辣椒CaPI的克隆与功能分析

doi:10.13560/j.cnki.biotech.bull.1985.2023-0957

摘要/Abstract

摘要：

【目的】 PISTILLATA（PI）基因属于典型的Type II型MADS-box基因家族成员，是ABC（D）E模型中的B类基因，在植物发育过程中起着重要作用，但辣椒PI同源基因功能研究未见报道。探索辣椒PI基因功能，为深入研究植物PI同源基因的功能机制奠定基础。【方法】 利用RT-PCR的方法从一年生辣椒（Capsicum annuum L.）花器官的cDNA中克隆PI同源基因CaPI，并通过生物信息学方法分析其理化性质、亚细胞定位、蛋白结构和系统进化关系；利用实时荧光定量PCR（RT-qPCR）技术分析基因在辣椒不同组织中的表达特征；构建植物过表达载体35S:CaPI，通过floral-dipping法转化拟南芥。【结果】 该基因开放阅读框648 bp，编码215个氨基酸，相对分子质量为25.13 kD。氨基酸多重序列比对表明，CaPI蛋白N端含有“MGRGKIEIKRIEN”保守基序。系统进化树分析证实，CaPI与马铃薯、番茄和矮牵牛的PI同源基因亲缘关系较近。RT-qPCR证实CaPI主要在花中表达，在花萼中表达量最高，其次是花瓣，在雄蕊中低表达，而在雌蕊中几乎不表达。在拟南芥中过表达CaPI，与野生型拟南芥（Col-0）相比，35S:CaPI转基因植株表现出莲座叶和分枝数量增多等表型，但不影响花器官的发育。【结论】 辣椒CaPI具有促进植物分枝发育的功能。

关键词: CaPI, 辣椒, MADS-box, 基因表达

Abstract:

【Objective】 The PISTILLATA（PI）gene belongs to the typical type II MADS-box gene family and is a class B gene in the ABC（D）E model, and plays an important role in plant development. However, functions of the PI homologous genes in pepper（Capsicum annuum L.）have not been reported. This study explored the function of pepper PI gene, laying a foundation for in-depth research on the functional mechanism of plant PI homologs.【Method】 We cloned a PI homologous gene CaPI from the cDNA of floral organ tissues of pepper using RT-PCR, and analyzed its physicochemical properties, subcellular localization, protein structure, and phylogenetic relationship through bioinformatics methods. The expression pattern of CaPI in different tissues of pepper was performed using real-time quantitative PCR（RT-qPCR）method. A plant overexpression vector of 35S:CaPI was constructed and transformed into Arabidopsis using floral-dipping method.【Result】 The CaPI gene contains an open reading frame of 648 bp and encodes a peptide of 215 amino acids with a relative molecular weight of 25.13 kD. Multiple amino acid sequence alignment indicated that the N-terminus of CaPI contains a conserved motif of ‘MGRGKIEIKRIEN’. Phylogenetic tree analysis with homologous proteins of other species showed that the CaPI gene was closely related to the PI homologous genes of potato, tomato, and petunia. The RT-qPCR analysis showed that CaPI was predominantly expressed in flowers, with the highest expression level in the sepals, followed by petals, with low expression in stamens and almost no expression in pistils. The overexpression of CaPI in Arabidopsis revealed that, compared to wild type（Col-0）plant, the 35S:CaPI transgenic plants exhibited phenotypes such as increased number of rosette leaves and branches, but did not affect the development of floral organs.【Conclusion】 CaPI in the pepper functions in promoting plant branching development.

Key words: CaPI, Capsicum annuum L., MADS-box, gene expression

吴星星, 洪海波, 甘志承, 李瑞宁, 黄先忠. 辣椒CaPI的克隆与功能分析[J]. 生物技术通报, 2024, 40(3): 193-201.

WU Xing-xing, HONG Hai-bo, GAN Zhi-cheng, LI Rui-ning, HUANG Xian-zhong. Cloning and Preliminary Functional Analysis of CaPI Gene in Capsicum annuum L.[J]. Biotechnology Bulletin, 2024, 40(3): 193-201.

图/表 8

表1 本研究使用到的引物

Table 1 Primer information used in this study

引物名称 Primer name	引物序列 Primer sequence（5'-3'）	引物用途 Primer purpose
CaPI-R	$\text{GGG}\underline{\text{GTACC}}\text{ATGGGGAGAGGGAAAATAGAGATAAA}$	35S:CaPI载体35S:CaPI Vector
CaPI-F	$\text{GC}\underline{\text{TCTAG}}\text{ACTACATTCTTTCATGTAGATTTGGCT}$	35S:CaPI载体35S:CaPI Vector
qCaPI-R	CTTCTGGGAGGAGGCTATGG	RT-qPCR
qCaPI-F	AAGATCTCAGACTGCTTGGC	RT-qPCR
qCaUBI3-R	TGTCCATCTGCTCTCTGTTG	RT-qPCR
qCaUBI3-F	CACCCCAAGCACAATAAGAC	RT-qPCR
qAtactin2-R	CCTGGACCTGCCTCATCATAC	RT-qPCR
qAtactin2-F	CTGGATCGGTGGTTCCATTC	RT-qPCR

图1 辣椒CaPI蛋白磷酸化位点分析

Fig. 1 Analysis of phosphorylation sites of CaPI protein in C. annuum L.

图2 CaPI蛋白结构分析 A：CaPI蛋白二级结构；B：CaPI蛋白（左）和拟南芥PI蛋白（右）空间结构对比

Fig. 2 Structural analysis of CaPI protein A: Secondary structure of CaPI protein. B: Comparison of spatial structures between CaPI（left）and AtPI（right）proteins

图3 植物PI类蛋白氨基酸序列多重序列比对

Fig. 3 Multiple amino-acid sequence alignments of the plant PI-like proteins

图4 辣椒CaPI蛋白和其他植物的系统进化树 AT：拟南芥，AT5G20240.1；Ca：辣椒，CaPI、CaMADS74和CaMADS53；SMEL：茄子，SMEL4.1_08g015360.1.01、SMEL4.1_02g021760.1.01；Solyc：番茄，Solyc06g059970.4.1、Solyc02g084630.3.1；Peaxi：矮牵牛，Peaxi162-Scf00922g00026.1、Peaxi162Scf00591g00074.1；PGSC：马铃薯，PGSC0003DMG401007392；TRAES：小麦，TRAES3BF021600020CFD t1、TRAES3BF048900050CFD t1、TRAES3BF068500020CFD t1、TRAES3BF009000010CFD t1；Os：水稻，Os01t0883100-01、Os05t0423400-0

Fig. 4 Phylogenetic tree of the CaPI proteins in C. annuum L. and other plant species AT: Arabidopsis thaliana, AT5G20240.1; Ca: Capsicum annuum, CaPI, CaMADS74 and CaMADS53; SMEL: Solanum melongena, SMEL4.1_08g015360.1.01, SMEL4.1_02g021760.1.01; Solyc: Solanum lycopersicum, Solyc06g059970.4.1, Solyc02g084630.3.1; Peaxi: Petunia hybrida, Peaxi162Scf00922g00026.1, Peaxi162Scf00591g00074.1; PGSC: Solanum tuberosum, PGSC0003DMG401007392; TRAES: Triticum aestivum, TRAES3BF021600020CFD t1, TRAES3BF048900050CFD t1, TRAES3BF068500020CFD t1, TRAES3BF009000010CFD t1; Os: Oryza sativa, Os01t0883100-01, Os05t0423400-0

图5 RT-qPCR分析CaPI的组织表达特征 A：CaPI在辣椒不同组织中的表达特征；B：CaPI在花萼、花瓣、雄蕊、雌蕊中的表达情况。小写字母表示在0.01水平上差异显著。下同

Fig. 5 Tissue expression pattern of the CaPI gene using RT-qPCR A: Expression profiles of the CaPI gene in different tissues of C. annuum L.. B: Expression profiles of the CaPI gene in four tissues: sepals, petals, stamens, and pistils. Lowercase letters indicate significant differences at P=0.01 level. The same below

图6 35S:CaPI转基因拟南芥的表型分析 A：生长30 d的35S:CaPI转基因植株与野生型（Col-0）拟南芥的表型对比，#1和#2代表2个独立的转基因株系；B：开花时莲座叶数目统计；C：开花天数统计；D：开花时分枝数统计；E：RT-qPCR分析CaPI在转基因植株和对照中的相对表达量

Fig. 6 Phenotype survey of the 35S:CaPI transgenic plants in Arabidopsis thaliana A: Comparisons of phenotypes between the 35S:CaPI transgenic lines and wild type（Col-0）plants grown for 30 d. #1 and #2 represent two independent transgenic plants, respectively. B: Statistics on the number of rosette leaves during flowering stages. C: Statistics of flowering times. D: Statistics of branch numbers during flowering stages. E: RT-qPCR analysis of the relative expression level of the CaPI gene

图7 拟南芥野生型（Col-0）与35S:CaPI转基因植株花形态对比

Fig. 7 Comparison of flower morphologies between the wild-type（Col-0）and 35S:CaPI transgenic Arabi-dopsis plants

参考文献 41

[1]	Wang YS, Zhang JL, Hu ZL, et al. Genome-wide analysis of the MADS-box transcription factor family in Solanum lycopersicum[J]. Int J Mol Sci, 2019, 20(12): 2961. doi: 10.3390/ijms20122961 URL
[2]	Becker A, Theissen G. The major clades of MADS-box genes and their role in the development and evolution of flowering plants[J]. Mol Phylogenet Evol, 2003, 29(3): 464-489. doi: 10.1016/s1055-7903(03)00207-0 pmid: 14615187
[3]	Schilling S, Pan SR, Kennedy A, et al. MADS-box genes and crop domestication: the jack of all traits[J]. J Exp Bot, 2018, 69(7): 1447-1469. doi: 10.1093/jxb/erx479 pmid: 29474735
[4]	Ferrario S, Immink RG, Angenent GC. Conservation and diversity in flower land[J]. Curr Opin Plant Biol, 2004, 7(1): 84-91. pmid: 14732446
[5]	Pelaz S, Ditta GS, Baumann E, et al. B and C floral organ identity functions require SEPALLATA MADS-box genes[J]. Nature, 2000, 405(6783): 200-203. doi: 10.1038/35012103
[6]	Coen ES, Meyerowitz EM. The war of the whorls: genetic interactions controlling flower development[J]. Nature, 1991, 353(6339): 31-37. doi: 10.1038/353031a0
[7]	Weigel D, Meyerowitz EM. The ABCs of floral homeotic genes[J]. Cell, 1994, 78(2): 203-209. doi: 10.1016/0092-8674(94)90291-7 pmid: 7913881
[8]	Zhang Y, Zhao T, Wang Y, et al. Expression characterization of ABCDE class MADS-box genes in Brassica rapa with different pistil types[J]. Plants: basel, 2023, 12(11): 2218.
[9]	Theissen G. Development of floral organ identity: stories from the MADS house[J]. Curr Opin Plant Biol, 2001, 4(1): 75-85. doi: 10.1016/s1369-5266(00)00139-4 pmid: 11163172
[10]	Rodríguez-Cazorla E, Ortuño-Miquel S, Candela H, et al. Ovule identity mediated by pre-mRNA processing in Arabidopsis[J]. PLoS Genet, 2018, 14(1): e1007182. doi: 10.1371/journal.pgen.1007182 URL
[11]	Sundström JF, Nakayama N, Glimelius K, et al. Direct regulation of the floral homeotic APETALA1 gene by APETALA3 and PISTILLATA in Arabidopsis[J]. Plant J, 2006, 46(4): 593-600. pmid: 16640596
[12]	Piwarzyk E, Yang YZ, Jack T. Conserved c-terminal motifs of the Arabidopsis proteins APETALA3 and PISTILLATA are dispensable for floral organ identity function[J]. Plant Physiol, 2007, 145(4): 1495-1505. doi: 10.1104/pp.107.105346 pmid: 17965182
[13]	田云芳, 卢超, 徐艳花, 等. 两种国兰MADS-box家族B类基因PI/GLO的克隆与时空表达特性分析[J]. 西北农业学报, 2022, 31(10): 1337-1343.
	Tian YF, Lu C, Xu YH, et al. Cloning and analysis of spatio-temporal expression characteristics of PI/GLO gene of MADS-box family in two chinese orchids[J]. Acta Agric Boreali-Occidentalis Sin, 2022, 31(10): 1337-1343.
[14]	游伟. 甜荞FaesPI_1和FaesPI_2基因启动子的克隆与功能分析[D]. 荆州: 长江大学, 2022.
	You W. Cloning and functional identification of FaesPI_1 and FaesPI_2 gene promoters in Fagopyrum esculentum[D]. Jingzhou: Yangtze University, 2022.
[15]	邹学校, 马艳青, 戴雄泽, 等. 辣椒在中国的传播与产业发展[J]. 园艺学报, 2020, 47(9): 1715-1726.
	Zou XX, Ma YQ, Dai XZ, et al. Spread and industry development of pepper in China[J]. Acta Hortic Sin, 2020, 47(9): 1715-1726. doi: 10.16420/j.issn.0513-353x.2020-0103
[16]	Añibarro-Ortega M, Pinela J, Alexopoulos A, et al. The powerful solanaceae: food and nutraceutical applications in a sustainable world[J]. Adv Food Nutr Res, 2022, 100: 131-172. doi: 10.1016/bs.afnr.2022.03.004 pmid: 35659351
[17]	Zhu ZS, Sun BM, Wei JL, et al. Construction of a high density genetic map of an interspecific cross of Capsicum chinense and Capsicum annuum and QTL analysis of floral traits[J]. Sci Rep, 2019, 9(1): 1054. doi: 10.1038/s41598-018-38370-0
[18]	Saha G, Park JI, Jung HJ, et al. Genome-wide identification and characterization of MADS-box family genes related to organ development and stress resistance in Brassica rapa[J]. BMC Genomics, 2015, 16(1): 178. doi: 10.1186/s12864-015-1349-z URL
[19]	齐伟辰, 陆静梅, 杨利民, 等. 人参PgPI基因3'端序列的克隆与分析[J]. 吉林农业大学学报, 2016, 38(4): 426-430.
	Qi WC, Lu JM, Yang LM, et al. Cloning and sequence analysis of PgPI gene from Panax ginseng C.A.Mey[J]. J Jilin Agric Univ, 2016, 38(4): 426-430.
[20]	蒋素华, 黄萍, 王默霏, 等. 萼脊兰MADS-box基因的克隆及表达载体构建[J]. 华北农学报, 2017, 32(3): 65-69. doi: 10.7668/hbnxb.2017.03.010
	Jiang SH, Huang P, Wang MF, et al. Cloning and construction of expression vector of MADS-box gene from Sedirea japonica[J]. Acta Agric Boreali Sin, 2017, 32(3): 65-69.
[21]	徐熔, 任洪杰, 王海竹, 等. 大蒜MADS-box基因AsPI的克隆及表达分析[J]. 园艺学报, 2017, 44(1): 69-79. doi: 10.16420/j.issn.0513-353x.2016-0732
	Xu R, Ren HJ, Wang HZ, et al. Cloning and expression analysis of MADS-box gene AsPI in garlic[J]. Acta Hortic Sin, 2017, 44(1): 69-79.
[22]	冯垒, 王义琴, 韩欣妤, 等. 墨兰PI基因过表达载体构建及功能初步分析[J]. 分子植物育种, 2023, 21(9): 2941-2947.
	Feng L, Wang YQ, Han XY, et al. Construction of overexpression vector of PI gene in Cymbidium sinense and preliminary analysis of its function[J]. Mol Plant Breed, 2023, 21(9): 2941-2947.
[23]	郑赟, 王昊宁, 刘靖文, 等. 牡丹花发育相关基因PsPI的克隆与表达分析[J]. 分子植物育种, 2021, 19(7): 2185-2192.
	Zheng B, Wang HN, Liu JW, et al. Cloning and expression analysis of PsPI gene in tree peony(Paeonia suffruticosa)[J]. Mol Plant Breed, 2021, 19(7): 2185-2192.
[24]	Gan Z, Wu X, Biahomba SAM, et al. Genome-wide identification, evolution, and expression characterization of the pepper(Capsicum spp.) MADS-box gene family[J]. Genes, 2022, 13(11): 2047. doi: 10.3390/genes13112047 URL
[25]	Kohli DK, Bachhawat AK. CLOURE: Clustal output reformatter, a program for reformatting ClustalX/ClustalW outputs for SNP analysis and molecular systematics[J]. Nucleic Acids Res, 2003, 31(13): 3501-3502. pmid: 12824353
[26]	Tamura K, Stecher G, Peterson D, et al. MEGA6: molecular evolutionary genetics analysis version 6.0[J]. Mol Biol Evol, 2013, 30(12): 2725-2729. doi: 10.1093/molbev/mst197 pmid: 24132122
[27]	牛西强, 罗潇云, 胡能兵, 等. 辣椒组织总RNA两种提取方法比较及RT-qPCR验证[J]. 安徽科技学院学报, 2021, 35(6): 42-47.
	Niu XQ, Luo XY, Hu NB, et al. Comparison of two isolation methods of total RNA from tissues of Capsicum annuum and RT-qPCR verification[J]. J Anhui Sci Technol Univ, 2021, 35(6): 42-47.
[28]	Wan H, Yuan W, Ruan M, et al. Identification of reference genes for reverse transcription quantitative real-time PCR normalization in pepper(Capsicum annuum L.)[J]. Biochem Biophys Res Commun, 2011, 416(1/2): 24-30. doi: 10.1016/j.bbrc.2011.10.105 URL
[29]	Livak KJ, Schmittgen TD. Analysis of relative gene expression data using real-time quantitative PCR and the 2(-Delta Delta C(T))Method[J]. Methods, 2001, 25(4): 402-408. doi: 10.1006/meth.2001.1262 pmid: 11846609
[30]	Schwarz-Sommer Z, Huijser P, Nacken W, et al. Genetic control of flower development by homeotic genes in Antirrhinum majus[J]. Science, 1990, 250(4983): 931-936. doi: 10.1126/science.250.4983.931 pmid: 17746916
[31]	Kramer EM, Dorit RL, Irish VF. Molecular evolution of genes controlling petal and stamen development: duplication and divergence within the APETALA3 and PISTILLATA MADS-box gene lineages[J]. Genetics, 1998, 149(2): 765-783. doi: 10.1093/genetics/149.2.765 pmid: 9611190
[32]	黄方, 迟英俊, 喻德跃. 植物MADS-box基因研究进展[J]. 南京农业大学学报, 2012, 35(5): 9-18.
	Huang F, Chi YJ, Yu DY, et al. Research advances of MADS-box genes in plants[J]. J Nanjing Agric Univ, 2012, 35(5): 9-18.
[33]	Goto K, Meyerowitz EM. Function and regulation of the Arabidopsis floral homeotic gene PISTILLATA[J]. Genes Dev, 1994, 8(13): 1548-1560. doi: 10.1101/gad.8.13.1548 URL
[34]	Chung YY, Kim SR, Kang HG, et al. Characterization of two rice MADS box genes homologous to GLOBOSA[J]. Plant Sci, 1995, 109(1): 45-56. doi: 10.1016/0168-9452(95)04153-L URL
[35]	Yao SG, Ohmori S, Kimizu M, et al. Unequal genetic redundancy of rice PISTILLATA orthologs, OsMADS2 and OsMADS4, in lodicule and stamen development[J]. Plant Cell Physiol, 2008, 49(5): 853-857. doi: 10.1093/pcp/pcn050 URL
[36]	Bartlett ME, Williams SK, Taylor Z, et al. The maize PI/GLO ortholog Zmm16/sterile tassel silky ear1 interacts with the zygomorphy and sex determination pathways in flower development[J]. Plant Cell, 2015, 27(11): 3081-3098. doi: 10.1105/tpc.15.00679 URL
[37]	陈露露, 李香景, 张映, 等. 茄子(Solanum melongena)MADs-box家族基因SmA GL9的克隆与表达分析[J]. 分子植物育种, 2023, 21(5): 1393-1400.
	Chen LL, Li XJ, Zhang Y, et al. Cloning and analysis of MADs-box family gene SmA GL9 in Solanum melongena[J]. Mol Plant Breed, 2023, 21(5): 1393-1400.
[38]	Riechmann JL, Meyerowitz EM. Determination of floral organ identity by Arabidopsis MADS domain homeotic proteins AP1, AP3, PI, and AG is independent of their DNA-binding specificity[J]. Mol Biol Cell, 1997, 8(7): 1243-1259. pmid: 9243505
[39]	Deng W, Zhou L, Zhou YT, et al. Isolation and characterization of three duplicated PISTILLATA genes in Brassica napus[J]. Mol Biol Rep, 2011, 38(5): 3113-3120. doi: 10.1007/s11033-010-9981-9 pmid: 20127515
[40]	Boualem A, Troadec C, Camps C, et al. A cucurbit androecy gene reveals how unisexual flowers develop and dioecy emerges[J]. Science, 2015, 350(6261): 688-691. doi: 10.1126/science.aac8370 pmid: 26542573
[41]	Zhu L, Shi Y, Zang Q, et al. Functional analysis of PI-like gene in relation to flower development from bamboo(Bambusa oldhamii)[J]. J Genet, 2016, 95(1): 71-78. doi: 10.1007/s12041-015-0605-y URL