研究表明,中国不同生态地理种群(生态型)的茨菰形态和代谢组成存在显著差异,影响了其药用和营养价值(Fang 等,2012)。为了探索茨菰黄酮的自然变异,我们收集了中国不同地区的生态型,并使用超高效液相色谱-串联质谱法(UPLC-MS)对花中的主要生物活性黄酮芹菜素进行了定量。对 72 个表现出不同芹菜苷含量的生态型进行了基于代谢物的全基因组关联研究(mGWAS)(图 1a;数据集 S1)。关联分析表明,这些生态型中芹菜苷含量的自然变异受位于 2 号和 9 号染色体上的两个位点控制(图 1b-c)。在 2 号染色体上的基因座中,我们发现了一个 TREHALOSE-6-PHOSPHATE SYNTHASE1 基因(CiTPS1,Cse_sc000461.1_g010.1)和 CiRHM1(Cse_sc000461.1_g020.1)(图 1b;表 S1)。共线性分析表明,TPS1-RHM1 基因簇在双子叶植物中是保守的(图 S1)。18 个生态型的 RNA-seq 结果表明,CiRHM1 的表达与芹菜素含量呈负相关(图 1d,表 S2),而 CiTPS1 的表达则没有相关性(图 S2a,表 S2)。此外,我们还在 C. indicum 基因组的 6 号染色体上发现了一个 CiRHM1 的旁系亲属,命名为 CiRHM1-like (Cse_sc005633.1_g060.1,图 S3),与 CiRHM1 相比,其表达与芹菜素含量的相关性较低(图 S2b)。因此,CiRHM1 被选为进一步功能分析的候选基因。随后的调查确定了位于 CiRHM1 内含子中的 SNP(LG02: 36801176)(表 S1)。与具有 G/G 基因型的生态型相比,具有该 SNP 的同源 T/T 基因型的生态型的芹菜苷含量明显更高(图 1e)。(a) 72 个 C. indicum 生态型中芹菜素含量的频率分布。芹菜苷含量的类别显示在 x 轴上,生态型的相应计数显示在 y 轴上。(b)曼哈顿图显示与芹菜素含量相关的 SNP 的 GWAS 信号。(c) Q-Q 图显示芹菜素的 GWAS 结果。(d) CiRHM1 表达水平与芹菜素含量之间的相关性分析。(e) 方框图显示芹菜素含量与 SNP LG02:36801176 之间存在显著关联。(f)Cirhm1 突变体的基因分型。(g)WT 和 Cirhm1 突变体的表型。(h) WT 和 Cirhm1 突变体的株高测量。(i) WT 和 Cirhm1 突变体花中鼠李糖和 UDP 葡萄糖含量。(j) WT 和 Cirhm1 突变体花中黄酮苷元的含量。数据以三个生物重复的平均值 ± SD 表示。WT 与 Cirhm1 突变体之间的统计学意义采用学生 t 检验(*P &lt; 0.05, **P &lt; 0.01, ***P &lt; 0.001 和 ****P &lt; 0.0001)。我们利用 CRISPR/Cas9 基因编辑平台敲除了 C. indicum 中的 CiRHM1(Liu 等人,2023 年)。我们设计了两个单导 RNA(sgRNA)来特异性靶向 CiRHM1 基因的第一个外显子,并产生了两个 Cirhm1 突变体(图 1f)。
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来源期刊
Plant Biotechnology Journal
Plant Biotechnology Journal 生物-生物工程与应用微生物
CiteScore
20.50
自引率
2.90%
发文量
201
审稿时长
1 months
期刊介绍: Plant Biotechnology Journal aspires to publish original research and insightful reviews of high impact, authored by prominent researchers in applied plant science. The journal places a special emphasis on molecular plant sciences and their practical applications through plant biotechnology. Our goal is to establish a platform for showcasing significant advances in the field, encompassing curiosity-driven studies with potential applications, strategic research in plant biotechnology, scientific analysis of crucial issues for the beneficial utilization of plant sciences, and assessments of the performance of plant biotechnology products in practical applications.
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