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。     

利用分子标记定位普通菜豆抗炭疽病基因

为了定位中国普通菜豆的抗炭疽病基因, 选取抗炭疽病地方品种红芸豆(国家库编号F2322)与高感菜豆品种京豆(国家库编号F0777)配制杂交组合, 构建F₂抗感分离群体和F_2:3家系, 用菜豆炭疽菌81号生理小种鉴定抗病性并分析遗传性。结果表明, 红芸豆对菜豆炭疽菌81号小种的抗性是由一显性单基因控制的, 暂将该基因命名为Co-F2322。用分离群体分组分析法(BSA)和SSR、CAPs分子标记技术, 将该基因定位在B1连锁群上, 利用软件Mapmaker 3.0和Mapchart 3.0计算标记与目的基因间的遗传距离, 检测到3个SSR标记BMc32、C871、Pvm98和2个CAPs标记g1224、g683与抗炭疽病基因连锁, 遗传距离分别为26.06、3.58、13.56、3.81和12.75 cM。     

菜豆普通细菌性疫病抗性基因定位

菜豆普通细菌性疫病是世界上危害普通菜豆生产的最严重的病害之一。龙芸豆5号是我国黑龙江省的主栽品种,对菜豆普通细菌性疫病表现出良好的抗性。为定位来源于龙芸豆5号的抗性基因,本研究构建了包含785个单株的F2分离群体。基于该群体构建了一张包含206个SSR标记,总长度1648.42 c M,标记间平均遗传距离8.00 c M的遗传图谱。图谱包含12个连锁群,各连锁群平均长度137.37 c M,连锁群上标记数量3~35个。结合温室表型鉴定结果,采用QTL Ici Mapping v4.0软件的完备区间作图法进行QTL定位和效应估计。接种14 d后在Pv06染色体上检测到一个抗病QTL。该位点位于标记p6s249与p6s183之间,加性效应值为0.44,说明增效基因来源于龙芸豆5号,LOD值为5.93,表型贡献率为4.61%,该抗病QTL的效应值相对较低,将在培育稳定持久的抗菜豆普通细菌性疫病的品种中发挥作用。最后,对抗性基因紧密连锁的11对SSR引物与菜豆普通细菌性疫病抗性的关联分析表明,SSR标记p6s249与菜豆普通细菌性疫病抗性极显著关联(P0.001),该标记可用于抗病分子育种。     

大豆灰斑病1号生理小种抗性基因的SSR标记

针对中国大豆灰斑病1号生理小种,以抗所有生理小种的品系东农40566为母本,以感所有生理小种的品种东农410为父本配制杂交组合,杂交得到F2代后连续自交3代得到F5代群体。该群体经人工接种灰斑病1号生理小种后,利用BSA法对500个SSR标记进行筛选,其中3个标记Satt565、SOYGPATR和Satt396在抗、感池间表现出稳定的多态性,并且在F2代个体中表现出抗性与多态性协同分离的趋势。3个标记与抗性基因的连锁顺序为Satt565—SOYGPATR—Hrcs1—Satt396,它们与抗性基因的连锁距离分别为12.7cM、6.5cM、14.7cM。推测抗大豆灰斑病1号生理小种的基因可能位于C1连锁群上。     

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。     

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。     

一个抗赤星病基因的SSR标记连锁群

为筛选到与抗赤星病基因连锁更加紧密的SSR标记,并绘制出抗病基因的SSR标记连锁图。本研究以一个位于M号连锁群上且与净叶黄抗赤星病基因有连锁关系的SSR标记为基础,将高密度遗传连锁图谱中位于M号连锁群上的130对SSR引物进行合成及扩增筛选,通过数据分析,获得了一个抗赤星病基因的SSR标记连锁群。该连锁群包括12个标记,全长181.5cM,平均间距15.1cM,抗性基因被定位在标记J4与J9之间,其中与J9的遗传距离仅为4cM,为下一步抗性基因的精细定位奠定了良好的基础。     

小麦新品种济麦22抗白粉病基因的分子标记定位

为明确济麦22携带抗白粉病基因的染色体位置,利用济麦22与感病亲本中国春杂交,用小麦白粉菌(Blumeria graminis f. sp. tritici)强毒性小种E20对F₂抗、感分离群体和F_2:3家系进行抗病鉴定和遗传分析。结果表明,济麦22携带1个显性抗白粉病基因, 暂被命名为PmJM22。运用SSR和EST标记及分离群体分组分析法(bulked segregant analysis, BSA),将其定位在2BL染色体上,与4个SSR和5个EST标记间的连锁距离为7.7 cM (Xwmc149)到31.3 cM (Xbarc101)。通过分析2BL上其他抗白粉病基因的来源、染色体位置和抗性反应,认为PmJM22不同于Pm6、Pm26、Pm33和MlZec1。     

一个新的抗玉米矮花叶病基因的发现及初步定位

由SCMV引起的矮花叶病是我国的主要玉米病害之一, 鉴定和发掘新的抗病基因对于玉米抗病遗传育种具有重要意义。以抗病自交系海9-21和感病自交系掖478杂交的一个BC₂F₃群体为试验材料, 通过人工接种矮花叶病毒进行抗病性鉴定, 发现该分离群体中抗病植株与感病植株数符合1∶3的分离比例, 推测其抗病基因是由1对隐性基因控制。抗感池和SSR标记连锁分析表明, 存在一个新的玉米矮花叶病隐性抗病基因(或等位基因), 将该基因命名为scm3。scm3基因来源于抗病玉米自交系海9-21, 位于第3染色体短臂3.04~3.05区域, 在SSR标记umc1965和bnlg420之间, 遗传距离分别为45.7 cM和6.5 cM。连锁的标记还有umc1307、umc2265、bnlg2241和umc2166, 它们与scm3之间的遗传距离分别是8.3、13.3、15.5和19.7 cM, 这些SSR标记与scm3基因在染色体上的排列顺序为umc1965—scm3—bnlg420—umc1307—umc2265—bnlg2241—umc2166。     

普通菜豆根系相关性状的关联分析

幼苗期根系发育对作物的生长发育具有重要作用。利用生长袋纸培系统对324份普通菜豆种质的主根长、根干重、根体积、根表面积等9个根系相关性状进行表型鉴定,并结合覆盖全基因组、有多态性的116对SSR标记,利用MLM（Q+K）模型进行表型和标记的关联分析。表型分析表明,324份材料的9个根系相关性状表型变异丰富,平均变异系数的变动范围是10.09%~37.03%;基因型分析表明,116个多态性SSR标记共检测到919个等位变异位点,每个标记的平均基因多样性指数为0.59,多态性信息含量（PIC）平均值为0.54,显示这些标记具有较高的基因多样性;群体结构分析表明,供试材料分为两个亚群,与普通菜豆起源于两个基因库对应;关联分析结果显示,以P<0.01作为显著条件,共检测到48个显著标记位点,其中有10个位点同时与2个以上性状相关联,有5个位点与前人研究结果一致。研究结果为进一步理解普通菜豆根系的遗传机理提供了理论参考,也为分子标记辅助选择改良普通菜豆根系奠定了基础。     

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.     

Simultaneous selection for resistance to five bacterial, fungal, and viral diseases in three Andean?��?Middle American inter-gene pool common bean populations

Numerous bacterial, fungal, and viral diseases cause severe damage on roots, foliage, stem, pods, and seeds, resulting in yield and quality losses in common bean (Phaseolus vulgaris L.) worldwide. Cultivars with resistance to multiple diseases are needed to reduce these losses and dependence on pesticides for disease control. Our objective was to determine the effectiveness of simultaneous selection in the F₁ and F₂ for resistance to five diseases, namely angular leaf spot (ALS), anthracnose (ANT), bean common mosaic (BCM), common bacterial blight (CBB), and common bean rust (CBR) in three Andean x Middle American inter-gene pool double-cross populations, namely ST?=???Chocho??/??Catrachita??//G 5686/VAX 3, CN?=???DIACOL Calima??/VAX 6//A 193/G 5686, and CB?=?A 483/??Talash??//Wilkinson 2/G 5686. One hundred seventy-five F₁ plants of ST, 177 of CN, and 195 of CB and their parents were evaluated in the greenhouse using sequential inoculations with pathogens causing BCM, CBR, ALS, CBB, and ANT, in that order. Progenies of surviving F₁ plants were again evaluated in the F₂, using similar sequential inoculations. The F₄-derived F₅ breeding lines were developed using single-seed descent method. No selection was practiced for any trait in the F₃ and F₄. In the F₅, five breeding lines from ST, two from CN, and one from CB exhibited intermediate to high levels of resistance to the five diseases when compared with the parents. Thus, selection in the F₁ and F₂ was effective for simultaneous introgression of resistance to the five diseases in all three Andean?×?Middle American inter-gene pool common bean populations.     

Introgressing resistance to bacterial and viral diseases from the middle American to Andean common bean

The genetic base of cultivars within market classes of common bean (Phaseolus vulgaris L.) is narrow. Moreover, small- and medium-seeded Middle American cultivars often possess higher yield and resistance to abiotic and biotic stresses than their large-seeded Andean counterparts. Thus, for broadening the genetic base and breeding for higher yielding multiple stress resistant Andean cultivars use of inter-gene pool populations is essential. Our objective was to determine the feasibility of introgressing resistance to Been common mosaic virus (BCMV, a potyvirus), and the common [caused by Xanthomonas campestris pv. phaseoli (Xcp) and X. campestris pv. phaseoli var. fuscans (Xcpf)] and halo [caused by Pseudomonas syringae pv. phaseolicola (Psp)] bacterial blights from the Middle American to Andean bean, using gamete selection. Also, we investigated the relative importance of the use of a landrace cultivar versus elite breeding line as the last parent making maximum genetic contribution in multiple-parent inter-gene pool crosses for breeding for resistance to diseases. Two multiple-parent crosses, namely ZARA I = Wilkinson 2 /// ‘ICA Tundama’ / ‘Edmund’ // VAX 3 / PVA 773 and ZARA II = ‘Moradillo’ /// ICA Tundama / Edmund // VAX 3 / PVA 773 were made. From the F₁ to F₅ single plant selection was practiced for resistance to the common and halo bacterial blights in both populations at Valladolid, Spain. The parents and F₅-derived F₆ breeding lines were evaluated separately for BCMV, and common and halo bacterial blights in the greenhouse at Filer and Kimberly, Idaho in 2001. They were also evaluated for the two bacterial blights, growth habit, seed color and 100-seed weight at Valladolid in 2002. All 20 F₁ plants of ZARA I were resistant or intermediate to common and halo bacterial blights in the greenhouse, but their F₂ and subsequent families segregated for both bacterial blights. Segregation for resistant, intermediate, and susceptible plants for common bacterial blight occurred in the F₁ of ZARA II. Simple correlation coefficient for common bacterial blight between the F₁ and F₁-derived F₂ families was positive (r = 0.54 P < 0.05) for ZARA II. From the F₂ to F₅ the number of families resistant to both bacterial blights decreased in both populations. Only four of 20 F₁ plants in ZARA I resulted in seven F₆ breeding lines, and only one of 32 F₁ plants in ZARA II resulted in one F₆ breeding line resistant to the three diseases. None of the selected breeding lines had seed size as large as the largest Andean parent. The use of elite breeding line or cultivar as the last parent making maximum genetic contribution to the multiple-parent inter-gene pool crosses, relatively large population size in the F₁, and simultaneous selection for plant type, seed traits as well as resistance to diseases would be crucial for introgression and pyramiding of favorable alleles and quantitative trait loci (QTL) of interest between the Andean and Middle American beans.     

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.     

Growth habit and gene pool effects on inheritance of yield in common bean

Summary To satisfy farmer and consumer preferences, breeding efforts to increase yield potential in common bean must take into account the interrelated effects of growth habit, seed size, maturity, and gene pool on yield expression in segregating populations. To examine the relationships among these traits, a genetic study was conducted to determine the effect of growth habit on yield and seed size in crosses among five bean lines from diverse gene pools. Two parental bean lines had determinate, type I growth habits and large seed size typical of the Neuva Granada-Andean gene pool. Two other lines were tropical Mesoamerican types with type II growth habits and small seed size; and the fifth line, G13625, a landrace of the Jalisco gene pool from the Mexican highlands, had a type IV climbing growth habit and medium seed size. Individual F₂ plants from each cross and parental lines were evaluated for growth habit and yield component traits under high input field conditions. The following season, the evaluations were repeated on random F₃ plants. Of the five parental lines, only G13625 showed significant GCA effects for yield in both the F₂ and F₃ generations. Improved yielding ability of G13625 progeny was associated with an increased expression of climbing bean growth habit traits: guide length, climbing ability, node number on main stem, and plant height. Crosses between Andean x Mesoamerican and Andean x Jalisco genotypes, as well between growth habit type I (Andean x Andean) and between type II (Mesoamerican x Mesoamerican) had very low parent-offspring heritability values for yield. Yield heritability was only significant for crosses between Mesomerican x Jalisco gene pools. An apparent simple genetic control of growth habit modification towards semi-climbing and climbing types is proposed as the major reason for increased yields in these crosses. No genetic linkage between genes controlling growth habit and seed size was detected which might restrict the development of high yielding large-seeded type II lines.     

Inheritance of resistance to the chlorosis component of tan spot of wheat caused by Pyrenophora tritici-repentis, races 1 and 3

The fungus Pyrenophora tritici-repentis, causal agent of tan spot of wheat, produces two phenotypically distinct symptoms, tan necrosis and extensive chlorosis. The inheritance of resistance to chlorosis induced by P. tritici-repentis races 1 and 3 was studied in crosses between common wheat resistant genotypes Erik, Hadden, Red Chief, Glenlea, and 86ISMN 2137 and susceptible genotype 6B-365. Plants were inoculated under controlled environmental conditions at the two-leaf stage and disease rating was based on presence or absence of chlorosis. In all the resistant × susceptible crosses, F₁ plants were resistant and the segregation of the F₂ generation and F₃ families indicated that a single dominant gene controlled resistance. Lack of segregation in a partial diallel series of crosses among the resistant genotypes tested with race 3␣indicated that the resistant genotypes possessed␣the same resistance gene. This resistance gene was effective against chlorosis induced by P.␣tritici-repentis races 1 and 3.     

Independent, Alternate, and Simultaneous Selection for Resistance to Anthracnose and Angular Leaf Spot and Effects on Seed Yield in Common Bean (Phaseolus vulgaris L.)

Two double-cross populations were used to evaluate the efficiency of independent, alternate, and simultaneous selection practiced from the F₂ to F₈ for resistance to anthracnose and angular leaf spot of common bean (Phaseolus vulgaris L.). Seven resistant and high-yielding lines were selected from each of the four environments used during this study. These lines and the seven parents involved in two populations were evaluated in an 8 × 8 lattice design with three replications in two cropping seasons. Pathogen inoculum was used to create the three test environments: anthracnose alone, angular leaf spot alone, and anthracnose and angular leaf spot together. All entries were also evaluated in a fourth, disease-free environment. Selection for resistance to anthracnose and angular leaf spot was effective in both populations. Mean disease scores of all selected lines for anthracnose were lower than that of angular leaf spot irrespective of selection environment. Among the three stress environments, yields were higher in the anthracnose environment. However, lines selected alternately for anthracnose and angular leaf spot were usually higher yielding, and the highest yielding line in both populations originated from this selection environment. The mean yield of selected lines was higher and the highest yielding line originated from the population involving a parent (G 1805) belonging to the Mexican highland race ‘Jalisco’. Positive association existed between seed yield of protected and pathogen-inoculated environments. No association was found between resistance to anthracnose and angular leaf spot.     

Sources of resistance to angular leaf spot (Phaeoisariopsis griseola) in common bean core collection, wild Phaseolus vulgaris and secondary gene pool

Angular leaf spot (ALS) is one of the most devastating diseases of common bean (Phaseolus vulgaris L.) in tropical and subtropical countries. The causal fungus, Phaeoisariopsis griseola(Sacc.) Ferr. is highly variable and a diverse source of resistance genes is required to manage this disease. We evaluated a common bean core collection,primary and secondary gene pools and lines derived from inter-specific crosses of P. vulgaris and P. coccineus or P. polyanthus (secondary gene pool) for resistance to angular leaf spot. Of the 1441 accessiones in the core collection, only 2.2% were resistant to both Andean and Mesoamerican races of P. griseola, 28% were resistant only to Andean and 9% to Mesoamerican races. Of the 32 resistant accessions, 68%originated from Bolivia, Colombia,Guatemala and Mexico. More accessions from these countries should be examined for P. griseola reaction. Very few wild P. vulgaris accessions (4%), were resistant to ALS. In contrast, high levels of resistance (62%) were found in the secondary gene pool. Among the 1010 lines from inter-specific crosses, 109 lines were highly resistant. These genotypes from the primary and secondary common bean gene pools resistant to Andean and Mesoamerican races of P. griseola offer a potential for developing broad and durable ALS resistance. This revised version was published online in August 2006 with corrections to the Cover Date.