茶氨酸合成酶基因的SNP挖掘和遗传定位

茶氨酸合成酶(Theanine synthetase,TS)基因是茶树茶氨酸代谢过程中的关键酶基因。本研究以氨基酸含量差异明显的亲本及其杂交所得F_1子代为研究材料,克隆TS基因的c DNA序列,挖掘其SNPs位点,并成功将杂合SNP位点定位在遗传连锁群上。研究结果显示,通过序列比对在亲本间检测到3个SNPs,验证得到1个杂合的位点SNP735。将此位点成功转化为dCAPS标记,该标记在子代中的基因型分离比为1∶1,利用该群体已构建的茶树遗传图谱进行遗传定位,将dCAPS标记定位在连锁群LG03上,相邻标记为TM299和TM517。联合此标记及其相邻标记与游离氨基酸总含量和茶氨酸含量进行统计分析,表明具有显著的相关性。     

玉米自交系微小遗传差异对产量优势的贡献

对3个玉米自交系遗传差异不同的株系自交3代后株系间产量及相互间杂交优势进行分析。结果表明,同一自交系在遗传上存在微小差异的株系,产量水平及其产量构成因素仍然存在一定差异。自交系初始遗传差异越大,后代株系间的产量差异越大;初始单株遗传差异较小的两个玉米自交系昌7-2和郑58具有微小遗传差异株系间杂交组合的超中亲优势分别达到10.55%、4.77%,超高亲优势分别达到3.69%、3.94%。对杂交优势贡献主要来自行粒数,其次是千粒重。通过关联分析找出行粒数相关基因的SNP标记14个(-Log P4),千粒重相关基因的SNP标记3个(-Log P3)。在开放授粉的条件下,株系间微小遗传差异有利于提高亲本和杂交制种产量。     

Investigation and genetic mapping of a Glomerella leaf spot resistance locus in apple

Apple Glomerella leaf spot (GLS) is a severe fungal disease that damages apple leaves during the summer in China. Breeding new apple varieties that are resistant to the disease is considered the best way of controlling GLS. Fine mapping and tightly linked marker are critically essential for the preselection of resistant seedlings. In this study, a population of 207 F₁ individuals derived from a cross between ‘Golden Delicious’ and ‘Fuji’ was used to construct a fine simple sequence repeat (SSR)‐based genetic linkage map. The position of R_gls, a locus responsible for resistance to GLS, was identified on apple linkage group (LG) 15 using SSR markers CH05g05 and CH01d08, which was adapted from a published set of 300 SSR markers that were developed using the bulked segregant analysis (BSA) method. These two SSR markers flanked the gene, and its recombination rate was 8.7% and 23.2%, respectively. A total of 276 newly developed SSR markers around the target region and designed from the genome apple assembly contig of LG15 were screened. Only nine of these were determined to be linked to the R_gls locus. Thus, a total of 11 SSR markers were in linkage with R_gls, and mapped at distances ranging from 0.5 to 33.8 cM. The closest marker to the R_gls locus was S0405127, which showed a genetic distance of approximately 0.5 cM. The first mapping of the gene R_gls was constructed, and the locations of the 11 effective primers in the ‘Golden Delicious’ apple genome sequence were anchored. This result facilitates better understanding of the molecular mechanisms underlying the trait of resistance to GLS and could be used in improving the breeding efficiency of GLS‐resistant apple varieties.     

苹果分子标记及辅助育种研究进展

从基于集群分离分析法、杂交群体、全基因组关联分析和功能基因分子标记4个方面对苹果相关的分子标记及其在辅助育种上的应用进行了综述,为苹果分子标记辅助育种和揭示重要性状的遗传提供依据。     

Breeding for increased grain protein and micronutrient content in wheat: Ten years of the GPC-B1 gene

To provide food and nutrition security for a growing world population, continued improvements in the yield and nutritional quality of agricultural crops will be required. Wheat is an important source of calories, protein and micronutrients and is thus a priority to breed for improvements in these traits. The GRAIN PROTEIN CONTENT-B1 (GPC-B1) gene is a positive regulator of nutrient translocation which increases protein, iron and zinc concentration in the wheat grain. In the ten years since it was cloned, the impacts of GPC-B1 allelic variation on quality and yield traits have been extensively analyzed in diverse genetic backgrounds in field studies spanning forty environments and seven countries. In this review, we compile data from twenty-five studies to summarize the impact of GPC-B1 allelic variation on fifty different traits. Taken together, the results demonstrate that the functional copy of the GPC-B1 gene is associated with consistent positive effects on grain protein, Fe and Zn content with only marginally negative impacts on yield. We conclude that the GPC-B1 gene has the potential to increase nutritional and end use quality in a wide range of modern cultivars and environments and discuss the possibilities for its application in wheat breeding.     

大豆籽粒蛋白质含量相关QTL定位研究进展

籽粒蛋白质含量是大豆品质性状改良的主要目标之一。笔者介绍了大豆遗传图谱的构建与基因组测序发展历程,从基于分离群体的连锁分析和基于自然群体的关联分析两方面阐述了大豆籽粒蛋白质含量QTL定位研究进展,进而讨论了大豆蛋白质含量MAS育种存在的问题,最后展望了大豆蛋白质含量分子遗传改良的研究趋势。以期为大豆高蛋白育种提供参考。     

四川省不同地域的核盘菌遗传多样性分析

 核盘菌(Sclerotinia sclerotiorum)属于世界性分布的植物病原真菌,可以危害油菜等多种经济作物。研究不同地域核盘菌的遗传多样性对了解核盘菌的遗传演化过程和指导病害防控具有重要意义。实验采用序列相关扩增多态性(sequence-related amplified polymorphism,SRAP)标记对四川省17个不同地理来源的66株核盘菌菌株的遗传多样性进行了分析。10对检测引物共获得129个位点,其中123个为多态位点,占95.35%。UPGMA聚类结果显示,在相似性系数为0.7时,66个核盘菌菌株分为5类(Ⅰ、Ⅱ、Ⅲ、Ⅳ、Ⅴ),分别包含60、2、2、1和1个菌株。在相似性系数为0.74时,第Ⅰ类又可分为3个亚类(Ⅰ-1、Ⅰ-2、Ⅰ-3),分别包含21、37和2个菌株。聚类及组成分分析结果显示,四川省各地区的核盘菌菌株具有较高的遗传多样性,但其遗传变异与菌株地理来源无明显相关性。     

香蕉与B基因组相关的SCAR标记研究

香蕉(Musa L.)是由2个二倍体野生种Musa acuminata Colla(AA基因型)和Musa balbisiana Colla(BB基因型)种内或种间杂交进化而来,其B基因组中带有重要的优良基因。利用与香蕉B基因组相关的gypsy-IRAP分子标记,成功开发了一对SCAR引物,适用于鉴定尖叶蕉(AAw)、长梗蕉(BB)、香牙蕉(AAA)、贡蕉(AAcv)、大蕉、粉蕉(ABB)、粉大蕉(ABB)、龙牙蕉(AAB)以及四倍体香蕉(AAAB)等是否含有B基因组。     

Identification of Co-dominant SSR Markers Associated with Genes Controlling α′-and α-subunit-null β-conglycinin Phenotypes in Soybean (Glycine max (L.) Merr.)

Studies have shown that the three subunits of β-conglycinin are the main potential allergens of soybean sensitive patients.And β-conglycinin has adverse effects on nutrition and food processing.So solation and production of lines with lower β-conglycinin content has been the focus of recent soybean breeding projects.Soybean lines with deficiency in one or all subunits of β-conglycinin have been obtained.An effective and rapid system to identify such mutations will facilitate genetic manipulation of the β-conglycinin subunit composition.Here,two segregating F_2 populations were developed from crosses between Cgy-1/cgy-1 (CC),an α′-lacking line (Δα′),and DongNong 47 (DN47),a wild-type (Wt) Chinese soybean cultivar with normal globulin components,and Cgy-2/cgy-2 (CB),an α-lacking line (Δα),and DN47.These populations were used to estimate linkage among the cgy-1 (conferring α′-null) and cgy-2 (α-null) loci and simple sequence repeat (SSR) markers.Seven SSR markers (Sat_038,Satt243,Sat_307,Sat_109,Sat_231,Sat_108 and Sat_190) were determined to co-segregate with cgy-1,and six SSR markers (Satt650,Satt671,Sat_418,Sat_170,Satt292 and Sat_324) co-segregated with cgy-2.Linkage maps being composed of seven SSR markers and cgy-1 locus,and six SSR markers and the cgy-2 locus were then constructed.It assigned that the cgy-1 gene to chromosome 10 at a position between Sat_307 and Sat_231,and the cgy-2 gene to chromosome 20 at a position between Satt650 and Satt671.These markers should enable map-based cloning of the cgy-1 and cgy-2 genes.For different subunit-deficiency types[α′-null,α-null and (α′+α)-null types],the two sets of SSR markers could also detect of polymorphism between three normal cultivars and seven related mutant lines.The identification of these markers is great significance to the molecular marker-assisted breeding of soybean β-conglycinin subunits.     

用全基因组关联分析解析籼稻垩白的遗传基础

利用272份全球籼稻微核心种质的重测序SNP基因型,对海南三亚、广东深圳、浙江杭州和湖北荆州4个地点收集到的垩白粒率和垩白度性状采用TASSEL软件进行全基因组关联分析,解析籼稻垩白的遗传基础和挖掘影响垩白粒率和垩白度的优异等位基因。结果表明,依据SNP数据,可将籼稻微核心种质分成3个亚群。4个地点分别检测到42个和44个与垩白粒率和垩白度显著关联的位点,位于全部12条染色体上。2个性状分别有21个和19个位点在2个以上环境下同时被检测到,这些位点中有12个位点同时影响垩白粒率和垩白度,11个位点附近都有已克隆的水稻品质相关基因。其中,第5染色体3.3~5.3 Mb区间在4个地点都被检测到与垩白粒率显著关联,以杭州点对垩白粒率的贡献最大,优异等位基因载体品种为IRGC121689;第12染色体的17.5~18.0 Mb区间在三亚和杭州都被检测到与垩白度显著关联,以三亚点的垩白度贡献最大,优异等位基因载体品种为IRGC122285。这些位点和品种资源可作水稻外观品质分子改良的重要基因和品种资源。