SRS: An intelligent and robust approach for confirmation of plant transcription factor–DNA interactions

IF 10.1 1区 生物学 Q1 BIOTECHNOLOGY & APPLIED MICROBIOLOGY Plant Biotechnology Journal Pub Date : 2024-10-22 DOI:10.1111/pbi.14488
Qi Zhou, Yulu Ye, Haiyan He, Zhigang Meng, Tao Zhou, Jingtao Zhang, Yameng Li, Jilong Zhang, Zhaoyi Liao, Yuan Wang, Sandui Guo, Chengzhen Liang
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An alternative, the RUBY/eYGFPuv assay, uses modified plant leaf colour as a visible, cost-effective method for studying DNA–protein interaction (Sun <i>et al</i>., <span>2023</span>). Advances in genomics, including RNA sequencing and ChIP-Seq, underscore the need for efficient, reliable visual detection systems to map TF binding sites, crucial for elucidating their regulatory roles and broader biological impacts.</p>\n<p>To develop a visual reporter for TF–DNA interactions, we targeted genes influencing leaf colour by modulating chlorophyll (Chl) degradation. The <i>Stay-Green1</i> (<i>SGR1</i>) gene, crucial for Chl breakdown during senescence, encodes magnesium dechelatase. Mutations in <i>SGR1</i> result in a stay-green phenotype, while overexpression leads to yellowing (Shimoda <i>et al</i>., <span>2016</span>). We chose <i>SGR1</i> from 32 candidates, divided into three subgroups, and cloned <i>SGR1</i> genes from <i>Arabidopsis thaliana</i> (<i>AtSGR1</i>), <i>Oryza sativa</i> (<i>OsSGR1</i>), and two from <i>Ginkgo biloba</i> (<i>GbSGR1</i> and <i>GbSGR1L</i>) (Figure S1). Using the <i>Cauliflower Mosaic Virus 35S</i> promoter, we expressed these genes in <i>Nicotiana benthamiana</i> leaves via <i>Agrobacterium tumefaciens</i>-mediated transformation (Figure S2). All transformed areas exhibited accelerated yellowing, with <i>AtSGR1</i> exhibiting the most rapid and significant Chl degradation, demonstrating its potential as a TF–DNA interaction reporter (Figure 1a–c). Additionally, enhancements including a Kozak consensus sequence for improved translation, darkness to stimulate yellowing, and maintaining temperatures between 22 and 25°C significantly boosted Chl degradation (Figure S3).</p>\n<figure><picture>\n<source media=\"(min-width: 1650px)\" srcset=\"/cms/asset/94290b66-4196-4cb7-b4d0-59dbec6d6b71/pbi14488-fig-0001-m.jpg\"/><img alt=\"Details are in the caption following the image\" data-lg-src=\"/cms/asset/94290b66-4196-4cb7-b4d0-59dbec6d6b71/pbi14488-fig-0001-m.jpg\" loading=\"lazy\" src=\"/cms/asset/8acd5d0a-ed44-420e-8d33-63b02f8f6973/pbi14488-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>Development and Utilization of the SRS System. (a) Phenotypic variations in <i>N. benthamiana</i> leaves post-injection with different <i>SGR1</i> genes. (b) Dynamic changes in Chl content in <i>SGR1</i>-injected leaf spots. Mean ± SD (<i>n</i> = 10). (c) Expression levels of <i>AtSGR1</i> (yellow), <i>OsSGR1</i> (pink), <i>GbSGR1</i> (blue), and <i>GbSGR1L</i> (grey) in injected spots. (d) Design and workflow of the SMGY model. (e–h) Phenotypes of detached wild-type and six <i>NbSGR1</i> gene-edited <i>N. benthamiana</i> leaves 10 days after dark treatment. (i–p) Dynamic phenotypic in <i>N. benthamiana</i> leaves injected with <i>pFHY1::SGR1-p35S::FAR1</i> over time. (q) Changes in Chl content in injected areas. (r–s) Expression of <i>FAR1</i> and <i>SGR1</i> in the injected spots. (t) Protein levels of SGR1 in the injected spots. NbActin (NbACT) was used for protein loading control. Scale Bar, 0.5 cm.</div>\n</figcaption>\n</figure>\n<p>To efficiently monitor Chl level changes, we developed the Smart Model for tracking Chl change from Green to Yellow (SMGY). This model utilizes a second-order polynomial regression and a colour difference correction matrix, calibrated against a standard colour chart to minimize image colour variations. We integrated a remote diagnosis system via the WeChat Mini Program for on-site, real-time, non-destructive Chl detection in plant leaves (Figure 1d). To predict SPAD values from images, we analysed 14 features with significant correlations (<i>r</i> &gt; 0.5; Figure S4a; Table S1) and used a stacking ensemble of five machine learning models (Figure S4b; Table S2). After 100 iterations, the model achieved an <i>R</i><sup>2</sup> of 0.85, RMSE of 2.4, and NRMSE of 12.24% (Figure S4c–e; Table S3). The SMGY model offers a user-friendly, efficient, and non-destructive method for accurate Chl quantification, facilitating rapid monitoring of Chl fluctuations while preserving plant integrity. To address potential false positives from <i>NbSGR1</i> gene activation in <i>N. benthamiana</i>, we used CRISPR/Cas9 technology to knock out its six <i>SGR1</i> homologous genes, distributed across different chromosomes (Figure S5a). We designed a CRISPR-Cas9 construct with 12 sgRNAs under the <i>AtU6-26</i> promoter, which was introduced into <i>N. benthamiana</i> (Figure S5b). Genetic analysis revealed a homozygous plant, CR19, with all six <i>NbSGR1</i> genes edited (Figure S6a). CR19 showed delayed leaf yellowing and reduced Chl degradation under dark conditions, making it ideal as a host for subsequent SRS research (Figures 1e–h and S6b–d).</p>\n<p>To increase the likelihood of TFs and target DNA interacting within the same cell, we developed the <i>pTF-SGR1</i> plasmid featuring two independent expression cassettes: <i>p35S</i>::<i>TF</i> and <i>pY</i>::<i>SGR1</i>, with multiple cloning sites for ease of molecular manipulation (Figure S7). We evaluated this system using the FAR1 TF and the <i>FHY1</i> promoter, which regulates the nuclear accumulation of phytochrome A. Interactions were confirmed via ChIP-PCR, Y1H, and EMSA (Lin <i>et al</i>., <span>2007</span>). We constructed <i>pFHY1</i>::<i>SGR1</i>-<i>p35S</i>::<i>FAR1</i>, infiltrated <i>N. benthamiana</i> leaves with it, and observed significant colour shifts from green to yellow, indicative of interaction, while controls showed minimal changes (Figures 1i–p and S8). Elevated expression of <i>SGR1</i> in the presence of <i>FAR1</i> and the <i>FHY1</i> promoter was confirmed (Figure 1q–t). Specificity tests with a mutated <i>FAR1</i> gene and a non-interacting <i>OsTB1</i> promoter validated the system's sensitivity and specificity (Figure S9a,b). Negative controls included vectors with either the <i>FAR1</i> gene or the <i>FHY1</i> promoter alone, and an empty vector, with minimal changes observed in controls (Figure S9c–f).</p>\n<p>To assess the SRS's ability to characterize interactions between TFs and their target promoters across diverse functions, we tested three TF-promoter pairs (Figure S10). For example, the TIG1 TF from the TCP family, which activates <i>SAUR39</i> and influences rice tiller angles (Zhang <i>et al</i>., <span>2019</span>), was tested by delivering the <i>pSAUR39</i>::<i>SGR1</i>-<i>p35S</i>::<i>TIG1</i> vector into <i>N. benthamiana</i> leaves. This resulted in significant colour changes and increased <i>SGR1</i> transcript levels, unlike controls (Figures S10, S11a–e and S12a,b). We also examined the interaction between MYB29 TF and the <i>SUR1</i> promoter (Ma <i>et al</i>., <span>2013</span>), observing expected colour changes with the <i>pSUR1</i>::<i>SGR1</i>-<i>p35S</i>::<i>MYB29</i> construct (Figures S10, S11f–j and S12c,d). Additionally, the interaction between the avrBs3 protein from <i>Xanthomonas campestris</i> and the pepper <i>Bs3</i> promoter (Römer <i>et al</i>., <span>2007</span>) was confirmed through noticeable colour changes upon co-expression (Figures S10, S11k–o and S12e,f). Furthermore, we demonstrated the feasibility of the SRS system in validating the interaction between the senescence-associated TF AtNAP (Zhang and Gan, <span>2012</span>) and its downstream target gene, the <i>SAG113</i> promoter (Figure S13). These experiments demonstrate the SRS's robustness and reliability in verifying specific plant TF–DNA interactions.</p>\n<p>We further tested the SRS in various plants beyond <i>N. benthamiana</i>, confirming its effectiveness in species like rapeseed and different types of lettuce (Figure S14). However, some plants showed unexpected phenotypes, indicating the need for future optimization of experimental conditions.</p>","PeriodicalId":221,"journal":{"name":"Plant Biotechnology Journal","volume":"31 1","pages":""},"PeriodicalIF":10.1000,"publicationDate":"2024-10-22","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.14488","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

Transcription factors (TFs), representing 5%–8% of eukaryotic nuclear genome, bind specific DNA sequences like promoters to regulate transcription (Lambert et al., 2018). Identifying these sequences is vital for understanding TF functions. Techniques such as chromatin immunoprecipitation sequencing (ChIP-Seq), electrophoretic mobility shift assay (EMSA), yeast one-hybrid (Y1H) assay, dual-luciferase reporter LUC/REN assay, and β-glucuronidase (GUS) reporter are used to validate TF–promoter interactions but require extensive instrumentation and chemicals (Abid et al., 2022; Park, 2009). An alternative, the RUBY/eYGFPuv assay, uses modified plant leaf colour as a visible, cost-effective method for studying DNA–protein interaction (Sun et al., 2023). Advances in genomics, including RNA sequencing and ChIP-Seq, underscore the need for efficient, reliable visual detection systems to map TF binding sites, crucial for elucidating their regulatory roles and broader biological impacts.

To develop a visual reporter for TF–DNA interactions, we targeted genes influencing leaf colour by modulating chlorophyll (Chl) degradation. The Stay-Green1 (SGR1) gene, crucial for Chl breakdown during senescence, encodes magnesium dechelatase. Mutations in SGR1 result in a stay-green phenotype, while overexpression leads to yellowing (Shimoda et al., 2016). We chose SGR1 from 32 candidates, divided into three subgroups, and cloned SGR1 genes from Arabidopsis thaliana (AtSGR1), Oryza sativa (OsSGR1), and two from Ginkgo biloba (GbSGR1 and GbSGR1L) (Figure S1). Using the Cauliflower Mosaic Virus 35S promoter, we expressed these genes in Nicotiana benthamiana leaves via Agrobacterium tumefaciens-mediated transformation (Figure S2). All transformed areas exhibited accelerated yellowing, with AtSGR1 exhibiting the most rapid and significant Chl degradation, demonstrating its potential as a TF–DNA interaction reporter (Figure 1a–c). Additionally, enhancements including a Kozak consensus sequence for improved translation, darkness to stimulate yellowing, and maintaining temperatures between 22 and 25°C significantly boosted Chl degradation (Figure S3).

Abstract Image
Figure 1
Open in figure viewerPowerPoint
Development and Utilization of the SRS System. (a) Phenotypic variations in N. benthamiana leaves post-injection with different SGR1 genes. (b) Dynamic changes in Chl content in SGR1-injected leaf spots. Mean ± SD (n = 10). (c) Expression levels of AtSGR1 (yellow), OsSGR1 (pink), GbSGR1 (blue), and GbSGR1L (grey) in injected spots. (d) Design and workflow of the SMGY model. (e–h) Phenotypes of detached wild-type and six NbSGR1 gene-edited N. benthamiana leaves 10 days after dark treatment. (i–p) Dynamic phenotypic in N. benthamiana leaves injected with pFHY1::SGR1-p35S::FAR1 over time. (q) Changes in Chl content in injected areas. (r–s) Expression of FAR1 and SGR1 in the injected spots. (t) Protein levels of SGR1 in the injected spots. NbActin (NbACT) was used for protein loading control. Scale Bar, 0.5 cm.

To efficiently monitor Chl level changes, we developed the Smart Model for tracking Chl change from Green to Yellow (SMGY). This model utilizes a second-order polynomial regression and a colour difference correction matrix, calibrated against a standard colour chart to minimize image colour variations. We integrated a remote diagnosis system via the WeChat Mini Program for on-site, real-time, non-destructive Chl detection in plant leaves (Figure 1d). To predict SPAD values from images, we analysed 14 features with significant correlations (r > 0.5; Figure S4a; Table S1) and used a stacking ensemble of five machine learning models (Figure S4b; Table S2). After 100 iterations, the model achieved an R2 of 0.85, RMSE of 2.4, and NRMSE of 12.24% (Figure S4c–e; Table S3). The SMGY model offers a user-friendly, efficient, and non-destructive method for accurate Chl quantification, facilitating rapid monitoring of Chl fluctuations while preserving plant integrity. To address potential false positives from NbSGR1 gene activation in N. benthamiana, we used CRISPR/Cas9 technology to knock out its six SGR1 homologous genes, distributed across different chromosomes (Figure S5a). We designed a CRISPR-Cas9 construct with 12 sgRNAs under the AtU6-26 promoter, which was introduced into N. benthamiana (Figure S5b). Genetic analysis revealed a homozygous plant, CR19, with all six NbSGR1 genes edited (Figure S6a). CR19 showed delayed leaf yellowing and reduced Chl degradation under dark conditions, making it ideal as a host for subsequent SRS research (Figures 1e–h and S6b–d).

To increase the likelihood of TFs and target DNA interacting within the same cell, we developed the pTF-SGR1 plasmid featuring two independent expression cassettes: p35S::TF and pY::SGR1, with multiple cloning sites for ease of molecular manipulation (Figure S7). We evaluated this system using the FAR1 TF and the FHY1 promoter, which regulates the nuclear accumulation of phytochrome A. Interactions were confirmed via ChIP-PCR, Y1H, and EMSA (Lin et al., 2007). We constructed pFHY1::SGR1-p35S::FAR1, infiltrated N. benthamiana leaves with it, and observed significant colour shifts from green to yellow, indicative of interaction, while controls showed minimal changes (Figures 1i–p and S8). Elevated expression of SGR1 in the presence of FAR1 and the FHY1 promoter was confirmed (Figure 1q–t). Specificity tests with a mutated FAR1 gene and a non-interacting OsTB1 promoter validated the system's sensitivity and specificity (Figure S9a,b). Negative controls included vectors with either the FAR1 gene or the FHY1 promoter alone, and an empty vector, with minimal changes observed in controls (Figure S9c–f).

To assess the SRS's ability to characterize interactions between TFs and their target promoters across diverse functions, we tested three TF-promoter pairs (Figure S10). For example, the TIG1 TF from the TCP family, which activates SAUR39 and influences rice tiller angles (Zhang et al., 2019), was tested by delivering the pSAUR39::SGR1-p35S::TIG1 vector into N. benthamiana leaves. This resulted in significant colour changes and increased SGR1 transcript levels, unlike controls (Figures S10, S11a–e and S12a,b). We also examined the interaction between MYB29 TF and the SUR1 promoter (Ma et al., 2013), observing expected colour changes with the pSUR1::SGR1-p35S::MYB29 construct (Figures S10, S11f–j and S12c,d). Additionally, the interaction between the avrBs3 protein from Xanthomonas campestris and the pepper Bs3 promoter (Römer et al., 2007) was confirmed through noticeable colour changes upon co-expression (Figures S10, S11k–o and S12e,f). Furthermore, we demonstrated the feasibility of the SRS system in validating the interaction between the senescence-associated TF AtNAP (Zhang and Gan, 2012) and its downstream target gene, the SAG113 promoter (Figure S13). These experiments demonstrate the SRS's robustness and reliability in verifying specific plant TF–DNA interactions.

We further tested the SRS in various plants beyond N. benthamiana, confirming its effectiveness in species like rapeseed and different types of lettuce (Figure S14). However, some plants showed unexpected phenotypes, indicating the need for future optimization of experimental conditions.

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SRS:确认植物转录因子与 DNA 相互作用的智能而稳健的方法
转录因子(TFs)占真核生物核基因组的 5%-8%,与启动子等特定 DNA 序列结合,调节转录(Lambert 等人,2018 年)。识别这些序列对于了解 TF 的功能至关重要。染色质免疫共沉淀测序(ChIP-Seq)、电泳迁移测定(EMSA)、酵母单杂交(Y1H)测定、双荧光素酶报告LUC/REN测定和β-葡萄糖醛酸酶(GUS)报告等技术可用于验证TF与启动子的相互作用,但需要大量的仪器和化学试剂(Abid等人,2022年;Park,2009年)。另一种方法是 RUBY/eYGFPuv 分析法,它利用改良的植物叶片颜色作为研究 DNA 蛋白相互作用的一种可见、经济有效的方法(Sun 等人,2023 年)。基因组学的进步,包括 RNA 测序和 ChIP-Seq,突出表明需要高效、可靠的可视检测系统来绘制 TF 结合位点图,这对阐明其调控作用和更广泛的生物学影响至关重要。为了开发 TF-DNA 相互作用的可视报告器,我们以通过调节叶绿素(Chl)降解来影响叶片颜色的基因为目标。Stay-Green1(SGR1)基因编码镁脱螯酶,对叶绿素在衰老过程中的分解至关重要。SGR1 基因突变会导致留绿表型,而过表达则会导致黄化(Shimoda 等人,2016 年)。我们从 32 个候选基因中选择了 SGR1,将其分为三个亚组,并克隆了拟南芥(AtSGR1)、大豆(OsSGR1)和银杏叶(GbSGR1 和 GbSGR1L)中的 SGR1 基因(图 S1)。我们使用花椰菜花叶病毒 35S 启动子,通过农杆菌介导的转化在烟草叶中表达了这些基因(图 S2)。所有转化区都表现出加速黄化,其中 AtSGR1 的 Chl 降解最迅速、最显著,显示出其作为 TF-DNA 相互作用报告物的潜力(图 1a-c)。此外,包括改进翻译的 Kozak 共识序列、刺激黄化的黑暗条件以及将温度保持在 22 至 25°C 之间等增强措施都显著促进了 Chl 降解(图 S3)。(a) 注射不同 SGR1 基因后 N. benthamiana 叶片的表型变化。(b) 注射 SGR1 后叶斑中 Chl 含量的动态变化。平均值 ± SD(n = 10)。(c) 注射点中 AtSGR1(黄色)、OsSGR1(粉红色)、GbSGR1(蓝色)和 GbSGR1L(灰色)的表达水平。(d)SMGY 模型的设计和工作流程。(e-h)黑暗处理 10 天后脱落的野生型叶片和六片 NbSGR1 基因编辑的 N. benthamiana 叶片的表型。(i-p)注射 pFHY1::SGR1-p35S::FAR1 的 N. benthamiana 叶片随着时间推移的动态表型。(q)注射区域 Chl 含量的变化。(r-s)注射点中 FAR1 和 SGR1 的表达。(t)注射点中 SGR1 的蛋白水平。NbActin(NbACT)用于蛋白负载对照。为了有效监测 Chl 水平的变化,我们开发了跟踪 Chl 从绿色到黄色变化的智能模型(SMGY)。该模型利用二阶多项式回归和色差校正矩阵,根据标准色图进行校准,以尽量减少图像色差。我们通过微信小程序集成了一个远程诊断系统,用于现场、实时、无损地检测植物叶片中的 Chl(图 1d)。为了从图像中预测 SPAD 值,我们分析了 14 个具有显著相关性(r &gt; 0.5;图 S4a;表 S1)的特征,并使用了五个机器学习模型的堆叠组合(图 S4b;表 S2)。经过 100 次迭代,该模型的 R2 为 0.85,RMSE 为 2.4,NRMSE 为 12.24%(图 S4c-e;表 S3)。SMGY 模型为准确定量 Chl 提供了一种用户友好型、高效且非破坏性的方法,有助于在保持植物完整性的同时快速监测 Chl 波动。为了解决 N. benthamiana 中 NbSGR1 基因激活可能产生的假阳性,我们使用 CRISPR/Cas9 技术敲除了分布在不同染色体上的六个 SGR1 同源基因(图 S5a)。我们设计了一个在 AtU6-26 启动子下含有 12 个 sgRNA 的 CRISPR-Cas9 构建,并将其导入 N. benthamiana(图 S5b)。遗传分析发现了一种同源植株 CR19,其全部六个 NbSGR1 基因都被编辑过(图 S6a)。CR19 在黑暗条件下表现出延迟的叶片黄化和减少的 Chl 降解,使其成为后续 SRS 研究的理想宿主(图 1e-h 和 S6b-d)。为了提高 TF 和靶 DNA 在同一细胞内相互作用的可能性,我们开发了 pTF-SGR1 质粒,它具有两个独立的表达盒:p35S::TF 和 pY::SGR1,并有多个克隆位点,便于分子操作(图 S7)。我们使用 FAR1 TF 和 FHY1 启动子对该系统进行了评估,FHY1 启动子调控植物色素 A 的核积累。
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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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