遗传

Common buckwheat ( F. esculentum ) is an allogamy crop, which is heterogony. There is heterogeneity in the species. To reveal the genetic diversity within cultivar population, In order to explore the sampling strategy that can reveal genetic diversity of buckwheat resources on the molecular level. PCR with intron-splice junction primers and long random primers was employed to reveal the genetic diversity within nine common buckwheat varieties and one tartary buckwheat cultivar population among different individuals. We established the sampling strategy in its genetic diversity study. Then we used the established sampling strategy, and the same PCR markers technique,to analysis the genetic diversity of 86 common buckwheat resources, the main results are as follows

甜荞是花柱异长自交不亲和的异花授粉作物，品种内存在一定的异质性，为了准确揭示甜荞遗传资源的遗传多样性，本研究采用因子分析法对86份甜荞遗传资源农艺性状数据进行分析；采用长随机引物和内含子切接点引物的PCR分子标记技术，对9个甜荞品种和1个苦荞品种不同个体间的遗传多样性进行了分析，建立了甜荞资源遗传多样性研究的取样策略；并利用建立的取样策略，采用PCR标记技术，对这86份甜荞资源的遗传多样性进行了分析，取得如下主要结果

We presumed that the term of Y-linked inheritance cannot confuse with that of sex-limited inheritance, and that though the sex-limited factor and the sex-influenced inheritance gene are both located on autosome with some distance, but they are still different.

对现行的遗传学教材中存在的专业术语同名异义现象进行探研，针对Y连锁遗传、限性遗传、从性遗传、单倍体、多倍性和累加作用等专业术语存在的表达不清，相互矛盾，同名异义等问题，进行分析探讨，并提出Y连锁遗传不能与限性遗传相混淆，限性遗传和从性遗传的基因是位于常染色体上，但二者存在区别。

The thesis also draw several conclusions as follows:(1) Orthogonal experiment design method can be viewed as a special case of genetic algorithm, i. e. a genetic algorithm with a fixed initial population, an oriented-mutation operator and one evolution epoch.(2) In terms of running steps, genetic algorithm is more complex than orthogonal experiment design method.

论文首次对正交试验设计法和遗传算法这两种独立发展起来的方法进行比较研究，提出(1)正交试验设计法是遗传算法的一种特例，即是一种初始种群固定的、只使用定向变异算子的、只进化一代的遗传算法；(2)遗传算法产生的优化解优于正交试验设计法产生的优化解，且遗传算法处理交互作用项的效率高于正交试验设计法；(3)遗传算法的步骤比正交试验设计法复杂，所需的试验次数也要多。

There were three isozyme (AMY1, AMY2 and AMY3) at the locus of amylase in Qinghai Merino, moreover, there were two genotypes of AMY2A and AMY2O at the AMY2. Monomorphism was tested at the locus of AMY in Gansu Alpine Merino. The degree of genetic variability estimated by Nei's expected average heterozygosity for the 6 blood protein loci was relatively higher in Gansu Alpine Merino and in Qinghai Merino than that in others, which indicated that there are higher genetic variations and richer genetic diversity in Alpine Merino.

从6个血液蛋白位点的Nei氏预期平均基因杂合度所估计的群体内的遗传变异以及与本研究其它群体的结果相比来看，甘肃高山细毛羊和青海细毛羊的群体内的遗传变异相对较大，而其它群体内的遗传变异则相对较小，说明高原型细毛羊群体内遗传变异程度较大，遗传多样性较丰富，具有较大的选择潜力，为高原型细毛羊进一步选育提高提供了遗传基础。

Hereditary 遗传的例句: While tallness is evidently a hereditary characteristic, any individual's actual height depends on the interaction between their genes and the environment.

虽然身高是一种明显的遗传特征，但是个体的实际身高则取决于基因和环境的。。。

Hereditary 遗传的例句:While tallness is evidently a hereditary characteristic, any individual's actual height depends on the interaction between their genes and the environment.

虽然身高是一种明显的遗传特征，但是个体的实际身高则取决。。。---点击查看全文

AMOVAresults showed there were 95.99%genetic variance within subpopulations,4.01% genetic variance between subpopulationsfor Schima superba;there were 75.36% genetic variance within subpopulation,24.64%genetic variance between subpopulations for Castanopsis chinensis;there were 89.55%genetic variance within subpopuiations,10.45% genetic variance betweensubpopulations for Cryptocarya chinensis.

AMOVA分析结果表明，荷木有95.99％的遗传变异表现在亚种群内，有4.01％的遗传变异表现在亚种群间，即95.99％的遗传变异是由于个体与个体之间的差异造成的，有4.01％的遗传变异是由于个体在不同的群落造成的；锥栗有75.36％的遗传变异表现在亚种群内，有24.64％的遗传变异表现在亚种群间，即75.36％的遗传变异是由于个体与个体之间的差异造成的，有24.64％的遗传变异是由于个体在不同的群落造成的；厚壳桂有89.55％的遗传变异表现在亚种群内，有10.45％的遗传变异表现在亚种群间，即89.55％的遗传变异是由于个体与个体之间的差异造成的，有10.45％的遗传变异是由于个体在不同的群落造成的。

This course systematically describes the structure and function, transmission, expression and regulation, and evolution of genetic materials, covering basis of cytology for inheritance, molecular basis of genetic materials, Mendel's principles of inheritance, linkage and sex linkage, genemutation, variations in chromosome structure and number, quantitative genetics, inbreeding and heterosis, inheritance of bacteria and viruses, extranuclear inheritance, gene engineering, genomics, gene expression and regulation, developmental genetics, population genetics and evolution.

本课程全面系统地介绍遗传物质的结构与功能、遗传物质的传递、遗传物质的表达与调控、遗传物质的进化等，包括遗传的细胞学基础、遗传物质的分子基础、孟德尔遗传、连锁遗传和性连锁、基因突变、染色体结构变异、染色体数目变异、数量性状的遗传、近亲繁殖和杂种优势、细菌和病毒的遗传、细胞质遗传、基因工程、基因组学、基因表达的调控、遗传与发育、群体遗传与进化。

Furthermore, out of 497 fAFLP markers, 80 special bands were found to be able to distinguish the four groups from each other and may be applied for germplasm characterization and molecular assistant classification of Meretrix clam.4 Molecular classification of two species of Meretrix clam based on fAFLP and ITS sequences4.1 The results of fAFLP maker analysis of S, G and W showed that each group had their own specific loci among which there were 53 special loci in W group, much more than those of S group (14) and G group (21). Among the 53 loci, nine were all dominant loci. These unique loci could be taken as molecular markers to distinguish W from other groups. The genetic similarity indexes and distance matrix between S and G groups were 0.9585 and 0.0424 respectively, but the genetic similarity indexes and distance matrix between W group and S or G group was 0.7939 or 0.7941, and 0.2308 or 0.2305 respectively. The results revealed that significant difference existed between W and S or G groups in molecular genetic structure. The phylogenetic trees by the methods of UPGMA and NJ also indicated that S and G populations were very closely related, while W population was a relatively independent cluster, lying beyond the species which S and G belong to.4.2 The internal transcribed spacer region of the rDNA from S group, G group and W group were PCR amplified and sequenced. The results showed that the size of ITS ranged between 1266-1269bp in W group, while those in G and S groups were 1614bp and 1520bp respectively. The GC content ranged 62.32-62.62% in W group while it was 61.77% in G group. The genetic distances between three populations of W group were 0.001～0.003, but it was 0.110 or 0.147 respectively between W group and G group or S group. Phylogenetic trees by NJ method also showed that G group was very closely related to S group, while W group was a relatively independent cluster.

在457个总扩增位点中找出了53个W的特有位点，远多于S群体(14)和G(21)群体，而且在53个特有位点中有9个出现频率为100%的位点，这些位点可以作为区分其它2个群体的特征性标记；S– G群体特有的位点有112个，其中有4个位点出现频率为100%，可作为S– G群体区别于W群体的特征性标记。S群体和G群体间的遗传相似性系数为0.9585，遗传距离只有0.0424，在NJ和UPGMA法构建的亲缘关系的树状图上均首先聚在一起，说明二者的亲缘关系很近，应属于种内群体间的关系；而W与S和G的遗传相似性系数均较小(0.7939和0.7941)，相对遗传距离很大而且十分相近(0.2308和0.2305)，在亲缘关系树状图上单独分出一支，也表明W与S和G群体间的亲缘关系较远。4.2 ITS序列比较分析通过对白壳文蛤、山东文蛤和广西文蛤的ITS序列扩增电泳、PCR-RFLP分析和ITS序列分析发现，W的ITS序列长度在1266-1269 bp，而S和与G的ITS序列总长度分别为1520 bp和1614 bp；从ITS1和ITS2长度来看，W分别为739-741 bp和316-317 bp，S为895 bp和414 bp，G为987 bp和416 bp；而从ITS碱基组成来看，W的GC含量在62.32-62.62%之间，而G群体为61.77%。W的3个壳色不同群体间的遗传距离仅0.001、0.002和0.003，S与G群体间的遗传距离是0.010，说明W群体内变异很小，而S与G群体间已出现明显的遗传分化，但还均属于种内群体间的遗传变异；而W与G和S的遗传距离分别达到0.110、0.147，两个类群差异显著，已远超出种内群体间的遗传变异。

But significant differences were found in coefficient of variation and broad-sense heritability (H2) of the three characters: CV and H2 of self-pollinated fruiting rate were both greatest, with the variation mainly resulted from inheritance, and high inheritance potential; H2 of fertile flower rate was the least and its variation was less from inheritance; CV of average fruit weight was the least and its inheritance potential is small. Thirdly, the ratios of sweet to bitter kernel of F1 progenies in positive and reverse crosses between Katy and Taianshuixing were 18∶16 and 13∶12, and were both in agreement with a 1∶1 segregation by χ2 test, which demonstrated that the bitter kernel character of Katy was heterozygous.

但3个性状的变异系数和广义遗传力(H2)均差异很大，其中自交坐果率的变异系数(101.5%～139.1%)和广义遗传力(87.1%～91.4%)均较大，表明变异主要来自遗传效应，并且自交坐果率的遗传潜能大；有效花比率的广义遗传力最小(36.8%～49.1%)，表明其遗传效应较小；平均单果重的变异系数最小(24.0%～29.7%)，说明平均单果重的遗传潜能小；（3）凯特与泰安水杏正反交的杂种一代甜仁与苦仁的比例分别为18∶16和13∶12，经χ2检验符合1∶1的分离比例，证明控制凯特杏甜仁与苦仁这对性状的基因位点是杂合的。

genetic effect of radiation：遗传辐射效应 遗传辐射效应

genetic drift 遗传漂变 | genetic effect of radiation 遗传辐射效应 遗传辐射效应 | genetic element 遗传成份

genetic homeostasis：遗传的自动调节,遗传稳态,遗传自由调节

genetic heterogeneity 遗传性异质性,遗传异质性,遗传杂合率 | genetic homeostasis 遗传的自动调节,遗传稳态,遗传自由调节 | genetic homogeneity 遗传纯合率

Mendelian inheritance：孟德尔式遗传

在绘制系谱时,必须使用统一的符号单基因遗传(monogenic inheritance)是指一种遗传性状或遗传病,是由一对等位基因控制的或一对等位基因起主要作用的遗传方式,等位基因基本上按孟德尔规律进行传递,所以这种遗传方式也称为孟德尔式遗传(Mendelian inheritance).

cytoplasmic inheritance：细胞质遗传

136、细胞质遗传(cytoplasmic inheritance): 由细胞质内的基因即细胞质基因所决定的遗传现象和遗传规律叫做,又称染色体外遗传、核外遗传、母体遗传等. 137、母性影响(maternal effect):正反交的结果不同,子代表型受到母本基因型的影响而和母本的表型一样的现象.

mendel's law：孟德尔遗传定律

遗传机制一直是生物学家关注的重大课题,1865年,孟德尔通过豌豆子代遗传性状所显示的规律,提出生物的性状是通过独立的单位即"遗传因子" 一代一代遗传下去的,总结出著名的孟德尔遗传定律(Mendel's Law).

genetic polymorphism：遗传多态

第三节 自然群体中的遗传多态性一,遗传多态性 在自然界, 生物群体中的遗传变异是很普遍的现象, 同一群体中存在的两种或两种以上 变异类型的现象称作遗传多态(genetic polymorphism).一般不同变异型之间不存在中间类型,且遗传方式清楚,

tradition：(遗传)

△遗传(tradition)有两种:一是人的遗传(太十五1~9;西二8),一是使徒的遗传(林十一2原文「我所传给你们的遗传;帖后二15,三6「教训」原文均「遗传」. 人的遗传要排除,使徒的遗传要坚守. 遗传又可以译为传说、传统. 因而我们当继承使徒教会的传说、传统.

autosomal dominant：常染色体显性遗传

所以患者的子女可以接受DNA检查,以便得悉他们会否有发病的危险. 本症的遗传可依据遗传的形式和基因所在的染色体区分. 本症可属於常染色体显性遗传(autosomal dominant)、常染色体隐性遗传(autosomal recessive)、或X连锁遗传(X-linked)

autosomal recessive：常染色体隐性遗传

所以患者的子女可以接受DNA检查,以便得悉他们会否有发病的危险. 本症的遗传可依据遗传的形式和基因所在的染色体区分. 本症可属於常染色体显性遗传(autosomal dominant)、常染色体隐性遗传(autosomal recessive)、或X连锁遗传(X-linked)

hereditation：遗传性的影响 遗传影响 遗传作用

hereditaryxanthomaoftendon 遗传性肌腱黄色瘤 | hereditation 遗传性的影响 遗传影响 遗传作用 | heredity 遗传 遗传特性 遗传性