适应性演化的分子遗传机制：以高海拔适应为例

自达尔文时代起,解析适应性演化的机制一直是进化生物学和生态学领域研究最重要的科学问题之一。适应性演化通常指在自然选择驱动下,物种为提高适合度而演化出特定的表型。表型的适应表现在形态、生理生化、组织学、行为学等多个层级。随着分子生物学和测序技术的发展,越来越多的研究揭示了适应性复杂性状的遗传基础。研究适应性演化的分子遗传机制有助于理解塑造生物多样性的进化驱动力以及阐明基因型、表型和环境之间的关联关系。目前已有主效基因、超基因、多基因遗传、非编码区调控、重复序列调控、基因渐渗等多种假说可以解释适应性演化的遗传机制。高海拔极端环境的强选择压力极大地促进了物种表型和遗传适应的发生,对多组学数据的剖析为物种适应性演化提供了新的见解。本文对适应性演化的遗传机制、高海拔极端环境适应研究进展以及目前面临的主要挑战进行了综述,并对未来的发展趋势进行了展望,以期为该领域的科研人员提供参考。     

牛无角性状研究进展

角是牛科动物特有的组织结构,但是在现代化养殖中容易造成人员伤亡,而人为除角又会违背动物福利且浪费人力物力,因此牛无角性状引发了高度关注。综述了牛角的形态及发生规律、自然界中存在的天然无角及角畸形性状,归纳总结了导致无角和角畸形性状的基因突变,以及通过基因编辑技术培育无角牛的研究进展,并展望了牛角性状发生机制的研究方向。     

农业反刍动物重要乳性状表型测定方法及研究进展

乳性状作为农业反刍动物的重要经济性状,其表型测定指标内容丰富,测定方法繁多复杂.为进一步凝练重要乳性状表型测定内容,以更好地培育改良中国特色的乳用动物种质资源、创制产量品质优异的新基因资源,本文从乳性状表型测定的常规乳性状表型与特色乳营养成分性状表型测定指标与测定方法、中红外光谱检测法,以及特色乳用畜种简介等四个方面,对我国主要农业反刍动物的重要乳性状表型的详细测定方法及其研究进展进行综述.     

水稻粒形遗传的研究进展

水稻（Oryza sativa）粒形性状包括粒长、粒宽、粒厚、粒重和长宽比等,是构成水稻产量的重要因素之一。因此,阐明水稻粒形遗传控制的机理,对提高水稻产量具有十分重要的意义。水稻粒形的遗传是多基因共同作用的数量性状遗传,相对于单一基因控制的性状,研究要相对复杂。该文综述了水稻粒形的遗传特点、QTL定位和基因克隆,并展望了粒形遗传的研究前景。     

我国陆地棉基础种质表型性状的遗传多样性分析

选用43份陆地棉基础种质为研究材料,随机区组排列种植,并进行果枝数、铃数、株高等田间性状调查和衣分、铃重、纤维品质等测定.按照不同时期、不同来源、不同生态区对这些基础种质分别进行表型性状的遗传多样性分析.结果表明:基础种质间在产量、品质、农艺性状等表型性状上差异显著或极显著,遗传多样性指数为0.88;3期基础种质大部分性状差异不显著,但第2、3期基础种质比第1期的纤维长、整齐度高、细度好、衣分增加、早熟性提高、抗病和耐旱性增强,第2期基础种质遗传多样性和遗传丰富度最高;来自不同棉区的基础种质表型性状差异较大,黄河流域棉区基础种质综合性状较好,长江流域棉区产量性状较高,北部特早熟棉区早熟性好,美国引进种质抗黄萎病性较强;国内基础种质比国外品种在纤维长、强、细上的变异系数均有不同程度降低,但国内基础种质表型多样性比引进品种高.以上研究说明引进品种经过长期的环境适应、自然选择和人工选育后,产生了表型变异较为丰富的基础种质类型.     

生物性状发育的遗传修饰

在生物性状发育过程中,除有遗传基础——基因型的控制以外,另一个必要因素,它包括一般的生长发育条件(如温度、营养等)和遗传景背成分。分析修饰基因及其对非等位基因在性状发育上的影响途径和机制,既阐明修饰基因概念,又讲清其对某非等位基因所决定性状的影响的事实例证。把修饰基因作为某非等位基因的细胞内环境条件之一,显示性状发育的复杂性,客观地反映基因与表型(性状)的关系。     

火龙果种质资源果实特性的遗传多样性分析

为筛选火龙果(Hylocereus undatus)优良种质资源,对22份种质资源果实的表型性状、农艺性状、品质性状进行遗传多样性分析。结果表明,火龙果种质资源果实的表型性状、农艺性状和品质性状具有丰富的遗传多样性和较高的变异性,表型性状的多样性指数(H′)为0～1.04,品质性状为0.40～2.01;农艺性状的变异系数(CV)为0.06～0.38,品质性状为0.01～0.62。聚类分析表明,在遗传距离为15时,火龙果22份种质资源可分为5类,说明不同资源间亲缘关系较远。这为发掘火龙果的育种潜力,筛选优异基因资源,改良种质奠定了基础。     

菜用和观赏甘薯种质资源遗传多样性分析

为了发掘菜用和观赏甘薯优异种质资源,通过对国家种质徐州甘薯试管苗库中1000余份资源材料进行鉴定,筛选了96份优异种质。利用30对SSR引物对入选材料进行了遗传多样性和群体结构分析,明确了这些材料遗传差异;并对入选材料12个表型质量性状进行主成分和聚类分析。结果表明:扩增的总条带数为275条,其中多态性条带为269条,多态率97.8%;利用DPS软件计算入选材料间的Nei72遗传距离为0.15~0.76,平均遗传距离0.66;群体结构分为3个组群,与分子标记聚类结果相似,表明入选材料有较大的遗传差异性;表型质量性状主成分分析得到5个主要成分,其累计贡献率达到80.50%;利用表型质量性状,可聚为8个组群。本研究通过分子标记与表型质量性状分析为下一步杂交选育菜用和观赏甘薯新品种提供了亲本选择信息。     

水稻轮回选择群体XTBG-HP1表型遗传多样性分析

该研究基于4个陆稻群体及172个水稻品种或杂交组合,构建了水稻多亲本隐性核不育轮回选择群体XTBG-HP1,并经过4次轮回重组,采用16个表型性状对其进行了遗传多样性分析。结果表明:(1)该群体14个数量性状符合正态分布,各表型均存在极端性状个体。(2)数量性状变异系数范围为0.08～0.41,均值为0.20; Shannon-Wiener多样性指数范围为0.72～1.92,均值为1.50。(3)群体在株型与产量构成因子性状方面有显著的相关性,对株型的选择可以实现产量性状的改良。(4)剑叶长、每穗粒总数、千粒重、穗长、粒长、一次枝梗数、有效穗数、剑叶宽、二次枝梗数、抽穗期10个性状可作为群体综合评价指标。(5)剑叶长、二次枝梗数、每穗粒总数3个表型性状具有较高的遗传变异、丰富的遗传多样性及与综合得分F值相关系数较高。综合以上结果发现,后期群体进行基因挖掘、品种改良以及优良育种材料的选育可以基于剑叶长、二次枝梗数及每穗粒总数3个表型性状,同时要充分利用群体株型与产量构成因子性状间的显著相关性。此外,该研究群体中极端单性状或综合得分F值较高的个体,可进一步用于品种选育。     

浙江省薄皮甜瓜地方品种的表型遗传多样性

利用表型性状探讨了浙江省沿海地区27份薄皮甜瓜地方品种资源的遗传多样性。结果表明48个质量性状遗传多样性指数在0.17–1.98之间;33个数量性状的变异系数在4.56%–83.50%,表明其丰富的遗传多样性。形态学聚类分析表明,在相似系数0.30处可以将27个资源分成两大类,这与按生育期长短分类结果完全一致;亚类的划分与果实形状、种子形状、叶片颜色、果皮颜色、覆纹颜色等质量性状具有一定的相关性,但其划分依据相对独立。本研究结果进一步丰富了甜瓜的评价体系,并为今后优异基因资源的挖掘与利用提供重要依据。     

Mapping the four‐horned locus and testing the polled locus in three Chinese sheep breeds

Four‐horned sheep are an ideal animal model for illuminating the genetic basis of horn development. The objective of this study was to locate the genetic region responsible for the four‐horned phenotype and to verify a previously reported polled locus in three Chinese breeds. A genome‐wide association study (GWAS) was performed using 34 two‐horned and 32 four‐horned sheep from three Chinese indigenous breeds: Altay, Mongolian and Sishui Fur sheep. The top two significant single nucleotide polymorphisms (SNPs) associated with the four‐horned phenotype were both located in a region spanning positions 132.6 to 132.7 Mb on sheep chromosome 2. Similar locations for the four‐horned trait were previously identified in Jacob, Navajo‐Churro, Damara and Sishui Fur sheep, suggesting a common genetic component underlying the four‐horned phenotype. The two identified SNPs were both downstream of the metaxin 2 (MTX2) gene and the HOXD gene cluster. For the top SNP—OAR2:g.132619300G>A—the strong associations of the AA and AG genotypes with the four‐horned phenotype and the GG genotype with the two‐horned phenotype indicated the dominant inheritance of the four‐horned trait. No significant SNPs for the polled phenotype were identified in the GWAS analysis, and a PCR analysis for the detection of the 1.8‐kb insertion associated with polled sheep in other breeds failed to verify the association with polledness in the three Chinese breeds. This study supports the hypothesis that two different loci are responsible for horn existence and number. This study contributes to the understanding of the molecular regulation of horn development and enriches the knowledge of qualitative traits in domestic animals.     

Live fast, die young: trade-offs between fitness components and sexually antagonistic selection on weaponry in Soay sheep

Males are predicted to compete for reproductive opportunities, with sexual selection driving the evolution of large body size and weaponry through the advantage they confer for access to females. Few studies have explored potential trade-offs of investment in secondary sexual traits between different components of fitness or tested for sexually antagonistic selection pressures. These factors may provide explanations for observed polymorphisms in both form and quality of secondary sexual traits. We report here an analysis of selection on horn phenotype in a feral population of Soay sheep (Ovis aries) on the island of Hirta, St. Kilda, Scotland. Soay sheep display a phenotypic polymorphism for horn type with males growing either normal or reduced (scurred) horns, and females growing either normal, scurred, or no (polled) horns; further variation in size exists within horn morphs. We show that horn phenotype and the size of the trait displayed is subject to different selection pressures in males and females, generating sexually antagonistic selection. Furthermore, there was evidence of a trade-off between breeding success and longevity in normal-horned males, with both the normal horn type and larger horn size being associated with greater annual breeding success but reduced longevity. Therefore, selection through lifetime breeding success was not found to act upon horn phenotype in males. In females, a negative association of annual breeding success within the normal-horned phenotype did not result in a significant difference in lifetime fitness when compared to scurred individuals, as no significant difference in longevity was found. However, increased horn size within this group was negatively associated with breeding success and longevity. Females without horns (polled) suffered reduced longevity and thus reduced lifetime breeding success relative the other horn morphs. Our results therefore suggest that trade-offs between different components of fitness and antagonistic selection between the sexes may maintain genetic variation for secondary sexual traits within a population.     

Genome-wide association mapping identifies the genetic basis of discrete and quantitative variation in sexual weaponry in a wild sheep population

Understanding the genetic architecture of phenotypic variation in natural populations is a fundamental goal of evolutionary genetics. Wild Soay sheep (Ovis aries) have an inherited polymorphism for horn morphology in both sexes, controlled by a single autosomal locus, Horns. The majority of males have large normal horns, but a small number have vestigial, deformed horns, known as scurs; females have either normal horns, scurs or no horns (polled). Given that scurred males and polled females have reduced fitness within each sex, it is counterintuitive that the polymorphism persists within the population. Therefore, identifying the genetic basis of horn type will provide a vital foundation for understanding why the different morphs are maintained in the face of natural selection. We conducted a genome-wide association study using ～36000 single nucleotide polymorphisms (SNPs) and determined the main candidate for Horns as RXFP2, an autosomal gene with a known involvement in determining primary sex characters in humans and mice. Evidence from additional SNPs in and around RXFP2 supports a new model of horn-type inheritance in Soay sheep, and for the first time, sheep with the same horn phenotype but different underlying genotypes can be identified. In addition, RXFP2 was shown to be an additive quantitative trait locus (QTL) for horn size in normal-horned males, accounting for up to 76% of additive genetic variation in this trait. This finding contrasts markedly from genome-wide association studies of quantitative traits in humans and some model species, where it is often observed that mapped loci only explain a modest proportion of the overall genetic variation.     

Influence of selection forms on genetic structure of domestic animals

Analysis of genetic structure of pure and crossbred sheep and cattle with the use of genetic-biochemical markers was carried out. Data on breed- and locus-specific genetic traits, stable in the time, were obtained. In sheep, breed-specific peculiarities of genetic structure partly related with the belonging of breeds to breed groups with fine-, semi-fine and coarse wool. The preferable influence of artificial selection at the phenotype complex traits in comparison with natural selection and animal origin on the genetic structure of crossbred sheep was revealed. However, the more profound effects of natural selection on the genetic structure of crossbred cattle were observed.     

Polyceraty (multi‐horns) in Damara sheep maps to ovine chromosome 2

Polyceraty (presence of multiple horns) is rare in modern day ungulates. Although not found in wild sheep, polyceraty does occur in a small number of domestic sheep breeds covering a wide geographical region. Damara are fat‐tailed hair sheep, from the south‐western region of Africa, which display polyceraty, with horn number ranging from zero to four. We conducted a genome‐wide association study for horn number with 43 Damara genotyped with 606 006 SNP markers. The analysis revealed a region with multiple significant SNPs on ovine chromosome 2, in a location different from the mutation for polled in sheep on chromosome 10. The causal mutation for polyceraty was not identified; however, the region associated with polyceraty spans nine HOXD genes, which are critical in embryonic development of appendages. Mutations in HOXD genes are implicated in polydactly phenotypes in mice and humans. There was no evidence for epistatic interactions contributing to polyceraty. This is the first report on the genetic mechanisms underlying polyceraty in the under‐studied Damara.     

Genome‐wide association reveals the locus responsible for four‐horned ruminant

Phenotypic variability in horn characteristics, such as their size, number and shape, offers the opportunity to elucidate the molecular basis of horn development. The objective of this study was to map the genetic determinant controlling the production of four horns in two breeds, Jacob sheep and Navajo‐Churro, and examine whether an eyelid abnormality occurring in the same populations is related. Genome‐wide association mapping was performed using 125 animals from the two breeds that contain two‐ and four‐horned individuals. A case–control design analysis of 570 712 SNPs genotyped with the ovine HD SNP Beadchip revealed a strong association signal on sheep chromosome 2. The 10 most strongly associated SNPs were all located in a region spanning Mb positions 131.9–132.6, indicating the genetic architecture underpinning the production of four horns is likely to involve a single gene. The closest genes to the most strongly associated marker (OAR2_132568092) were MTX2 and the HOXD cluster, located approximately 93 Kb and 251 Kb upstream respectively. The occurrence of an eyelid malformation across both breeds was restricted to polled animals and those carrying more than two horns. This suggests the eyelid abnormality may be associated with departures from the normal developmental production of two‐horned animals and that the two conditions are developmentally linked. This study demonstrated the presence of separate loci responsible for the polled and four‐horned phenotypes in sheep and advanced our understanding of the complexity that underpins horn morphology in ruminants.     

A single nucleotide polymorphism on chromosome 10 is highly predictive for the polled phenotype in Australian Merino sheep

The aim of this study was to fine map the genomic location of the Horns locus in the Australian Merino sheep population and to identify markers that can be used to predict the horn phenotype. A linkage disequilibrium analysis of horn data from Australian Merino sheep mapped the Horns locus to a small region on chromosome 10. A single nucleotide polymorphism in the region was found to be highly predictive for the polled phenotype in an experimental population of Merino sheep. This was owing to a dominance effect of one of the alleles when inherited maternally. It was suggested that a genetic test would provide a good predictor of the polled phenotype. Finally, an evaluation of industry data showed that the SNP is at very different frequencies in Poll Merino sheep that have been bred for polledness (based on phenotype alone) compared with the Merino sheep breed.     

New phenotypes for new breeding goals in dairy cattle

Cattle production faces new challenges regarding sustainability with its three pillars - economic, societal and environmental. The following three main factors will drive dairy cattle selection in the future: (1) During a long period, intensive selection for enhanced productivity has deteriorated most functional traits, some reaching a critical point and needing to be restored. This is especially the case for the Holstein breed and for female fertility, mastitis resistance, longevity and metabolic diseases. (2) Genomic selection offers two new opportunities: as the potential genetic gain can be almost doubled, more traits can be efficiently selected; phenotype recording can be decoupled from selection and limited to several thousand animals. (3) Additional information from other traits can be used, either from existing traditional recording systems at the farm level or from the recent and rapid development of new technologies and precision farming. Milk composition (i.e. mainly fatty acids) should be adapted to better meet human nutritional requirements. Fatty acids can be measured through a new interpretation of the usual medium infrared spectra. Milk composition can also provide additional information about reproduction and health. Modern milk recorders also provide new information, that is, on milking speed or on the shape of milking curves. Electronic devices measuring physiological or activity parameters can predict physiological status like estrus or diseases, and can record behavioral traits. Slaughterhouse data may permit effective selection on carcass traits. Efficient observatories should be set up for early detection of new emerging genetic defects. In the near future, social acceptance of cattle production could depend on its capacity to decrease its ecological footprint. The first solution consists in increasing survival and longevity to reduce replacement needs and the number of nonproductive animals. At the individual level, selection on rumen activity may lead to decreased methane production and concomitantly to improved feed efficiency. A major effort should be dedicated to this new field of research and particularly to rumen flora metagenomics. Low input in cattle production is very important and tomorrow's cow will need to adapt to a less intensive production environment, particularly lower feed quality and limited care. Finally, global climate change will increase pathogen pressure, thus more accurate predictors for disease resistance will be required.     

A sensitised mutagenesis screen in the mouse to explore the bovine genome: study of muscle characteristics

Meat yield and quality are closely related to muscle development. The muscle characteristics mainly take place during embryonic and postnatal phases. Thus, genetic control of muscle development in early stages represents a significant stake to improve product quality and production efficiency. In bovine, several programmes have been developed to detect quantitative trait loci (QTL) affecting growth, carcass composition or meat quality traits. Such strategy is incontestably very powerful yet extremely cumbersome and costly when dealing with large animals such as ruminants. Furthermore, the fine mapping of the QTL remains a real challenge. Here, we proposed an alternative approach based on chemical mutagenesis in the mouse combined with comparative genomics to identify regions or genes controlling muscle development in cattle. At present, we isolated seven independent mouse lines of high interest. Two lines exhibit a hypermuscular phenotype, and the other five show various skeletomuscular phenotypes. Detailed characterisation of these mouse mutants will give crucial input for the identification and the mapping of genes that control muscular development. Our strategy will provide the opportunity to understand the function and control of genes involved in improvement of animal physiology.