野生大豆对大豆花叶病毒株系SC13的抗性遗传和基因定位

大豆花叶病毒(SMV,soybean mosaic virus)病是广泛分布于我国各大豆产区的大豆主要病害之一。SMV株系SC13是我国北方大豆产区广泛分布的株系之一。为拓宽大豆对SMV的抗病种质,研究了中国大豆核心种质材料野生大豆ZYD03715对大豆花叶病毒株系SC13的抗性遗传方式,确定与栽培大豆抗源对同一株系的抗性位点间的等位性关系,并对抗性基因进行了标记定位。结果表明:野生大豆抗源ZYD03715对SMV株系SC13的抗性由1对隐性基因控制,广谱抗源科丰1号的抗性受1对显性基因控制,且两个抗源携带的抗性基因是不等位的。采用分离群体组群分析发现,野生大豆ZYD03715对SC13的抗性位点(r~ySC13)位于大豆14号染色体(B2连锁群)上,处于2个SSR标记Satt416和Satt083一侧,与其距离分别为4.1 c M和0.9 c M。利用科丰1号×南农1138-2的F_2群体,将科丰1号所携带的抗性基因(R~k_(SC13))定位在大豆2号染色体(D1b连锁群)上的Satt558和Sat_254标记之间,遗传距离分别为3.7 c M和16.1 c M。以往发现大豆对SMV不同株系的抗性都分别由1对显性基因控制,本研究在野生大豆中鉴定出隐性抗病基因,并标记定位了该隐性抗病基因,它将为大豆抗病性育种的分子标记辅助选择以及抗性基因的精细定位和克隆奠定基础。     

动物遗传工程

942404 。大豆花叶病毒抗性基因的RFLP及小卫星作图[英]/Yu,Y.G.…∥Phytopathology.一1994,84(1).一60～64E译自DBA,1994,13(7),94—04034] 用限静l性片段长度多形性(RFLP)和小卫星或简单序列重复(SSR)作为遗传标记,鉴别赋予大豆花叶病毒(SMV)抗性的基因Rsv在染色体上的位置。通过对作为抗性亲本的大豆品系PI 96983和作为感受态亲本的栽培种Lee68间进行杂交,建立了F2代株群。对107株F2株植进行了亲株间多形性(25RFLP和3SSR位点)分析。通过用SMV菌株Gl接种F2:3子代,测定了Rsv基因型。还收集了有关大豆基因wl/W1(控制花色素…     

灰布支黑豆对大豆孢囊线虫(Heteroderaglycines)14号小种的抗性遗传

大豆孢囊线虫（Ｈｅｔｅｒｏｄｅｒａ ｇｌｙｃｉｎｅｓ）是危害大豆生产的世界性病害。山西省兴县“灰布支黑豆”是对目前我国鉴定的所有流行小种表现出免疫或高抗的重要抗源。利用目前国际通用的一套鉴别寄主和小种划分标准,通过人工接种的方法,确定了１４号是北京马连洼中国农业科学院植物保护研究所实验站土壤中大豆孢囊线虫群体的主导小种。用敏感的栽培品种“冀豆７号”作母本,与灰布支黑豆杂交,采用人工接种的方法,对后代群体进行大豆孢囊线虫１４号小种的抗性鉴定。Ｆ１的２个单株都表现出抗性。随机取２个单株的Ｆ２代群体,分别测定每个群体的１１６和７８个单株。每个群体都表现出４３抗：２１感的分离比例,支持兴县灰布支黑豆对大豆孢囊线虫１４号小种的抗性是由３对基因控制、一对隐性基因对两对显性基因的上位和两对显性基因互补作用的遗传假设。随机取Ｆ３代的３０个株系,每个株系随机测定１０～１５个单株。１９抗：３８分离：７感的株系间分离比确认上述的遗传假设是正确的。     

中国大豆花叶病毒SC7外壳蛋白基因的序列测定及其与美国株系的比较

为了探索大豆花叶病毒(Soybean mosaic virus,SMV)SC7外壳蛋白(Coat protein,CP)基因序列与病毒致病性作用及其与美国株系的对应关系,本研究通过反转录-聚合酶链式反应(RT-PCR),克隆了我国SMV SC7株系的CP基因,并测定了其全序列。结果表明:CP基因长度为795bp,编码的CP蛋白为265个氨基酸。在致病性反应上,SC7的毒力比美国的毒株更强些。在分子水平上,CP基因核苷酸序列差异为4%~5%,编码的氨基酸序列差异为1%~2%。美国株系N端都存在与蚜传有关的保守基序DAG(Asp-Ala-Gl),但在SC7为DAD(Asp-AlaAsp)。将序列信息与SMV株系在鉴别寄主上的症状反应进行综合分析发现,CP基因的同源性与SMV在鉴别寄主上的致病性反应没有明显关系。     

中国大豆花叶病毒SC7外壳蛋白基因的序列测定及其与美国株系的比较北大核心CSCD

为了探索大豆花叶病毒（Soybean mosaic virus,SMV）SC7外壳蛋白（Coat protein,CP）基因序列与病毒致病性作用及其与美国株系的对应关系,本研究通过反转录-聚合酶链式反应（RT-PCR）,克隆了我国SMV SC7株系的CP基因,并测定了其全序列。结果表明：CP基因长度为795bp,编码的CP蛋白为265个氨基酸。在致病性反应上,SC7的毒力比美国的毒株更强些。在分子水平上,CP基因核苷酸序列差异为4%~5%,编码的氨基酸序列差异为1%~2%。美国株系N端都存在与蚜传有关的保守基序DAG（Asp-Ala-Gl）,但在SC7为DAD（Asp-AlaAsp）。将序列信息与SMV株系在鉴别寄主上的症状反应进行综合分析发现,CP基因的同源性与SMV在鉴别寄主上的致病性反应没有明显关系。     

黄淮海北部地区大豆育成品种对黄淮海主要SMV流行株系的抗性评价

采用人工接种方法研究了166份黄淮海北部地区近年来生产上种植品种及近期育成品种(系)对SMV的抗性,利用黄淮海地区SMV流行株系SC3、SC6、SC7、SC11以及混合4个株系进行了抗性鉴定,从客观上评价了上述品种(系)的抗性。结果显示:对4个株系均表现抗病(中抗、高抗和免疫)的共82份,占49.4%;其中对3个株系表现高抗或免疫的32份,占19.3%;对4个株系表现高抗或免疫的23份,占13.9%。对混合株系表现抗病的108份,占65.1%。其中表现免疫的45份,占27.1%,表现高抗的29份,占17.5%。对4个株系和混合株系均表现抗病的62份,占37.3%;表现免疫和高抗的14份,占8.4%。近年育成品种对SC3、SC7株系较早期育成品种的抗性显著增强;来自河北、北京、山西的品种抗性较好,病情指数整体较低。鉴定筛选出对接种的4个株系及混合株系均表现免疫的品种冀豆9号和石豆6号,可作为抗病育种的重要抗源。本研究还发现部分品种对接种的4个株系和混合株系表现出抗性差异,表明SMV株系间存在着明显的互作。     

大豆花叶病毒研究进展

大豆花叶病毒（Soybean mosaic virus,SMV）病是在世界范围内广泛分布并普遍发生的病毒病害之一,导致大豆严重减产和种质衰退。这引起了国内外许多学者的科研兴趣,研究内容涉及SMV株系划分与发生分布、传播流行方式、寄主上的症状和影响因素、基因组结构组成及各基凶功能、植物生理生化抗性、大豆SMV抗性遗传育种等各方面。本文综述了近年来国内外SMV的科研方向和进展,旨在为进一步的研究提供依据。     

大豆花叶病的抗性遗传──Ⅰ．几个引用抗原对东北大豆花叶病毒二号株系的抗性遗传

本文通过１２个（抗×感）杂交组合Ｆ＿１、Ｆ＿２、回交ＣＦ１和基因等位性测交组合Ｆ＿１、Ｆ＿２群体对东北大豆花叶病毒２号株系抗性的分析,明确了４个引用抗原的抗性水平及应用价值。鲁豆４和跃进４抗原的抗性为两对具有抑制作用的显性基因控制,抗、感分离比例为１３：３;徐豆２和辽８１－５０１７抗原的抗性为两对显性互补基因控制,抗、感分离比例为９：７,但在其杂交后代中易出现大量顶枯株。等位性测验表明：吉林２１和跃进４、鲁豆４的抗病基因不在同一座位,并且独立遗传。跃进４和鲁豆４抗原有亲缘关系。     

大豆花叶病毒黄淮5号株系的基因组全序列分析

测定了大豆花叶病毒(SMV)我国黄淮5号(Y5)株系的基因组全序列.该病毒基因组全长9*!585个核苷酸,3′-末端具poly(A)尾,包含单一开放读码框,编码一个349.2kD的多聚蛋白.基因组全序列和美国SMV G2和G7株系的核苷酸同源性分别为97.4%和96.9%.多聚蛋白酶解后产生马铃薯Y病毒属典型的10个成熟蛋白.Y5、G2和G7 3个株系的不同成熟蛋白间氨基酸序列的同源性为89.6%～100%.多重比较分析表明,Y5株系P1蛋白N-末端区域与G2和G7存在明显差异.进一步分析显示,这3个株系的6K1、6K2、NIa-Pro、NIa-VPg、NIb蛋白中心区域和CP蛋白高度保守,P1蛋白N-末端,CI和P3蛋白C-末端以及HC-Pro蛋白变异较大,但是美国G2和G7株系已报道序列P1蛋白区域存在可能的测序错误.     

大豆5个花叶病毒株系抗性基因的定位

以科丰 1号×南农 1138 2为亲本构建的RIL群体NJRIKY为材料 ,对群体进行了 5个SMV株系 (Sa、Sc 8、Sc 9、N1 、N3)的抗病性鉴定。结果表明 :大豆对 5个SMV株系的抗性均受一对显性基因控制。用Mapmaker 3 0进行连锁分析 ,发现Rsa与Rn1、Rn3和Rsc9均连锁 ,距离分别为 2 1 4cM、2 3 5cM和 35 3cM ;Rsc8只和Rn1连锁 ,距离为 35 8cM ;Rn1和Rn3之间的遗传距离最近 ,为 10 2cM。多点分析结果表明 :5个抗病基因的排列顺序和遗传距离为Rsc8 35 8cM Rn1 10 3cM Rn3 2 1 5cM Rsa 35 8cM Rsc9。根据RFLP、SSR标记分析结果构建了一套大豆遗传图谱 ,该图谱包含 2 2个连锁群、2 5 6个标记 ,总遗传距离为 30 5 0 9cM。将 5个抗病基因定位于N8 D1b W连锁群 ,有 3个RFLP标记和Rn1、Rn3都连锁 ,分别为A6 91T、K4 77I、LC5T。它们与Rn1、Rn3的距离分别为 15 0 4cM、17 82cM、15 37cM和 16 14cM、17 82cM、16 5 8cM。     

Genetics of resistance to two strains of soybean mosaic virus in differential soybean genotypes

There are seven pathotypes of soybean mosaic virus (SMV) representing seven strain groups (G1-G7) in the United States. Soybean genotypes [Glycine max (L.) Merr.] may exhibit resistant (R), susceptible (S), or necrotic (N) reactions upon interacting with different SMV strains. This research was conducted to investigate whether reactions to two SMV strains are controlled by the same gene or by separate genes. Two SMV-resistant soybean lines, LR1 and LR2, were crossed with the susceptible cultivar Lee 68. LR1 contains a resistance gene Rsv1-s and is resistant to strains G1-G4 and G7. LR2 contains the Rsv4 gene and is resistant to strains G1-G7. Two hundred F(2:3) lines from LR1 x Lee 68 and 262 F(2:3) lines from LR2 x Lee 68 were screened for SMV reaction. Seeds from each F2 plant were randomly divided into two subsamples. A minimum of 20 seeds from each subsample were planted in the greenhouse and plants were inoculated with either G1 or G7. G1 is the least virulent, whereas G7 is the most virulent strain of SMV. The results showed that all the F(2:3) lines from both crosses exhibited the same reaction to G1 and G7. No recombinants were found in all the progenies for reactions to G1 and G7 in either cross. The results indicate that reactions to both G1 and G7 are controlled by either the same gene or very closely linked genes. This research finding is valuable for studying the resistance mechanism and interactions of soybean genotypes and SMV strains and for breeding SMV resistance to multiple strains.     

Complementary action of two independent dominant genes in Columbia soybean for resistance to Soybean mosaic virus

A stem-tip necrosis disease was observed in the soybean [Glycine max (L.) Merr.] cultivar Columbia and its derivative OX686 when infected with a necrosis-causing strain of Soybean mosaic virus (SMV) in Canada. A dominant gene named Rsv3 was found in OX686 for the necrotic reaction. In the present research we have found that Columbia is resistant to all known SMV strains G1-G7, except G4. Genetic studies were conducted to investigate the inheritance of resistance in Columbia and interactions of resistance gene(s) with SMV strains. Columbia was crossed with a susceptible cultivar, Lee 68, and with resistant lines PI96983, Ogden, and LR1, each possessing a resistance gene at the Rsv1 locus. F(1) individuals, F(2) populations, and F(2:3) lines from these crosses were inoculated with G7 or G1 in the greenhouse. Our inheritance data confirmed the presence of two independent dominant genes for SMV resistance in Columbia. Results from allelism tests further demonstrate that the two genes (referred to as R3 and R4 in this article) in Columbia were independent of the Rsv1 locus. R3 appears to be the same gene previously reported as Rsv3 in OX686, which was derived from Columbia. The R3 gene confers resistance to G7, but necrosis to G1. The other gene, R4, conditions resistance to G1 and G7 at the early seedling stage and then a delayed mild mosaic reaction (late susceptible) 3 weeks later. Plants carrying both the R3 and R4 genes were completely resistant to both G1 and G7, indicating that the two genes interact in a complementary fashion. Plants heterozygous for R3 or R4 exhibited systemic necrosis or late susceptibility, suggesting that the resistance is allele dosage dependent. The R4 gene appeared epistatic to R3 since it masked expression of necrosis associated with the response of R3. The complementary interaction of two resistance genes, as exhibited in Columbia, can be useful in development of soybean cultivars with multiple and durable resistance to SMV.     

Genetic analysis of resistance to soybean mosaic virus in j05 soybean

Soybean cultivar J05 was identified to be resistant to the most virulent strain of soybean mosaic virus (SMV) in northeastern China. However, the reaction of J05 to SMV strains in the United States of America is unknown, and genetic information is needed to utilize this germplasm in a breeding program. The objectives of this study were to determine the reaction of J05 to all US strains of SMV (G1-G7), the inheritance of SMV resistance in J05, and the allelic relationship of resistance genes in J05 with other reported resistance genes. J05 was crossed with susceptible cultivar Essex (rsv) to study the inheritance of SMV resistance. J05 was also crossed with PI 96983 (Rsv1), L29 (Rsv3), and V94-5152 (Rsv4) to test the allelism of resistance genes. F(2) populations and F(2:3) lines from these crosses were inoculated with G1 or G7 in the greenhouse. Inheritance and allelism studies indicate that J05 possesses 2 independent dominant genes for SMV resistance, one at the Rsv1 locus conferring resistance to G1 and necrosis to G7 and the other at the Rsv3 locus conditioning resistance to G7 but susceptibility to G1. The presence of both genes in J05 provides resistance to G1 and G7. J05 is unique from the previous sources that carry 2 genes of Rsv1Rsv3 and will be useful in breeding for SMV resistance.     

Inheritance and allelism of resistance to soybean mosaic virus in Zao18 soybean from China

Soybean mosaic disease caused by soybean mosaic virus (SMV) occurs wherever soybean [Glycine max (L.) Merr.] is grown and is considered one of the most important soybean diseases in many areas of the world. Use of soybean cultivars with resistance to SMV is a very effective way of controlling the disease. China has rich soybean germplasm, but there is very limited information on genetics of SMV resistance in Chinese soybean germplasm and reaction of the resistance genes to SMV strains G1-G7. There also is no report on allelic relationships of resistance genes in Chinese soybeans with other named genes at the three identified loci Rsv1, Rsv3, and Rsv4. The objectives of this study were to examine reactions of Chinese soybean cultivar Zao18 to SMV strains G1-G3 and G5-G7, to reveal the inheritance of SMV resistance in Zao18 and to determine the allelic relationship of resistance genes in Zao18 with previously reported resistance genes. Zao18 was crossed with the SMV-susceptible cultivar Lee 68 to study the inheritance of resistance. Zao18 was also crossed with the resistant lines PI96983, L29, and V94-5152, which possess Rsv1, Rsv3, and Rsv4, respectively, to examine the allelic relationship between the genes in Zao18 and genes at these three loci. Our research results indicated that Zao18 possesses two independent dominant genes for SMV resistance, one of which is allelic to the Rsv3 locus; the other is allelic with Rsv1. The presence of both genes (Rsv1 and Rsv3) in Zao18 confers resistance to SMV strains G1-G7.     

Inheritance and allelism tests of Raiden soybean for resistance to soybean mosaic virus

The gene symbol Rsv2 was previously assigned to the gene in the soybean [Glycine max (L.) Merr.] line OX670 for resistance to soybean mosaic virus (SMV). The Rsv2 gene was reported to be derived from the Raiden soybean (PI 360844) and to be independent of Rsv1. Accumulated data from our genetic experiments were in disagreement with this conclusion. In this study, Raiden and L88-8431, a Williams BC5 isoline with SMV resistance derived from Raiden, were crossed with two SMV-susceptible cultivars to investigate the mode of inheritance of SMV resistance in Raiden. They were also crossed with five resistant cultivars to examine the allelomorphic relationships of the Raiden gene with other reported genes at the Rsv1 locus. F1 plants, F2 populations, and F2-derived F3 (F2:3) lines were tested with SMV strains G1 or G7 in the greenhouse or in the field. The individual plant reactions were classified as resistant (R, symptomless), necrotic (N, systemic necrosis), or susceptible (S, mosaic). The F2 populations from R x S crosses segregated in a ratio of 3 (R + N):1 S and the F2:3 lines from Lee 68 (S) x Raiden (R) exhibited a segregation pattern of 1 (all R):2 segregating:1 (all S). The F2 populations and F2:3 progenies from all R x R crosses did not show any segregation for susceptibility. These results demonstrate that the resistance to SMV in Raiden and L88-8431 is controlled by a single dominant gene and the gene is allelic to Rsv1. The heterozygous plants from R x S and R x N crosses exhibited systemic necrosis when inoculated with SMV G7, indicating a partial dominance nature of the resistance gene. Raiden and L88-8431 are both resistant to SMV G1-G4 and G7, but necrotic to G5, G6, and G7A. Since the resistance gene in Raiden is clearly an allele at the Rsv1 locus and it exhibits a unique reaction to the SMV strain groups, assignment of a new gene symbol, Rsv1-r, to replace Rsv2 would seem appropriate. Further research is ongoing to investigate the possible existence of the Rsv2 locus in OX670 and its relatives.     

Fitness penalty in susceptible host is associated with virulence of Soybean mosaic virus on Rsv1‐genotype soybean: a consequence of perturbation of HC‐Pro and not P3

The multigenic Rsv1 locus in the soybean plant introduction (PI) ‘PI96983’ confers extreme resistance against the majority of Soybean mosaic virus (SMV) strains, including SMV‐N, but not SMV‐G7 and SMV‐G7d. In contrast, in susceptible soybean cultivars lacking a functional Rsv1 locus, such as ‘Williams82’ (rsv1), SMV‐N induces severe disease symptoms and accumulates to a high level, whereas both SMV‐G7 and SMV‐G7d induce mild symptoms and accumulate to a significantly lower level. Gain of virulence by SMV‐N on Rsv1‐genotype soybean requires concurrent mutations in both the helper‐component proteinase (HC‐Pro) and P3 cistrons. This is because of the presence of at least two resistance (R) genes, probably belonging to the nucleotide‐binding leucine‐rich repeat (NB‐LRR) class, within the Rsv1 locus, independently mediating the recognition of HC‐Pro or P3. In this study, we show that the majority of experimentally evolved mutational pathways that disrupt the avirulence functions of SMV‐N on Rsv1‐genotype soybean also result in mild symptoms and reduced accumulation, relative to parental SMV‐N, in Williams82 (rsv1). Furthermore, the evaluation of SMV‐N‐derived HC‐Pro and P3 chimeras, containing homologous sequences from virulent SMV‐G7 or SMV‐G7d strains, as well as SMV‐N‐derived variants containing HC‐Pro or P3 point mutation(s) associated with gain of virulence, reveals a direct correlation between the perturbation of HC‐Pro and a fitness penalty in Williams82 (rsv1). Collectively, these data demonstrate that gain of virulence by SMV on Rsv1‐genotype soybean results in fitness loss in a previously susceptible soybean genotype, this being a consequence of mutations in HC‐Pro, but not in P3.     

Gain of virulence on Rsv1-genotype soybean by an avirulent Soybean mosaic virus requires concurrent mutations in both P3 and HC-Pro

In soybean, Rsv1, a single dominant resistance gene, invokes extreme resistance (ER) against most Soybean mosaic virus (SMV) strains, including SMV-N, but not SMV-G7, which provokes a virulent lethal systemic hypersensitive response (LSHR). The elicitor functions of the two viruses provoking Rsv1-mediated ER and LSHR have been mapped to the N-terminal 271 amino acids of P3 from SMV-N and SMV-G7, respectively, which differ by nine residues between the two strains. To identify amino acids of P3 from SMV-N provoking Rsv1-mediated ER, the unique residues of SMV-G7 were substituted with those of SMV-N. Of the mutants tested on Rsv1-genotype soybean, only SMV-G7(I788R) and SMV-G7(T948A) lost virulence. However, substitution of amino acids of SMV-N, individually or in combination, with the reciprocal residues from SMV-G7 at these two positions failed to confer virulence to SMV-N. In the search for additional virulence determinants, a series of SMV-N chimeras was generated in which fragments within a region from near the middle of the helper-component proteinase (HC-Pro) cistron to the 5' end of the cytoplasmic inclusion cistron, nucleotides 1,605 to 3,787, were replaced with those of SMV-G7. Only SMV-N-derived chimeras harboring the 3' region of HC-Pro, at least from nucleotide 2,013, and the entire 5' end of P3 (nucleotides 2,430 to 3,237) from SMV-G7 were virulent whereas reciprocal exchanges resulted in loss of SMV-G7 virulence. This region of HC-Pro differs by three amino acids between SMV-N and SMV-G7. Analyses of SMV-G7-derived HC-Pro site-directed mutants showed that only SMV-G7(M683R) lost virulence on Rsv1-genotype soybean; however, SMV-N(R682M) failed to gain virulence. Nevertheless, an SMV-N derived mutant with three concurrent substitutions, R682M+R787I+A947T, gained virulence. The data indicate that both P3 and HC-Pro are involved in virulence of SMV on Rsv1-genotype soybean.     

Genetic confirmation of 2 independent genes for resistance to soybean mosaic virus in J05 soybean using SSR markers

J05 soybean was previously identified to carry 2 independent genes, Rsv1 and Rsv3, for "soybean mosaic virus" (SMV) resistance by inheritance and allelism studies. The objective of this research was to confirm the 2 genes in J05 using molecular markers so that a marker-assisted selection can be implemented. The segregation of F(2) plants from J05 x Essex exhibited a good fit to a 3:1 ratio when inoculated with SMV G1. Three simple sequence repeat (SSR) markers near Rsv1, Satt114, Satt510, and Sat_154, amplified polymorphic DNA fragments between J05 and Essex and were closely linked to the gene on soybean molecular linkage group (MLG) F, thus verifying the presence of Rsv1 in J05 for resistance to SMV G1. The presence of Rsv3 in J05 was confirmed by 2 closely linked SSR markers on MLG B2, Satt726 and Sat_424, in F(2:3) lines that were derived from the SMV G1-susceptible F(2) plants and segregated in a 1:2:1 ratio for reaction to SMV G7. Two closely linked markers for Rsv4, Satt296 and Satt542, segregated independently of SMV resistance, indicating the absence of Rsv4 in J05. These SSR markers for Rsv1 and Rsv3 can serve as a useful molecular tool for selection and pyramiding of genes in J05 for SMV resistance.     

Genetic analysis and mapping of genes for resistance to multiple strains of Soybean mosaic virus in a single resistant soybean accession PI 96983

Soybean mosaic virus (SMV) is one of the most broadly distributed soybean (Glycine max (L.) Merr.) diseases and causes severe yield loss and seed quality deficiency. Multiple studies have proved that a single dominant gene can confer resistance to several SMV strains. Plant introduction (PI) 96983 has been reported to contain SMV resistance genes (e.g., Rsv1 and Rsc14) on chromosome 13. The objective of this study was to delineate the genetics of resistance to SMV in PI 96983 and determine whether one gene can control resistance to more than one Chinese SMV strain. In this study, PI 96983 was identified as resistant and Nannong 1138-2 was identified as susceptible to four SMV strains SC3, SC6, SC7, and SC17. Genetic maps based on 783 F₂ individuals from the cross of PI 96983 × Nannong 1138-2 showed that the gene(s) conferring resistance to SC3, SC6, and SC17 were between SSR markers BARCSOYSSR_13_1114 and BARCSOYSSR_13_1136, whereas SC7 was between markers BARCSOYSSR_13_1140 and BARCSOYSSR_13_1185. The physical map based on 58 recombinant lines confirmed these results. The resistance gene for SC7 was positioned between BARCSOYSSR_13_1140 and BARCSOYSSR_13_1155, while the resistance gene(s) for SC3, SC6, and SC17 were between BARCSOYSSR_13_1128 and BARCSOYSSR_13_1136. We concluded that, there were two dominant resistance genes flanking Rsv1 or one of them at the reported genomic location of Rsv1. One of them (designated as “Rsc-pm”) conditions resistance for SC3, SC6, and SC17 and another (designated as “Rsc-ps”) confers resistance for SC7. The two tightly linked genes identified in this study would be helpful to cloning of resistance genes and breeding of multiple resistances soybean cultivars to SMV through marker-assisted selection (MAS).