盐肤木AGAMOUS同源基因的克隆及其功能分析

doi:10.11707/j.1001-7488.LYKX20230496

摘要/Abstract

摘要：

目的: AGAMOUS（AG）基因在控制雌蕊、雄蕊的发育中起着重要作用。对盐肤木中AG同源基因的克隆与功能分析，有利于明确AG基因在盐肤木花器官发育中的功能，并为进一步探索盐肤木花性别分化机制提供参考。方法: 基于实验室已有的转录组数据并结合RACE技术，从盐肤木花中克隆获得盐肤木AG同源基因，并对其编码的蛋白进行结构和系统进化分析；通过实时定量PCR技术分析盐肤木AG同源基因在雌、雄及两性花的不同花期中的表达特征；构建盐肤木AG同源基因的过表达载体，采用花序浸染法进行拟南芥遗传转化，获得T2代转基因植株，观察转基因植株表型。结果: 在盐肤木克隆获得了AG同源基因的2个可变剪接转录本，分别为RcAG和第6个外显子缺失的Rcag。RcAG包含729 bp的开放阅读框，编码242个氨基酸；Rcag包含687 bp的开放阅读框，编码228个氨基酸。系统进化树分析结果表明，RcAG与其同科植物杧果和阿月浑子的AG同源蛋白亲缘关系较近。qRT-PCR分析表明，在盐肤木不同发育阶段的雌、雄及两性花中，RcAG和Rcag呈现丰度持续升高的趋势，且在盐肤木雄花中，RcAG和Rcag的丰度要极显著高于雌花及两性花。过表达拟南芥表型观察发现，过表达RcAG导致拟南芥花瓣和雄蕊缺失，萼片尖端柱头化，萼片基部边缘出现胚珠结构，而过表达Rcag的拟南芥出现花瓣数量增多和雄蕊数量减少。结论: Rcag可能由于K区42 bp碱基的缺失丧失AG基因的正常功能，与RcAG相互竞争，共同调控盐肤木雌、雄蕊的发育。这一结果为进一步探索RcAG和Rcag在盐肤木性别分化中的作用奠定基础。

关键词: 盐肤木, 可变剪接, RcAG, Rcag, 功能分析

Abstract:

Objective: AGAMOUS (AG) plays an important role in controlling the development of pistil and stamen. The cloning and functional analysis of AG homologous gene is helpful to clarify the function of AG gene in the flower organ development of Rhus chinensis, and lays a foundation for further exploration of the gender differentiation mechanism of R. chinensis flowers. Method: Based on existing transcriptome data in this laboratory, and combined with RACE technology, an AG homologous gene was cloned from R. chinensis flowers, and the structure and phylogenetic evolution of its encoded protein were analyzed. The real-time quantitative PCR was used to analyze the expression characteristics of AG homologous gene of R. chinensis in female, male and bisexual flowers at different flowering stages. Furthermore, the overexpression vector of AG homologous gene of R. chinensis was constructed, the transgenic plants was obtained by inflorescence staining and the transgenic plant phenotype was observed. Result: Two alternative splicing transcripts of AG homologous gene were cloned from R. chinensis, namely RcAG and Rcag with the deletion of the sixth exon. RcAG contains 729 bp open reading frame and can encode 242 amino acids. Rcag contains 687 bp open reading frame, encoding 228 amino acids. Phylogenetic tree analysis showed that RcAG was closely related to AG homologous proteins of Mangifera indica and Pistacia vera. qRT-PCR analysis showed that the abundance of RcAG and Rcag in female, male and bisexual flowers of R. chinensis showed a continuously increasing trend at different developmental stages, and the abundance of RcAG and Rcag in male flowers was significantly higher than that in female and bisexual flowers. Phenotypic observation of Arabidopsis thaliana showed that overexpression of RcAG in A. thaliana resulted in loss of petals and stamens, stigmatization of the tip of the sepal, and ovular structure at the edge of the base of the sepal. However, the number of petals increased and the number of stamens decreased in Rcag transgenic Arabidopsis. Conclusion: Based on the above results, Rcag loses the normal function of AG gene probably due to the absence of 42 bp base in K-region, and competes with RcAG to jointly regulate the development of female and stamen of R. chinensis. These results lay a foundation for the further exploration of RcAG and Rcag in the sex differentiation of R. chinensis.

Key words: Rhus chinensis, alternative splicing, RcAG, Rcag, functional analysis

中图分类号:

S718.46

王芳岚,项明,张霞,顾磊,刘文,陈发菊. 盐肤木AGAMOUS同源基因的克隆及其功能分析[J]. 林业科学, 2024, 60(6): 94-101.

Fanglan Wang,Ming Xiang,Xia Zhang,Lei Gu,Wen Liu,Faju Chen. Cloning and Functional Analysis of AGAMOUS Homologous Gene in Rhus chinensis[J]. Scientia Silvae Sinicae, 2024, 60(6): 94-101.

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引物primer	序列sequence(5'→3')	用途Application
5' RcAG1/2	AACCCCAAAGGCAGAAACCT	RACE巢式PCR引物 RACE nested PCR primers
3' RcAG1/2	CATCGCTTCAGCTTGGTGTG
Long primer	CTAATACGACTCACTATAGGGCAAGCAGTGGTATCAACGCAGAGT
Short primer	CTAATACGACTCACTATAGGGC
qRcAG F	GCAGAAATCGAATACATGCAGAAGAGGG	qRT-PCR引物 qRT-PCR primers
qRcAG R	CTAACTGGAGGGCCATCTGGTCC
qRcag R	CTAACTGGAGGGCCATCTGGTCC
qRcag F	CAGATCCTTTTTGGAAATTGATTTGCACAAC
ACTIN F	TCCACCGTCCGATCATCAGAAC
ACTIN R	GCACGTTCCATTCCTCCACC
yfm-1300s AG/ag F	GCGAGCTCGGTACCCGGATGGCCTTTCCAAACGAATCAAGAG	表达载体引物 Expression vector primers
yfm-1300s AG/ag R	GCAGGTCGACTCTAGAGGCATATTAGACTAACTGGAGGGC	表达载体引物 Expression vector primers
gRcag-F	CTTGAATGTCAAGGAACTCAAGAAC	基因组序列引物 Genome sequence primers
gRcag-R	TCGAAGGAGCTGGTTGTTGTTG	基因组序列引物 Genome sequence primers

蛋白名称Protein name	物种Species	蛋白登录号GenBank
PvMADS1	阿月浑子Pistacia vera	XP_031287460
MiAG	杧果Mangifera indica	AER34988
CsAG	甜橙Citrus sinensis	ADP02394
CcAG	甜橙Citrus sinensis	XP_006449577
AG	拟南芥Arabidopsis thaliana	P17839
SHP1	拟南芥Arabidopsis thaliana	P29381
SHP2	拟南芥Arabidopsis thaliana	P29385
STK	拟南芥Arabidopsis thaliana	Q38836
AP1	拟南芥Arabidopsis thaliana	P35631
FUL	拟南芥Arabidopsis thaliana	Q38876
AGL79	拟南芥Arabidopsis thaliana	AEE77628
AP3	拟南芥Arabidopsis thaliana	P35632
PI	拟南芥Arabidopsis thaliana	P48007
SEP1	拟南芥Arabidopsis thaliana	P29382
SEP2	拟南芥Arabidopsis thaliana	P29384
SEP3	拟南芥Arabidopsis thaliana	O22456
SEP4	拟南芥Arabidopsis thaliana	NP_178466
FAR	金鱼草Antirrhinum majus	CAB42988
PLE	金鱼草Antirrhinum majus	AAB25101
FBP6	碧冬茄Petunia × hybrid	CAA48635
FBP3	碧冬茄Petunia × hybrid	CAA50549
FBP7	碧冬茄Petunia × hybrid	CAA57311
FBP11	碧冬茄Petunia × hybrid	CAA57445
TAG1	番茄Solanum lycopersicum	Q40168
TAGL1	番茄Solanum lycopersicum	NP_001300859
TAGL11	番茄Solanum lycopersicum	AAM33102
MtAGa	蒺藜状苜蓿Medicago truncatula	AGV55405
MtAGb	蒺藜状苜蓿Medicago truncatula	AGV55406
NbAG	本氏烟Nicotiana benthamiana	AFK13159
NbSHP	本氏烟Nicotiana benthamiana	AFK13160
MastAG	星花木兰Magnolia stellata	AFH74392
MawuAG	红花玉兰Magnolia wufengensis	AEO52692
MafiAG	含笑Magnolia figo	AFH74385
MagrAG	荷花木兰Magnolia grandiflora	AFH74382
EuplAG	领春木Euptelea pleiosperma	ADC79699
LMADS10	麝香百合Lilium longiflorum	AIJ29174
OMADS4	文心兰Oncidium Gower Ramsey	AIJ29176
OsMADS3	稻Oryza sativa	Q40704
OsMADS58	稻Oryza sativa	Q2V0P1

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