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。     

烤烟叶数、叶面积的遗传分析

以叶数较少、叶面积较小的烤烟品种丸叶为母本(P1),以叶数较多、叶面积较大的烤烟品种Coker319为父本,构建了6个世代分离群体,利用植物数量性状主基因+多基因混合遗传模型的联合分离分析方法,分析烤烟杂交组合丸叶×Co-ker319叶数、叶面积的遗传效应。结果表明:烤烟的叶数和叶面积均受2对加性-显性-上位性主基因+加性-显性-上位性多基因(E0)控制,其中叶数遗传以加性效应及显性×显性上位性效应为主,叶面积几种遗传效应差不多,其上位性效应>加性效应>显性效应,叶数和叶面积在B1世代的主基因遗传率分别为36.91%和2.13%,多基因遗传率分别为31.00%和19.53%,B2世代的主基因遗传率分别为51.60%和50.92%,多基因遗传率分别为16.84%和13.26%,F2世代的主基因遗传率分别为42.63%和30.32%,多基因遗传率分别为42.08%和12.18%,叶数和叶面积的主基因遗传率较高,适合在早代选择。     

黄瓜抗黑星病不同基因源的遗传分析

基于苗期人工接种鉴定结果,获得2份抗黑星病黄瓜材料(HX1,Cucumis sativus var.sativus,DI=5;HX5,C.sativusvar.xishuangbannesis,DI=38.7)和1份感病材料(HX8,C.sativus var.sativus,DI=80)。利用上述3份材料构建了2个组合(HX1×HX8,HX5×HX8)的6世代群体(P1、P2、F1、F2、B1和B2),并分别进行黑星病苗期人工接种鉴定。采用主基因+多基因联合遗传分析方法进行遗传分析,结果表明2份材料抗黑星病的遗传规律不同。组合HX1×HX8的F1单株表现为抗病,而组合HX5×HX8的F1单株基本表现为感病。HX1对黑星病的抗性符合两对加性-显性-上位性主基因+加性-显性多基因混合遗传模型(E_1模型),HX5的抗性遗传符合加性-显性多基因模型(C模型)。在组合HX1×HX8中,两对主基因的加性效应均大于显性效应,B1、B2和F2群体的主基因遗传率分别为72.51%、98.19%和96.91%,多基因遗传率均为0,表明HX1对黑星病的抗性以主基因遗传为主;HX5对黑星病的抗性遗传以多基因的显性效应为主。     

大白菜抽薹性状的主基因＋多基因遗传分析

以大白菜易抽薹自交系06S1703和耐抽薹自交系06J32形成的P1、P2、F1、F2、B1和B2等6个世代为材料,应用主基因+多基因多世代联合分析方法,对大白菜抽薹性状进行了研究.结果表明,大白菜的抽薹性受2对加性-显性-上位性主基因+加性-显性-上位性多基因控制,其中2对主基因的加性效应值分别为-3.575 8和-13.619,显性效应值分别为-3.755 2和-2.257 7.B1、B2和F2世代的主基因遗传率分别为87.95%、95.13%和96.25%,只在B1群体中检测到多基因效应,遗传率仅为1.39%,说明大白菜的抽薹性是以主基因遗传为主,可以进行早期选择.     

陕北黄芥芥酸含量的主基因+多基因遗传分析

以吴旗黄芥×长安芥菜组合的6个世代P1、P2、F1、B1、B2和F2群体为材料,利用植物数量性状主基因+多基因模型的多世代联合分析方法研究了该组合芥酸含量的遗传特征.结果表明:吴旗黄芥×长安芥菜组合芥酸含量受2对加性-显性-上位性主基因+加性-显性-上位性多基因(E模型)控制.主基因效应中,加性效应大于显性效应,第一对主基因加性效应(da)和显性效应(ha)分别为-4.718 0和4.419 5;第二对主基因的加性效应(db)和显性效应(hb)分别-4.005 8和2.023 7;2对主基因对芥酸含量的贡献差异较大,第二对主基因加性和显性效应之和占第一对主基因加性和显性效应之和的65.98%;2对主基因间存在一定的互作效应(绝对值在0.338 7～3.694 1),其中第一对主基因显性×第二对主基因加性效应(jba)较大,为3.694 1.B1、B2和F2群体芥酸含量主基因遗传率分别为68.83%、44.76%和87.99%;多基因遗传率分别为20.29%、41.21%和0,F2代表现出较高的遗传力,可在早期世代对芥酸含量进行选择.     

萝卜不同抗源对黑腐病抗性的遗传分析

不同抗病基因的挖掘是作物持久抗性遗传改良的基础。本研究利用2份抗黑腐病(Xanthamonas campestris pv.campestris)萝卜(Raphanus sativus L.)材料(KB10Q-22、KB10Q-24)和1份感病材料(KB10Q-33)构建了2个F2群体,采用苗期剪叶+喷雾法接种黑腐病菌Xcc8004进行抗病性鉴定。应用P1、P2、F1、F24个世代的数量性状主基因+多基因混合遗传分析方法,研究了萝卜2个不同抗源抗黑腐病的遗传规律,结果表明2份材料的遗传规律不同。以KB10Q-22为母本的F1植株表现为抗病,其遗传模型为E_0模型,即2对加性-显性-上位性主基因+加性-显性-上位性多基因模型;而以KB10Q-24为母本的F1植株表现为感病,其遗传模型为D_0模型,即1对加性-显性主基因+加性-显性-上位性多基因模型。两群体主基因遗传率分别为87.73%和55.64%,抗性遗传以主基因为主。     

烤烟不同生育时期产量性状的遗传效应分析

以烤烟高产品种竖把老母鸡和台烟7号与低产品种TI245配制成2个杂交组合,分别获得6个世代植株(P1、P2、F1、F2、B1、B2),运用主基因+多基因混合遗传多世代联合法对2个组合不同生育时期的产量性状进行遗传分析。研究结果表明,2个组合的产量性状在性状建成中发挥调控作用的基因数目与基因效应存在发育阶段性差异。基因加性效应与显性效应存在于整个发育过程中,且效应程度在不同生育时期存在明显差异,同时加性×加性、显性×显性互作效应在产量性状的发育过程中呈间断性表达。基因遗传力在不同生育时期存在差异,现蕾期产量性状的表型变异受基因遗传效应的决定作用高于其他2个生育时期,受环境因素影响小,且不同组合间的基因效应也存在显著差异,组合Ⅱ的遗传效应明显高于组合Ⅰ。不同组合的烤烟产量性状在不同生育时期主基因+多基因遗传效应差异显著,受环境影响程度不同,因此在育种工作中既要考虑基因效应,又要注意环境影响。     

白菜叶裂数性状主基因+多基因遗传分析

以叶片全缘的大白菜自交系(P1)和叶缘深裂的欧洲白菜型油菜自交系(P2)杂交所获得的6个基本世代(P1、P2、F1、B1、B2、F2)为材料,应用主基因+多基因混合遗传模型对白菜叶裂数进行遗传分析。结果表明,白菜的叶裂数受2对加性-显性-上位性主基因+加性-显性多基因的控制,第1对主基因加性效应为-1.154 7,显性效应为-1.516 8;第2对主基因的加性效应为-1.154 8,显性效应为1.034 9;多基因加性效应为0.591 9,显性效应为1.145 2,2对主基因间存在明显的交互作用。B1、B2和F2世代叶裂数的主基因遗传率分别为88.48%、90.40%、93.03%;多基因遗传率分别为4.114%、0、0。B1、B2、F2世代叶裂数表现出较高的主基因遗传率,受环境影响较小。在白菜叶裂数性状的改良中应以主基因为主,并适于早代选择。     

野生甜瓜'云甜-930'对白粉病抗性的遗传分析

以经过多代自交选育的高抗白粉病材料野生甜瓜'云甜-930'(P1)与感病栽培甜瓜'华莱士'(P2)组配,构建了P1、P2、F1、B1、B2和F2 6个世代,对大棚栽培条件下各世代材料的白粉病自然发病状况进行考察,用植物数量性状主基因+多基因混合遗传模型的多世代联合分析法,研究野生甜瓜'云甜-930'对白粉病的抗性遗传规律.结果显示:野生甜瓜'云甜-930'对白粉病的抗性遗传符合2对加性-显性-上位性主基因+加性-显性-上位性多基因混合遗传模型(E-0),2对主基因的加性效应相等,da和db均为-15.76,2对主基因的显性效应ha和hb分别为14.98和19.87,第2对主基因的显性效应大于第1对;2对主基因互作效应中除了显性×显性效应(l=-7.73)较小外,其它互作效应均较大,加性×加性效应i为31.46,加性×显性效应jab为-26.86,而显性×加性效应jba为-17.07.该组合的B1、B2和F2群体抗病性主基因遗传率分别为73.31%、69.15%和97.61%,多基因遗传率分别为18.83%、25.86%和0,环境变异在2.39%～7.86%之间.研究表明,野生甜瓜'云甜-930'对白粉病的抗性受2对加性-显性-上位性主基因+加性-显性-上位性多基因控制,同时还受到环境的影响.在甜瓜抗白粉病育种中,在F2代主基因的选择效率最高.     

雌雄同株黄瓜单性结实性主基因+多基因混合遗传分析

以雌雄同株黄瓜强单性结实自交系'6457'和非单性结实自交系'6426'为亲本,建立了5世代联合群体(P1、P2、F1、F2、F2∶3),采用植物数量性状主基因+多基因混合遗传模型对群体的单性结实性进行多世代联合分析.结果表明:雌雄同株黄瓜单性结实性表现为不完全显性遗传,符合D-2遗传模型,受1对加性主基因+加性-显性多基因控制.主基因加性效应值为14.7,多基因加性效应值为20.9,多基因显性效应值为25.8.F2的遗传率为56.6%,F2∶3的遗传率为48.7%.因此,对雌雄同株黄瓜单性结实性的遗传改良,可选择强单性结实性材料,通过杂交、回交转移主基因,达到选育强单性结实性材料目的.     

Recent advances in the study of Kaposi's sarcoma-associated herpesvirus replication and pathogenesis

It has now been over twenty years since a novel herpesviral genome was identified in Kaposi's sarcoma biopsies. Since then, the cumulative research effort by molecular biologists, virologists, clinicians, and epidemiologists alike has led to the extensive characterization of this tumor virus, Kaposi's sarcoma-associated herpesvirus(KSHV; also known as human herpesvirus 8(HHV-8)), and its associated diseases. Here we review the current knowledge of KSHV biology and pathogenesis, with a particular emphasis on new and exciting advances in the field of epigenetics. We also discuss the development and practicality of various cell culture and animal model systems to study KSHV replication and pathogenesis.     

The structure, reproduction and taxonomy of Vidalia and Osmundaria (Rhodophyta, Rhodomelaceae)

Comprises species occurring mostly in subtidal habitats in tropical, subtropical and warm-temperate areas of the world. An analysis of the type species, V. spiralis (Sonder) Lamouroux ex J. Agardh, a species from Australia, establishes basic characters for distinguishing species in the genus. These characters are (1) branching patterns of thalli, (2) flat blades that may be spiralled on their axis, (3) width of the blade, (4) primary or secondary derivation of sterile and fertile branchlets and (5) position of sterile and fertile branchlets on the thalli. Application of the latter two characters provides an important basic method for separation of species into three major groups. Osmundaria , a genus known only in southern Australia, was studied in relation to Vidalia , and its separation from the Vidalia assemblage is not accepted. Species of Vidalia therefore are transferred to the older genus name, Osmundaria. Two new species, Osmundaria papenfussii and Osmundaria oliveae are described from Natal. Confusion in the usage of the epithet, Vidalia fimbriala Brown ex Turner has been clarified, and Vidalia gregaria Falkenberg, described as an epiphyte on Osmundaria pro/ifera Lamouroux, is revealed to be young branches of the host, Osmundaria prolifera.     

New or rare chromosome counts in Artemisia L. (Asteraceae, Anthemideae) and related genera from Kazakhstan

Fifteen chromosome counts of six Artemisia taxa and one species of each of the genera Brachanthemum, Hippolytia, Kaschgaria, Lepidolopsis and Turaniphytum are reported from Kazakhstan. Three of them are new reports, two are not consistent with previous counts and the remainder are confirmations of very scarce (one to four) earlier records. All the populations studied have the same basic chromosome number, x = 9, with ploidy levels ranging from 2x to 6x. Some correlations between ploidy level, morphological characters and distribution are noted.     

肝癌中HBV和HCV基因和抗原的分布及意义

采用原位分子杂交方法检测HCV RNA及HBV X基因;采用免疫组织化学方法研究HCV核心抗原,非结构区C33c抗原及HBxAg在肝细胞肝癌中的定位及分布.结果表明(1)HCV RNA、HBV X基因在肝细胞肝癌组织检出率分别为40%(55/136)和82%(112/136).HCV RNA定位于癌细胞的胞浆内,阳性细胞呈散在、灶状及弥漫分布三种形式;HBV X基因在肝癌细胞中的分布呈胞浆型、核型及核浆型,阳性细胞也呈上述三种分布形式;(2)HCV C33c抗原、核心抗原在肝细胞肝癌中的阳性率为81%(133/164)及86%(141/164).C33c抗原定位于癌细胞及肝细胞的胞浆内;核心抗原既定位于癌细胞核中,又可定位于胞浆中.C33c抗原阳性细胞以灶状分布为主;而核心抗原阳性细     

Selection with two alleles and complete dominance

For a plant selection model with frequency-independent viabilities, fertilities and selfing rates, it is shown that apart from global fixation, for certain parameter combinations a protected polymorphism and facultative fixation (either allele may become fixed according to initial frequencies) may both occur. Facultative fixation requires different selling rates for the dominant and recessive type. Protection of the polymorphism requires resource allocation for male and female function. In this connection the problem of purely genetically caused population extinction is discussed.
For general frequency dependence and regular segregation, the chances for establishment of a completely recessive gene are compared to those of a completely dominant gene. It is proven that the process of establishment of the recessive gene, despite a fitness advantage, may be considerably endangered by drift effects if random mating prevails. The recessive gene may reach the same effectivity in establishment as a dominant gene, only if the recessive homozygote mates exclusively with its own type during the period of establishment.