花生根瘤菌遗传多样性的RFLP分析

利用16S rRNA PCR-RFLP和16S-23S rRNA IGS PCR-RFLP技术对分离自我国不同地区的55株花生慢生根瘤菌和6株参比菌株进行了遗传多样性研究.16S rRNA PCR-RFLP分析结果表明,在63%的相似性水平上,91%的供试花生幔生根瘤菌与B.japonicum和B.elkanii聚在一起;16S-23S rRNA IGS PCR-RFLP分析结果表明,供试花生慢生根瘤菌具有较丰富的遗传多样性,在65.8%的相似性水平上可分为3大类群.     

花生栽培种(Arachis hypogaea)类型间遗传差异的SSR分析

本文采用110对SSR引物分析28份花生栽培种资源(7份多粒型、5份龙生型、8份普通型和8份珍珠豆型)间的遗传差异,其中有46对引物在不同品种间检测出2～9个等位基因,多态性信息量(PIC)为0.080～0.869.对28份材料的聚类分析表明,SSR聚类结果与根据形态特征的分类结果基本一致,但在多粒型品种上存在一定差异.标记pPGSseq15C12在本研究中所有的珍珠豆型品种上均扩增出特异性条带,序列分析表明该标记在珍珠豆型与其它类型间扩增片段的差异是由于ATT重复次数不同所致.     

Genetic variation vis-à-vis molecular polymorphism in groundnut, Arachis hypogaea L.

Recent studies on the genus Arachis using molecular markers have revealed very little demonstrable polymorphism in the cultivated groundnut, A. hypogaea. This has led to the hasty generalization that the groundnut lacks genetic variation. However, this is in complete contradiction to the results of other lines of investigations into the origin and evolution of A. hypogaea. Further, a characterization of the world collection for various traits also shows significant levels of variation for almost all genetic traits. The literature review in this article suggests that the lack of genetic variation was inferred because of an inadequacy in the material studied, and the range of techniques used to study molecular polymorphism. A comprehensive and rigorous examination of the material available in the groundnut world collection, either by improving current techniques, or by using such advanced techniques as SSRs and AFLP could well reveal polymorphism at the molecular level.     

Association of root, specific leaf area and SPAD chlorophyll meter reading to water use efficiency of peanut under different available soil water

Drought is the major abiotic constraint affecting peanut productivity and quality worldwide. There is a pressing need to improve the water use efficiency (WUE) of rain-fed peanut production. Breeding varieties with higher water use efficiency is seen as providing part of the solution. The objectives of this work were to (i) evaluate genetic variation in WUE, harvest index, root dry weight, specific leaf area (SLA) and SPAD chlorophyll meter reading (SCMR) among peanut genotypes in response to different available soil water levels and (ii) assess the relevance of root dry weight, SLA and SCMR to WUE in peanut under receding soil moisture levels. Two greenhouse experiments were conducted in the dry and rainy seasons in 2002/2003. The 11 peanut genotypes (ICGV 98300, ICGV 98303, ICGV 98305, ICGV 98308, ICGV 98324, ICGV 98330, ICGV 98348, ICGV 98353, Tainan 9, KK 60-3 and Tifton-8) and three soil moisture levels [field capacity (FC), 2/3 available soil water (AW) and 1/3 AW] were laid out in a factorial randomized complete block design (RCBD) with six replications. At 37, 67, and 97 day after sowing (DAS), data were recorded for SLA and SCMR. Root dry weight, harvest index (HI) and WUE were recorded at harvest. Drought reduced WUE, root dry weight and HI. Across both seasons, Tifton-8 and ICGV 98300 had high WUE and also had large root systems under drought conditions. ICGV 98324 and Tifton-8 had low SLA and high SCMR under stressed and non-stressed condition. Under drought conditions, ICGV 98324 had high HI and Tifton-8 had low HI. Root dry weight had a greater contribution to WUE under well-watered and mild drought (2/3 AW). Under severe drought (1/3 AW), SLA showed a more important contribution to WUE than the other traits. Traits that were associated to high WUE under drought conditions were different among different peanut genotypes. ICGV 98300 maintained high root dry weight under 2/3 AW and ICGV 98324 maintained low SLA and high SCMR under 1/3 AW. Tifton-8 had both large root systems and low SLA associated with high WUE.     

中国北方主栽花生品种抗旱性鉴定与评价

人工控水条件下,通过盆栽试验,在花生植株的结荚期和饱果期, 测定29个品种(系)的株高、分枝数、生物累积量、叶片含水量和光合色素含量等与抗旱性有关的13个表型性状和生理生化指标,采用抗旱系数法和隶属函数值法,鉴定各性状指标水分胁迫下的抗旱性。结果表明,相同指标评价不同花生品种抗旱性时得出的结果不同,依此可将供试品种(系)划分为抗旱性强、中、弱和不抗旱4类,即供试品种中唐科8号、冀花2号、冀花4号、花育25、花育17、花育22、大唐油、花育21具有较强的抗旱能力;花育20、花育24、潍花6号、花育27、鲁花11、阜花11、阜花13、唐油4号、丰花1号和G2具有中等抗旱能力;具有较弱抗旱能力的品种(系)有16-8、阜花10号、M5、花育16和鲁花14;而花育19、花育23、丰花6号、潍花8号、M7和TE-2在结荚期和饱果期均无抗旱能力。水分胁迫至结荚期,除分枝数和类胡萝卜素外,其余各形态型状和生理生化指标及其综合D值均可作为鉴定品种(系)抗旱性的依据;水分胁迫至饱果期,只有叶面积与抗旱系数间的相关极显著。无论在结荚期或饱果期,综合D值可作为鉴定品种抗旱性的指标,单一指标均不能准确判定某品种(系)的抗旱性。     

源于大豆EST的花生属（Arachis）同源SSR标记的开发及利用

通过拼接394 370条大豆EST共获得82 614条Uni-EST,其中2 082条包含2 191个SSR位点,平均每22.96 kb EST出现1个SSR。二核苷酸重复在大豆EST-SSR中占比例最大(63.5%),其次是三核苷酸重复(30.9%);AG/CT在SSR基序(motif)中出现频率最高(35.8%),AT/AT (25.4%)次之。2082条SSR-EST共设计引物685对,其中582对在4个大豆品种中得到有效扩增,98对检测出多态性。582对可扩增引物在花生属中的可转移性分析表明,大豆EST-SSR在花生属9大区组间的可转移性有所差异(12.4%~15.7%),匍匐区组最高,大根区组最低,平均为14.2%。79对可转移性同源标记在花生区组中的多态性分析表明,供试SSR有69个在10野生种间检测出多态性,仅5个在22个栽培品种中具多态性。对引物ES-105在大豆和花生区组中的扩增产物测序结果显示,两个大豆品种间仅SSR位点存在3个AT重复差异,其余序列均一致,而大豆与花生区组间的扩增产物在序列上存在较大差异,花生区组除缺失SSR位点外,侧翼序列也存在频密的插入/缺失和置换。研究结果表明,通过大豆EST开发花生属同源SSR标记具可行性。作为有功能的分子标记,大豆EST-SSR在花生区组内多态性丰富,可直接用于大豆-花生比较基因组研究。     

花生蛋白质、脂肪含量及其它农艺性状的配合力和遗传参数分析

三个高蛋白与三个高脂肪品种进行完全双列杂交,研究以籽仁重、蛋白质和脂肪含量为主的15个性状的配合力、遗传相关及杂种优势.结果表明:两种配合力的方差分析F值均达显著标准,但加性效应占主要优势,总配合力与杂种实际表现高度相关.郑71—3是高产高脂肪的理想亲本,奇科可作为高蛋白材料加以利用.在性状间相关中,蛋白与脂肪为显著负相关,但二者与籽仁产量呈弱的正、负相关,有利高产高油分和高产高蛋白品系的选育.花生杂种一代有明显优势,但营养生长性状、结实性状和脂肪含量趋向高亲,而出仁率、百仁重和蛋白含量趋向低亲.     

Genetics of nonnodulation in groundnut (Arachis hypogaea L.). Studies with single and mixed Rhizobium strains

Summary Genetic studies of nonnodulation in groundnut were carried out in a cross, NC 17×PI 259747, with a single Rhizobium strain, NC 92, and a native Rhizobium population.The normal nodulation of the parents, F₁ generations and backcross progenies, and the F₂ segregation for nodulation and nonnodulation confirmed that nonnodulation in groundnut is controlled by two duplicate recessive genes.Approved ICRISAT Journal Article No. 211.     

Interspecific hybridization in the genus Arachis through embryo culture

Summary The embryos of a cultivated tetraploid peanut (Arachis hypogaea), a wild diploid species (A. villosa), and their hybrid embryos, which generally abort in nature, were cultured in vitro and the plants have been successfully transferred to the soil. The hybrids showed triploid chromosome number (3x=30). The significance of wide hybridization in peanut-improvement programs is discussed.     

Evolving gene pools in crop plants

Summary The three gene pool system can be applied usefully to the whole range of crop plants. The primary gene pool (GP1) show varying degrees of fragmentation. No morphological discontinuity is apparent between wild and cultivated Lathyrus sativus but clear discontinuities have developed between conspecific wild and cultivated Phaseolus and Vigna species. Further discontinuities can develop in cultigens where disruptive selection has been practiced, as in Beta vulgaris, Linum usitatissimum and Brassica oleracea where more than one distinct crop has evolved within a single biological species. Each such crop has developed its own distinctive gene pool.