大豆<em>GmRSZ21</em>基因克隆及表达分析

doi:10.3969/j.issn.1674-7968.2024.09.002

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Abstract The SR (serine/arginine-rich) protein family is a class of key regulators in plants, which is involved in plant growth and development, and responsive to abiotic stresses. In this study, GmRSZ21 (GenBank No. XP_014634806.1), the subfamily of RSZ (Zn-knuckles-type arginine/serine-rich protein), was cloned from soybean (Glycine max) and bioinformatics and expression analysis were carried out. The results showed that GmRSZ21 gene contained 4 exons and 3 introns, and the total length of the coding region was 561 bp. GmRSZ21 encoded 186 amino acids, among which arginine accounted for the highest proportion (19.4%). The relative molecular weight of GmRSZ21 protein was 21.36 kD, and its secondary structure was mainly random coil (57.53%), without transmembrane domains or signal peptides. The GmRSZ21 protein was predicted to be an unstable hydrophilic protein and located in the nucleus. Amino acid sequence comparison showed that the GmRSZ21 protein was highly conserved among different species. Phylogenetic analysis showed that the GmRSZ21 protein had the closest evolutionary relationship with its homologues in wild soybean (G. soja). The GmRSZ21 gene promoter contained 20 cis-acting elements, among which, the light response elements were most abundant. Expression analysis showed that GmRSZ21 was expressed in all tissues, with the highest expression in stems and the lowest expression in pods at the onset of bulging; the GmRSZ21 expression could be induced by drought and salt stress, and it was hypothesised that this gene might be participated in abiotic stresses in the soybean. This study provides a reference for the functional analysis of the SR protein family and its application in soybean molecular breeding.

Key words： Soybean Abiotic stress Gene cloning Bioinformatics analysis Zn-knuckles-type arginine/serine-rich protein (RSZ21)

Received: 30 April 2024

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S529

Corresponding Authors: * guoshangjing@qau.edu.cn; menglingzhi6@163.com

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	Articles by authors
	DU Meng-Xue
	WANG De-Ying
	LI Jing-Yu
	MEN Qing-Mei
	HE Yun
	MENG Ling-Zhi
	GUO Shang-Jing

Cite this article:

DU Meng-Xue,WANG De-Ying,LI Jing-Yu, et al. Cloning and Expression Analysis of GmRSZ21 Gene in Soybean (Glycine max)[J]. 农业生物技术学报, 2024, 32(9): 1971-1981.

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https://journal05.magtech.org.cn/Jwk_ny/EN/10.3969/j.issn.1674-7968.2024.09.002 OR https://journal05.magtech.org.cn/Jwk_ny/EN/Y2024/V32/I9/1971

[1] 黄骥, 王建飞, 张红生. 2004. 植物C2H2型锌指蛋白的结构与功能[J]. 遗传, 26(03):414-418.
(Huang J, Wang J F, Zhang H S.2004. Structure and function of plant C2H2 zinc finger protein[J]. Hereditas, 26(03): 414-418.)
[2] (Wang D Y, Sui C, Lv L J, et al.2023. Cloning and expression of GmMYB112 gene in Glycine max[J]. Molecular Plant Breeding, 1-15.) http://kns.cnki.net/kcms/detail/46.1068.S.20230330.1431.014.html.
[3] 翁洵, 顾进宝, 周小霞, 等. 2021. 木薯MeRSZ21a的克隆、生物信息学分析和表达模式分析[J]. 分子植物育种, 19(16): 5241-5249.
(Weng X, Gu J B, Zhou X X, et al.2021. Cloning, bioinformatics analysis and expression pattern of MeRSZ21a in cassava[J]. Molecular Plant Breeding, 19(16): 5241-5249.)
[4] 武子豪. 2024. 不同程度干旱对苗期大豆叶片生长和蛋白表达的影响[D]. 硕士学位论文, 东北农业大学, 导师: 董守坤, pp. 1-6.
(Wu Z H.2024. Effects of different degrees of drought on growth and protein expression of soybean leaves at seedling stage[D]. Thesis for M.S., Northeast Agricultural University, Supervisor: Dong S K, pp. 1-6.)
[5] 钟强. 2024. 转录因子GmbHLH120参与调控大豆干旱胁迫应答[D]. 硕士学位论文, 南昌大学, 导师: 王东, pp. 1-3.
(Zhong Q.2024. The transcription factor GmbHLH120 is involved in soybean response to drought stress[D]. Thesis for M.S., Nanchang University, Supervisor: Wang D, pp. 1-3.)
[6] Barta A, Kalyna M, Reddy A S.2010. Implementing a rational and consistent nomenclature for serine/arginine-rich protein splicing factors (SR proteins) in plants[J]. The Plant Cell, 22(9): 2926-2929.
[7] Bustingorri C, Lavado R S.2011. Soybean growth under stable versus peak salinity[J]. Scientia Agricola, 68(1): 102-108.
[8] Butt H, Bazin J, Prasad K V S K, et al.2022. The rice serine/arginine splicing factor RS33 regulatespre‐mRNA splicing during abiotic stress responses[J]. Cells, 11(11): 1796.
[9] Chen T, Cui P, Chen H, et al.2013. A KH-domain RNA-binding protein interacts with FIERY2/CTD phosphatase-like 1 and splicing factors and is important for pre-mRNA splicing in Arabidopsis[J]. PLOS Genetics, 9: 10.
[10] Chen Y H, Weng X, Zhou X X, et al.2022. Overexpression of cassava RSZ21b enhances drought tolerance in Arabidopsis[J]. Journal of Plant Physiology, 268: 153574.
[11] El-Sabagh A, Sorour S, Ueda A, et al.2015. Evaluation of salinity stress effects on seed yield and quality of three soybean cultivars[J]. Azarian Journal of Agriculture, 2(5): 138-141.
[12] Ge H, Manley J L.1990. A protein factor, ASF, controls cell-specific alternative splicing of SV40 early pre-mRNA in vitro[J]. Cell, 62(1): 25-34.
[13] Graveley B R.2000. Sorting out the complexity of SR protein functions[J]. RNA, 6(9): 1197-1211.
[14] Graveley B R.2001. Alternative splicing: Increasing diversity in the proteomic world[J]. Trends in Genetics, 17: 100-107.
[15] Gregorio J J, Villalobos-López M A, Chavarría-Alvarado K L, et al.2020. Genome-wide transcriptional changes triggered by water deficit on a drought-tolerant common bean cultivar[J]. BMC Plant Biology, 20(1): 525.
[16] Kalyna M, Barta A.2004. A plethora of plant serine/arginine-rich proteins: Redundancy or evolution of novel gene functions?[J]. Biochemical Society Transactions, 32(4): 561-564.
[17] Kalyna M, Lopato S, Barta A.2003. Ectopic expression of atRSZ33 reveals its function in splicing and causes pleiotropic changes in development[J]. Molecular Biology of the Cell, 14(9): 3565-3577.
[18] Kapoor D, Bhardwaj S, Landi M, et al.2020. The impact of drought in plant metabolism: How to exploit tolerance mechanisms to increase crop production[J]. Applied Sciences, 10(16): 5692.
[19] Krainer A R, Maniatis T.1985. Multiple factors including the small nuclear ribonucleoproteins U1 and U2 are necessary for pre-mRNA splicing in vitro[J]. Cell, 42(3): 725-736.
[20] Kumar K R, Kirti P B.2012. Novel role for a serine/arginine-rich splicing factor, AdRSZ21 in plant defense and HR-like cell death[J]. Plant Molecular Biology, 80(4-5): 461-476.
[21] Kumar S, Stecher G, Li M, et al.2018. MEGA X: Molecular evolutionary genetics analysis across computing platforms[J]. Molecular Biology and Evolution, 35(6): 1547-1549.
[22] Laloum T, Carvalho S D, Martín G, et al.2023. The SCL30a SR protein regulates ABA-dependent seed traits and germination under stress[J]. Plant, Cell & Environment, 46(7): 2112-2127.
[23] Li Y, Guo Q H, Liu P, et al.2021. Dual roles of the serine/arginine-rich splicing factor SR45a in promoting and interacting with nuclear cap-binding complex to modulate the salt-stress response in Arabidopsis[J]. New Phytologist, 230(2): 641-655.
[24] Long J C, Caceres J F.2009. The SR protein family of splicing factors: Master regulators of gene expression[J]. The Biochemical Journal, 417(1): 15-27.
[25] Melo J P, Kalyna M, Duque P.2020. Current challenges in studying alternative splicing in plants: The case of Physcomitrella patens SR proteins[J]. Frontiers in Plant Science, 11: 286.
[26] Mundhe S, Patil R, Oak M D, et al.2022. Accelerating soybean improvement through genomics-assisted breeding[J]. Accelerated Plant Breeding, 4(03): 41-62.
[27] Muthusamy M, Yoon E K, Kim J A, et al.2020. Brassica rapa SR45a regulates drought tolerance via the alternative splicing of target genes[J]. Genes (Basel), 11(2): 182.
[28] Palusa S G, Ali G S, Reddy A S.2007. Alternative splicing of pre-mRNAs of Arabidopsis serine/arginine-rich proteins: Regulation by hormones and stresses[J]. The Plant Journal, 49: 1091-1107.
[29] Papiernik S K, Grieve C M, Lesch S M, et al.2005. Effects of salinity, imazethapyr, and chlorimuron application on soybean growth and yield[J]. Communications in Soil Science and Plant Analysis, 36: 951-967.
[30] Rabie R K, Kumazawa K.1988. Effect of salt stress on nitrogen nutrition and yield quality of nodulated soybeans[J]. Soil Science and Plant Nutrition, 34: 385-391.
[31] Reddy A S, Shad A G.2011. Plant serine/arginine-rich proteins: Roles in precursor messenger RNA splicing, plant development, and stress responses[J]. Wiley Interdisciplinary Reviews RNA, 2(6): 875-889.
[32] Roth M B, Murphy C, Gall J G.1990. A monoclonal antibody that recognizes a phosphorylated epitope stains lampbrush chromosome loops and small granules in the amphibian germinal vesicle[J]. Journal of Cell Biology, 111: 2217-2223.
[33] Roth M B, Zahler A M, Stolk J A.1991. A conserved family of nuclear phosphoproteins localized to sites of polymeraseⅡtranscription[J]. Journal of Cell Biology, 115: 587-596.
[34] Shan B, Bao G, Shi T, et al.2022. Genome-wide identification of BBX gene family and their expression patterns under salt stress in soybean[J]. BMC Genomics, 23(1): 820.
[35] Tanabe N, Yoshimura K, Kimura A.2007. Differential expression of alternatively spliced mRNAs of Arabidopsis SR protein homologs, atSR30 and atSR45a, in response to environmental stress[J]. Plant & Cell Physiology, 48(7): 1036-1049.
[36] Wahl M C, Will C L, Luhrmann R.2009. The spliceosome: Design principles of a dynamic RNP machine[J]. Cell, 136: 701-718.
[37] Wang D Y, Du M X, Li J Y, et al.2023. Overexpression of GhSWEET42, a SWEET-like gene from cotton, enhances the oil content and seed size[J]. Biotechnology & Biotechnological Equipment, 37: 1.
[38] Wang Z B, Li G F, Sun H Qet al.2018. Effects of drought stress on photosynthesis and photosynthetic electron transport chain in young apple tree leaves[J]. Biology Open, 7(11): bio035279.
[39] Xu C J, Shan J M, Liu T M, et al.2023. CONSTANS-LIKE 1a positively regulates salt and drought tolerance in soybean[J]. Plant Physiology, 191(4): 2427-2446.
[40] Yan Q, Xia X, Sun Z, et al.2017. Depletion of Arabidopsis SC35 and SC35-like serine/arginine-rich proteins affects the transcription and splicing of a subset of genes[J]. PLOS Genetcis, 13(3): e1006663.
[41] Yoshimura K, Mori T, Yokoyama K, et al.2011. Plant-specific SR-related protein atSR45a interacts with spliceosomal proteins in plant nucleus[J]. Plant Molecular Biology, 70(3): 241-252.
[42] Zahler A M, Lane W S, Stolk J A, et al.1992. SR proteins: A conserved family of pre-mRNA splicing factors[J]. Genes & Development, 6: 837-847.
[43] Zhang W, Du B, Liu D, et al.2014. Splicing factor SR34b mutation reduces cadmium tolerance in Arabidopsis by regulating iron-regulated transporter 1 gene[J]. Biochemical and Biophysical Research Communications, 455: 312-317.