陆地棉配合力与杂种优势、遗传距离的相关性分析

 用10个陆地棉亲本进行不完全双列杂交,共配置了45个组合,计算亲本的一般配合力（GCA）、特殊配合力(SCA)、杂种优势,并结合SSR标记研究了陆地棉亲本配合力与杂种优势、遗传距离之间的相关关系。配合力分析发现,10个亲本的一般配合力和特殊配合力存在显著或极显著差异。分析亲本配合力、杂种优势和遗传距离的相关性发现,子棉产量、皮棉产量、衣分的一般配合力和杂种优势呈显著或极显著相关,纤维长度、比强度、麦克隆值、株高、果枝数、单株铃数、铃重、子棉产量、皮棉产量、衣分的特殊配合力和杂种优势均呈极显著正相关,而与遗传距离相关均不显著。单株铃数、铃重、子棉产量、皮棉产量、衣分的杂种优势与遗传距离均为正向显著或极显著相关。在育种实践中这些显著或极显著相关的性状可能具有较高的改良潜力。     

杂交水稻产量及农艺性状杂种优势分析

为探讨杂种优势与双亲值、双亲一般配合力（GCA）、组合特殊配合力（SCA）、双亲遗传距离的关系,利用10个不育系和10个恢复系,按不完全双列杂交配制100个组合,对杂交水稻产量及农艺性状的杂种优势进行了分析,探索杂种优势的预测方法。结果表明：杂种一代的超亲优势和对照优势主要体现在穗长、每穗总粒数、每穗实粒数几个性状上,其具有正向超亲优势组合的比例分别达到61.0%、66.0%和53.0%,具有正向对照优势的比例分别为62.0%、78.0%和79.0%,结实率性状具有正向对照优势的比例也达到58.0%。杂种优势与父母本值、父母本平均值、高亲值、低亲值及父母本差值都有较为密切的关系,超亲优势与高亲值在8个性状上都极显著相关;对照优势与母本值、父母本平均值、高亲值都呈显著或极显著正相关。杂种优势与SCA和亲本的GCA效应值密切相关,特别是对照优势与SCA和双亲的GCA都呈显著或极显著正相关,同时与父母本的GCA之差和之和都有较大的关系。杂种优势与遗传距离的关系比较复杂,当遗传距离在5~5.5范围内,双亲的距离越远,杂种优势越强。     

二倍体苜蓿主要性状配合力及杂种优势分析

以3份花药离体培养单倍体苜蓿与2份扁蓿豆材料作为亲本,组配10个杂交组合,分析7个主要农艺性状的配合力,探究苜蓿与扁蓿豆的杂种优势与亲本一般配合力(GCA)、特殊配合力(SCA)和遗传距离之间的相关关系。结果表明,节间长受加性效应和非加性效应共同影响,株高、节间数、单株产量其遗传主要受加性效应影响较大。各性状的杂种优势在不同组合间差异较大。在二倍体苜蓿与扁蓿豆种间杂交组合中,XJ-3×CY-5和CY-35×HB各农艺性状特殊配合力的效应值适宜,杂种优势强,可作为优良杂交组合进行利用。研究表明,可通过组合间的SCA与杂种优势来提高亲本的选配效率,但利用SRAP标记遗传距离预测苜蓿杂种优势还有待进一步研究。     

大豆杂交种异地鉴定及选育方法初探

为了研究大豆杂交种杂种优势大小及其稳定性,进一步探讨杂交大豆选育方法,通过对2006—2010年异地鉴定试验初次测产及二次测产结果进行分析。结果表明,大豆杂交种同常规对照品种比较,具有较强的杂种优势,增产效果显著。大豆杂交种各产量性状间差异明显,这是由杂交种的遗传基础决定的,与杂交种的亲本的遗传基础及配合力有关。杂交种产量优势主要来自于三粒荚数、四粒荚数、单株荚数、单株粒数、单株产量、分枝数等产量性状,为杂交大豆新品种选育提供了依据。同时指出了大豆杂交种异地鉴定中存在的问题及解决方法。     

芝麻配合力的研究

本文对54个芝麻杂交组合10个性状进行配合力分析,结果得出:一般配合力方差明显大于特殊配合力方差,表明这些性状的遗传主要受加性基因控制.同一亲本不同性状或同一性状不同亲本间的一般配合力和组合的特殊配合力相差很大.即使双亲的一般配合力都为负值,也不能排除获得特殊配合力较高的组合.特殊配合力与双亲一般配合力均值呈显著、极显著的正相关.果轴长、单株产量、单株蒴数、株高和千粒重5个性状的总配合力与单株实产呈极显著的正相关,腿高和黄尖长呈极显著的负相关.上述分析结果有利于芝麻亲本选配及杂种后代的选择.     

芝麻杂种优势与配合力效应关系的研究

本文对54个芝麻杂交组合,10个性状的杂种优势与配合力效应关系研究表明:芝麻杂种优势普遍存在,而且超显性优势较强,其优势顺序依次为单株产量>单株蒴数>果轴长>株高,其它性状优势较小.各性状的杂种优势与其特殊配合力效应均呈显著的正相关.杂种优势主要由其特殊配合力效应提供.但某些组合的特殊配合力效应很小,甚至为负值,其杂种优势表现也很明显,这主要是由于亲本一般配合力效应中包括很大部分杂种优势效应.因此,在选配强优组合时,除了考虑组合的特殊配合力效应外,亲本的优势效应也是不可忽视的.     

结球甘蓝产量性状的配合力与杂种优势分析

结球甘蓝全株重和叶球重是其产量性状的重要构成因素。研究其配合力和杂种优势表现,对甘蓝杂交育种和创制高产结球甘蓝杂交种具有重要意义。本研究通过6×7不完全双列杂交设计,对结球甘蓝产量性状的配合力效应和F₁代杂种优势表现进行了分析,并基于SSR标记对13个亲本进行了聚类分析和遗传距离计算。结果表明,亲本880014、739和12119的产量性状一般配合力效应好,可作为优良的亲本材料。产量性状特殊配合力效应值高的组合为15109×01-20、12119×01-20、1602×13127和15109×739;产量性状杂种优势好的组合是1344×99011、1344×739、15109×739和12119×01-20。综上,15109×739和12119×01-20是具有增产潜力的优良组合。在中等遗传距离条件下,杂交组合产量性状特殊配合力好,杂种优势强。     

K,V型杂种小麦优势的研究

利用５（Ａ）×２（Ｒ）两组亲本杂交的１０个杂种及其相应的亲本材料，探讨高产条件下Ｋ、Ｖ型小麦的杂种优势。结果表明：单株产量有很强的杂种优势，７个组合超双亲平均值为７．１１％～２５．１％，其中３个为１５．７％～２５．１％，４个组合超标优势２．４％～１８．１％。Ｋ、Ｖ型杂种优势的主要表现是千粒重的增高，其次是穗粒数，有３个组合超双亲平均值。单株穗数的减少对杂种产量有影响，选择多穗亲本，对提高杂种的穗数有效     

夏大豆产量性状的遗传力和配合力分析

用６个夏大豆品种进行双列杂交试验，估算了主要产量性状的遗传力、配合力效应。结果表明：大豆有效分枝数，每荚粒数，百粒重的狭义遗传力较高，可以进行早代选择；单株数、单株产量的狭义遗传力较低，在中高世代进行选择效果较好。大豆产量性状的加性遗传效应都是主要的，并以单株产量表现较大的特殊配合力效应。新品系８５２１２．８４２４０Ｂ１、７７２４９都是高产育种较理想的亲本材料，尤以品系７７２４９育种的效果最佳。     

杂交粳稻亲本产量性状优异配合力的标记基因型筛选

提高杂交粳稻竞争优势的关键是改良其恢复系产量性状的配合力。为使之更富成效,选用115个SSR引物扩增6个粳稻BT型不育系和12个恢复系的标记基因型,并按NCII遗传设计配制72个F1组合,分析18个亲本的单株日产量、单株有效穗数、每穗总粒数、每穗实粒数、千粒重5个性状的配合力,结合亲本SSR分子标记数据和性状配合力数据筛选了5个性状优异配合力的标记基因型。结果发现20个SSR标记基因型与亲本产量及其构成性状配合力显著相关。其中8个与亲本单个性状配合力相关;6个同时与亲本2个性状配合力相关;4个同时与亲本3个性状配合力相关;2个同时与亲本4个性状配合力相关。同时与多个性状配合力相关的标记基因型,对各性状的作用方向有正有负。RM152-165/170是单株日产量和单株有效穗数优异配合力效应最大的标记基因型,可使F1的相应性状值增加20.6%和12.7%。优异配合力的标记基因型可直接用于粳稻恢复系配合力的分子标记辅助改良。     

食用向日葵产量与籽粒主要性状配合力及遗传分析

选用4份分枝型恢复系和6份雄性不育系材料作亲本,按照不完全双列杂交（NCII）设计配制24份向日葵杂交组合,对组合的小区产量、单株产量、单盘实粒数、百粒重、籽仁率、籽粒长度和籽粒宽度7个性状的亲本配合力、遗传参数及竞争优势进行分析。结果表明,24份组合的7个性状存在真实性的遗传差异。在亲本不育系一般配合力（GCA）选择的基础上,应注意组合特殊配合力（SCA）的选择,GCA效应值高的亲本育种潜力较大,组配出优势组合的概率大;籽粒长度和籽粒宽度的狭义遗传力较低,分别为7.91%和14.89%,不宜进行早代选择;GCA较高的不育系为亲本A和亲本D,其中亲本A在各性状上均为正向GCA效应值,且在供试不育系中,其GCA效应值最大,其次为亲本D;组合1×A小区产量的SCA效应值及竞争优势最高,为本试验中的最优组合,其他籽粒性状与对照相比也均有提升。     

Heterosis and combining ability for grain yield and other agronomic traits in winter triticale

Hybrid breeding is a widely discussed alternative for triticale. Heterosis as well as general (GCA) and specific combining ability (SCA) effects were estimated for eight agronomic traits. The experiment comprised 24 F₁ hybrids, produced by a chemical hybridizing agent, together with their six female and four male parents, grown in drilled plots in two locations. In comparison with the mid‐parent values, hybrids averaged a 6.4 dt/ha (10.1%) higher grain yield, 8.4% more kernels per spike, a 6.8% higher 1000‐kernel weight, 9.7% lower falling number (FN) and 4.4% greater plant height. SCA effects for grain yield were significant and ranged from 4.5 to 6.9 dt/ha for grain yield. Together with GCA x location interactions, they explained most of the variation. For 1000‐kernel weight, GCA effects were predominant. SCA and interactions with location accounted for most of the variation in FN, whereas interactions were negligible for plant height. Correlations between mid‐parent and hybrid performance and between GCA and per se performance of parents were tight for all traits except grain yield, which allows for pre‐selection of parental lines. Although the amount of heterosis in triticale at present is closer to wheat than to rye, by selecting parents for combining ability and identifying heterotic patterns, grain yield heterosis of up to 20% appears sufficiently encouraging to embark on hybrid breeding.     

Hybrid performance and heterosis in spring bread wheat, and their relations to SSR-based genetic distances and coefficients of parentage

Development of hybrids is considered to be a promising avenue to enhance the yield potential of crops. We investigated (i) the amount of heterosis observed in hybrid progeny, (ii) relative importance of general (GCA) versus specific (SCA) combining ability, and (iii) the relationship between heterosis and genetic distance measures in four agronomic traits of spring bread wheat. Eight male and 14 female lines, as well as 112 hybrids produced in a factorial design were grown in replicated trials at two environments in Mexico. Principal coordinate analysis based on Rogers' distance (RD) estimates calculated from 113 SSRs revealed three different groups of parents. Mid-parent heterosis (MPH) for grain yield averaged 0.02 t ha⁻¹ (0.5%) and varied from −15.33% to 14.13%. MPH and hybrid performance (F1P) were higher for intra-group hybrids than for inter-group hybrids, with low values observed in inter-group crosses involving two non-adapted Chinese parents. Combined analyses of variance revealed significant differences among parents and among hybrids. Estimates of GCA variances were more important than SCA variances for all traits. Tight correlations of GCA with line per se performance, and mid-parent value with F1P were observed for all traits. In contrast, correlations of MPH with RD and coefficient of parentage were not significant. It was concluded that the level of heterosis in spring wheat was too low to warrant a commercial exploitation in hybrids. SSRs proved to be a powerful tool for the identification of divergent groups in advanced wheat breeding materials.     

印水型杂交粳稻产量及产量构成因素的配合力分析

为确定新育成印水型杂交粳稻亲本的潜力,并为印水型杂交粳稻育种提供理论基础,本研究以4个不育系和4 个恢复系为亲本进行不完全双列杂交,研究产量及其构成因素的配合力。结果表明：产量性状一般配合力(GCA)方差均达到极显著水平,除结实率外,父本的一般配合力方差大于母本,单株产量、有效穗和结实率的特殊配合力(SCA)方差达到显著或极显著水平。139A和晚轮422 的GCA效应较高,产量性状以Ⅱ类为主,139A×晚轮422 和辽粳10A×晚轮422 的单株产量水平及组合SCA效应较高。父本GCA效应和组合SCA效应对产量性状的影响较大,母本GCA效应对产量性状的影响相对较小。本研究中,父本的遗传差异大于母本,对产量性状的影响也大于母本,139A和晚轮422 有较大的应用潜力。     

Ga糯玉米自交系的配合力分析与评价

摘要：利用不完全双列杂交NCⅡ设计,以3个经遗传改良的Ga糯玉米自交系为父本,与8个糯玉米自交系进行杂交。对24个杂交组合进行农艺性状鉴定,分析Ga糯玉米自交系主要农艺性状的配合力效应。结果表明,父、母本各性状的一般配合力和特殊配合力效应均达极显著差异。Ga糯玉米自交系具有良好的配合力,其中,CM327的一般配合力效应比较高,其组配的杂交种在产量、穗长、行粒数等性状上具有明显优势,具有很好的杂优利用潜力。Ga糯玉米自交系的选育利用,有助于糯玉米种质的扩增与杂种优势的利用。     

Genetic analysis of rapeseed self-incompatibility lines reveals significant heterosis of different patterns for yield and oil content traits

Self‐incompatibility is one of the most effective approaches to utilizing heterosis in oilseed rape around the world. To evaluate the heterosis of double low self‐incompatibility, the possibility of combining seed yield and oil content, and the genetic effects of parents on their hybrid progenies, a 2‐year field trial using a 3 × 22 NC II mating design was conducted during the 1999‐2001 growing seasons in Wuhan, China. Significant differences in seed yield per plant and seed oil content were observed among the F1 hybrids and between F1 progenies and their parents. However, the heterosis for seed yield per plant was much greater than that for seed oil content. Mid‐parent heterosis and high‐parent heterosis of seed yield per plant ranged from 5.50 to 64.11% and from –2.81 to 46.02%, while those of seed oil content ranged from –1.55 to 7.44% and –3.61 to 6.55%, respectively. Non‐additive genetic effects were a major mechanism that accounted for the yield heterosis in addition to additive effects. In contrast, seed oil content heterosis was mainly dependent on an additive genetic effect. General combining ability (GCA) determined the stability of hybrid cultivars. In hybrid breeding, parental materials might be selected by the sum of GCAs and variances of special combining abilities (SCAs) of female and male parents for traits affected by both additive and non‐additive effects, and by the sum of GCAs of two parents for traits controlled mainly by additive effects. Primary branches and their siliques were the most important yield traits.     

Heterosis and combining ability for plant height and its components in hybrid wheat with Triticum timopheevi cytoplasm

The heterosis and combining ability for plant height and its components of hybrid wheat were investigated in an incomplete diallel experiment including 5 CMS lines and 4 restorer lines. The results showed that heterosis (HS) and heterobeltiosis (HBS) occurred in plant height (PH) and length of the first internode (LFI), second internode (LSI), third internode (LTI), basal internode (LBI) and the spike (LS) of hybrids, but their values varied among crosses and characters; the HS and HBS of LBI were larger than those of other characters, the HS and HBS of LSI and LTI contributed a lot to those of PH. There were significant relationships between internode lengths and PH for specific combining ability (SCA) and general combining ability (GCA), and among lengths of the adjacent internodes for SCA and/or GCA effects. However, the relationships of LS with the lengths of internodes and PH were insignificant for GCA, SCA, HS and HBS. The SCA effects were more important than GCA effects for LFI, the reverse was true for LSI, LTI, LS and PH, and the SCA effects was nearly equal to the GCA effects for LBI. So, LFI was mainly influenced by non-additive effect of genes, while LSI, LTI, LS and PH were mainly controlled by additive gene effects, LBI was controlled equally by additive and non-additive effects of genes. The genes that control the length of specific internode not only affect PH, but also the length of the adjacent internode. The genetic system in charge of lengths of internodes and plant height is independent of that for length of spike. Thus, it is possible to develop new wheat cultivars or hybrid combinations having long spike but dwarf plant height. This revised version was published online in July 2006 with corrections to the Cover Date.