谷子miR169家族及其靶基因的鉴定与功能分析

doi:10.16035/j.issn.1001-7283.2022.02.008

作物杂志,2022, 第2期: 54–63 doi: 10.16035/j.issn.1001-7283.2022.02.008

• 遗传育种·种质资源·生物技术 • 上一篇下一篇

谷子miR169家族及其靶基因的鉴定与功能分析

卢平¹(), 康庆芳¹, 赵孟瑶¹, 张凤洁², 武强强², 马芳芳², 王宇珅², 韩渊怀², 王兴春¹, 李雪垠¹^,^*()

¹山西农业大学生命科学学院,030801,山西晋中
²山西农业大学农学院,030801,山西晋中

收稿日期:2021-04-19 修回日期:2022-02-12 出版日期:2022-04-15 发布日期:2022-04-24
通讯作者: 李雪垠
作者简介:卢平,主要从事植物生物信息学研究,E-mail： luping10925@163.com
基金资助:
国家重点研发计划(2018YFD1000700);国家重点研发计划(2018YFD1000706);国家自然科学基金(31801434);山西农业大学科技创新基金项目(2017YJ28);山西省重点研发计划项目(201803D221019-2);山西省应用基础研究项目(201801D221298);山西农业大学科技创新基金项目(2017YJ01)

Identification and Functional Analysis of miR169 Family and Its Target Genes in Setaria italica

Lu Ping¹(), Kang Qingfang¹, Zhao Mengyao¹, Zhang Fengjie², Wu Qiangqiang², Ma Fangfang², Wang Yushen², Han Yuanhuai², Wang Xingchun¹, Li Xueyin¹^,^*()

¹College of Life Sciences, Shanxi Agricultural University, Jinzhong 030801, Shanxi, China
²College of Agriculture, Shanxi Agricultural University, Jinzhong 030801, Shanxi, China

Received:2021-04-19 Revised:2022-02-12 Online:2022-04-15 Published:2022-04-24
Contact: Li Xueyin

摘要/Abstract

摘要：

microRNA广泛参与植物中多个生长发育过程,miR169家族是最保守的miRNA家族之一。对谷子miR169（sit-miR169）家族进行生物信息学分析,包括染色体分布、系统进化、碱基保守性、二级结构和sit-miR169及其靶基因的表达。鉴定了15个sit-miR169,分布于7条染色体上。系统进化分析显示,sit-miR169家族前体sit-MIR169大致可以分为2簇,部分sit-MIR169成员与水稻osa-MIR169家族成员亲缘关系较近。sit-miR169的前体均可形成稳定的二级茎环结构,成熟体均产生于前体的5′端臂上,且成熟序列的碱基保守性很强。sit-miR169在花、叶和根中均有表达,具有明显组织表达特异性。sit-miR169的靶基因主要是NF-YA转录因子基因,此外还有L型凝集素类受体蛋白激酶、ω-6脂肪酸去饱和酶、转运蛋白Sec1a、SDG40蛋白、环指跨膜蛋白和核糖体大亚基假尿苷合酶SVR1基因等。miR169通过调控靶基因,尤其是NF-YA的表达量来影响植物的生长发育和对环境的应答。谷子NF-YA基因主要在根和穗中表达,表现出明显的组织表达特异性。此外,sit-miR169靶基因的表达受环境诱导,如干旱条件能进一步诱导Seita.9G521100基因在根中的表达。

关键词: 谷子, miRNA, miR169, 靶基因, 生物信息学

Abstract:

MicroRNA are widely involved in various plant growth and development processes, and the miR169 family is one of the most conservative miRNA families. In this study, a series of bioinformatic analyses were conducted on the miR169 family of Setaria italica (sit-miR169), including chromosomal distribution, phylogeny, base conservativeness, secondary structures, and the expression of sit-miR169 and its target genes. We identified 15 sit-miR169 distributed on seven chromosomes. Phylogenetic analysis showed that the sit-MIR169 family could be mainly divided into two clusters, and some members of sit-MIR169 were closely related to the members of the osa-MIR169 family in rice. All the precursors of sit-miR169 formed a stable secondary stem-loop structure, and the mature ones were all generated from the 5'-end arms of the precursors, and the mature sequences had a strong base conservativeness. The sit-miR169 was expressed in flowers, leaves, and roots, with obvious tissue specificity. The target genes of sit-miR169 were mainly NF-YA transcription factor genes, in addition to L-type lectin-domain containing receptor kinase, ω-6 fatty acid desaturase, protein transporter Secla, protein SDG40, ring finger transmembrane domain-containing protein, and ribosomal large pseudouridine synthase SVR1 genes. The miR169 affected plant growth and development and environmental response by regulating the expression of target genes, especially the NF-YA gene. The NF-YA gene in Setaria italica was mainly expressed in roots and spikes, showing obvious specificity tissue expression. In addition, the expression of sit-miR169 target genes was induced by the environmental conditions, for example, drought condition further induced the expression of Seita.9G521100 in roots.

Key words: Setaria italica, miRNA, miR169, Target gene, Bioinformatics

卢平, 康庆芳, 赵孟瑶, 张凤洁, 武强强, 马芳芳, 王宇珅, 韩渊怀, 王兴春, 李雪垠. 谷子miR169家族及其靶基因的鉴定与功能分析[J]. 作物杂志, 2022 (2): 54–63

Lu Ping, Kang Qingfang, Zhao Mengyao, Zhang Fengjie, Wu Qiangqiang, Ma Fangfang, Wang Yushen, Han Yuanhuai, Wang Xingchun, Li Xueyin. Identification and Functional Analysis of miR169 Family and Its Target Genes in Setaria italica[J]. Crops, 2022(2): 54–63

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miRNA	miRNA基因座 miRNA locus	染色体定位 Chromosome location	成熟序列 Mature sequence	碱基数 Base number	星标序列 Star sequence	碱基数 Base number
sit-miR169a	sit-MIR169a	Chr1: 6337067-6337254 (-)	CAGCCAAGGAUGACUUGCCGG	21	GCAAGUUUGUCCAUGGCUACG	21
sit-miR169b	sit-MIR169b	Chr4: 30531819-30531966 (+)	CAGCCAAGGAUGACUUGCCGG	21	GGCAAGUUGUCCUUGGCUACA	21
sit-miR169c	sit-MIR169c	Chr6: 1523821-1523981 (-)	CAGCCAAGGAUGACUUGCCGG	21	GCAAGUCUGUCCUUGGCUACA	21
sit-miR169d	sit-MIR169d	Chr6: 1522499-1522640 (-)	CAGCCAAGGAUGACUUGCCGG	21	GCAAGUCUGUCCUUGGCUACA	21
sit-miIR169e	sit-MIR169e	Chr7: 29380903-29381033 (-)	CAGCCAAGGAUGACUUGCCGG	21	GCAAGUCUGUCCUUGGCUACA	21
sit-miR169f	sit-MIR169f	Chr1: 37871079-37871206 (-)	UAGCCAAGGAUGACUUGCCGG	21	AGGUUUUUCUCGCUGGCUACA	21
sit-miR169g	sit-MIR169g	Chr2: 36921080-36921208 (+)	UAGCCAAGGAUGACUUGCCUG	21	AGGCAGUCUCCUUGGCUAGCC	21
sit-miR169h	sit-MIR169h	Chr2: 36923990-36924147 (+)	UAGCCAAGGAUGACUUGCCUG	21	AGGCAGUCUCCUUGGCUAGUC	21
sit-miR169i	sit-MIR169i	Chr2: 36926242-36926373 (+)	UAGCCAAGGAUGACUUGCCUG	21	AGGCAGUCUCCUUAGGUAGUC	21
sit-miR169j	sit-MIR169j	Chr2: 30310044-30310172 (-)	UAGCCAAGGAUGACUUGCCUG	21	GGCAAGUCAUCUGUGACUACG	21
sit-miR169k	sit-MIR169k	Chr3: 6158109-6158242 (+)	UAGCCAAGAAUGACUUGCCU	20	AUGGUAGGCAUUCUGGUUAAG	21
sit-miR169l	sit-MIR169l	Chr6: 33994504-33994663 (+)	UAGCCAAGGAUGACUUGCCUG	21	CGGCAGUCUCCUUGGCUAGCC	21
sit-miR169m	sit-MIR169m	Chr6: 33997852-33997981 (+)	UAGCCAAGGAUGACUUGCCUG	21	GGGCAGUCUCCUUGGCUAGCC	21
sit-miR169n	sit-MIR169n	Chr6: 34000992-34001127 (+)	UAGCCAAGGAUGACUUGCCUG	21	AGGCAGUCUCCUUGGCUAGCC	21
sit-miR169o	sit-MIR169o	Chr8: 12119169-12119306 (+)	UAGCCAAGAAUGACUUGCCU	20	GGCGAGUCUUCUUGGCUAGCC	21

谷子miR169家族及其靶基因的鉴定与功能分析

Identification and Functional Analysis of miR169 Family and Its Target Genes in Setaria italica

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