棉花高品质纤维性状的主基因与多基因遗传分析

利用主基因与多基因混合遗传模型联合分析方法 ,通过纤维强度不同的 5个亲本配制的 8个组合 ,研究了棉花主要纤维品质性状的遗传。联合分析发现 ,在不同性状不同组配方式的 14个组合中 ,有 12个存在主基因 ,表明了纤维性状主基因存在的普遍性 ,以F2∶3 家系的预测效果最好 ;双亲纤维品质性状均存在较大差异的组合——— 72 35×TM1F2 代强度主基因的遗传率为 0 .196 ,麦克隆值为 0 .32 0 ,长度为 0 .139,回交世代的主基因遗传率小。除纤维长度总的显性效应为较高的正值外 ,其余各纤维性状的主基因显性与多基因显性的总和为负值或接近 0 ,杂合状态下大多数纤维品质性状表型值会偏向中亲值或低亲值 ,单纯依靠表型选择效率低。因此 ,很有必要对棉花品质性状进行分子标记辅助育种选择     

龙生型高油酸花生种质油酸亚油酸含量及其比值的遗传分析

应用植物数量性状主基因+多基因混合遗传模型,对2个龙生型花生高油酸种质与低油酸珍珠豆型品种杂交组合F2的油酸、亚油酸含量及其比值(O/L值)进行遗传分析,结果表明:花生油酸、亚油酸含量的遗传均表现为1对主基因加性-显性模型。控制油酸含量主基因的加性、显性效应值和遗传率在组合I中分别为8.6281、-2.0164和65.26%,在组合II中则分别为10.6638、1.0652和71.39%;控制亚油酸含量主基因的加性、显性效应值和遗传率在组合I中分别为8.0327、1.2858和73.64%,在组合II中则分别为9.0885、-1.0826和71.59%。O/L值的遗传表现为2对主基因加性-显性-上位性模型。2对主基因的加性效应值分别为0.6855、0.6814(组合I)和1.6842、0.8835(组合II),显性效应值分别为-0.6838、0.024(组合I)和-1.6559、-0.5127(组合II);加性×加性效应(i)、加性×显性效应(jab)、显性×加性效应(jba)、显性×显性效应(l)分别为0.6812、0.024、-0.6803、-0.0244(组合I)和0.8822、-0.5124、-0.8594、0.496(组合II);组合I、II主基因遗传率分别为82.57%和88.64%。     

普通丝瓜始雌花节位遗传分析

选用始雌花节位有差异的普通丝瓜品种配制‘五叶香丝瓜’ב短圆筒丝瓜’(L1×L2)和‘短圆筒丝瓜’ב蛇形丝瓜’(L2×L3)2套组合,通过调查P1、P2、F1、B1、B2和F2植株的始雌花节位,利用主基因 多基因混合遗传模型联合分离分析了始雌花节位遗传规律。结果显示:L1×L2始雌花节位遗传符合2对加性-显性-上位性主基因 加性-显性多基因遗传模型,L2×L3的遗传符合1对加性主基因 加性-显性多基因遗传模型;L1×L2组合的B1、B2和F2群体遗传率(主基因 多基因)分别为66.13%、51.29%和68.27%,L2×L3组合的B1、B2和F2群体遗传率(主基因 多基因)分别为82.02%、64.87%和65.62%;L1×L2组合B1、B2和F2群体的环境方差占总表型方差的比例分别是23.43%、48.69%和31.73%,L2×L3组合B1、B2和F2群体的环境方差占总表型方差的比例分别是34.27%、55.40%和34.38%。结果表明:普通丝瓜始雌花节位是由主基因和多基因控制的数量性状,早熟性(较低的始雌花节位)不太可能通过杂种优势来实现;始雌花节位遗传不稳定,易受环境因素的影响,但定向选择会有较好的效果。     

烟草白粉病抗性基因的遗传分析

以烟草抗白粉病品种台烟7号为母本,感病品种NC89为父本,构建6个世代的群体,利用主基因 多基因混合遗传模型的分离分析方法,研究烟草白粉病的抗性遗传规律。结果表明,烟草白粉病抗性的遗传是由两对加性-显性-上位性主基因 加性-显性-上位性多基因（E-0模型）控制的。B1、B2和F2世代主基因的遗传率分别为88.05%、32.62%、84.43%,主基因遗传率很大,说明可以在抗病育种早期进行选择;B1、F2世代多基因遗传率均为0.00%,说明烟草白粉病的发生受一定环境影响。     

甘蓝型油菜含油量的主基因+多基因遗传效应分析

应用多世代联合分析数量性状主基因和多基因混合遗传的统计方法,分析了甘蓝型油菜两个组合的5个世代——亲本P1、P2、F1、F2和F2：3家系材料含油量的遗传效应。结果表明,分离世代F2及F2：3家系含油量次数分布均呈混合的正态分布,符合主基因＋多基因的遗传特征。D-2模型是该项研究两个甘蓝型油菜杂交组合含油量的最适遗传模型,含油量的遗传是由一对加性主基因和加-显性多基因共同控制的。组合1（1141Bx垦C1-1）主基因加性效应值为-1．74,表明亲本1141B中主基因位点上的等位基因降低含油量,而亲本垦C1-1中的等位基因增加含油量。多基因加性效应值和显性效应值分别为1．20和-1．93;F2的主基因遗传力和多基因遗传力分别为68．21％和27．17％;F2：3的主基因遗传力和多基因遗传力分别为81．70％和16．80％。组合2（32Bx垦C1-2）主基因加性效应值为-3．74,表明亲本32B中主基因位点上的等位基因降低含油量,而亲本垦C1-2中的等位基因增加含油量。多基因加性效应值和显性效应值分别为-1．99和0．93;F2的主基因遗传力和多基因遗传力分别为66．20％,和28．10％;F2：3的主基因遗传力和多基因遗传力为81．00％和14．90％。两组合在F2：3家系世代含油量的主基因遗传力均较F2高,因此认为高含油量育种中在F2：3家系进行选择效率较高。     

辣椒株高遗传分析

以辣椒矮秆自交系B9431（P1）和高秆自交系‘吉林长椒’（P2）为双亲,构建P1、F1、P1、B1、B2和F2 6个家系世代群体,应用植物数量性状主基因＋多基因混合遗传模型对该6个世代群体株高进行多世代联合分析,结果显示：株高遗传符合1对主基因＋多基因遗传模型,高秆对矮秆表现为不完全显性,F1代株高的势能比值为0．39,显性程度为0．91。B1、B2和F2群体主基因遗传率分别为20．35％、17．20％和35．29％,多基因遗传率分别为5．08％、19．75％和0;主基因效应表现为负向加性效应,其值为-6．43,显性效应为0;多基因加性效应值和显性效应值分别为-8．89和9．77。研究还表明,主基因与多基因间的基因效应存在一定差异,主基因加性效应值相当于多基因加性效应值的72．33％,主基因无显性效应,显性效应是由多基因控制遗传。     

光温敏雄性不育水稻不育临界温度性状的遗传分析

光温敏不育系不育临界温度性状的稳定非常困难,其根本原因在于对这一性状的遗传模式缺乏了解。从粳型光敏不育系N5088S中分离出仅存在临界温度差异的H5088S株系,以两者为亲本,构建了包括正反交、回交及F2分离群体在内的7世代群体。将每粒谷苗一分为四而形成基因型构成相同的4套材料,每套材料进行不同温度处理,以花粉育性为指标采用IECM算法进行遗传分析。结果表明：四种温度条件下,正、反交F1育性差异不明显,表现低临界温度特性;F2在不同温度下育性分离比例不同,23.5℃处理下低临界温度对高临界温度为显性;不育临界温度符合两对主效基因和微效基因共同作用的混合遗传模型,主效基因的遗传力为80％-97％。     

黄瓜雄花性状的遗传分析

为了解黄瓜雄花花器的遗传特性,该研究以雄花器官较小的华南型黄瓜二早子为母本,花器较大的加工型黄瓜NC-76为父本,构建4世代遗传群体,并采用多世代联合分离分析方法,分析黄瓜雄花花器性状的遗传特性。结果表明:分离群体的雄花花梗和花冠长2个性状均表现为单峰分布,表明两性状为数量性状且有主基因控制;花梗长性状符合2对完全显性主基因+加性-显性多基因(E-5)模型,花冠长性状符合2对加性-显性-上位性主基因+加性-显性-上位性多基因(E-1)模型;控制花梗长性状的两对主基因的加性效应相等,为0.573,多基因的加性效应和显性效应值相差不大,且均为负向;控制花冠长度性状的2对主基因的加性效应均为0,显性效应分别为-0.226和-0.472,在上位性作用中以加性×加性和显性×显性互作为主,多基因以显性效应为主,正向显性效应值为0.613,大于负向的加性效应值。花梗和花冠长度两个性状在F2群体中主基因遗传率分别为61.04%和69.60%,多基因遗传率均为0。由此看出黄瓜雄花花器性状为数量遗传,遗传率相对较高。该研究结果显示在黄瓜杂交育种中对花器大小选择可以在较早世代选择。     

植物数量性状遗传体系的分离分析方法研究

在传统的数量性状多基因遗传模型基础上提出主基因-多基因遗传模型具普遍性,纯主基因或纯多基因遗传模型只是其特例。由此初步建立了植物数量性状遗传体系分离分析方法。目前该方法可以检验2～3个主基因的个别遗传效应、多基因整体的遗传效应和两者的遗传率。本文介绍这种分离分析方法的研究经过、主要进展及应用效果,并以实例说明其分析步骤、方法和效果。     

辣椒开花期的主基因+多基因遗传分析

应用植物数量性状主基因+多基困混合遗传模型对早熟辣椒‘E100’与‘L101’杂交组合多个世代群体开花期进行了联合分析.结果表明:开花期由两对加性-显性-上位性主基因+加性-显性-上位性多基因的控制;主基因遗传率在B1、B2和F2世代分别为55.27%、53.83%和76.05%;B1、B2和F2世代多基因遗传率分别为34.13%、42.78%和16.94%.     

食用调和油中花生油含量的近红外光谱分析

采用偏最小二乘法(PLS)等方法建立了食用调和油中花生油含量定量分析的近红外光谱定标模型。采集食用调和油样品在4 000 cm-1~10 000 cm-1范围内的近红外漫反射光谱,光谱经一阶导数处理后,采用偏最小二乘法建立样品中花生油含量的定标模型,并用Leave-one-out内部交叉验证法对模型进行验证。模型相关系数为0.99961,校正均方根RMSEC为0.830%。比较不同光谱预处理方法对定标模型的影响,结果表明一阶导数Corr.coeff最好。采用不同的化学计量学方法建立的定标模型中以偏最小二乘回归法最理想。     

大豆品种资源子粒中磷含量差异研究

以239份大豆品种资源为试材,研究其子粒中全磷和无机磷含量的差异表现,分析大豆子粒中磷含量水平,并筛选高全磷、高无机磷资源材料。研究结果表明,供试239份大豆品种子粒中的全磷、无机磷含量存在极显著差异;其分布范围分别为全磷6．24～9．56g／kg,无机磷0．12～0．37g／kg;平均含量分别为7．78g／kg,0．20g／kg;无机磷与全磷含量的比值为1．39％～4．94％,平均为2．56％。同时,筛选出子粒中高全磷、高无机磷含量的大豆品种各5个,其中品种洋黄豆、高家营黑豆、绿75、郭柳条青、大毛角为高全磷材料;品种8012混-1、黄豆、白露快、平顶黄、黑大粒为高无机磷材料;     

Physiology of Oil Seeds: II. Dormancy Release in Virginia-type Peanut Seeds by Plant Growth Regulators

Germination, ethylene production, and carbon dioxide production by dormant Virginia-type peanuts were determined during treatments with plant growth regulators. Kinetin, benzylaminopurine, and 2-chloroethylphosphonic acid induced extensive germination above the water controls. Benzylaminopurine and 2-chloroethylphosphonic acid increased the germination of the more dormant basal seeds to a larger extent above the controls than the less dormant apical seeds. Coumarin induced a slight stimulation of germination while abscisic acid, 2,4-dichlorophenoxyacetic acid, and succinic acid 2,2-dimethylhydrazide did not stimulate germination above the controls. In addition to stimulating germination, the cytokinins also stimulated ethylene production by the seeds. In the case of benzylaminopurine, where the more dormant basal seeds were stimulated to germinate above the control to a larger extent than the less dormant apical seeds, correspondingly more ethylene production was induced in the basal seeds. However, the opposite was true of kinetin for both germination and ethylene production. When germination was extensively stimulated by the cytokinins, maximal ethylene and carbon dioxide evolution occurred at 24 and 72 hours, respectively. Abscisic acid inhibited ethylene production and germinaton of the seeds while carbon dioxide evolution was comparatively high. The crucial physiological event for germination of dormant peanut seeds was enhancement of ethylene production by the seeds.     

Changes of Endogenous ABA Content in Relevance to the Vigor of Peanut Seeds

During the development of peanut (Arachis hypogaea L. ) seed, the endogenous ABA content increased steadily'in hypocotyl, increased to a peak at 40 d after pegging with a drastic decline afterwards in testa; and in cotyledon, increased to a peak at 60 d after pegging but with a slight fall afterwards. There seemed to be a close relationship between the increose of vigor index and net loss of endogenous ABA content in the peanut seed germinating in vitro. Osmoticum (mannitol) promoted the endogenous ABA in the cotyledon and hypocotyl. and Fluridone inhibited that in the cotyledon. There were two different paths of the endogenous ABA synthesis in peanut seed, C40 in the cotyledon and C15 in the hypocotyl. When peanut seeds were put in the conditions of precocious maturation or germination tine endogenous ABA content fell down. Result from this experiment concluded that the hypocotyls played an important role in the transition from development to germination of. peanut seed.     

激光辐照花生种子的细胞学效应

本试验考察了用Ar (488 nm)激光辐照对花生种子胚轴细胞形态结构以及根尖细胞染色体的影响。研究结果表明:在辐照功率密度为5.12 W/cm2,时间为10 s、25 s、55 s情况下,胚轴细胞均有不同程度的损伤;且均能诱发根尖细胞染色体畸变。处理时间延长,细胞破坏加剧,主要表现在细胞中膜系统、脂体、蛋白体和细胞核,出现了异形、合并或结构混乱等现象。染色体畸变类型也随之增加。各激光处理剂量均对花生种子萌发产生抑制作用。     

Ditylenchus destructor in Hulls and Seeds of Peanut

The potato rot nematode, Ditylenchus destructor Thorne, is reported for the first time in hulls and seeds of peanut. The populations found differed from D. dipsaei and D. myceliophagus in habitat, number of lateral incisures, shape of tail tip, and length of postvulval sac. Infected hulls had brown necrotic tissue at the point of connection with the peg, and a black discoloration appeared first along the longitudinal veins. Infected seeds were usually shrunken, and testae and embryos had a yellow to brown or black discoloration. Of 877 seed samples graded "damaged" from all major peanut producing areas of South Africa, 73% were infected.     

Physiology of Oil Seeds: IV. Role of Endogenous Ethylene and Inhibitory Regulators during Natural and Induced Afterripening of Dormant Virginia-type Peanut Seeds

To further elucidate the regulation of dormancy release, we followed the natural afterripening of Virginia-type peanut (Arachis hypogaea L.) seeds from about the 5th to 40th week after harvest. Seeds were kept at low temperature (3 ± 2 C) until just prior to testing for germination, ethylene production, and internal ethylene concentration. Germination tended to fluctuate but did not increase significantly during the first 30 weeks; internal ethylene concentrations and ethylene production remained comparatively low during this time. When the seeds were placed at room temperature during the 30th to 40th weeks after harvest, there was a large increase in germination, 49% and 47% for apical and basal seeds, respectively. The data confirm our previous suggestion that production rates of 2.0 to 3.0 nanoliters per gram fresh weight per hour are necessary to provide internal ethylene concentrations at activation levels which cause a substantial increase of germination. Activation levels internally must be more than 0.4 microliter per liter and 0.9 microliter per liter for some apical and basal seeds, respectively, since dormant-imbibed seeds containing these concentrations did not germinate. Abscisic acid inhibited germination and ethylene production of afterripened seeds. Kinetin reversed the effects of ABA and this was correlated with its ability to stimulate ethylene production by the seeds. Ethylene also reversed the effects of abscisic acid. Carbon dioxide did not compete with ethylene action in this system. The data indicate that ethylene and an inhibitor, possibly abscisic acid, interact to control dormant peanut seed germination. The inability of CO₂ to inhibit competitively the action of ethylene on dormancy release, as it does other ethylene effects, suggests that the primary site of action of ethylene in peanut seeds is different from the site for other plant responses to ethylene.