以SSR标记对普通菜豆抗炭疽病基因定位

由菜豆炭疽菌引起的菜豆炭疽病是危害我国菜豆生产的主要病害之一, 鉴定和发掘新的抗病基因对于菜豆抗病育种具有十分重要的意义。以来自安第斯基因库的我国菜豆抗炭疽病地方品种红花芸豆与感病地方品种京豆杂交的F₂群体为试验材料, 通过人工接种菜豆炭疽菌81号小种进行抗病性鉴定, 发现该分离群体中抗病植株数与感病植株数符合3∶1的分离比例, 确定红花芸豆对菜豆炭疽菌81号小种的抗性由显性单基因控制, 将此基因命名为Co-F2533。用分离群体分组分析法(BSA)和微卫星多态性分析(SSR)技术对红花芸豆中的抗炭疽病基因进行分子标记鉴定, 用Mapmaker3.0计算标记与目的基因间的遗传距离, 发现B6连锁群上的4个SSR标记BM170、Clon1429、BMD37、Clon410与抗炭疽病基因Co-F2533连锁, 遗传距离分别为6.6、18.4、20.9和30.9 cM, 这些SSR标记与Co-F2533基因在B6连锁群上的排列顺序为Clon1429-Co-F2533- BM170-BMD37-Clon410。根据基因所在连锁群的位置、抗病基因的基因库来源可知Co-F2533是一个新的来源于安第斯基因库的抗炭疽病基因。     

以SSR标记对普通菜豆抗炭疽病基因定位

由菜豆炭疽菌引起的菜豆炭疽病是危害我国菜豆生产的主要病害之一, 鉴定和发掘新的抗病基因对于菜豆抗病育种具有十分重要的意义。以来自安第斯基因库的我国菜豆抗炭疽病地方品种红花芸豆与感病地方品种京豆杂交的F₂群体为试验材料, 通过人工接种菜豆炭疽菌81号小种进行抗病性鉴定, 发现该分离群体中抗病植株数与感病植株数符合3∶1的分离比例, 确定红花芸豆对菜豆炭疽菌81号小种的抗性由显性单基因控制, 将此基因命名为Co-F2533。用分离群体分组分析法(BSA)和微卫星多态性分析(SSR)技术对红花芸豆中的抗炭疽病基因进行分子标记鉴定, 用Mapmaker3.0计算标记与目的基因间的遗传距离, 发现B6连锁群上的4个SSR标记BM170、Clon1429、BMD37、Clon410与抗炭疽病基因Co-F2533连锁, 遗传距离分别为6.6、18.4、20.9和30.9 cM, 这些SSR标记与Co-F2533基因在B6连锁群上的排列顺序为Clon1429-Co-F2533- BM170-BMD37-Clon410。根据基因所在连锁群的位置、抗病基因的基因库来源可知Co-F2533是一个新的来源于安第斯基因库的抗炭疽病基因。     

普通小麦品种Brock抗白粉病基因分子标记定位

为明确利用Brock转育成的小麦抗白粉病品系3B529(京411*7//农大015/Brock, F₆)抗性的遗传基础,将高感白粉病小麦品系薛早和3B529杂交,获得F₁代、F₂分离群体和F_2:3家系。抗病性鉴定和遗传分析结果表明,3B529对E09小种的抗性受1对显性基因控制,暂被定名为MlBrock。利用BSA和分子标记分析,获得了与MlBrock连锁的3个SSR标记Xcfd81、Xcfd78、Xgwm159和2个SCAR标记SCAR203和SCAR112,根据SSR和SCAR标记在中国春缺体四体、双端体和缺失系的定位结果,将MlBrock定位在小麦染色体臂5DS Bin 0~0.63区间上。MlBrock与Xcfd81和SCAR203共分离,与SCAR112的遗传距离为0.5 cM。这些分子标记的建立有利于今后Brock抗白粉病基因分子标记辅助选择和基因聚合。综合抗白粉病基因MlBrock的染色体定位和抗谱分析结果,推测MlBrock很可能是Pm2基因。     

大豆对大豆花叶病毒株系SC6和SC17抗病基因的精细定位

针对我国北方和长江流域大豆产区广泛分布的SMV株系SC6和SC17,利用2个抗病大豆品种Q0926和中豆35分别与感病品种南农1138-2和南农菜豆5号配制2个抗感杂交组合Q0926×南农1138-2和中豆35×南农菜豆5号以及一个抗抗组合Q0926×中豆35,研究3个组合的F₁、F₂、F_2:3抗性遗传规律,探讨Q0926对SC6和中豆35对SC17及2个抗病品种对同一SMV株系抗性基因的等位关系,并对大豆对2个株系的抗病基因进行了标记定位。结果显示,Q0926×南农1138-2和中豆35×南农菜豆5号2个抗感杂交组合在分别接种SC6和SC17后,F₁表现抗病,F₂呈3抗∶1感分离比例,F_2:3家系呈1抗∶2分离∶1感病的分离比率,表明Q0926对SC6和中豆35对SC17的抗病性分别由1对显性基因控制;抗抗组合Q0926×中豆35的F₁和F₂在接种2个株系后均未发现感病单株,表明Q0926与中豆35对SC6和SC17株系的抗病基因分别是等位或紧密连锁的。分别利用2个抗感组合的F₂和F_2:3群体对2个抗病基因的定位结果显示,第2染色体上的25个SSR标记与抗SC6的基因R_SC6连锁,最近的2个标记与抗性基因R_SC6的排列次序和遗传距离为BARCSOYSSR_02_0617(0.775 cM)-R_SC6-BARCSOYSSR_02_0621(0.519 cM);第2染色体上的38个SSR标记与抗SC17的基因R_SC17连锁。最近的2个标记与抗性基因R_SC17的排列次序和遗传距离为BARCSOYSSR_02_0622(0.264 cM)-R_SC17-BARCSOYSSR_02_0627(0.262 cM),其对应的物理区间分别为52 kb和60 kb。抗性遗传研究为抗大豆花叶病毒育种的亲本选配、后代选择提供了理论指导,抗性基因的标记定位研究为抗性基因的分子标记辅助选择和抗病基因的图位克隆奠定了基础。     

水稻抗白叶枯病基因Xa14的遗传定位

Xa14是一个高抗菲律宾白叶枯病生理小种5的显性基因,Taura等将它定位在水稻第4染色体长臂末端。本研究利用中国国家基因中心的水稻第4染色体测序结果,用SSR标记对Xa14进行遗传定位,为进一步用图位克隆法克隆该基因奠定基础。利用775株IRBB14/IR24 F₂中的145株高感群体,将基因Xa14限定在SSR标记HZR970-8和HZR988-1之间的区间,与两个分子标记的距离各为0.34 cM,并找到了在该群体中与基因共分离的HZR645-4、HZR669-2、HZR669-5和HZR669-7四个SSR标记。利用763株IRBB14/珍珠矮F₂中158株高感群体,将基因Xa14限定在分子标记HZR648-5与RM280之间的区段,找到了一个与基因紧密连锁的SSR标记HZR648-5,与基因的距离为1.90 cM。将两个F₂群体的定位结果进行整合,表明Xa14位于分子标记HZR970-8和HZR988-1之间的3个BAC克隆上,并与这两个标记紧密连锁。     

小麦品种中梁21抗条锈病基因遗传分析与SSR标记定位

用7个我国当前流行的条锈菌生理小种评价中梁21的苗期条锈抗性,结果表明该品种对我国优势流行小种具有良好的抗性。采用CYR30小种对中梁21与铭贤169杂交的F₁、BC₁、F₂及F₃代群体进行遗传分析,并利用SSR分子标记进行遗传作图,发现中梁21对CYR30的抗性由1个显性基因控制,暂命名为Yrzhong21。该基因与位于小麦5AL染色体上的10个SSR位点Xgwm186、Xbarc165、Xwmc795、Xbarc40、Xgwm156、Xgwm617、Xwmc415、Xbarc151、Xwmc338和Xgwm666连锁,其中最近的侧翼位点为Xgwm186和Xbarc165,其遗传距离分别是7.5 cM和2.7 cM。系谱分析及结合分子标记结果表明,该基因可能来自Ciemenp。与已定位于5A染色体上的抗条锈病基因的比较表明,Yrzhong21可能是一个抗条锈病的新基因。用标记Xgwm186和Xbarc165检测中梁系列品种,其中仅17%扩增到与中梁21相同的位点,表明该基因在抗条锈病育种中可能有很大的应用潜力。     

从野生二粒小麦导入普通小麦的抗白粉病基因MlWE18分子标记定位

野生二粒小麦(Triticum turgidumvar. dicoccoides)是小麦抗白粉病遗传改良的重要基因资源。利用野生二粒小麦WE18与普通小麦品种(系)连续多次杂交和自交,育成对白粉病菌生理小种E09高度抵抗的小麦新品系3D249(京双27//燕大1817/WE18/3/温麦4,F₇)。利用高感白粉病品系薛早和3D249组配杂交组合,获得杂种F₁代、F₂分离群体和F₃代家系,进行苗期白粉病抗性鉴定和遗传分析。结果表明,小麦品系3D249对E09小种的抗性受显性单基因控制,暂命名该基因为MlWE18。利用集群分离分析法(BSA)和分子标记分析,发现4个简单重复序列(SSR)标记(Xwmc525、Xwmc273、Xcfa2040和Xcfa2240)、1个EST-STS标记(Xmag1759)和1个EST-STS序列标记(XE13-2)与抗白粉病基因MlWE18连锁,在遗传连锁图谱上的顺序为Xwmc525–Xcfa2040–Xwmc273–XE13-2–Xmag1759–MlWE18–Xcfa2240。SSR标记的染色体缺失系物理定位结果表明,抗白粉病基因MlWE18位于小麦7A染色体长臂末端的Bin 7AL 16–0.85–1.00。与已知定位于该染色体区域的Pm基因遗传连锁图谱比较表明,MlWE18与抗白粉病基因Pm1、MlIW72、PmU、Mlm2033和Mlm80均位于7AL相同染色体区段。     

陆地棉抗黄萎病性状的遗传及分子标记研究

 以陆地棉抗黄萎病品系常96和感病品种军棉1号为研究材料,构建了一个含有138个F₂单株的作图群体。利用强致病力菌株VD8对P₁、P₂、F₁、F_2：3群体进行营养钵接种,估算各世代的相对病指。应用主基因 多基因混合遗传模型分析得出该组合的最适遗传模型为C-0模型,即加性-显性-上位性多基因模型。对1998对SSR引物和230对SRAP引物进行筛选,获得148个SSR和6个SRAP多态性标记位点,进一步利用MAPMAKER作图软件,构建了一张含122个标记位点的陆陆杂种遗传连锁图。利用复合区间作图法在第9染色体NAU462-JESPR114区间内,检测到1个抗黄萎病QTL,可解释的表型变异为13.8%。     

小麦品系天95HF2抗叶锈基因定位

苗期基因推导表明,小麦品系天95HF2高抗我国目前多数叶锈菌生理小种。为了确定这一品系所携带的抗病基因,以天95HF2和感病小麦品种郑州5389杂交,获得F1和F2代群体,用叶锈菌小种FHTT和PHTS分别对双亲及其杂交后代进行叶锈抗性鉴定并进行分子标记分析。结果表明,用叶锈菌小种FHTT接种F2代群体时呈现1对显性基因的抗感分离比例,经过亲本和抗感池间标记筛选以及F2代群体的标记检测,Lr1的STS标记WR003和位于5DL的SSR标记wmc443与该抗病基因连锁,遗传距离分别为2.9cM和3.1cM,根据抗性特点和染色体位置推断该基因可能为Lr1。用叶锈菌小种PHTS接种F2代群体时呈现2对基因的抗感分离,分子标记分析结果表明,其中一个基因为Lr1,另一个基因可能为LrZH84。     

中棉所12的黄萎病抗性遗传与育种应用研究

 以2个海岛棉品种和5个陆地棉品种为材料与中棉所12进行正反交,配制14个杂交组合的F₁和F₂ 。采用纸钵育苗,撕底伤根接种方法对14个组合的F₁和F₂群体进行黄萎病抗性鉴定。结果表明,以中棉所12作父本与海岛棉抗黄萎病品种或陆地棉抗黄萎病品种进行杂交,F₂抗（耐）病株与感病株的分离符合3：1的分离规律,说明海岛棉的抗黄萎病性对于中棉所12的耐黄萎病性为显性,中棉所12的耐黄萎病性对于陆地棉的感黄萎病性为显性,控制黄萎病抗性的基因为一个显性主基因。然而,以中棉所12为母本与海岛棉品种、抗病陆地棉品种和感病陆地棉品种进行杂交,F₂群体中90%以上的个体为抗病类型,说明中棉所12的细胞质中存在着抗黄萎病的遗传成分,具有细胞质母体遗传的特点,在棉花抗黄萎病育种中具有重要的利用价值。     

An allelic series at the Co-1 locus conditioning resistance to anthracnose in common bean of Andean origin

In this study, we characterized the genetic resistance of the Andean bean cultivars Kaboon and Perry Marrow and their relation to other sources of anthracnose resistance in common bean. Based on the segregation ratio (3R:1S) observed in two F₂ populations we demonstrated that Kaboon carries one major dominant gene conferring resistance to races 7 and 73 of Colletotrichum lindemuthianum. This gene in Kaboon is independent from the Co-2 gene and is an allele of the Co-1 gene present in Michigan Dark Red Kidney (MDRK) cultivar. Therefore, we propose the symbol CO-1 ² for the major dominant gene in Kaboon. The Co-1 is the only gene of Andean origin among the Co anthracnose resistance genes characterized in common bean. When inoculated with the less virulent Andean race 5, the segregation ratio in the F₂ progeny of Cardinal and Kaboon was 57R:7S (p = 0.38). These data indicate that Kaboon must possess other weaker dominant resistance genes with a complementary mode of action, since Cardinal is not known to possess genes for anthracnose resistance. Perry Marrow, a second Andean cultivar with resistance to a different group of races, was shown to possess another resistant allele at the Co-1 locus and the gene symbol Co-1 ³ was assigned. In R × R crosses between Perry Marrow and MDRK or Kaboon, no susceptible F₂ plants were found when inoculated with race 73. These findings support the presence of a multiple allelic series at the Andean Co-1 locus, and have major implications in breeding for durable anthracnose resistance in common bean. This revised version was published online in July 2006 with corrections to the Cover Date.     

普通菜豆抗炭疽病基因SCAR标记鉴定

利用12个菜豆品种（鉴别寄主）评价了7个抗炭疽病基因SCAR标记的可靠性和实用性,其中SBB14_1150/1050标记引物扩增没有特异性,SAS13₉₅₀没有扩增带。用5个可靠的菜豆抗炭疽病基因SCAR标记（SCAreoli₁₀₀₀、SH18₁₁₀₀、SAB3₄₀₀、SB12₃₅₀ 和SCF10₁₀₇₂）,对127份普通菜豆抗炭疽病品种进行抗炭疽病基因分子标记鉴定,82份未检测到SCAR标记,45份分别含有1~3个SCAR标记;检测到SCAR标记的资源中,13份含有SCAreoli₁₀₀₀标记,13份含有SH18₁₁₀₀标记,5份含有SAB3₄₀₀标记,9份含有SB12₃₅₀标记,11份含有SCF10₁₀₇₂标记。分析表明抗病品种含有的抗病基因标记与品种来源存在相关性。     

Genetic characterization of anthracnose resistance genes Co-4 3 and Co-9 in common bean cultivar tlalnepantla 64 (PI 207262)

Tlalnepantla 64 (PI 207262) is an important source of genes for resistance to common bean anthracnose, caused by Colletotrichum lindemuthianum. However, these genes have not been fully characterized. Inheritance studies using crosses involving PI 207262 show that two independent genes confer resistance to anthracnose. Allelism tests showed that the genes are located at distinct loci from the previously identified resistance genes Co-1, Co-2, Co-3, Co-5, Co-6, and Co-10. Also, no segregation was observed in relation to Co-4, Co-4 ², Co-9, and to the gene present in cultivar Widusa, indicating that PI 207262 harbors alleles of these genes. We conclude that PI 207262 harbors two anthracnose resistance genes, Co-4 and Co-9. The Co-4 allele of PI 207262 would be different from Co-4 and Co-4 ² and it is proposed Co-4 ³ as the genetic symbol for this resistance allele. As PI 207262 is the parent of BAT 93, the Co-9 symbol represents the gene of both cultivars. Also, one allele of Co-9 gene was detected in cultivar Widusa.     

Inheritance of angular leaf spot resistance in common bean line BAT 332 and identification of RAPD markers linked to the resistance gene

The existence of genetic variability for angular leaf spot (ALS) resistance in the common bean germplasm allows the development of breeding lines resistant to this disease. The BAT 332 line is an important resistance source to common bean ALS. In this work we determined the inheritance pattern and identified RAPD markers linked to a resistance gene present in BAT 332. Populations F₁, F₂,BCs and BCr derived from crosses between BAT 332 and cultivar Rudá were used. Rudá is a commercial cultivar with carioca type grains and susceptible to ALS. The resistance of BAT 332 to race 61.41 of the pathogen was confirmed. Segregation analysis of the plants indicated that a single dominant gene confers resistance. For identification of RAPD markers linked to the resistance gene, bulk segregant analysis (BSA) was used. Two RAPD markers,OPAA07₉₅₀ and OPAO12₉₅₀, linked in coupling phase at 5.10 and 5.83 cM of this gene, respectively, were identified. These molecular markers are important for common bean breeders and geneticists as source of genetic information and for marker assisted selection in breeding programs. This revised version was published online in July 2006 with corrections to the Cover Date.     

Performance of upland coloured cotton germplasm lines in line × tester crosses

Anthracnose is a serious disease affecting dry bean production especially in the cool highland areas worldwide. The objective of this research was to study the inheritance of anthracnose resistance in market-class dry beans. A complete diallel set of crosses was generated from nine diverse parents comprising six resistant and three susceptible to anthracnose. The F₁ and F₂ crosses and parents were artificially inoculated with Colletotriclum lindenumthianum Race-767 in a growth room. There was significant variation for anthracnose resistance among genotypes. General combining ability (GCA) and specific combining ability effects were significant for resistance, indicating importance of both additive and non-additive effects, respectively. Preponderance of GCA effects (66%) suggested that additive effects were more important than non-additive effects (24%), which were also reflected by high heritability estimates (70%), and suggested that simple selection or backcrossing would be useful for improving the resistance in market class varieties. The study was not conclusive on whether epistatic gene action played a major role, but if available it might have biased the dominance gene effects. Reciprocal effects (10%) were not significant (P > 0.05), suggesting that cytoplasmic genes did not play a major role in modifying anthracnose resistance. Parental lines G2333, AB136, NAT002, and NAT003 showed highly negative GCA effects qualifying them as suitable parents for transferring resistance genes to their progenies. A few major genes, 1–3, displaying partial dominance conditioned anthracnose resistance, suggesting a possibility of using marker-assisted selection to improve anthracnose resistance in market-class dry beans.     

Characterization of the anthracnose resistance gene present in Ouro Negro (Honduras 35) common bean cultivar

Ouro Negro (Honduras 35) is a highly productive Mesoamerican black seeded bean cultivar that possesses a major dominant gene conferring resistance to anthracnose (causal organism Colletotrichum lindemuthianum). In this work the anthracnose resistance gene present in Ouro Negro was characterized by studying allelic relationships to the following previously characterized anthracnose resistance genes (cultivars): Co-1 (MDRK), Co-1 ² (Kaboon), Co-1 ³ (Perry Marrow), Co-2 (Cornell 49-242), Co-3 (Mexico 222), Co-4 (TO), Co-4 ² (SEL 1308), Co-5 (SEL1360), Co-6 (AB 136), and the resistance genes present in PI 207262 and Widusa. In addition, we determined the resistance spectrum of Ouro Negro in relation to 19 pathotypes of C. lindemuthianum. The allelism tests confirmed that the dominant anthracnose resistance gene present in Ouro Negro is positioned at a locus distinct from those with which it was compared. We propose that this new gene be named Co-10. The inoculation of Ouro Negro with the 19 pathotypes of C. lindemuthianum demonstrated that Co-10 confers resistance to pathotypes 23, 64, 67, 73, 81, 83, 87, 89, 95, 102, 117, 119, 343, 453, 1033, 1545 and 1600. The identification of Co-10 is an important contribution to bean breeding programs that are in constant need of new sources of resistance to anthracnose. This revised version was published online in July 2006 with corrections to the Cover Date.     

Inheritance of anthracnose resistance in the common bean cultivar Widusa

Snap bean (Phaseolus vulgaris L.) cultivar, Widusa, was crossed to Michigan Dark Red Kidney (MDRK), Michelite, BAT 93, Mexico 222, Cornell 49–242, and TO cultivars to study the inheritance of resistance to anthracnose in Widusa. The segregation patterns observed in six F₂ populations supported an expected 3R:1S ratio suggesting that Widusa carries a single dominant gene conditioning resistance to races 7, 65, 73, and 453 of Colletotrichum lindemuthianum, the causal organism of bean anthracnose. Allelism tests conducted with F₂ populations derived from crosses between Widusa and Cornell 49–242 (Co-2), Mexico 222 (Co-3), TO (Co-4), TU (Co-5), AB 136 (Co-6), BAT 93 (Co-9), and Ouro Negro (Co-10), inoculated with races 7, 9, 65 and 73, showed a segregation ratio of 15R:1S. These results suggest that the anthracnose resistance gene in Widusa is independent from the Co-2, Co-3, Co-4,Co-5, Co-6, Co-9, and Co-10 genes. A lack of segregation was observed among 200 F₂ individuals from the cross Widusa/MDRK, and among 138 F₂ individuals from the cross Widusa/Kaboon inoculated with race 65, suggesting that Widusa carries an allele at the Co-1 locus. We propose that the anthracnose resistance allele in Widusa be named Co-1 ⁵ as Widusa exhibits a unique reaction to race 89 compared to other alleles at the Co-1 locus. RAPD marker A18₁₅₀₀ co-segregated in repulsion-phase linkage with the Co-1 ⁵ gene at a distance of 1.2 cM and will provide bean breeders with a ready tool to enhance the use of the Co-1 ⁵ gene in future bean cultivars.     

Use of molecular markers to accelerate the breeding of common bean lines resistant to rust and anthracnose

The main goal of this work was to introduce resistance genes for rust, caused by Uromyces appendiculatus, and anthracnose, caused by Colletotrichum lindemuthianum, in an adapted common bean cultivar through marker-assisted backcrossing. DNA fingerprinting was used to select plants genetically closer to the recurrent parent which were also resistant to rust and to race 89 of C. lindemuthianum. DNA samples extracted from the resistant parent (cv. Ouro Negro), the recurrent parent (cv. Rudá), and from BC₁, BC₂ and BC₃ resistant plants were amplified by the RAPD technique. The relative genetic distances in relation to the recurrent parent varied between 9 and 59% for BC₁, 7 and 33% for BC₂, and 0 and 7% for BC₃ resistant plants. After only three backcrosses, five lines resistant to rust and anthracnose with, approximately, 0% genetic distance in relation to the recurrent parent were obtained. These lines underwent field yield tests in two consecutive growing seasons and three of them presented a good yield performance, surpassing in that sense their parents and most of the reference cultivars tested.