摘要
大豆花叶病毒(SMV,soybean mosaic virus)病是世界大豆主产区广泛存在且普遍发生的主要病害之一,对大豆的产量和品质均可造成严重危害。本文综合分析了近年来通过遗传定位发现的大豆花叶病毒抗性基因及其紧密连锁的分子标记,探讨了分子标记在提高大豆抗病育种中的应用,总结了RSC3(w)、RSC14-r和RSC18等抗大豆花叶病毒基因的物理位置及其候选基因。基于候选基因测序、实时荧光定量PCR、病毒介导基因沉默(VIGS,virus induced gene silencing)和基因编辑CRISPR/Cas9等技术梳理出GsCAD1、GmCAL和GmMLRK1等一系列直接或间接参与大豆花叶病毒抗性的相关基因,为大豆抗大豆花叶病毒基因调控网络的完善奠定了基础。本综述总结分析了大豆与大豆花叶病毒的相互作用机制,聚焦分析大豆抗性基因Rsv3等对大豆花叶病毒抗病机制研究进展,并对抗大豆花叶病毒育种的研究方向提出了展望,以期为大豆抗性基因分子标记的应用和分子调控机制的研究提供参考。
大豆花叶病毒(SMV,soybean mosaic virus)病感染大豆后主要引起褪绿、皱缩和矮化等花叶症状及顶枯等坏死症状,是世界大豆主产区广泛存在且普遍发生的主要病害之一,对大豆产量和品质均可造成严重危害。由于其分布广、危害重、化学药剂难以防治,大豆花叶病毒病一直是大豆种植区域需要解决的重要问题之一。对大豆花叶病毒防治最为经济有效的手段是寻找优异的抗大豆花叶病毒基因,发掘有效的分子标记,通过分子生物育种技术培育抗病大豆新品种。
美国等国外学者在通过接种大豆花叶病毒鉴定筛选出Tousan140、Columbia和SL-1104等抗病材料的基础
近年,随着大豆产业的蓬勃发展以及分子生物技术的进步,对大豆花叶病毒抗性基因的研究取得了一系列新的进
大豆对大豆花叶病毒存在质量抗性和数量抗性2种类型的抗性位点,王大刚
在2号染色体上,基于抗性基因位点Rsv4的标记定
图 1 大豆抗大豆花叶病毒基因在2号染色体上的物理位置及候选基因
Fig. 1 Candidate genes, physical maps of SMV resistance loci on chromosome 2
虚线箭头部分表示大豆花叶病毒抗性基因的物理区间;最下面的框内是大豆花叶病毒抗性候选基因的个数及范围。下同
The dashed lines arrow indicated that the physical distance of SMV resistance gene; the number and range of SMV resistance candidate genes in the bottom box. The same as below
染色体 Chr. | 抗性基因位点 Resistance gene loci | 标记及物理距离(kb) The flanking markers and physical distance | 候选基因 Putative candidate gene | 参考文献 References |
|---|---|---|---|---|
| 2 | Rsv4 | Rsv4-86105snp_42~Rsv4-RC-3_55, 9.8 | NM_001249088、NM_001253944 |
[ |
| 2 | RSC3(w) | BARCSOYSSR_02_0610~ZL-52, 175.0 | - |
[ |
| 2 | RSC7 | BARCSOYSSR_02_0667~BARCSOYSSR_02_0670, 77.0 | Glyma.02G127700、Glyma.02G127800 |
[ |
| 2 | RSC13 | BARCSOYSSR_02_0610~BARCSOYSSR_02_0621, 191.0 | Glyma.02G121500、Glyma.02G121600、Glyma.02G121900、Glyma.02G122000、Glyma.02G122200 |
[ |
| 2 | RSC11K | Gm02_BLOCK_11273955_11464884~Gm02_BLOCK_11486875_11491354, 217.0 | Glyma.02G119700 |
[ |
| 2 | RSC9 | BARCSOYSSR_02_0610~BARCSOYSSR_02_0618, 163.0 |
Glyma.02G122000、 LOC100812666 |
[ |
| 3 | qTsmv-3 | Sat_379~Chr03-4, 86.0 | Glyma.03G005500 |
[ |
| 6 | RSC14-r | BARCSOYSSR_06_0786~BARCSOYSSR_06_0790, 136.8 | Glyma.06G176000、Glyma.06G176100 |
[ |
| 13 | Rsv1-r | SNP-38~SNP-50, 154.5 | Glyma.13G184800、Glyma.13G184900 |
[ |
| 13 | RSC18 | Gm13_bin65, 415.357 | Glyma.13G150000、Glyma.13G151100、Glyma.13G21640 |
[ |
| 13 | Rsvg2 | BARCSOYSSR_13_1138~BARCSOYSSR_13_1139, 2.83 | Glyma.13G191400 |
[ |
| 13 | qSMV13 | ss715614844~ss715614864, 97.2 | Glyma13G184200 |
[ |
| 13 | GmRmv | dCAPS3029~dCAPS3045, 157.0 | Glyma.13G190000、Glyma.13G190300、Glyma.13G190400 |
[ |
-表示无
- indicated no
此外,王大刚
在6号染色体上,继Yang
图 2 大豆抗大豆花叶病毒基因在3号和6号染色体上的物理位置及候选基因
Fig. 2 Candidate genes, physical maps of SMV resistance loci on chromosome 3 and 6
在大豆13号染色体上(
图 3 大豆抗大豆花叶病毒基因在13号染色体上的物理位置及候选基因
Fig. 3 Candidate genes, physical maps of SMV resistance loci on chromosome 13
此外,在13号染色体上定位的抗性基因还有Rsvg2和RSC3
基于全基因组关联分析(GWAS,genome wide association study)的方法,Che
Che
核苷酸结合位点-富亮氨酸重复结构域类基因家族是目前从植物中克隆得到抗性基因数目最多的一类,也是植物基因组中最大的基因家族之一,在真核生物中广泛存在。通过构建大豆花叶病毒抗性品种早熟18的细菌人工染色体(BAC,bacterial artificial chromosome)文库并进行测序,Ma
基因名称 Gene name | 版本 (Wm82.a4.v1) Version (Wm82.a4.v1) | 染色体位置 (bp) Chr. location | 氨基酸 AA | 基因注释 Gene annotation (BLASTX) | 研究方法 Research methods | 参考文献 References |
|---|---|---|---|---|---|---|
| GsCAD1 | Glyma.01G025800 | Gm01: 2712068~2715389 | 231 | 肉桂醇脱氢酶 | 转基因 |
[ |
| GmCAL | Glyma.02G121600 | Chr02: 11802163~11806533 | 243 | MADS-box蛋白 | 转基因、基因沉默 |
[ |
| GmMLRK1 | Glyma.02G122000 | Gm02: 11833114~11836011 | 847 | 凝集素类受体激酶 | 转基因、基因编辑 |
[ |
| GmPAP2.1 | Glyma.06G028100 | Gm06: 2182332~2187155 | 474 | 紫色酸性磷酸酶 | 转基因、基因沉默 |
[ |
| GmKR3 | Glyma.06G267300 | Gm06: 45145421~45149155 | 636 | TIR-NB-LRR蛋白 | 转基因 |
[ |
| GmGSL7c | Glyma.08G308200 | Gm08: 42057929~42095863 | 1412 | 胼胝质合酶 | 基因沉默 |
[ |
| GmST1 | Glyma.13G191400 | Gm13: 29886351~29887777 | 344 | 磺基转移酶 | 转基因 |
[ |
| RSC3Q | Glyma.13G263800 | Gm13: 36098210~36100800 | 357 | 2OG-Fe(II)的氧化还原酶 | 基因沉默 |
[ |
| Rsc4-3 | Glyma.14G204700 | Chr.14: 47831268~47846928 | 1307 | NB-LRR蛋白 | 转基因、基因编辑 |
[ |
| NBS_C | Glyma.14G204700 | Chr.14: 47831268~47846928 | 1307 | NB-LRR蛋白 | 序列比对、转基因、基因沉默 |
[ |
| NBS_D | Glyma.14G205000 | Chr.14: 47855677~47868591 | 1292 | NB-LRR蛋白 | 序列比对 |
[ |
| NBS_E | Glyma.14G205300 | Chr.14: 47895256~47907012 | 1302 | NB-LRR蛋白 | 序列比对 |
[ |
| GmPR1-6 | Glyma.15G062400 | Gm15: 4787447~4788213 | 164 | 病程相关蛋白 | 基因沉默 |
[ |
| GmSZFP | Glyma.18G003600 | Gm18: 299768~302374 | 356 | C2H2型锌指蛋白 | 基因沉默 |
[ |
转录因子在植物抗病过程中具有重要的作用,Ren
此外,大豆氧化还原酶、磺基转移酶、类受体激酶、胼胝质合酶和异黄酮合成酶等也参与了大豆对大豆花叶病毒的抗性反
过表达来源于粟酒裂殖酵母菌的核糖核酸酶基因PAC1的转基因大豆接种大豆花叶病毒后,大豆花叶病毒的积累及症状发展显著的被抑制,且其同时可增强对菜豆普通花叶病毒(BCMV,bean common mosaic virus)、西瓜花叶病毒(WMV,watermelon mosaic virus)和菜豆荚斑驳病毒(BPMV,bean pod mottle virus)等多种病毒的抗性,为抵抗RNA病毒提供了有效的控制策
Widyasari
在Seo
图 4 Rsv3介导对大豆花叶病毒抗性的调控网
Fig. 4 Proposed signaling network for Rsv3-mediated resistance to soybean mosaic virus
左边表示Rsv3介导的抗性反应;右边表示感病反应,施用外源脱落酸后产生部分抗性
The left represents the Rsv3-mediated resistance; The right represents the susceptibility, and showed partial resistance with exogenous ABA
转基因过表达研究表明GmKR3增强了大豆对病毒的抗性,而转录组测序以及基因定量表达分析发现抗性的增强至少有一部分是通过脱落酸信号转导实现
大豆花叶病毒抗性基因Rsc4-3编码螺旋卷曲-核苷酸结合位点-富亮氨酸重复结构域类抗病蛋
不同于Rsv3介导的抗病途径,Rsv4介导大豆抗病毒免疫途径,该基因不仅对大豆花叶病毒具有抗性,且对马铃薯Y病毒属的病毒也存在广谱抗性。当真核正链RNA病毒在宿主细胞形成的膜室复合物中复制其基因组时,双链RNA(dsRNA,double-stranded RNA)复合物在膜室内复制形成,从而逃避抗病毒免疫监测。大豆中的Rsv4基因具有广谱的抗性,在感病品种Enrei中包含两个串联重复的同源开放阅读框(NM_001249088和NM_001253944)编码RNase H蛋白,而在大豆花叶病毒抗性品种Peking中,有3.6 kb的核苷酸序列缺失,导致只有一个开放阅读
此外,茉莉酸途径、水杨酸信号通路和胼胝质沉积途径可能参与了大豆其他相关基因对大豆花叶病毒的抗性反应。Zhao
Helm
冀豆17对大豆花叶病毒N3表现抗病,而对SC8表现感病,当N3株系侵染冀豆17时,涉及硝酸还原酶(NR,nitrate reductase)和一氧化氮合酶(NOS,nitric oxide synthase)途径的一氧化氮(NO,nitric oxide)被诱导产生,并在细胞膜和细胞壁上产生丰富的H2O2,促进胼胝质积
刘士超
王大刚
蔡晗
加强抗病品种选育,提高作物抗病性是防治作物病害的主要途径之一。从诸多大豆种质资源中鉴定新的大豆花叶病毒抗性位点对抗大豆花叶病毒育种至关重要。我国是大豆发源地和大豆分布区域最广的国家,从南到北拥有数量十分丰富的野生大豆种质资
随着大豆全基因组测序的完善和优化,分子设计育种技术成为大豆抗病育种的关键之一。而新的抗性基因的发掘可以持续为不断变化的大豆花叶病毒株系提供有效的抗性位点。近年,新发掘的与大豆花叶病毒抗性基因位点共分离或紧密连锁的分子标记为辅助抗病育种奠定了基
尽管已经定位了许多大豆花叶病毒抗性位点,但多数的推广品种是否携带抗性基因,携带多少抗性基因仍然需要进一步明确。此外,随着突破现有抗性基因的新大豆花叶病毒株系的出
抗性基因的标记定位对锁定关键基因具有重要作用,然而在同一基因区域中存在较为紧密连锁的抗性基因为研究单个基因的功能及作用机理提出了难题。通过扩大后代分离群体的构建及精细定位,利用完整的大豆基因组序列和蛋白质组学、代谢组学等技术对单个抗性基因进行分子克隆具有一定的可行性,而抗性基因功能的明确也为利用抗大豆花叶病毒分子育种奠定扎实的基因基础。
抗病育种最好的结果是选育出对多个病毒或株系均具有抗性的品种,而利用新的分子生物技术,如病毒介导基因沉默、转基因过表达、基因编辑CRISPR/Cas9等为实现这一目标提供了可
分子标记,特别是与抗性基因紧密连锁或共分离的分子标记,在大豆抗病种质鉴
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