Genetic evidence against panmixia in the European eel

The panmixia hypothesis--that all European eel (Anguilla anguilla) migrate to the Sargasso Sea for reproduction and comprise a single, randomly mating population--is widely accepted. If true, then this peculiar life history strategy would directly impact the population genetics of this species, and eels from European and north African rivers should belong to the same breeding population through the random dispersal of larvae. To date, the panmixia hypothesis has remained unchallenged: genetic studies realized on eel's mitochondrial DNA failed to detect any genetic structure; and a similar lack of structure was found using allozymes, with the exception of clinal variation imposed by selection. Here we have used highly polymorphic genetic markers that provide better resolution to investigate genetic structure in European eel. Analysis of seven microsatellite loci among 13 samples from the north Atlantic, the Baltic Sea and the Mediterranean Sea basins reveals that there is global genetic differentiation. Moreover, pairwise Cavalli-Sforza and Edwards chord distances correlate significantly with coastal geographical distance. This pattern of genetic structure implies non-random mating and restricted gene flow among eels from different sampled locations, which therefore refute the hypothesis of panmixia. Consequently, the reproductive biology of European eel must be reconsidered.     

Gene flow maintains a large genetic difference in clutch size at a small spatial scale

Understanding the capacity of natural populations to adapt to their local environment is a central topic in evolutionary biology. Phenotypic differences between populations may have a genetic basis, but showing that they reflect different adaptive optima requires the quantification of both gene flow and selection. Good empirical data are rare. Using data on a spatially structured island population of great tits (Parus major), we show here that a persistent difference in mean clutch size between two subpopulations only a few kilometres apart has a major genetic component. We also show that immigrants from outside the island carry genes for large clutches. But gene flow into one subpopulation is low, as a result of a low immigration rate together with strong selection against immigrant genes. This has allowed for adaptation to the island environment and the maintenance of small clutches. In the other area, however, higher gene flow prevents local adaptation and maintains larger clutches. We show that the observed small-scale genetic difference in clutch size is not due to divergent selection on the island, but to different levels of gene flow from outside the island. Our findings illustrate the large effect of immigration on the evolution of local adaptations and on genetic population structure.     

Cryptic genetic variation promotes rapid evolutionary adaptation in an RNA enzyme

Cryptic variation is caused by the robustness of phenotypes to mutations. Cryptic variation has no effect on phenotypes in a given genetic or environmental background, but it can have effects after mutations or environmental change. Because evolutionary adaptation by natural selection requires phenotypic variation, phenotypically revealed cryptic genetic variation may facilitate evolutionary adaptation. This is possible if the cryptic variation happens to be pre-adapted, or "exapted", to a new environment, and is thus advantageous once revealed. However, this facilitating role for cryptic variation has not been proven, partly because most pertinent work focuses on complex phenotypes of whole organisms whose genetic basis is incompletely understood. Here we show that populations of RNA enzymes with accumulated cryptic variation adapt more rapidly to a new substrate than a population without cryptic variation. A detailed analysis of our evolving RNA populations in genotype space shows that cryptic variation allows a population to explore new genotypes that become adaptive only in a new environment. Our observations show that cryptic variation contains new genotypes pre-adapted to a changed environment. Our results highlight the positive role that robustness and epistasis can have in adaptive evolution.     

Strong population substructure is correlated with morphology and ecology in a migratory bat

Examining patterns of inter-population genetic diversity can provide valuable information about both historical and current evolutionary processes affecting a species. Population genetic studies of flying and migratory species such as bats and birds have traditionally shown minimal population substructure, characterized by high levels of gene flow between populations. In general, strongly substructured mammalian populations either are separated by non-traversable barriers or belong to terrestrial species with low dispersal abilities. Species with female philopatry (the tendency to remain in or consistently return to the natal territory) might show strong substructure when examined with maternally inherited mitochondrial DNA, but this substructure generally disappears when biparentally inherited markers are used, owing to male-mediated gene flow. Male-biased dispersal is considered typical for mammals, and philopatry in both sexes is rare. Here we show strong population substructure in a migratory bat species, and philopatry in both sexes, as indicated by concordance of nuclear and mtDNA findings. Furthermore, the genetic structure correlates with local biomes and differentiation in wing morphology. There is therefore a close correlation of genetic and morphological differentiation in sympatric subspecific populations of this mammalian species.     

Contemporary fisherian life-history evolution in small salmonid populations

The relative importance of natural selection and random drift in phenotypic evolution has been discussed since the introduction of the first population genetic models. The empirical evidence used to evaluate the evolutionary theories of Fisher and Wright remains obscure because formal tests for neutral divergence or sensitive attempts to separate the effects of selection and drift are scarce, subject to error, and have not been interpreted in the light of well-known population demography. We combined quantitative genetic and microsatellite DNA analyses to investigate the determinants of contemporary life-history evolution in isolated populations of grayling (Thymallus thymallus, Salmonidae) that originated from a common source 80-120 years ago. Here we show that natural selection was the dominant diversifying agent in the evolution of the quantitative traits. However, the populations were founded by a small number of individuals, exhibit very low microsatellite-based effective sizes and show genetic imprints of severe 'bottlenecks'; which are conditions often suggested to constrain selection and favour drift. This study demonstrates a very clear case of fisherian evolution in small natural populations across a contemporary timescale.     

Relative fitness can decrease in evolving asexual populations of S. cerevisiae

It is generally accepted from the darwinian theory of evolution that a progressive increase in population adaptation will occur in populations containing genetic variation in fitness, until a stable equilibrium is reached and/or the additive genetic variation is exhausted. However, the theoretical literature of population genetics documents exceptions where mean population fitness may decrease in response to evolutionary changes in gene frequency, due to varying selective coefficients, sexual selection or to epistatic interactions between loci. Until now, no examples of such exceptions have been documented from fitness estimates in either natural or experimental populations. We present here direct evidence that, as a result of epistatic interactions between adaptive mutations, mean population fitness can decrease in asexual evolving populations of the yeast Saccharomyces cerevisiae.     

基于MHCⅡ类B基因的凹耳臭蛙(Odorrana tormota)种群遗传分化模式

利用II类MHC基因单基因座位Odto-A作为分子标记,对皖南山区凹耳臭蛙6个种群的遗传多样性和遗传分化进行研究.结果显示,皖南凹耳臭蛙总的基因多样性为0.812,核苷酸多样性为0.018.局域种群单倍型多样性变化范围为0.531-0.864,香溪种群单倍型多样性最高,最低的是漳河种群.与线粒体cyt b基因所揭示的单倍型多样性差别不大,但B基因的核苷酸多样性较之线粒体cyt b基因的高达一个数量级.暗示MHC基因丰富的核苷酸多态性可能与其病原体抗性多样性密切相关.分子变异分析结果显示,皖南山区凹耳臭蛙种群MHC II类B基因遗传变异主要来源于种群内,种群间发生了显著的遗传分化(Fst=0.05644,P=0.00391).成对种群间的遗传分化分析结果显示,直线距离最近的浮溪和香溪种群间也发生了显著的遗传分化,暗示这两个种群经历了不同的选择压力.受平衡选择的作用,MHC基因与基于中性分子标记所揭示的遗传格局不同,基于MHC基因的种群遗传分化与水系和直线地理距离均没有明显的相关性,而与种群所经历的选择压力密切相关.结果表明皖南凹耳臭蛙不同局域种群所经历的环境病原体的选择压力存在时空变异.     

Migration and population genetics of the grain aphid Macrosiphum miscanti (Takahashi) in relation to the geographic distance and gene flow

The population genetics of the grain aphid Macrosiphum miscanti (Takahashi) is analyzed by microsatellite markers. Samples collected from 15 locations in China have been examined at 5 polymorphic microsatellite loci. Overall, genetic diversity displays a relation between the migration and gene flow in the grain aphid: a free and frequent gene flow is found in the eastern populations, and gene isolation occurs in the two western populations, especially Datong population and Guiyang population. The natural barriers may present an insurmountable obstacle preventing gene flow and aphid migration. However, a spatial genetic differentiation between populations is correlated with their geographical separation, indicating the geographic differentiation may play an important role in shaping the genetic structure of M. miscanti populations. In addition, most populations of grain aphids are out of Hardy-Weinberg equilibrium and there is heterozygote deficit. Based on F statistics, the average genetic differentiation among different geographical populations is relatively low. It seems that the long distance migration of the grain aphid may enhance gene flow and decrease genetic differentiation among different populations.     

Scanning for sisnatures of geosraphically restricted selection based on population genomics analysis

Natural selection, as the driving force of human evolution, has direct impact on population differentiation. However, it is still unclear to what extent the genetic differentiation has been caused by natural selection. To explore this question, we performed a genome-wide scan with single nucleotide polymorphism （SNP） data from the International HapMap Project. Single locus FsTanalysis was applied to assess the frequency difference among populations in autosomes. Based on the empirical distribution of FsT, we identified 12669 SNPs correlating to population differentiation and 1853 candidate genes subjected to geographic restricted natural selection. Further interpretation of gene ontogeny revealed 121 categories of biological process with the enrichments of candidate genes. Our results suggest that natural selection may play an important role in human population differentiation. In addition, our analysis provides new clues as well as research methods for our understanding of population differentiation and natural selection.     

Adaptation varies through space and time in a coevolving host-parasitoid interaction

One of the central challenges of evolutionary biology is to understand how coevolution organizes biodiversity over complex geographic landscapes. Most species are collections of genetically differentiated populations, and these populations have the potential to become adapted to their local environments in different ways. The geographic mosaic theory of coevolution incorporates this idea by proposing that spatial variation in natural selection and gene flow across a landscape can shape local coevolutionary dynamics. These effects may be particularly strong when populations differ across productivity gradients, where gene flow will often be asymmetric among populations. Conclusive empirical tests of this theory have been particularly difficult to perform because they require knowledge of patterns of gene flow, historical population relationships and local selection pressures. We have tested these predictions empirically using a model community of bacteria and bacteriophage (viral parasitoids of bacteria). We show that gene flow across a spatially structured landscape alters coevolution of parasitoids and their hosts and that the resulting patterns of adaptation can fluctuate in both space and time.     

Ocean currents mediate evolution in island lizards

Islands are considered to be natural laboratories in which to examine evolution because of the implicit assumption that limited gene flow allows tests of evolutionary processes in isolated replicates. Here we show that this well-accepted idea requires re-examination. Island inundation during hurricanes can have devastating effects on lizard populations in the Bahamas. After severe storms, islands may be recolonized by over-water dispersal of lizards from neighbouring islands. High levels of gene flow may homogenize genes responsible for divergence, and are widely viewed as a constraining force on evolution. Ultimately, the magnitude of gene flow determines the extent to which populations diverge from one another, and whether or not they eventually form new species. We show that patterns of gene flow among island populations of Anolis lizards are best explained by prevailing ocean currents, and that over-water dispersal has evolutionary consequences. Across islands, divergence in fitness-related morphology decreases with increasing gene flow. Results suggest that over-water dispersal after hurricanes constrains adaptive diversification in Anolis lizards, and that it may have an important but previously undocumented role in this classical example of adaptive radiation.     

生态位构建的进化意义及其生态与行为响应

生态位构建是指有机体对局部环境中重要组成成分的建造、修复以及选择的一种能力.重点讨论了生态位构建的进化意义以及由生态位构建引起的生态和行为响应,主要结果包括:(1)生态继承作为与基因继承并行的遗传途径,扩展了对有机体适应性的机理解释;(2)环境变化与有机体对该变化导致的选择压的响应之间存在的时滞能够产生进化惯量与动量;(3)生态位构建与生态系统工程之间存在三个层面的差异;(4)Baldwin效应、自然选择和生态位构建分别体现了有机体对环境变化的中性、被动和主动等三种不同响应;(5)由于生态位构建可取决于学习的过程,因此它可以解释动物行为对策的进化.通过对生态位构建中这些热点问题以及其理论研究不足的讨论,提出了该领域中三个潜在的研究方向.     

生境片断化对植物的遗传影响

生境片断化指大片连续的生境被分割成空间隔离的小生境的现象。通常认为，生境片断化使植物残遗种群由于经历随机遗传漂变和高水平的近交以及基因流的下降，而发生遗传侵蚀，遗传多样性下降，遗传结构改变，变得更加分化。但近期的研究证明，并不是所有的片断化事件都导致植物种群遗传变异丧失，且种群问的基因流甚至有可能增加了。片断化对植物种群的遗传作用还受到诸如世代长短的种间差异、片断化前的丰富度、有性和无性繁殖系统的多样性、种子库以及和传粉媒介及种子传播者的相互作用等的影响。     

多辐溲疏居群过氧化物酶同工酶分化的研究

运用聚丙烯酰胺凝胶电泳，测试了采自四川南川县金佛山不同生境的多辐溲疏５个居群５０株个体的过氧化物酶同工酶，对酶谱带位置进行了二态编码，然后采用Ｒｏｇｅｒｓ－Ｔａｎｉｍｏｔｏ，Ｓｏｋａｌ－Ｍｉｃｈ－ｅｎｅｒ，Ｓｏｋａｌ－Ｓｎｅａｔｈ，Ｊａｃｃａｒｄ等结合系数用组平均法（ＵＰＧＭＡ）对各谱带位置进行了聚类分析．结果表明，相同生境同一居群内的个体间表现出较大的遗传同质性，而来源于不同生境的不同居群个体间却呈现出较大的遗传趋异性；同时，５个居群不但具有许多共同谱带，而且整体相聚的结合系数大多超过０．５，这表明５个居群在很早以前可能是属于同一大居群，在长期进化过程中，由于微生境的地理与气候因子选择，使得多辐溲疏现仅在金佛山海拔６００～１２００ｍ的约ｋｍ２范围内呈岛状分布；又由于其特殊的繁殖方式——居群内个体虽能杂交，但因该种仅能正常开花传粉，大部分种子败育，使得居群内个体遗传变异性不能通过有性生殖方式固定下来，仅能通过营养繁殖方式繁殖后代，而正是营养繁殖导致了居群内较大遗传同质性以及居群间的遗传趋异性．在整个进化过程中生境只不过是对那些遗传变异起到了选择固定作用     

Out of Africa again and again

The publication of a haplotype tree of human mitochondrial DNA variation in 1987 provoked a controversy about the details of recent human evolution that continues to this day. Now many haplotype trees are available, and new analytical techniques exist for testing hypotheses about recent evolutionary history using haplotype trees. Here I present formal statistical analysis of human haplotype trees for mitochondrial DNA, Y-chromosomal DNA, two X-linked regions and six autosomal regions. A coherent picture of recent human evolution emerges with two major themes. First is the dominant role that Africa has played in shaping the modern human gene pool through at least two--not one--major expansions after the original range extension of Homo erectus out of Africa. Second is the ubiquity of genetic interchange between human populations, both in terms of recurrent gene flow constrained by geographical distance and of major population expansion events resulting in interbreeding, not replacement.     

Maintaining a behaviour polymorphism by frequency-dependent selection on a single gene

Accounting for the abundance of genetic variation in the face of natural selection remains a central problem of evolutionary biology. Genetic polymorphisms are constantly arising through mutation, and although most are promptly eliminated, polymorphisms in functionally important traits are common. One mechanism that can maintain polymorphisms is negative frequency-dependent selection on alternative alleles, whereby the fitness of each decreases as its frequency increases. Examples of frequency-dependent selection are rare, especially when attempting to describe the genetic basis of the phenotype under selection. Here we show frequency-dependent selection in a well-known natural genetic polymorphism affecting fruitfly foraging behaviour. When raised in low nutrient conditions, both of the naturally occurring alleles of the foraging gene (for(s) and for(R)) have their highest fitness when rare-the hallmark of negative frequency-dependent selection. This effect disappears at higher resources levels, demonstrating the role of larval competition. We are able to confirm the involvement of the foraging gene by showing that a sitter-like mutant allele on a rover background has similar frequency-dependent fitness as the natural sitter allele. Our study represents a clear demonstration of frequency-dependent selection, and we are able to attribute this effect to a single, naturally polymorphic gene known to affect behaviour.     

云南松的种群遗传与进化

本文从种群遗传学的角度研究了云南松（pinus yunnanensis)的遗传体制，种群内的多态现象，种群的遗传结构，演化潜力，生态小种和地理小种以及共交种等问题，得出的若干结论如下：（1）种内存在巨大的遗传变异，如在自然 群中表明的，几乎所有可见的形态性状都具有多态现象，这种巨大的遗传变异是自然选择进化的一个必要条件。（2）自然种群中，大多数个体的基因型很多座位都是杂合的，它们常表现出杂种优势，并且也可能表明增强了生理上发育上的体内平衡。（3）由于种群大，而且又分割成许多相对独立的亚群，各种进化要素都有能同时起作用，并已分化出生态种和地理小种，（4）云南松具有拟态种子，其起源和适应意义作了初步讨论。     

Low gene copy number shows that arbuscular mycorrhizal fungi inherit genetically different nuclei

Arbuscular mycorrhizal fungi (AMF) are ancient asexually reproducing organisms that form symbioses with the majority of plant species, improving plant nutrition and promoting plant diversity. Little is known about the evolution or organization of the genomes of any eukaryotic symbiont or ancient asexual organism. Direct evidence shows that one AMF species is heterokaryotic; that is, containing populations of genetically different nuclei. It has been suggested, however, that the genetic variation passed from generation to generation in AMF is simply due to multiple chromosome sets (that is, high ploidy). Here we show that previously documented genetic variation in Pol-like sequences, which are passed from generation to generation, cannot be due to either high ploidy or repeated gene duplications. Our results provide the clearest evidence so far for substantial genetic differences among nuclei in AMF. We also show that even AMF with a very large nuclear DNA content are haploid. An underlying principle of evolutionary theory is that an individual passes on one or half of its genome to each of its progeny. The coexistence of a population of many genomes in AMF and their transfer to subsequent generations, therefore, has far-reaching consequences for understanding genome evolution.     

Genetic mechanisms and evolutionary significance of natural variation in Arabidopsis

Genomic studies of natural variation in model organisms provide a bridge between molecular analyses of gene function and evolutionary investigations of adaptation and natural selection. In the model plant species Arabidopsis thaliana, recent studies of natural variation have led to the identification of genes underlying ecologically important complex traits, and provided new insights about the processes of genome evolution, geographic population structure, and the selective mechanisms shaping complex trait variation in natural populations. These advances illustrate the potential for a new synthesis to elucidate mechanisms for the adaptive evolution of complex traits from nucleotide sequences to real-world environments.     

Adaptive evolution drives divergence of a hybrid inviability gene between two species of Drosophila

Speciation--the splitting of one species into two--occurs by the evolution of any of several forms of reproductive isolation between taxa, including the intrinsic sterility and inviability of hybrids. Abundant evidence shows that these hybrid fitness problems are caused by incompatible interactions between loci: new alleles that become established in one species are sometimes functionally incompatible with alleles at interacting loci from another species. However, almost nothing is known about the genes involved in such hybrid incompatibilities or the evolutionary forces that drive their divergence. Here we identify a gene that causes epistatic inviability in hybrids between two fruitfly species, Drosophila melanogaster and D. simulans. Our population genetic analysis reveals that this gene--which encodes a nuclear pore protein--evolved by positive natural selection in both species' lineages. These results show that a lethal hybrid incompatibility has evolved as a by-product of adaptive protein evolution.