2025-5-6- 6
Home > Archive>Volume 25, Issue 6, 2024 >978-989. DOI:10.13430/j.cnki.jpgr.20240127001
PDF HTML XML Export Cite reminder
Cloning and Functional Characterization of the GmDUF247-1 Gene in Soybean Response to Saline-alkaline Stress
Author:
Affiliation:

College of Agriculture, Heilongjiang Bayi Agriculture University, Daqing 163319

Fund Project:

Foundation projects: National Natural Science Foundation of China (32101672, 32341033); National Key Research and Development Program (2021YFF1001100); Natural Science Foundation of Heilongjiang Province (JQ2021C002); Collaborative Innovation Achievement Program for “Double First-class” Disciplines in Heilongjiang Province (LJGXCG2023 -072); Heilongjiang Bayi Agricultural Reclamation University Young Innovative Talent Cultivation Program (ZRCQC202302); Heilongjiang Bayi Agricultural Reclamation University Introducing Talents Research Initiation Program (XYB202101); Innovative Research Program for Graduate Students of Heilongjiang Bayi Agricultural Reclamation University (YJSCX2022-Y07)

  • Article
    • | |
  • Metrics
    • |
  • Reference [41]
    • | | | |
  • Comments
    Abstract:

    Saline-alkaline lands, which are found with large area in China, are considered as potential exploitable land resource inagriculture. Breeding of new soybean cultivars showing salt-alkaline tolerance in these regions is a way to improve the soybean production in China. Therefore, identification of the negative regulatory genes to saline-alkaline stress is of interest, and editing of them in elite varieties is able to create new soybean cultivars with salt-alkaline tolerance. Previously, we found that the gene Glyma.02g271000 (named as GmDUF247-1) was down-regulated under mixed salt-alkaline stress condition. GmDUF247-1 was annotated with one DUF247 (Domain of Unknown Function 247) domain and one transmembrane domain, and the GmDUF247-1-GFP fusion protein was observed on the cell membrane when transiently expressing in tobacco leaves. GmDUF247-1 was detected with the highest transcripts in roots, and its expression was down-regulated under mixed saline-alkaline treatment. Through generating the hairy root composite plants, the transgenic plants overexpressing GmDUF247-1 showed more wilted leaves, lower survival rates, shorter roots and shoots if compared with these lines expressing the empty vector. Based on the haplotype analysis of GmDUF247-1 in soybean population, eight SNPs and four InDels in the promoter region were detected, implying alterations potentially in the binding of growth- and stress-related transcription. Three haplotypes were identified based on the coding sequence variations, and the haplotype GmDUF247-1H1 was detected with artificial selection. In summary, we provided the preliminary results on negative regulation of GmDUF247-1 under mixed salt-alkaline stress treatment, which will facilitate to systematically characterize its function and elucidate its potential in breeding new soybean cultivars with superior tolerance to mixed salt-alkaline stress.

    Reference
    [1] 董红云, 朱振林, 李新华, 杨丽萍, 张正. 山东省盐碱地分布、改良利用现状与治理成效潜力分析. 山东农业科学, 2017, 49(5): 134-139Dong H Y, Zhu Z L, Li X H, Yang L P, Zhang Z. Analysis on distribution, utilization status and governance effect of saline-alkali soil in Shandong province. Shandong Agricultural Sciences, 2017, 49(5): 134-139
    [2] 王世平, 陈月, 潘大伟, 薛文多, 周雷, 赵娜, 巩宗强, 张晓蓉. 盐碱地治理研究综述: 现状、问题与对策. 化工矿物与加工, 2023, 52(11): 59-68Wang S P, Chen Y, Pan D W, Xue W D, Zhou L, Zhao N, Gong Z Q, Zhang X R. Review on salt marshes management: Status, problems and counter measures. Industrial Minerals and Processing, 2023, 52(11): 59-68
    [3] 杨久涛, 孙红滨, 王桂峰, 汪丽, 邢晓飞, 杨武杰. 山东盐碱地农业综合开发利用现状与展望. 中国农业综合开发, 2023, (6): 7-12Yang J T, Sun H B, Wang G F, Wang L, Xing X F, Yang W J. Current situation and prospect of comprehensive agricultural development and utilization of saline and alkaline land in Shandong province. China Comprehensive Agricultural Development, 2023, (6): 7-12
    [4] Liu L L, Wang B S. Protection of halophytes and their uses for cultivation of saline-alkali soil in China. Biology: Basel, 2021, 10(5): 353
    [5] 韩毅强, 高亚梅, 杜艳丽, 张玉先, 杜吉到, 张文慧, 潘绍玉. 大豆耐盐碱种质资源鉴定. 中国油料作物学报, 2021, 43(6): 1016-1024Han Y Q, Gao Y M, Du Y L, Zhang Y X, Du J D, Zhang W H, Pan S Y. Identification of saline-alkali tolerant germplasm resources of soybean during the whole growth stage. Chinese Journal of Oil Crop Sciences, 2021, 43(6): 1016-1024
    [6] Sun S L, Liu X, Zhang T L, Yang H, Yu B J. Functional characterisation of the transcription factor GsWRKY23 gene from Glycine soja in overexpressed soybean composite plants and Arabidopsis under salt stress. Plants: Basel, 2023, 12(17): 3030
    [7] Phang T H, Shao G, Lam H M. Salt tolerance in soybean. Journal of Integrative Plant Biology, 2008, 50(10): 1196-1212
    [8] 胡壮壮, 王路路, 姜雪冰, 尹毛珠, 姜磊, 李进步, 沈维良. 我国大豆产业发展现状分析及对策. 大豆科技, 2023, (4): 1-11Hu Z Z, Wang L L, Jiang X B, Yin M Z, Jiang L, Li J B, Shen W L. Analysis and countermeasure of soybean industry development status in China. Soybean Science and Technology, 2023, (4): 1-11
    [9] Guan R X, Qu Y, Guo Y, Yu L L, Liu Y, Jiang J H, Chen J G, Ren Y L, Liu G Y, Tian L G, Jin L, Liu Z X, Hong H L, Chang R Z, Gilliham M, Qiu L J. Salinity tolerance in soybean is modulated by natural variation in GmSALT3. The Plant Journal, 2014, 80(6): 937-950
    [10] Liu Y, Yu L L, Qu Y, Chen J J, Liu X X, Hong H L, Liu Z X, Chang R Z, Gilliham M, Qiu L J, Guan R X. GmSALT3, which confers improved soybean salt tolerance in the field, increases leaf Cl- exclusion prior to Na+ exclusion but does not improve early vigor under salinity. Frontiers in Plant Science, 2016, 7: 1485
    [11] Li Y, Ye H, Vuong T D, Zhou L J, Do T D, Chhapekar S S, Zhao W Q, Li B, Jin T, Gu J B, Li C, Chen Y H, Li Y, Wang Z Y, Nguyen H T. A novel natural variation in the promoter of GmCHX1 regulates the conditional gene expression to improve salt tolerance in soybean. Journal of Experimental Botany, 2023: erad404
    [12] Jin T, Sun Y Y, Shan Z, He J B, Wang N, Gai J Y, Li Y. Natural variation in the promoter of GsERD15B affects salt tolerance in soybean. Plant Biotechnology Journal, 2021, 19(6): 1155-1169
    [13] Zhang W, Liao X L, Cui Y M, Ma W Y, Zhang X N, Du H Y, Ma Y J, Ning L H, Wang H, Huang F, Yang H, Kan G Z, Yu D Y. A cation diffusion facilitator, GmCDF1, negatively regulates salt tolerance in soybean. PLoS Genetics, 2019, 15(1): e1007798
    [14] 杨天瑞. 中间锦鸡儿3个DUF基因的生物信息学分析和CiDUF966-1基因功能分析. 呼和浩特: 内蒙古农业大学, 2018Yang T R. Bioinformatic analysis of three DUF genes from caragana intermedia and function characterization of CiDUF966-1. Hohhot: Inner Mongolia Agricultural University, 2018
    [15] Lv P Y, Wan J L, Zhang C T, Hina A, Al Amin G M, Begum N ,Zhao T J. Unraveling the diverse roles of neglected genes containing domains of unknown function (DUFs): Progress and perspective. International Journal of Molecular Sciences, 2023, 24(4): 4187
    [16] 白子彧. 大麦盐诱导根系表达基因HvSR1的鉴定及其功能分析专用载体的构建. 天津: 天津农学院, 2016Bai Z Y. The roots salt-induced genes HvSR1 identification in barley and construction of vector specially used in gene function analysis. Tianjin: Tianjin Agricultural University, 2016
    [17] 周敏, 付金娥, 韦树根, 潘丽梅. 青蒿不同部位总RNA提取方法比较. 江苏农业科学, 2017, 45: 31-33Zhou M, Fu J E, Wei S G, Pan L M. Comparison of total RNA extraction methods from different parts of Artemisia annua. Jiangsu Agricultural Sciences 2017, 45: 31-33
    [18] Jia B W, Wang Y, Zhang D J, Li W H, Cui H L, Jin J, Cai X X, Shen Y, Wu S Y, Guo Y X, Sun M Z, Sun X L. Genome-wide identification, characterization and expression analysis of soybean CHYR gene family. International Journal of Molecular Sciences, 2021, 22(22): 12192
    [19] Willems E, Leyns L, Vandesompele J. Standardization of real-time PCR gene expression data from independent biological replicates. Analytical Biochemistry, 2008, 379(1): 127-129
    [20] Kereszt A, Li D, Indrasumunar A, Nguyen C D, Nontachaiyapoom S, Kinkema M, Gresshoff P M. Agrobacterium rhizogenes-mediated transformation of soybean to study root biology. Nature Protocols, 2007, 2(4): 948-952
    [21] Wei P P, Wang L C, Liu A L, Yu B J, Lam H M. GmCLC1 confers enhanced salt tolerance through regulating chloride accumulation in soybean. Frontiers in Plant Science, 2016, 7: 1082
    [22] Liu L, Wang J B, Zhang Q, Sun T T, Wang P W. Cloning of the soybean GmNHL1 gene and functional analysis under salt stress. Plants: Basel, 2023, 12(22): 3869
    [23] 魏胜华, 孟娜. 改良CTAB法提取大戟属药用植物叶片总DNA试验. 湖北农业科学, 2011, 50: 3418-3420Wei S H, Meng N. A modified CTAB method for total DNA extraction from the medicinal herb leaves of Euphorbia Linn. Hubei Agricultural Sciences, 2011, 50: 3418-3420
    [24] Xu C J, Shan J M, Liu T M, Wang Q, Ji Y J, Zhang Y T, Wang M Y, Xia N, Zhao L. CONSTANS-LIKE 1a positively regulates salt and drought tolerance in soybean. Plant Physiology, 2023, 191(4): 2427-2446
    [25] Liu Y C, Zhang Y, Liu X N, Shen Y T, Tian D M, Yang X Y, Liu S L, Ni L B, Zhang Z, Song S H, Tian Z X. SoyOmics: A deeply integrated database on soybean multi-omics. Molecular Plant, 2023, 16(5): 794-797
    [26] Wannitikul P, Wattana-Amorn P, Sathitnaitham S, Sakulkoo J, Suttangkakul A, Wonnapinij P, Bassel G W, Simister R, Gomez L D ,Vuttipongchaikij S. Disruption of a DUF247 containing protein alters cell wall polysaccharides and reduces growth in Arabidopsis. Plants: Basel, 2023, 12(10): 1977
    [27] Rohner M, Manzanares C, Yates S, Thorogood D, Copetti D, Lübberstedt T, Asp T, Studer B. Fine-mapping and comparative genomic analysis reveal the gene composition at the S and Z self-incompatibility loci in grasses. Molecular Biology and Evolution, 2023, 40(1): msac259
    [28] Kondou Y, Noguchi K, Kutsuna S, Kawashima M, Yoneda A, Ishibashi M, Muto S, Ichikawa T, Nakazawa M, Matsui M. Overexpression of DWARF AND LESION FORMATION 1 (DLE1) causes altered activation of plant defense system in Arabidopsis thaliana. Plant Biotechnology, 2013, 30(4): 385-392
    [29] He Y X, Yang X D, Xu C, Guo D Q, Niu L, Wang Y, Li J W, Yan F, Wang Q Y. Overexpression of a novel transcriptional repressor GmMYB3a negatively regulates salt-alkali tolerance and stress-related genes in soybean. Biochemical and Biophysical Research Communications, 2018, 498(3): 586-591
    [30] Li L, Zhu Z, Liu J, Zhang Y, Lu Y, Zhao J M, Han X, Guo N. Transcription factor GmERF105 negatively regulates salt stress tolerance in Arabidopsis thaliana. Plants: Basel, 2023, 12(16): 3007
    [31] Leung H S, Chan L Y, Law C H, Li M W, Lam H M. Twenty years of mining salt tolerance genes in soybean. Molecular Breeding, 2023, 43(6): 45
    [32] Qu Y, Guan R X, Bose J, Henderson S W, Wege S, Qiu L J, Gilliham M. Soybean CHX-type ion transport protein GmSALT3 confers leaf Na+ exclusion via a root derived mechanism, and Cl- exclusion via a shoot derived process. Plant Cell Environment, 2021, 44(3): 856-869
    [33] Cai X X, Jia B W, Sun M Z, Sun X L. Insights into the regulation of wild soybean tolerance to salt-alkaline stress. Frontiers in Plant Science, 2022, 13: 1002302
    [34] Li J W, Sun M Z, Liu Y, Sun X L, Yin D K. Genome-wide identification of wild soybean mitochondrial calcium uniporter family genes and their responses to cold and carbonate alkaline stresses. Frontiers in Plant Science, 2022, 13: 867503
    [35] Cao Y X, Wang J, Zhao S Q, Fang Q X, Ruan J W, Li S L, Liu T X, Qi Y X, Zhang L, Zhang X M, Meng F L. Overexpression of the aldehyde dehydrogenase AhALDH3H1 from Arachis hypogaea in soybean increases saline-alkali stress tolerance. Frontiers in Plant Science, 2023, 14: 1165384
    [36] Saini H, Thakur R, Gill R, Tyagi K, Goswami M. CRISPR/Cas9-gene editing approaches in plant breeding. GM Crops & Food-Biotechnology in Agriculture and the Food Chain, 2023, 14(1): 1-17
    [37] Cao L, Yu Y, DuanMu H Z, Chen C, Duan X B, Zhu P H, Chen R R, Li Q, Zhu Y M, Ding X D. A novel Glycine soja homeodomain-leucine zipper (HD-Zip) I gene, Gshdz4, positively regulates bicarbonate tolerance and responds to osmotic stress in Arabidopsis. BMC Plant Biology, 2016, 16(1): 184
    [38] Pisias M T, Bakala H S, McAlvay A C, Mabry M E, Birchler J A, Yang B, Pires J C. Prospects of feral crop de novo redomestication. Plant Cell Physiology, 2022, 63(11): 1641-1653
    [39] Li F F, Chen G P, Xie Q L, Zhou S G, Hu Z L. Down-regulation of SlGT-26 gene confers dwarf plants and enhances drought and salt stress resistance in tomato. Plant Physiology and Biochemistry, 2023, 203: 108053
    [40] Li F F, Chen X Y, Zhou S G, Xie Q L, Wang Y S, Xiang X X, Hu Z L, Chen G P. Overexpression of SlMBP22 in tomato affects plant growth and enhances tolerance to drought stress. Plant Science, 2020, 301: 110672
    [41] Cheng Q, Gan Z R, Wang Y P, Lu S J, Hou Z H, Li H Y, Xiang H T, Liu B H, Kong F J, Dong L D. The soybean gene J contributes to salt stress tolerance by pup-regulating salt-responsive genes. Frontiers in Plant Science, 2020, 11: 272
    Related
    Cited by
    Comments
    Comments
    分享到微博
    Submit
Get Citation

Copy
Share
Article Metrics
  • Abstract:303
  • PDF: 527
  • HTML: 144
  • Cited by: 0
History
  • Received:January 27,2024
  • Online: June 11,2024
  • Published: June 11,2024
Article QR Code
You are the 634484th visitor 京ICP备09069690号-23
® 2025 All Rights Reserved
Supported by:Beijing E-Tiller Technology Development Co., Ltd.
Firefox, Chrome, IE10, IE11 are recommended. Other browsers are not recommended.