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作物杂志,2024, 第4期: 33–42 doi: 10.16035/j.issn.1001-7283.2024.04.005

• 遗传育种·种质资源·生物技术 • 上一篇    下一篇

甜菜C2H2型锌指蛋白转录因子家族全基因组鉴定及镉胁迫下的表达分析

姚琦1,2,3(), 王皓2,3, 徐翎清2,3, 兴旺2,3, 刘大丽2,3, 鲁振强1()   

  1. 1黑龙江省寒区植物基因与生物发酵重点实验室/黑龙江大学生命科学学院,150080,黑龙江哈尔滨
    2国家甜菜种质中期库/黑龙江大学现代农业与生态环境学院,150080,黑龙江哈尔滨
    3黑龙江大学省高校甜菜遗传育种重点实验室/现代农业与生态环境学院,150080,黑龙江哈尔滨
  • 收稿日期:2023-05-06 修回日期:2023-08-22 出版日期:2024-08-15 发布日期:2024-08-14
  • 通讯作者: 鲁振强,研究方向为植物分子生物学,E-mail:zhenqianglu@163.com
  • 作者简介:姚琦,研究方向为寒区作物生物技术与遗传工程,E-mail:15714511208@163.com
  • 基金资助:
    黑龙江省自然科学基金(LH2019C057);国家糖料产业技术体系项目(CARS-170102);黑龙江省教育厅基本科研业务费(2022-KYYWF-1070)

Genome-Wide Identification and Expression Analysis of C2H2 Zinc-Finger Protein Transcription Factor Family in Sugar Beet under Cadmium Stress

Yao Qi1,2,3(), Wang Hao2,3, Xu Lingqing2,3, Xing Wang2,3, Liu Dali2,3, Lu Zhenqiang1()   

  1. 1Province Key Laboratory of Plant Gene and Biological Fermentation in Cold Regions / College of Life Sciences, Heilongjiang University, Harbin 150080, Heilongjiang, China
    2National Beet Medium-Term Gene Bank / College of Advanced Agriculture and Ecological Environment, Heilongjiang University, Harbin 150080, Heilongjiang, China
    3Key Laboratory of Sugar Beet Genetics and Breeding / College of Advanced Agriculture and Ecological Environment, Heilongjiang University, Harbin 150080, Heilongjiang, China
  • Received:2023-05-06 Revised:2023-08-22 Online:2024-08-15 Published:2024-08-14

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摘要:

甜菜作为一类新兴的能源作物,在重金属污染土壤的修复中具有潜在的优势。探究镉胁迫下甜菜的应答机制,对于培育耐重金属胁迫的甜菜新种质以及生态修复具有重大意义。锌指蛋白转录因子(zinc-finger protein transcription factor)是植物中广泛存在的基因家族,全方面参与植物的生长发育,并响应生物和非生物胁迫。本研究通过全基因组鉴定以及理化性质、基因结构、保守基序、染色体定位和顺式作用元件分析发现,甜菜体内共有32个C2H2型锌指蛋白转录因子家族成员,可分为3个亚族,各成员具有数量不等的锌指结构域且不同亚族成员的基因结构及序列特征存在较大差异。通过对镉胁迫下的甜菜C2H2型锌指蛋白转录因子的表达和差异表达基因的调控网络分析发现,BVRB_6g137660、BVRB_8g189640、BVRB_1g000840和BVRB_007840在镉胁迫下表达量均不同程度上调,且可能调控了镉胁迫下甜菜金属耐受蛋白及ABC转运蛋白等重要基因的表达,推测这些转录因子在提高甜菜镉耐受性方面起到了关键作用。

关键词: 甜菜, 锌指蛋白, 镉胁迫, 转录因子

Abstract:

As an emerging energy crop, sugar beet has potential advantages in the remediation of heavy metal polluted soil. Exploring the response mechanism of sugar beet under cadmium stress is of great significance for breeding new germplasm resistant to heavy metal stress and ecological restoration. Zinc-finger protein transcription factor is a widely existing gene family in plants, which takes part in plant growth and development in various aspects and responds to biological and abiotic stresses. Through genome-wide identification and analysis of physicochemical properties, gene structure, conserved motifs, chromosome location and cis-element, we found that there were 32 members of the C2H2 zinc-finger protein transcription factor family in sugar beet, which could be divided into three subfamilies. Each member had different zinc-finger domains in different numbers, and the gene structure and sequence characteristics of different subfamilies were significantly different. By analyzing the expression of C2H2 zinc-finger protein transcription factors and the regulatory network of differentially expressed genes in sugar beet under cadmium stress, we found that the expression levels of BVRB_6g137660, BVRB_8g189640, BVRB_1g000840 and BVRB_007840 were up-regulated to varying degrees under cadmium stress. Speculating that these transcription factors play a key role in improving the cadmium tolerance of sugar beet.

Key words: Sugar beet, Zinc-finger protein, Cadmium stress, Transcription factor

表1

甜菜C2H2型锌指蛋白家族成员理化性质及亚细胞定位

基因ID
Gene ID		 转录本ID
Transcript ID		 氨基酸数量
Number of amino acids		 分子量
Molecular weight (u)		 等电点
Isoelectric point		 不稳定系数
Instability index		 亚细胞定位
Subcellular localization
BVRB_1g018520 KMT00022 366 41 146.19 8.46 70.84 细胞核
BVRB_6g136840 KMT08971 534 59 773.12 9.10 59.57 细胞核
BVRB_9g212520 KMT01234 342 37 043.98 8.84 71.81 细胞外,细胞核
BVRB_5g113850 KMT10727 563 62 233.31 8.77 56.24 细胞核
BVRB_1g012990 KMT19293 456 50 064.47 5.93 60.88 细胞核
BVRB_9g206210 KMT02271 343 37 459.07 6.24 60.35 细胞核
BVRB_7g179220 KMS97061 340 37 135.81 7.75 55.44 细胞核
BVRB_8g189640 KMT03820 242 25 661.67 8.09 53.01 细胞核
BVRB_1g015270 KMT19130 275 29 083.48 8.78 60.67 细胞核
BVRB_2g037310 KMT17528 186 20 667.45 8.86 57.60 细胞核
BVRB_1g018510 KMT00021 523 56 286.76 6.37 51.56 细胞核
BVRB_7g174490 KMT05313 231 25 076.07 5.84 38.19 细胞核
BVRB_2g046350 KMS99266 543 60 544.44 7.17 39.85 细胞核
BVRB_5g111450 KMT11057 237 26 905.18 8.52 59.79 细胞核
BVRB_6g147790 KMT07654 226 25 663.52 9.10 62.68 细胞核
BVRB_5g106070 KMT11669 187 21 346.69 5.52 59.95 细胞核
BVRB_6g130850 KMT09633 208 22 645.27 8.60 47.07 细胞核
BVRB_3g067630 KMS98868 154 17 264.82 5.64 63.00 细胞核
BVRB_3g067720 KMS98878 247 27 624.67 9.20 45.64 细胞核
BVRB_007850 KMS95480 371 41 815.85 6.12 41.96 细胞核
BVRB_3g068910 KMS98817 309 34 263.02 8.70 58.91 细胞核
BVRB_3g063640 KMT15255 323 35 834.41 8.56 58.90 细胞核
BVRB_6g138130 KMT08530 1460 164 803.16 6.37 42.75 细胞核
BVRB_016580 KMS94655 176 19 758.12 6.15 48.27 细胞核
BVRB_6g141700 KMT08346 247 25 923.68 8.64 68.65 细胞核
BVRB_007840 KMS95479 414 46 178.78 8.58 53.94 细胞核
BVRB_007870 KMS95482 370 41 964.66 8.12 44.37 细胞核
BVRB_007880 KMS95483 406 45 560.31 7.52 46.30 细胞核
BVRB_1g000840 KMT20065 513 57 833.77 5.84 49.07 细胞核
BVRB_6g137660 KMT09067 559 58 440.17 8.62 72.22 细胞核
BVRB_042870 KMS64767 88 10 142.79 11.72 50.60 叶绿体,线粒体,细胞核
BVRB_5g123490 KMS97785 641 73 777.76 5.00 56.65 高尔基体,细胞核

图1

甜菜C2H2型锌指蛋白家族进化树

图2

甜菜C2H2型锌指蛋白家族成员的进化树(a)、保守基序(b)、结构域(c)和基因结构(d)分析

图3

甜菜C2H2型锌指蛋白家族成员的保守基序序列

图4

甜菜、拟南芥、水稻的C2H2型锌指蛋白系统发育树 粉色为甜菜,绿色为拟南芥,蓝色为水稻。

图5

甜菜C2H2型锌指蛋白家族成员的染色体定位 染色体颜色表示基因密度,颜色越红密度越高,颜色越蓝密度越低。

图6

甜菜C2H2型锌指蛋白转录因子启动子顺式作用元件分析

图7

甜菜C2H2型锌指转录因子表达热图

图8

甜菜C2H2型锌指转录因子与靶基因调控网络图

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