Local effects of inbreeding on embryo number and consequences for genetic diversity in Kerguelen mouflon

A classical paradigm in population genetics is that homozygosity or inbreeding affects individual fitness through increased disease susceptibility and mortality, and diminished breeding success. Using data from an insular population of mouflon (Ovis aries) founded by a single pair of individuals, we compare embryo number of ewes with different levels of inbreeding. Contrary to expectations, ewes with the highest levels of homozygosity showed the largest number of embryos. Using two different statistical approaches, we showed that this relationship is probably caused by heterozygosity at specific genes. The genetics of embryo number coupled with cyclic dynamics could play a central role in promoting genetic variation in this population.     

Dominance Genetic Variance for Traits Under Directional Selection in Drosophila serrata

In contrast to our growing understanding of patterns of additive genetic variance in single- and multi-trait combinations, the relative contribution of nonadditive genetic variance, particularly dominance variance, to multivariate phenotypes is largely unknown. While mechanisms for the evolution of dominance genetic variance have been, and to some degree remain, subject to debate, the pervasiveness of dominance is widely recognized and may play a key role in several evolutionary processes. Theoretical and empirical evidence suggests that the contribution of dominance variance to phenotypic variance may increase with the correlation between a trait and fitness; however, direct tests of this hypothesis are few. Using a multigenerational breeding design in an unmanipulated population of Drosophila serrata, we estimated additive and dominance genetic covariance matrices for multivariate wing-shape phenotypes, together with a comprehensive measure of fitness, to determine whether there is an association between directional selection and dominance variance. Fitness, a trait unequivocally under directional selection, had no detectable additive genetic variance, but significant dominance genetic variance contributing 32% of the phenotypic variance. For single and multivariate morphological traits, however, no relationship was observed between trait–fitness correlations and dominance variance. A similar proportion of additive and dominance variance was found to contribute to phenotypic variance for single traits, and double the amount of additive compared to dominance variance was found for the multivariate trait combination under directional selection. These data suggest that for many fitness components a positive association between directional selection and dominance genetic variance may not be expected.     

A comparison of management strategies for conservation with regard to population fitness

Computer simulations have been carried out tocompare, under realistic genetic models, twomethods proposed in the literature to retaingenetic diversity in conservation programmes.In a two-step method, contributions of parentsare set up to produce minimum coancestry(kinship) among the offspring, and this isindependent of the mating system subsequentlyapplied. In a single-step method,contributions and matings are decidedsimultaneously in order to minimise coancestry.The comparison is made in terms of maintainedgenetic diversity and in terms of populationfitness. We conclude that the two methodsmaintain approximately the same geneticdiversity but the latter induces higher levelsof inbreeding, reducing the fitness of thepopulation. Avoidance of close relatives'matings improves this latter method, but thefitness levels do not reach those of thetwo-step scheme. We also investigate theperformances of different mating strategies incombination with minimum coancestry (two-stepmethod), concluding that these mating systemsdo not substantially affect the effectivenessof the management. Finally, we illustrate howminimum group coancestry can be restrictedto a minimum loss of fitness, if a measure ofthis is available for the individuals.     

分子标记在家畜遗传多样性研究中的应用

家畜遗传多样性是生物多样性的重要组成部分,与人类未来的生存与发展密切相关。中国拥有丰富的地方家畜品种资源,但由于保种不当和盲目引进外来品种进行杂交、资金缺乏等原因,许多品种已濒临灭绝。如何保存利用好我国优良的家畜遗传资源已成为越来越严峻的问题。随着生物学技术的不断发展与完善,许多分子标记技术已经应用于畜禽遗传资源的研究。简要介绍了在家畜遗传多样性研究中应用最广的几种分子标记及其特性,讨论了在家畜遗传多样性的研究中如何选用适当的分子标记。     

Genetic adaptation to captivity in species conservation programs

As wild environments are often inhospitable, many species have to be captive-bred to save them from extinction. In captivity, species adapt genetically to the captive environment and these genetic adaptations are overwhelmingly deleterious when populations are returned to wild environments. I review empirical evidence on (i) the genetic basis of adaptive changes in captivity, (ii) factors affecting the extent of genetic adaptation to captivity, and (iii) means for minimizing its deleterious impacts. Genetic adaptation to captivity is primarily due to rare alleles that in the wild were deleterious and partially recessive. The extent of adaptation to captivity depends upon selection intensity, genetic diversity, effective population size and number of generation in captivity, as predicted by quantitative genetic theory. Minimizing generations in captivity provides a highly effective means for minimizing genetic adaptation to captivity, but is not a practical option for most animal species. Population fragmentation and crossing replicate captive populations provide practical means for minimizing the deleterious effects of genetic adaptation to captivity upon populations reintroduced into the wild. Surprisingly, equalization of family sizes reduces the rate of genetic adaptation, but not the deleterious impacts upon reintroduced populations. Genetic adaptation to captivity is expected to have major effects on reintroduction success for species that have spent many generations in captivity. This issue deserves a much higher priority than it is currently receiving.     

iPS细胞的遗传安全性

自2006年Takahashi和Yamanaka首次成功地从小鼠成纤维细胞诱导得到诱导多能性干细胞(Induced pluripotent stem cells,iPS细胞)以来,iPS细胞由于其潜在的广阔应用前景而迅速成为干细胞研究领域的新热点;与此同时,iPS细胞的遗传安全性也越来越多地受到人们的关注。文章将对iPS细胞遗传安全性的研究进展进行综述,分析造成iPS细胞遗传不稳定的可能原因,希望可以促进对iPS细胞诱导条件的优化,获得遗传上较为安全的iPS细胞。     

Single large or several small? Population fragmentation in the captive management of endangered species

Captive populations of endangered species are typically maintained effectively as single random-mating populations by translocating individuals between institutions. Genetic, disease, and cost considerations, however, suggest that this may not be the optimal management strategy. Genetic theory predicts that a pooled population derived from several small isolated populations will have greater genetic diversity, less inbreeding, and less genetic adaptation to captivity than a single large population of equivalent total size, provided there are no population extinctions. These predictions were tested using populations of Drosophila with effective size comparisons of 50 vs. 2 × 25; 100 vs. 2 × 50 vs. 4 × 25, and 500 vs. 2 × 250 vs. 4 × 100 + 2 × 50 vs. 8 × 25 + 6 × 50. Populations were maintained at the indicated sizes as separate pedigreed populations for 50 generations. The several small treatments were subsequently pooled and maintained for eight to 10 generations prior to determination of fitness and evolutionary potential. Several small populations (pooled), when compared to single large populations of equivalent total size, were found to have lower average inbreeding coefficients, significantly higher reproductive fitness under competitive conditions, similar fitness under benign captive conditions, higher genetic diversity, and equivalent evolutionary potential. Trends favored the several small (pooled) populations in all comparisons at population sizes of 50 and 100. We recommend that endangered species in captivity be maintained as several small populations, with occasional exchange of genetic material. This has genetic benefits over current management both in captivity and especially for reintroductions, as well as reducing translocation costs and risks of disease transfer. Zoo Biol 17:467–480, 1998. © 1998 Wiley-Liss, Inc.     

The genetic rescue of two bottlenecked South Island robin populations using translocations of inbred donors

Populations forced through bottlenecks typically lose genetic variation and exhibit inbreeding depression. ‘Genetic rescue’ techniques that introduce individuals from outbred populations can be highly effective in reversing the deleterious effects of inbreeding, but have limited application for the majority of endangered species, which survive only in a few bottlenecked populations. We tested the effectiveness of using highly inbred populations as donors to rescue two isolated and bottlenecked populations of the South Island robin (Petroica australis). Reciprocal translocations significantly increased heterozygosity and allelic diversity. Increased genetic diversity was accompanied by increased juvenile survival and recruitment, sperm quality, and immunocompetence of hybrid individuals (crosses between the two populations) compared with inbred control individuals (crosses within each population). Our results confirm that the implementation of ‘genetic rescue’ using bottlenecked populations as donors provides a way of preserving endangered species and restoring their viability when outbred donor populations no longer exist.     

Fewer S‐alleles are maintained in plant populations with sporophytic as opposed to gametophytic self‐incompatibility

Plants use self‐incompatibility to reject pollen bearing alleles in common at the S‐locus. These systems are classified as gametophytic (GSI) if recognition involves haploid pollen or sporophytic (SSI) if recognition involves diploid paternal genotypes. Dominance in SSI systems reduces the number of S‐alleles, but it has not been clear which system should maintain greater diversity when all else is equal. We simulated finite populations to compare the equilibrium number of S‐alleles in populations with either GSI or a co‐dominant SSI system. When population size was constant, SSI systems maintained more S‐alleles than GSI systems. When populations fluctuated in response to an S‐Allee effect, fewer S‐alleles were observed in SSI systems when S‐allele diversity was low, and SSI populations were vulnerable to extinction over a broader range of parameters. Turnover rates at the S‐locus were also faster in SSI populations experiencing strong S‐Allee effects. Given the variable expectations concerning S‐allele diversity in these systems, we reviewed published estimates of S‐allele diversity. GSI populations have significantly more S‐alleles on average than SSI populations (GSI = 25.70 and SSI = 16.80). Dominance likely contributes to this pattern, although the demographic consequences of the S‐Allee effect may be important in populations with fewer than 10 S‐alleles.     

边际多样性方法及其在绵羊品种保护中的应用

本文介绍了边际多样性方法,并利用微卫星DNA遗传距离、灭绝概率等结果分析了中国北方11个绵羊品种的品种贡献率、边际多样性及保护潜力。结果表明,苏尼特羊(Sunite sheep)的边际多样性最高（－0.2008）,其次为滩羊(Tan sheep)(－0.1932)、兰州大尾羊(Lanzhou large tailed sheep)(－0.1843);岷县黑裘皮羊(Minxian black fur sheep)最低（－0.1268）。保护潜力最大的品种为兰州大尾羊（0.1419）,其次为同羊(Tong sheep)（0.1017）,最小的为小尾寒羊(Small tailed Han sheep)（0.0365）。根据边际多样性方法,作者认为确定需要保护的品种应该依据最大保护潜力而不是品种的濒危程度。11个绵羊品种的保护顺序依次是兰州大尾羊、同羊、汉中羊(Hanzhong sheep)、甘家羊(Ganjia sheep)、欧拉羊(Oula sheep)、岷县黑裘皮羊、乔科羊(Qiaoke sheep)、苏尼特羊、乌珠穆沁羊(Ujumqin sheep)和小尾寒羊。     

iPS细胞的遗传安全性

自2006年Takahashi和Yamanaka首次成功地从小鼠成纤维细胞诱导得到诱导多能性干细胞(Induced pluripotent stem cells, iPS细胞)以来, iPS细胞由于其潜在的广阔应用前景而迅速成为干细胞研究领域的新热点; 与此同时, iPS细胞的遗传安全性也越来越多地受到人们的关注。文章将对iPS细胞遗传安全性的研究进展进行综述, 分析造成iPS细胞遗传不稳定的可能原因, 希望可以促进对iPS细胞诱导条件的优化, 获得遗传上较为安全的iPS细胞。     

The role of female dominance hierarchies in the mating behaviour of mosquitofish

While studies of sexual selection focus primarily on female choice and male-male competition, males should also exert mate choice in order to maximize their reproductive success. We examined male mate choice in mosquitofish, Gambusia holbrooki, with respect to female size and female dominance. We found that the number of mating attempts made by a male was predicted by the dominance rank of females in a group, with dominant females attracting more mating attempts than subordinates. The number of mating attempts made by males was independent of the female size. The observed bias in the number of mating attempts towards dominant females may be driven either by straightforward male mate choice, since dominance and female fecundity are often closely related, or via the dominant females mediating male mating behaviour by restricting their access to subordinate females.     

Larval population density affects female weight and fecundity in the dung beetle Aphodius ater

1. Competition for food at high densities during larval development leads to reduced adult weight in the northern temperate dung beetle Aphodius ater. 2. Analysis of female beetles caught in the field showed that numbers of eggs and total egg load per female were correlated positively with beetle size. 3. Female beetles reared at different population densities during larval development in the laboratory were analysed with regard to their lifetime fecundity and reproductive lifespan. 4. High population densities during development had a negative influence on the number of eggs per female and on reproductive lifespan. Lifetime fecundity was correlated positively with female weight. 5. It was concluded that competition during larval development in the first generation of offspring will result in a lower number of offspring in the second generation in Aphodius ater, and thereby reduce parental fitness.