THE EFFECTS OF KIN-STRUCTURED COLONIZATION ON NUCLEAR AND CYTOPLASMIC GENETIC DIVERSITY

We investigate kin-structured migration and its effects on patterns of genetic variation in cytoplasmic and nuclear genomes. We show that colonization events involving close relatives, such as those that might characterize range expansion and the invasion of new habitats, can change the patterns of nuclear and cytoplasmic genetic variation expected at equilibrium. The difference in the patterns of variation between the nuclear and mitochondrial genomes suggests that it may be possible to estimate the time of the effective kin-structured colonization event. Observations in several taxa are discussed in light of these findings and in relation to their known geological history.     

COST OF REPRODUCTION IN POLEMONIUM VISCOSUM: PHENOTYPIC AND GENETIC APPROACHES

I measured the effect of early reproduction on subsequent growth and survival in the alpine perennial wildflower, Polemonium viscosum. Measurements were made over 4 yr on 34 maternal sibships under natural conditions. A significant phenotypic cost of early reproduction characterized the study population. Plants that flowered after only one year's growth had twice as many leaves and 25% more shoots than nonflowering individuals of equal age. However, early flowering decreased leaf number by 18% in the subsequent year and survivorship by 20% after two years relative to changes in leaf number and survival of nonflowering plants. For such trade-offs to shape the further evolution of reproductive schedules, flowering probability and those age-specific components of plant size that represent the energetic currency for reproductive costs must be heritable. Although families showed significant heterogeneity in the probability of early flowering, most (62%) entirely failed to flower. Moreover, phenotypic variation in vegetative size components at ages 1 and 2 had little genetic basis. Only at ages 3 and 4, after vegetative and demographic costs of early reproduction had been incurred, did vegetative size components (leaf length and number, and shoot number) vary significantly among families. Results of this study provide little evidence of a genetically based trade-off between early reproduction and subsequent survival in P. viscosum.     

DETECTING RANGE EXPANSIONS FROM GENETIC DATA

We propose a method that uses genetic data to test for the occurrence of a recent range expansion and to infer the location of the origin of the expansion. We introduce a statistic ψ (the directionality index) that detects asymmetries in the 2D allele frequency spectrum of pairs of population. These asymmetries are caused by the series of founder events that happen during an expansion and they arise because low frequency alleles tend to be lost during founder events, thus creating clines in the frequencies of surviving low‐frequency alleles. Using simulations, we show that ψ is more powerful for detecting range expansions than both and clines in heterozygosity. We also show how we can adapt our approach to more complicated scenarios such as expansions with multiple origins or barriers to migration and we illustrate the utility of ψ by applying it to a data set from modern humans.     

GENETIC VARIATION AND THE EVOLUTION OF EPIGENETIC REGULATION

Epigenetic variation has been observed in a range of organisms, leading to questions of the adaptive significance of this variation. In this study, we present a model to explore the ecological and genetic conditions that select for epigenetic regulation. We find that the rate of temporal environmental change is a key factor controlling the features of this evolution. When the environment fluctuates rapidly between states with different phenotypic optima, epigenetic regulation may evolve but we expect to observe low transgenerational inheritance of epigenetic states, whereas when this fluctuation occurs over longer time scales, regulation may evolve to generate epigenetic states that are inherited faithfully for many generations. In all cases, the underlying genetic variation at the epigenetically regulated locus is a crucial factor determining the range of conditions that allow for evolution of epigenetic mechanisms.     

FINE-GRAINED SPATIAL AND TEMPORAL VARIATION IN SELECTION DOES NOT MAINTAIN GENETIC VARIATION IN ERIGERON ANNUUS

Because interactions among plants are spatially local, the scale of environmental heterogeneity can have large effects on evolutionary dynamics. However, very little is known about the spatial patterns of variation in fitness and the relative magnitude of spatial and temporal variation in selection. Replicates of 12 genotypes of Erigeron annuus (Asteraceae) were planted in 288 locations within a field, separated by distances of 0.1 to 30.0 m, and replicated in two years. In a given year, most spatial variation in relative fitness (genotype-environment [G × E] interactions for fitness) occurred over distances of only 50 cm. Year effects were as large or larger than the spatial variation in fitness; in particular there was a large, three-way, genotype-year-environment interaction at the smallest spatial scale. The genetic correlation of fitness across years at a given location was near zero, 0.03. Thus, the relative fitness of genotypes is spatially unpredictable and a map of the selective environment has constantly shifting locations of peaks and valleys. Including measurements of soil nutrients as covariates in the analysis removed most of the spatial G × E interaction. Vegetation and microtopography had no effect on the G × E terms, suggesting that differential response to soil nutrients is the cause of spatial variation in fitness. However, the slope of response to NH₄ and P0₄ was negative; therefore the soil nutrients are probably just indicators of other, unknown, environmental factors. We explored via simulation the evolutionary consequences of spatial and temporal variation in fitness and showed that, for this system, the spatial scale of variation was too fine grained (by a factor of 3 to 5) to be a powerful force maintaining genetic variation in the population. The inclusion of both spatial and temporal variation in fitness actually reduced the coexistence of genotypes compared to pure spatial models. Thus the presence of spatial or temporal variation in selection does not guarantee that it is an effective evolutionary force maintaining diversity. Instead the pattern of selection favors generalist genotypes.     

SMALL POPULATION GENETIC VARIABILITY AT LOCI UNDER STABILIZING SELECTION

Genetic variability at a locus under stabilizing selection in a finite population is investigated using analytic methods and computer simulations. Three measures are examined: the number of alleles k, heterozygosity H, and additive genetic variance Vg. A nearly-neutral theory results. The composite parameter S = NV_M/V_s (where N is the population size, V_M the variance of new mutant allelic effects and V_s the weakness of stabilizing selection) figures prominently in the results. The equilibrium heterozygosity is similar to that of strictly neutral theory, H = 4N_μc/ (1 + 4N_μc), except that μ_c = where c is about 0.5. Simulations corroborate except for very low N. Genetic variability attains similar equilibrium values at both a “lone” locus and at an “embedded” locus. This agrees with my earlier work concerning molecular clock rates. These results modify the neutralist interpretation of data concerning genetic variability and genetic distances between populations. Low H values are proportional not to N but to . This may explain the narrow observed range of H among species. Heterozygosities need not be highly correlated to genetic variances. Genetic variances are not highly dependent on population size except in very small populations which are difficult to sample without bias because the smallest populations go extinct the fastest. Nearly neutral evolution will not be easily distinguished from strictly neutral theory under the Hudson-Kreitman-Aguade inter-/intraspecific variation ratio test, since a similar effective mutation rate holds for genetic distances and D = 2μ_ct, where . As with strictly neutral theory, comparisons across loci should show D and H to be positively correlated because of the shared μ_c. But unlike neutral theory, for a given locus, comparisons across species should show D and H to be negatively correlated. There is no obvious threshold of population size below which genetic variability inevitably declines. Extinction depends on both genetic variation and natural selection. Neither theory nor observation presently indicates the measure of genetic variability (k, H, V_G or other) that best indicates vulnerability of a small population to extinction.     

红皮云杉群体遗传多样的研究

在红皮云杉(Picea korainesis)分布区内,选取了有代表性的长白山及其支脉张广才岭、老爷岭、完达山,小兴安岭,大兴安岭,大兴安岭向内蒙古高原过渡地带以及锡霍特山脉的12个群体,运用群体遗传学、生理遗传学、森林遗传学以及林木育种的理论和方法,利用主成分和分层聚类分析等多种统计分析方法,从表型和分子水平等多层次较为系统地研究了红皮云杉群体内、群体间的变异,同时探讨了各种亲代、后代特征以及等位酶与生态环境因子之间的关系。,首次从亲代生物系统学特征,后代苗木形态、生长、生物量和矿物质元素等对红皮云杉群体遗传变异进行了研究,结果表明,红皮云杉具有丰富的遗传变异,群体内变异大于群体间变异;红皮云杉12个群体11个酶系统21个位点中约有27.2%的基因位点是多态的,群体间的变异量只占总变异量的15.2%,84.8%的变异存在于群体内。红皮云杉群体等位酶多态位点的比率在云杉属中处于较低的水平,群体间的分化与云杉其它树种相比处于较高的水平。等位酶与形态等具有相似的变异趋势。根据红皮云杉气候、亲代及后代特征群体区划结果,我们认为红皮云杉种子区划为:长白山种子区(Ⅰ);老爷岭、张广才岭、完达山种子区(Ⅱ);小兴安岭种子区(Ⅲ);大兴安岭北部种子区(Ⅳ);大兴安岭西南部种子区(Ⅴ);锡霍特山脉种子区(Ⅵ)。     

两种泥鳅不同群体遗传变异的RAPD分析

应用RAPD技术,分析了采自于我国黄河、长江和珠江三大水系中游的大鳞副泥鳅和泥鳅不同群体间的遗传变异。结果表明：种内不同群体间带纹相似度在0．730－0．938之间;遗传距离为0．089－0．245;种间不同群体间的带纹相似度为0．392－0．505,遗传距离为0．620－0．800。两种泥鳞采自武汉的群体,其不同个体间的相似度较之其它群体为低,表明其群体内遗传变异程度较高。     

中国脊髓灰质炎病毒疫苗株基因特征及其神经毒力的初步观察

中国脊髓灰质炎病毒疫苗株普遍存在基因变异的现象,如重组,点突变等。我们选出１０株有代表性的变异株,在具有人脊灰病毒受体基因的转基因小鼠ＰＶＲ－Ｔｇ２１中做毒力分析,发现Ｓａｂｉｎ １基因型与野毒基因型的重组株显示很强的神经毒力,其ＰＤ５０ｉｎＴＣＩＤ５０值为４．５,而Ｓｂｉｎ１标准株的ＰＤ５０值大于８０。另外两株Ｉ型疫苗株只有关键性核苷酸位点发生突变,只在位点５２５－发生突变的一株,其ＰＤ５０值为     

用DNA指纹法研究野生天鹅种群的遗传分化

DNA指纹技术自问世以来,已被广泛地用于法医学上个体识别和亲缘关系的鉴定。此外,人源DNA指纹探针(即多位点型小卫星探针)还被用于动植物等的研究,特别是在研究动物的繁育规律方面成效显著。近一两年来,DNA指纹技术也在分子水平上用来研究种群分化,为物种起源研究开辟了新的途径。本文利用人源多位点型小卫星探针,对分布在英国和美国的四种天鹅(小天鹅、疣鼻天鹅、大天鹅和喇叭天鹅)的种群结构和天鹅小卫星的分化初步进行了研究。用酶HaeIII和探针pSPT19.6分析了分布在英国的疣鼻天鹅种的两个群体(洛锡安群体和阿伯茨伯里群体)的DNA指纹图,结果表明两群体之间的遗传变异性大于群体内的遗传变异性;洛锡安群体内小卫星的变异程度较高。虽然小卫星在基因组中的作用尚不清楚,但某些天鹅小卫星在种间发生了分化,因而同一个种内不同个体的DNA指纹图有一些共同的特征,导致DNA指纹图的物种特异性。DNA指纹分析表明:小天鹅、大天鹅和喇叭天鹅在遗传上比较接近,而疣鼻天鹅与它们在遗传上相距较远,这与原来对天鹅种下分类情况是一致的。就遗传变异程度而言,在英国仕林布里奇的小天鹅为最高,英国卡拉乌尔洛克的大天鹅次之,英国阿伯茨伯里的疣鼻天鹅居第三,美国蒙大拿的喇叭天鹅最低。我们认为,基因迁移和遗传漂变对     

丙型肝炎病毒基因高变区变异的动力学研究

本文旨在对ＨＣＶ的基因高变区的变异规律进行初步探索。根据随访的５年、分别检测３个两例的ＨＣＶ持续感染者的高变区基因变异的资料分析,发现高变区的变异可能有两种不同的动态模式;一种为快速演变模式,表现为基因变异速度快、优势克隆转化快和同一时间点各克隆的遗传距离近;另一种灯对缓慢演变模式,表现为基因变异速度缓慢,优势克隆转化不明显,同一时间点不同克隆间的遗传距离远。该研究结果显示,ＨＣＶ高变区基因变划具     

微卫星标记对黑龙江流域大麻哈鱼遗传多样性的研究

采用 12个微卫星标记 ,对中国 3个大麻哈鱼洄游群体 (乌苏里江、黑龙江和绥芬河 )的遗传多样性进行了检测。计算出各个种群的基因杂合度、遗传多样性和各个座位的多态信息含量。结果表明 ,3个大麻哈鱼洄游种群的平均基因杂合度分别为 :0 .6 732、0 5 995、0 .6 917,种群遗传多样性分别为 0 .70 82、0 .6 5 11、0 .76 16。这些结果表明大麻哈鱼遗传多样性还比较丰富 ,其资源的恢复具有良好的前景 ,说明当前中国大麻哈鱼资源数量下降并非由遗传因素引起 ,主要原因可能是由于过度捕捞和水域环境污染等人为因素造成。人工增殖放流为恢复中国大麻哈鱼资源起到了重要作用 ,但目前大麻哈鱼的小种群极易产生遗传瓶颈的现状也应引起人们高度重视     

GENETIC VARIATION FOR FEMALE MATE DISCRIMINATION IN DROSOPHILA MELANOGASTER

Comparisons between the Canton-S and Tai-Y strains of Drosophila melanogaster (both wild type) revealed variation in female mate discrimination based on chemical courtship signals present as hydrocarbons on the male cuticle. Mating tests indicated that 7-tricosene, which is the primary hydrocarbon on the Canton-S male cuticle but is nearly absent from Tai-Y, was a significant component of the signal. The discrimination was asymmetrical in that Canton-S females clearly distinguished between the two types of males in no-choice tests, but Tai-Y females did not. F₁ females expressed an intermediate ability to discriminate, and female progeny of backcrosses expressed a mating phenotype very similar to that of the parental strain to which the backcross was made. Analysis of independent effects from the X and both major autosomes indicated that the discrimination is controlled by gene(s) on chromosome 3.     

GENETIC VARIATION IN INBREEDING DEPRESSION IN THE RED FLOUR BEETLE TRIBOLIUM CASTANEUM

Inbreeding depression varies among species and among populations within a species. Few studies, however, have considered the extent to which inbreeding depression varies within a single population. We report on two experiments to provide evidence that inbreeding depression is genetically variable, such that within a single population some lineages suffer severe inbreeding depression, others suffer only mild inbreeding depression, and some lineages actually increase in phenotypic value at higher levels of inbreeding. We examine the effects of population structure on inbreeding depression for two traits in the first experiment (adult dry weight and female relative fitness), and for seven traits in the second experiment (female and male adult dry weight, female and male relative fitness, female and male developmental time, and egg-to-adult viability). In the first experiment, we collected data from 4 families within each of 38 lineages derived from a single ancestral stock population and maintained for four generations of full-sib mating. Both traits demonstrate significant inbreeding depression and provide evidence that even within a single lineage there is significant genetic variability in inbreeding depression. In the second experiment, we collected data from 5 replicates for each of 15 lineages derived from the same ancestral population used in the first experiment; these lineages were maintained for four generations of full-sib mating. We also collected data on outbred control beetles in each generation and incorporated these data into the analyses to account for environmental effects in an unbiased manner. All traits except female and male developmental time show significant inbreeding depression. All traits showing inbreeding depression are genetically variable in inbreeding depression, as is evident from a significant linear lineage-×-f component. For both experiments, the effect of population structure on inbreeding depression is further evident from the increasing amount of variation that can be explained by the models used to measure inbreeding depression when additional levels of population structure are included. Genetic variation in inbreeding depression has important implications for conservation biology and may be an important factor in mating-system evolution.     

A MORPHOLOGIC AND GENETIC STUDY OF THE ISLAND FOX,UROCYON LITTORALIS

The Island Fox, Urocyon littoralis, is a dwarf form found on six of the Channel Islands located 30–98 km off the coast of southern California. The island populations differ in two variables that affect genetic variation: effective population size and duration of isolation. We estimate that the effective population size of foxes on the islands varies from approximately 150 to 1,000 individuals. Archeological and geological evidence suggests that foxes likely arrived on the three northern islands minimally 10,400–16,000 years ago and dispersed to the three southern islands 2,200–4,300 years ago. We use morphometrics, allozyme electrophoresis, mitochondrial DNA (mtDNA) restriction-site analysis, and analysis of hypervariable minisatellite DNA to measure variability within and distances among island fox populations. The amount of within-population variation is lowest for the smallest island populations and highest for the mainland population. However, the larger populations are sometimes less variable, with respect to some genetic measures, than expected. No distinct trends of variability with founding time are observed. Genetic distances among the island populations, as estimated by the four techniques, are not well correlated. The apparent lack of correspondence among techniques may reflect the effects of mutation rate and colonization history on the values of each genetic measure.     

THE EVOLVING GENETIC HISTORY OF A POPULATION OF LATHYRUS SYLVESTRIS: EVIDENCE FROM TEMPORAL AND SPATIAL GENETIC STRUCTURE

We analyze patterns of genetic microdifferentiation within a natural population of Lathyrus sylvestris, a perennial herb with both sexual reproduction and clonal growth. In a population from the northern foothills of the Pyrénées in southwestern France, a combined demographic and genetic investigation enabled the study not only of spatial genetic structure of the population, but also of the history of the population's spatial genetic structure over time. Excavation of all individuals allowed identification of clonemates. Age of each individual was determined by counting annual growth rings in the taproot, a method tested with individuals of known age planted in experimental gardens. Each individual was mapped, and genotypes of all individuals were determined using allozyme markers for a number of polymorphic loci. Distribution patterns and spatial genetic structure, both for all individuals and for different age classes, were analyzed using spatial autocorrelation statistics (Geary's Index, Moran's Index). Patterns of gene flow within the population were also studied using F-statistics and tests for random associations of alleles. Because age, allele frequencies, and location were known for each individual, it was possible to study how spatial genetic structure changed over time. Results from all these diverse approaches are consistent with one another, and clearly show the following: (1) founder effects, with the study transect being first colonized by individuals at either end of the transect that were homozygous for different alleles at one marker locus; (2) a difference in spatial distribution of individuals originated from sexual reproduction (seedlings) and from clonal growth (connected individuals); (3) restricted gene flow, due to inbreeding among related, clumped individuals; and (4) increase in heterozygote deficit within the youngest cohort of individuals. The results indicate that genetic differentiation in time was much less marked than differentiation in space. Nevertheless, the results revealed that the studied population is experiencing demographic and genetic variation in time, suggesting that it is not at equilibrium. On the one hand, spatial structuring is becoming less marked due to the recombination of founder genotypes; on the other hand, as establishment of new individuals increases, a new spatial structure emerges due to mating between relatives.     

凉水国家自然保护区天然红松林遗传变异的RAPD分析

采用随机扩增多态DNA(random amplified polymorphic DNA RAPD)技术,研究了凉水国家自然保护区天然红松林的遗传变异水平及其分布规律。16个10bp长度的随机引物在8个实验样地内72个个体中共检测了96个位点,其中55个是多态位点。在种水平上,红松的多态位点比率为P=58.51%;Nei's遗传变异指数为H=0.2868;Shannon's指数为I=0.3654,所有的变异中,有92.47%的变异存在于样地内, 7.53%的变异存在于样地间。根据各遗传多样性在不同样地的分布,初步探讨了红松遗传变异水平与其种群发生及生境的相互关系。     

LIFE-CYCLE COMPONENTS OF SELECTION IN ERIGERON ANNUUS: II. GENETIC VARIATION

Genetic variation for seedling and adult fitness components was measured under natural conditions to determine the relative importance of the seedling stage for lifetime fitness in Erigeron annuus. Variation in lifetime reproductive success can result from both the persistent effects of genetic variation expressed among seedlings and from variation in adult fitness components. Analysis of covariance was used to separate the stage specific from the cumulative effects of genetic variance expressed earlier in the life cycle. E. annuus produces seeds through apomixis, which allowed measurement of the fitness of replicate genotypes from germination through the entire life cycle. There were significant differences among genotypes for date of emergence, seedling size, survivorship and fecundity, but heritabilities were low, indicating slow response to selection. For all characters, environmental components of variance were one to two orders of magnitude larger than genetic variance components, resulting in broad sense heritabilities less than 0.1. For seedling size and fecundity, all of the genetic variance was in the form of genotype-environment interactions, often with large negative genetic correlations across environments. In contrast, genotypes differed in mean survivorship through one year, but there were no genotype-environment interactions for viability. Genetic differences in viability were primarily expressed as differences in overwinter survivorship. Genotype × environment interactions among sites and blocks were generated early in the life cycle while the genotype × environment interactions in response to competitive environment (open, annual cover, perennial cover) first appeared in adult fecundity. Genetic variation in lifetime fitness was not significant, despite a fourfold difference in mean fitness among genotypes.     

GENETIC VARIABILITY,QUEEN NUMBER,AND POLYANDRY IN SOCIAL HYMENOPTERA

Several hypotheses have been put forward to explain the adaptive significance of interspecific variation in mating frequencies by eusocial hymenopteran queens. Four of these hypotheses assert that polyandry is advantageous to queens because of the resultant increase in genetic variability within colonies (referred to as the “GV” hypotheses). Here we compare the frequency of polyandry between monogynous (single-queen) and polygynous (multiple-queen) ant species to test the hypotheses that (1) multiple mating functions primarily to increase intracolonial genetic variability, and (2) mating has costs (such as increased energetic losses or risk of predation or venereal disease). If one of the GV hypotheses is true and mating is costly, the frequency of polyandry should be lower in polygynous species (in which the presence of multiple queens results in low relatedness among workers) than in monogynous species. As predicted by the GV hypotheses, polyandry is less common among polygynous than among monogynous species. Furthermore, it seems that the causal relationship underlying this association is that the number of matings by queens depends on the number of queens present in the colony (rather than the number of queens being influenced by the number of matings), which also supports the GV hypotheses together with the assumption that mating has costs.     

MAINTENANCE OF POLYGENIC VARIATION IN SPATIALLY STRUCTURED POPULATIONS: ROLES FOR LOCAL MATING AND GENETIC REDUNDANCY

Although heritable genetic variation is critical to the evolutionary process, we know little about how it is maintained. Obviously, mutation-selection balance must play a role, but there is considerable doubt over whether it can account for heritabilities as high as 0.5, which are commonly found in natural populations. Most models of mutation-selection balance assume panmictic populations. In this paper we use Monte Carlo simulations to examine the effect of isolation by distance on the variation maintained by mutation in a polygenic trait subject to optimizing selection. We show that isolation by distance can substantially increase the total variation maintained in continuous populations over a wide range of dispersal patterns, but only if more than one genotype produces the optimal phenotype (genetic redundancy). Isolation by distance alone has only a slight effect on the variation maintained in the total population for neutral alleles. The combined effect of isolation by distance and genetic redundancy, however, allows the maintenance of substantial variation despite strong stabilizing selection. The mechanism is straightforward. Isolation by distance allows mutation and drift to operate independently in different parts of the population. Because of their independent evolutionary histories, different parts of the population independently draw from the available set of redundant genotypes. Because the genotypes are redundant, selection does not discriminate among them, and they will persist until eliminated by drift. The population as a whole maintains many distinct genotypes. We show that this process allows mutation to maintain high levels of variation, even under strong stabilizing selection, and that over a moderate range of dispersal patterns the amount of variation maintained in the entire population is independent of both the strength of selection and the variance of the dispersal distance. Furthermore, we show that individual heterozygosity is increased in locally mating populations when selection is strong. Finally, our simulations provide a rough picture of how selection and the dispersal pattern influence the spatial distribution of genetic and phenotypic variation.