大麦G—带变动性以及与染色粒的一致性分析

以大麦为材料,进行了Ｇ－带带纹变动性分析以及Ｇ－带与减数分裂粗线期染色粒的比较,有丝分裂早中期至中期两个不同时期Ｇ－带带纹总数减少３６％,染色体组的绝对长度缩短２５％。带数减少的幅度大于染色体长度缩短的幅度,染色体组中每条染色体之间带纹减少的比例不尽相同,变幅在０．２９－０．５０之间,不同染色体绝对长度减少的幅度在０．２７－３．７０μ之间,从早中期至中期,每单位染色体绝对长度带数具相对减少的趋势。     

家猪减数分裂粗线期二价体与有丝分裂中期染色体的比较研究

以性成熟公猪睾丸和外周血为材料,采用长低渗、高氯仿卡诺固定液固定和外周血细胞培养制备减数分裂粗线期二价体和有丝分裂中期染色体,通过对二价体和有丝分裂中期染色体分裂指数和长度的比较研究,发现二价体的分裂指数和长度分别是有丝分裂中期染色体的5倍和3．42倍（1．87～5．98）;同时以12号染色体为例,比较了二价体上的染色粒结构带与有丝分裂中期染色体G－带,表明染色粒结构带比中期染色体G－带纹丰富,而与早中期G－带带织吻合。     

节节麦细胞不同分裂时期和阶段的G-带核型及其变动性分析

采用改良的ASG法获得了中期和3个染色体凝缩程度不同的早中期阶段(分别称为早中期Ⅰ、Ⅱ、Ⅲ)染色体的G_带,并进行了G_带核型和变动性分析。所分析的分裂时期和阶段,每条染色体的全长显示出了密切邻近的多重的带纹,带纹细窄、大小较相近,带间区小,带纹分布较密集而均匀。随着有丝分裂进程推进,染色体的带纹数目减少,早中期Ⅰ、Ⅱ、Ⅲ至中期单倍染色体组的G_带带纹总数分别减少41%、36%、28%,而染色体组的绝对长度分别缩短43%、37%、27%,带数减少幅度与染色体长度缩短的幅度几乎相等。早中期Ⅰ至早中期Ⅱ、Ⅲ和早中期Ⅱ至早中期Ⅲ的带纹减少幅度与染色体长度缩短幅度也基本一致。染色体组中各染色体之间带纹减少和染色体缩短的比例不尽相同,有一定的变幅。早中期Ⅰ、Ⅱ、Ⅲ和中期染色体组中每单位绝对长度的带数(带/μm)分别为2.19、2.22、2.32和2.29,差异不大。对节节麦G_带的特性等问题进行了讨论。     

节节麦细胞不同分裂时期和阶段的G—带核型及其变动性分析

采用改良的ASG法获得了中期和3个染色体凝缩程度不同的早中期阶段（分别称为早中期Ⅰ、Ⅱ、Ⅲ）染色体的G-带,并进行了G-带核型和变动性分析。所分析的分裂时期和阶段,每条染色体的全长显示出了密切邻近的多重的带纹,带纹细窄、大小较相近,带间区小,带纹分布较密集而均匀。随着有丝分裂进程推进,染色体的带纹数目减少,早中期Ⅰ、Ⅱ、Ⅲ于中期单倍染色体组的G-带带纹总数分别减少41%、36%、28%,而染色体组的绝对长度分别缩短43%、37%、27%,带数减少幅度与染色体长度缩短的幅度几乎相等。早中期Ⅰ至早中期Ⅱ、Ⅲ和早中期Ⅱ至早中期Ⅲ的带纹减少幅度与染色体长度缩短幅度也基本一致。染色体组中各染色体之间带纹减少和染色体缩短的比例不尽相同,有一定的变幅。早中期Ⅰ、Ⅱ、Ⅲ和中期染色体组中每单位绝对长度的带数（带/μm）分别为2.19、2.22、2.32和2.29,差异不大。对节节麦G-带的特性等问题进行了讨论。     

家猪减数分裂粗线期二价体与有丝分裂中期染色体的比较研究

以性成熟公猪睾丸和外周血为材料,采用长低渗、高氯仿卡诺固定液固定和外周血细胞培养制备减数分裂粗线期二价体和有丝分裂中期染色体,通过对二价体和有丝分裂中期染色体分裂指数和长度的比较研究,发现二价体的分裂指数和长度分别是有丝分裂中期染色体的5倍和3.42倍(1.87～5.98);同时以12号染色体为例, 比较了二价体上的染色粒结构带与有丝分裂中期染色体G-带,表明染色粒结构带比中期染色体G-带带纹丰富,而与早中期G-带带纹吻合。 Abstract:Meiotic pachytene bivalents were obtained from porcine testes using prolonged hypotonic treatment combined with high chloroform Carnory's fixative solution. Mitotic metaphase chromosomes were prepared from blood cell culture. Comparative studies on division index and length of pachytene bivalents and mitosis metaphase chromosomes showed that those of the former are 5 times higher and 3.42(1.87～5.98) times longer than the latter, respectively. Chromomere maps of bivalents are more abundant than mitotic metaphase G-bands, while they are correspondent with mitotic early-metaphase G-bands. The result was found by using the chromosome 12 as a sample.     

四棱豆的核型和G-带带型研究

用改良ＡＳＧ法在四棱角Ｐｓｏｐｈｏｃａｒｐｕｓ ｔｅｔｒａｇｏｎｏｌｏｂｕｓ（Ｌ．）ＤＣ有丝分裂中期,染色体全长显示了密切邻近的多重Ｇ－带带纹,并进行了核型和Ｇ－带带型分析。核型公式为２ｎ＝１８＝４ｍ＋１４ｓｍ（２ＳＡＴ）,核型类型为２Ｂ。Ｇ－带带型分析表明,同源染色体的带纹数目、分布位置、染色深浅基本一致,可以较准确地进行配对;非同源染色体的带型有明显差异,可以准确区分。讨论了改良ＡＳＧ法在核型     

将大赖划种质转移给普通小麦的研究

大赖草比抗病品种“苏麦３号”更抗小麦赤霉病。经离体和活体赤霉病抗生单花滴注鉴定和有丝分裂中期及减数分裂中期Ｉ的Ｃ－分带分析,选育出添加了１对第２染色体的抗赤霉病异附加系,其４４条染色体在ＭＩ配成０．１２－０．４０１＋２１．７０－２１．９３Ⅱ＋０．０１－０．０４Ⅳ。经Ｃ－分带和生物素记的染色体组ＤＮＡ作探针的分子原位杂交分析证实分析证实添加的１对我源染色全在ＭＩ配成二价体,在细胞学上已基本稳定。     

番茄的CPD带型和45S rDNA位点的鉴别

采用CPD（PI和DAPI组合）染色对番茄减数分裂粗线期和有丝分裂中期染色体进行了显带分析,随后用两种不同的45S rDNA克隆在相同的分裂相进行了荧光原位杂交定位分析。CPD染色在8条粗线期染色体上显示出了10条红色的CPD带纹,在6对有丝分裂中期染色体上显示出了12条CPD带纹。有丝分裂中期染色体上的CPD带纹与粗线期染色体上显著的带纹具有对应性。用改良的CPD染色程序清晰而稳定地显示出这些特征性的CPD带纹为番茄的染色体,特别是有丝分裂中期染色体提供了新的识别标记。用番茄的一个45S rDNA克隆进行的荧光原位杂交,不仅在位于2号染色体短臂的随体上显示了强的杂交信号,而且在粗线期染色体的5个CPD带区或有丝分裂中期染色体的4对CPD带区显示了弱的杂交信号。然而,用来自小麦的45S rDNA克隆pTa71进行的原位杂交却只在随体上显示了杂交信号。鉴于所用的两个45S rDNA克隆在序列上的差异,推断在番茄基因组中只有随体含有45S rDNA单位的编码区,即番茄只有一对45S rDNA位点。     

荞麦染色体G—带BrdU—风油精法显带的研究

本文用ＢｒｄＵ风油精法进行了荞麦染色体Ｇ带显带研究,在其有丝分裂晚前期,早中期和中期的染色体上均显示出了Ｇ带带纹。但是,随着分裂时期的进展,染色体上出现的带纹数目依次减少。ＢｒｄＵ和风油精在染色体显带中的作用是使染色体伸长,并增大染色体线性区段间的差异,故显示出Ｇ带。     

将大赖草种质转移给普通小麦的研究：VI.端体异附加系的选育与鉴定

利用根尖细胞有丝分裂中期染色体计数,花粉母细胞减数分裂中期１（ＰＭＣ ＭＩ）染色体构型分析仪及Ｃ－分带,从普通小麦中国春与大赖草（ＬｅｙｍｕｓｒａｃｅｍｏｓｕｓＬａｍ．）杂种回交后代中,选育出两个端二体异附加系９５Ｇ０９,９５Ｇ１１和一个添加了一对大赖草第１４号染色体和另一对端体的双重异附加系９５Ｇ３０２（２ｎ＝４４＋２ｔ）,它们的ＰＭＣ ＭＩ染色体配对构型分别为０．２１个单价体（其中０．１６个端     

Patterns of Inheritance

SYNOPSIS. Every individual living organism on earth developsaccording to the specificationsof its individualized and uniqueDNA that is encoded as its genotype. The genotype consists ofmany genes and is established at the time of the individual'sbirth or separation from itsparent. Although offspring resembleparents, they are rarely if ever genetically identical to them.This result is a function of both the pattern of inheritanceand the organization imposed by the genetic system embodiedin the chromosomes. Genes are not just loose in the nucleus:they are organized into linear arrays on chromosomes. In thediploid, cross-fertilizing genetic system, the parents contributeabout equally to the offspring's genotype through the haploidnucleiof their gametes. In most diploids, vast amounts of geneticvariability are produced by the process of genetic recombination.This alone assures the genetic uniqueness of every individualof the new generation. The ultimate source of the variabilityis the process of gene mutation but the great storage capacityof the diploid system enhances recombinational variability.The powerful sources of recombination are: synapsis and crossing-over,processes that serve to scramble the genes. Independent assortmentat meiosis provides unique gametes; this latter effect is enhancedby high chromosome numbers. Since two parents are involved inthe formation of the individual, still another level of recombinationis achieved at fertilization. Patterns of genetic systems varygreatly from species to species: man, mouse, maize and melanogasterare considered. In a significant number of cases, chromosomenumber reductions, balanced chromosomal aberrations and polyploidyare present and serve to restrict recombination potential. Evengreater restrictions are imposed by the evolution, in naturalpopulations, of patterns of inheritance that partially or evencompletely by-pass recombination. Thus, total dependence onvegetative reproduction, loss of meiosis, self-fertilizationor parthenogenesis are examples. In organisms that have discardedthe attributes that assure recombination, the formation of bothnew species and new adaptations is impaired. This emphasizesthe key importance of the mode of inheritance for activatingprocesses that adjust the genes of living things to their environments.Future studies of patterns of inheritance in relation to theevolution of life on earth are needed.     

Patterns of parapatric speciation

Abstract. Geographic variation may ultimately lead to the splitting of a subdivided population into reproductively isolated units in spite of migration. Here, we consider how the waiting time until the first split and its location depend on different evolutionary factors including mutation, migration, random genetic drift, genetic architecture, and the geometric structure of the habitat. We perform large-scale, individual-based simulations using a simple model of reproductive isolation based on a classical view that reproductive isolation evolves as a by-product of genetic divergence. We show that rapid parapatric speciation on the time scale of a few hundred to a few thousand generations is plausible even when neighboring subpopulations exchange several individuals each generation. Divergent selection for local adaptation is not required for rapid speciation. Our results substantiates the claims that species with smaller range sizes (which are characterized by smaller local densities and reduced dispersal ability) should have higher speciation rates. If mutation rate is small, local abundances are low, or substantial genetic changes are required for reproductive isolation, then central populations should be the place where most splits take place. With high mutation rates, high local densities, or with moderate genetic changes sufficient for reproductive isolation, speciation events are expected to involve mainly peripheral populations.