甘蓝型油菜隐性上位核不育×恢复系遗传判别

利用定性分析方法,对甘蓝型油菜隐性上位核不育×恢复系的各种遗传情况进行鉴别。结果发现可以区分为6种类型,每种类型有3种遗传情况。同时对隐性上位核不育的遗传行为方式进行了讨论。     

Inheritance of two components of early maturity in groundnut (Arachis hypogaea L.)

Summary Knowledge of inheritance of early maturity or its components is important to groundnut breeders in developing short-duration cultivars. This study was conducted to determine the inheritance of two components of early maturity: days to first flower from sowing, and days to accumulation of 25 flowers from the appearance of first flower, using three groundnut genotypes. Two early-maturing (Chico and Gangapuri) and one late-maturing (M 13) genotypes were crossed in all possible combinations, including reciprocals. The parents, F₁, F₂, F₃, and backcross populations were evaluated for days to first flower from sowing, and for days to accumulation of 25 flowers. The data suggest that days to first flower in the crosses studied is governed by a single gene with additive gene action. Chico and Gangapuri possess the same allele for this component of earliness. Three independent genes with complete dominance at each locus appear to control the days to accumulation of 25 flowers. In crosses between late (M 13) and early (Chico or Gangapuri) parents, a segregation pattern suggesting dominant-recessive epistasis (13 late:3 early) was observed for this component. Segregation in the F₂ generation (1 late:15 early) of both early parents (Chico x Gangapuri) indicated that the genes for early accumulation of flowers in these two parents are at different loci.Submitted as ICRISAT J.A. No. 1557.     

Analysis of generation means and components of variance for parthenocarpy in cucumber (Cucumis sativus L.)

Parthenocarpy (seedless fruit) has potential for increasing yield in cucumber (Cucumis sativus var. sativus L.). To determine the inheritance of parthenocarpy in gynoecious cucumber, P₁, P₂, F₁, F₂, BC₁P₁, and BC₁P₂ generations derived from crossing two non‐parthenocarpic gynoecious inbred lines [Gy8 (P₂; processing type) and ‘Marketmore 80’ (P₂; MM, fresh market type)] with a highly parthenocarpic inbred line [2A (P₁; processing type)] were evaluated for fruit number in a greenhouse at Arlington, Wisc. in 1999 (designated 2A × Gy8 1999) and in the open‐field at Hancock, Wisc. in 2000 (designated 2A × Gy8 2000 and 2A × MM 2000). There were significant location and location × generation interaction effects, and therefore generation means analyses were conducted separately for each location. The minimum numbers of effective factors controlling parthenocarpy were estimated to be at least one (2A × Gy8 1999), two (2A × Gy8 2000) and four (2A × MM 2000). Results suggest that selection for parthenocarpy for multiple hand harvest operations will likely be more effective than that for once‐over machine harvest operations. However, the selection efficiency will likely vary across different populations and environments.     

Genetics of grain yield and other agronomic characters in t'ef (Eragrostis tef Zucc. Trotter). I. Generation means and variances analysis

Quantitative genetics of grain yield and other agronomic characters of t'ef (Eragrostis tef) were studied using the F₁, F₂, BC₁, and BC₂ of the cross Fesho × Kay Murri. The study was carried out to estimate gene effects controlling the inheritance of grain yield and related agronomic characters. Significant additive [d] and dominance × dominance [l] interaction effects were detected for grain yield. The variations of yield per panicle and panicle weight were explained in terms of [d], dominance [h], and additive × additive [i] interactions. Non-allelic gene interactions were also detected for kernel weight, harvest index, tiller number, plant height, days to heading and days to maturity. The simple additive-dominance model explained the variation for panicle length, culm diameter and plant weight, allowing unbiased estimates of additive (D) and dominance (H) variance components. Large dominance variances (H) were estimated for grain yield, yield per panicle, and panicle weight. The additive variances for plant height, panicle length, days to heading and days to maturity were higher than the respective dominance variances. High narrow-sense heritability (h²) values (> 0.50) were estimated for plant height, panicle length, days to heading and days to maturity. The lowest h² (0.09) was obtained for kernel weight for which there was little variability. Since grain yield and several important agronomic characters of t'ef are influenced by non-allelic gene interaction, it is advisable to delay selection for yield to later generations with increased homozygosity. This revised version was published online in July 2006 with corrections to the Cover Date.     

Common bean breeding for resistance against biotic and abiotic stresses: From classical to MAS breeding

Summary Breeding for resistance to biotic and abiotic stresses of global importance in common bean is reviewed with emphasis on development and application of marker-assisted selection (MAS). The implementation and adoption of MAS in breeding for disease resistance is advanced compared to the implementation of MAS for insect and abiotic stress resistance. Highlighted examples of breeding in common bean using molecular markers reveal the role and success of MAS in gene pyramiding, rapidly deploying resistance genes via marker-assisted backcrossing, enabling simpler detection and selection of resistance genes in absence of the pathogen, and contributing to simplified breeding of complex traits by detection and indirect selection of quantitative trait loci (QTL) with major effects. The current status of MAS in breeding for resistance to angular leaf spot, anthracnose, Bean common mosaic and Bean common mosaic necrosis viruses, Beet curly top virus, Bean golden yellow mosaic virus, common bacterial blight, halo bacterial blight, rust, root rots, and white mold is reviewed in detail. Cumulative mapping of disease resistance traits has revealed new resistance gene clusters while adding to others, and reinforces the co-location of QTL conditioning resistance with specific resistance genes and defense-related genes. Breeding for resistance to insect pests is updated for bean pod weevil (Apion), bruchid seed weevils, leafhopper, thrips, bean fly, and whitefly, including the use of arcelin proteins as selectable markers for resistance to bruchid seed weevils. Breeding for resistance to abiotic stresses concentrates on drought, low soil phosphorus, and improved symbiotic nitrogen fixation. The combination of root growth and morphology traits, phosphorus uptake mechanisms, root acid exudation, and other traits in alleviating phosphorus deficiency, and identification of numerous QTL of relatively minor effect associated with each trait, reveals the complexity to be addressed in breeding for abiotic stress resistance in common bean.     

水稻米粒延伸性QTLs定位和基因型与环境互作分析

 利用协青早B/密阳46所构建的重组自交系群体及其相应分子遗传图谱，在海南和杭州两地试验，以延伸率作为米粒延伸性考察指标，检测QTL主效应、上位性效应和基因型×环境互作效应的遗传分析方法，进行联合检测分析。结果表明，该性状两地间的平均表现和群体分布特征较为相似，但两地间表型值相关系数却较小。试验检测到1个控制该性状的QTL基因qCRE 6,其增效基因来自于父本，提高3.99%的米粒延伸率，可解释5.30%的表型变异，它不存在与环境间显著互作。另外，还检测到2对上位性互作基因，即qCRE 2与qCRE 5 1、qCRE 5 2与qCRE 7,前者与环境间存在有显著的基因型×环境互作，在杭州有增加米粒延伸性的效果。     

利用双向导入系和重组自交系解析水稻加工品质的遗传基础

水稻加工品质直接影响水稻的商品价值。为解析水稻加工品质的遗传基础,以粳稻秀水09和籼稻IR2061构建的2套双向导入系和1套重组自交系为材料,在温州和三亚环境下考察了稻米加工品质,并进行了加工品质性状的数量性状位点(QTL)定位。本研究构建了一张包含145个简单重复序列(SSR)分子标记的遗传连锁图,该连锁图总长1 567.8 cM,秀水09和IR2061背景导入系的平均背景回复率分别为90.15%和85.82%。双亲的糙米率和精米率无显著差异,秀水09整精米率显著高于IR2061。3套群体的加工品质均表现为连续分布,且糙米率、精米率和整精米率3个性状间彼此均呈显著正相关。在两个环境下共定位到影响糙米率、精米率和整精米率的29个主效QTL和20对上位性QTL,其中6个QTL在其中的两套群体中被重复定位到,2个QTL在两个环境下稳定表达,10个QTL与环境互作,说明遗传背景和环境显著影响加工品质QTL的表达。此外,在第7号染色体RM432~RM11区间、第8号染色体RM80~RM458区间和第9号染色体RM257~RM278区间均同时定位到影响糙米率、精米率和整精米率的QTL,秀水09等位基因在这些QTL处均提高加工品质。研究结果可为分子改良水稻加工品质提供重要基因资源的参考依据。     

Inheritance of heading time in spring barley evaluated in multiple environments

The inheritance of heading time of spring barley was studied in three extremely early genotypes IB, RL and ‘Mona’ (M), which is homozygous recessive for the early maturity ea8 (=ea_k) gene conferring extreme earliness under short daylengths and is relatively photoperiod insensitive, and five (GP, MA, PS, NU and BA) spring genotypes that are early to intermediate for heading time. Frequency distributions of F₂ generations grown at Ouled Gnaou, Morocco (32°15′ N), an environment which maximizes differences between photoperiod‐insensitive and photoperiod‐sensitive genotypes, indicated that across populations many loci were segregating in a complex Mendelian manner. IB and RL were both homozygous recessive for the ea8 gene, which conferred an early heading time. RL had partially dominant alleles at second locus (Enea8), which enhanced its earliness. Recovery of only progeny within the parental range of genotypes for heading time from the crosses of RL/M and IB/M suggests that numerous loci remained suppressed, perhaps latent, given their diverse parentage. The ea8 recessive homozygote in RL suppressed another unidentified locus which, when homozygous recessive in the absence of the ea8 recessive homozygote, conferred extreme earliness in one short daylength environment (Ouled Gnaou, Morocco) but was undetected in another environment (Davis, CA, USA). Epistatic gene action and genotype × environment effects strongly influenced heading time. In addition to a genetic system consisting of single‐locus recessive homozygotes conferring photoperiod insensitivity, a second genetic system, based on dominant alleles at one or a few loci, derived from the early heading Finnish landrace ‘Olli’, also confers extremely early heading time under short daylengths and relative photoperiod insensitivity in the genotype GP.     

Inheritance of culm number in two uniculm x multiculm wheat crosses

Summary Effective utilization of uniculm wheat (Triticum aestivum L.) germplasm in breeding programs requires an understanding of the inheritance of the uniculm character. The parents, F₁, F₂, and first generation backcrosses (B₁ and B₂) of two crosses, each utilizing a uniculm spring wheat line and a locally adapted winter wheat cultivar, were space planted in an experiment to acquire information regarding the genetic control of culm number. Significant F₁ deviations from midparent values revealed the presence of substantial non-additive gene effects. The scaling tests of Mather and the joint scaling test detected the presence of epistasis. Hayman's six-parameter model revealed that a negative dominance effect provided the major contribution to variation in culm number, while additive x additive and dominance x dominance gene effects were of considerable importance.     

Generation means analysis of plant architectural traits and fruit yield in melon

Unique architectural phenotypes have the potential for increasing yield in commercial melon (Cucumis melo L.). Therefore, a generation means analysis was conducted to investigate the inheritance of architectural traits (days to anthesis, primary branch number, fruit number and weight, and average weight per fruit). Progeny (F₁, F₂, BC₁P₁ and BC₁P₂) from a cross between US Department of Agriculture (USDA) line, USDA 846‐1 (P₁) and ‘TopMark’ (P₂) were evaluated at Arlington (AR) and Hancock (HCK), Wisconsin in 2001. Significant (P ≤ 0.05) environment effects and genotype × environment interactions (G × E) analyses necessitated analysis by location. Significant differences (P ≤ 0.05) among parents and generations were observed for all traits, and the two parental lines differed significantly for primary branch number, fruit number and average weight per fruit. Additive gene effects were most important in governing primary branch number and fruit number per plant, while dominance and epistatic genetic effects mainly controlled days to anthesis, fruit weight per plant and average weight per fruit. Narrow‐sense heritabilities were 0.62 (AR) for days to anthesis, 0.71 (AR) and 0.76 (HCK) for primary branch number, 0.68 (AR) and 0.70 (HCK) for fruit weight per plant, 0.33 (AR) and 0.45 (HCK) for fruit weight per plant, and 0.06 (AR) and 0.79 (HCK) for average weight per fruit. Estimations of the least number of effective factors for primary branch number were relatively consistent at both AR (approx. 4) and HCK (approx. 2). Results suggest that introgression of yield‐related genes from highly branched melon types (e.g. USDA 846‐1) into US Western Shipping germplasm may aid in the development of high‐yielding cultivars with concentrated fruit set suitable for machine and/or hand‐harvesting operations.