996 resultados para Ecological Genetics
Resumo:
One of the main aims of evolutionary biology is to explain why organisms vary phenotypically as they do. Proximately, this variation arises from genetic differences and from environmental influences, the latter of which is referred to as phenotypic plasticity. Phenotypic plasticity is thus a central concept in evolutionary biology, and understanding its relative importance in causing the phenotypic variation and differentiation is important, for instance in anticipating the consequences of human induced environmental changes. The aim of this thesis was to study geographic variation and local adaptation, as well as sex ratios and environmental sex reversal, in the common frog (Rana temporaria). These themes cover three different aspects of phenotypic plasticity, which emerges as the central concept for the thesis. The first two chapters address geographic variation and local adaptation in two potentially thermally adaptive traits, namely the degree of melanism and the relative leg length. The results show that although there is an increasing latitudinal trend in the degree of melanism in wild populations across Scandinavian Peninsula, this cline has no direct genetic basis and is thus environmentally induced. The second chapter demonstrates that although there is no linear, latitudinally ordered phenotypic trend in relative leg length that would be expected under Allen s rule an ecogeographical rule linking extremity length to climatic conditions there seems to be such a trend at the genetic level, hidden under environmental effects. The first two chapters thus view phenotypic plasticity through its ecological role and evolution, and demonstrate that it can both give rise to phenotypic variation and hide evolutionary patterns in studies that focus solely on phenotypes. The last three chapters relate to phenotypic plasticity through its ecological and evolutionary role in sex determination, and consequent effects on population sex ratio, genetic recombination and the evolution of sex chromosomes. The results show that while sex ratios are strongly female biased and there is evidence of environmental sex reversals, these reversals are unlikely to have caused the sex ratio skew, at least directly. The results demonstrate that environmental sex reversal can have an effect on the evolution of sex chromosomes, as the recombination patterns between them seem to be controlled by phenotypic, rather than genetic, sex. This potentially allows Y chromosomes to recombine, lending support for the recent hypothesis suggesting that sex-reversal may play an important role on the rejuvenation of Y chromosomes.
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The North Atlantic intertidal community provides a rich set of organismal and environmental material for the study of ecological genetics. Clearly defined environmental gradients exist at multiple spatial scales: there are broad latitudinal trends in temperature, meso-scale changes in salinity along estuaries, and smaller scale gradients in desiccation and temperature spanning the intertidal range. The geology and geography of the American and European coasts provide natural replication of these gradients, allowing for population genetic analyses of parallel adaptation to environmental stress and heterogeneity. Statistical methods have been developed that provide genomic neutrality tests of population differentiation and aid in the process of candidate gene identification. In this paper, we review studies of marine organisms that illustrate associations between an environmental gradient and specific genetic markers. Such highly differentiated markers become candidate genes for adaptation to the environmental factors in question, but the functional significance of genetic variants must be comprehensively evaluated. We present a set of predictions about locus-specific selection across latitudinal, estuarine, and intertidal gradients that are likely to exist in the North Atlantic. We further present new data and analyses that support and contradict these simple selection models. Some taxa show pronounced clinal variation at certain loci against a background of mild clinal variation at many loci. These cases illustrate the procedures necessary for distinguishing selection driven by internal genomic vs. external environmental factors. We suggest that the North Atlantic intertidal community provides a model system for identifying genes that matter in ecology due to the clarity of the environmental stresses and an extensive experimental literature on ecological function. While these organisms are typically poor genetic and genomic models, advances in comparative genomics have provided access to molecular tools that can now be applied to taxa with well-defined ecologies. As many of the organisms we discuss have tight physiological limits driven by climatic factors, this synthesis of molecular population genetics with marine ecology could provide a sensitive means of assessing evolutionary responses to climate change.
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In the present work, we apply both traditional and Next Generation Sequencing (NGS) tools to investigate some of the most important adaptive traits of wolves (Canis lupus). In the first part, we analyze the variability of three Major Histocompatibility Complex (MHC) class II genes in the Italian wolf population, also studying their possible role in mating choice and their influence on fitness traits. In the second section, as part of a larger canid genome project, we will exploit NGS data to investigate the transcript-level differences between the wolf and the dog genome that can be correlated to domestication.
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Melaleuca quinquenervia (Cav.) Blake (Myrtaceae) was imported into Florida from Australia over a century ago as a landscape plant. A favorable climate and periodic wildfires helped M. quinquenervia thrive; it now occupies about 200,000 hectares in southern Florida. A biological control (i.e., biocontrol) program against M. quinquenervia has been initiated, but not all biocontrol releases are successful. Some scientists have argued that poor biocontrol agent success may relate to genetic differences among populations of invasive weeds. I tested this premise by determining (1) the number and origins of M. quinquenervia introductions into Florida, (2) whether multiple introduction events resulted in the partitioning of Florida's M. quinquenervia populations into discrete biotypes, and (3) whether Oxyops vitiosa, an Australia snout beetle imported to control this weed, might discriminate among putative M. quinquenervia biotypes. Careful scrutiny of early horticultural catalogs and USDA plant introduction records suggested at least six distinct introduction events. Allozyme analyses indicated that the pattern of these introductions, and the subsequent redistribution of progeny, has resulted in geographic structuring of the populations in southern Florida. For example, trees on Florida's Gulf Coast had a greater effective number of alleles and exhibited greater heterozygosity than trees on the Atlantic Coast. Essential oil yields from M. quinquenervia leaves followed a similar trend; Gulf Coast trees yielded nearly twice as much oil as Atlantic Coast trees when both were grown in a common garden. These differences were partially explained by the predominance of a chemical phenotype (chemotype) very rich in the sesquiterpene (E)-nerolidol in M. quinquenervia trees from the Gulf Coast, but rich in a mixture of the monoterpene 1,8-cineole and the sesquiterpene viridiflorol in trees from the Atlantic Coast. Performance of O. vitiosa differed dramatically in laboratory studies depending on the chemotype of the foliage they were fed. Larval survivorship was four-fold greater on the (E)-nerolidol chemotype. Growth was also greater, with adult O. vitiosa gaining nearly 50% more biomass on the (E)-nerolidol plants than on the second chemotype. The results of this study thus confirmed the premise that plant genotype can affect the population dynamics of insects released as weed biocontrols. ^
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Brain size and architecture exhibit great evolutionary and ontogenetic variation. Yet, studies on population variation (within a single species) in brain size and architecture, or in brain plasticity induced by ecologically relevant biotic factors have been largely overlooked. Here, I address the following questions: (i) do locally adapted populations differ in brain size and architecture, (ii) can the biotic environment induce brain plasticity, and (iii) do locally adapted populations differ in levels of brain plasticity? In the first two chapters I report large variation in both absolute and relative brain size, as well as in the relative sizes of brain parts, among divergent nine-spined stickleback (Pungitius pungitius) populations. Some traits show habitat-dependent divergence, implying natural selection being responsible for the observed patterns. Namely, marine sticklebacks have relatively larger bulbi olfactorii (chemosensory centre) and telencephala (involved in learning) than pond sticklebacks. Further, I demonstrate the importance of common garden studies in drawing firm evolutionary conclusions. In the following three chapters I show how the social environment and perceived predation risk shapes brain development. In common frog (Rana temporaria) tadpoles, I demonstrate that under the highest per capita predation risk, tadpoles develop smaller brains than in less risky situations, while high tadpole density results in enlarged tectum opticum (visual brain centre). Visual contact with conspecifics induces enlarged tecta optica in nine-spined sticklebacks, whereas when only olfactory cues from conspecifics are available, bulbus olfactorius become enlarged.Perceived predation risk results in smaller hypothalami (complex function) in sticklebacks. Further, group-living has a negative effect on relative brain size in the competition-adapted pond sticklebacks, but not in the predation-adapted marine sticklebacks. Perceived predation risk induces enlargement of bulbus olfactorius in pond sticklebacks, but not in marine sticklebacks who have larger bulbi olfactorii than pond fish regardless of predation. In sum, my studies demonstrate how applying a microevolutionary approach can help us to understand the enormous variation observed in the brains of wild animals a point-of-view which I high-light in the closing review chapter of my thesis.
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本报告对木根麦冬的生态、遗传与进化等方面进行了综合研究,分析了木根麦冬居群内个体育性变异与基因流的模式与强度,研究了木根麦冬居群遗传变异在时间与空间的动态变化过程,深入探讨了该物种的适应策略、自然选择与进化模式。同时对生物进化中的一些基本问题进行了尝试性探讨。 一、影响有性繁殖生物居群中交配与繁殖成功的行为、生态与遗传现象最终决定等位基因与基因型的相对频率及其在世代间的变化。植物的交配系统不仅决定了居群未来世代的基因型频率,而且还影响到植物居群的有效大小、基因流和选择等其它进化因素。我们利用等位酶多态性,采用似然性方法与计算机模拟为木根麦冬三个居群的种子确定父本。共有90.1%的种子可以在居群中找到唯一的最可能父本。在这些种子中,56.1%在0.95的显著水平上可以确定唯一亲本。并且还发现:1.个体自交越多,产生的种子就越多;2.个体提供 给自己的有效花粉比提供给别的植株的有效花粉多,3.只接受花粉而不提供花粉的植株产生的种子少;4.只接受花粉而不提供花粉的植株产生种子的机会也少,综合我们以前的研究结果,可以认为,木根麦冬的交配系统正在或已经发 生了转变,从以异交为主到以自交为主。 二、点模式分析的结果表明在所研究的三个居群中,木根麦冬个体都表现出相对随机的分布。空间自相关分析却发现开花个体在空间聚集分布,呈斑块状开花。这个结果也表明个体空间分布模式与开花状态没有直接关系,集团性开花可能是一个促进花粉传播的适应特征:开花个体的聚集可能对传粉者形成强有力的吸引。空间自相关分析表明木根麦冬居群中大多数等位基因都聚集成一定大小的斑块。基因的聚集突出的说明了木根麦冬居群内基因流动的状况,花粉与种子的传播受到限制。传粉能力弱的传粉者以及种子的近距离的散布使基因局限于一定的小范围内,从而形成基因斑块,而斑块的大小由传粉者的活动范围及种子的传播距离决定。 三、基因纯合导致有害的隐性基因或部分致死的基因表达,使纯合子适合度降低,因此纯合子频率在世代间的变化将是衡量近交衰退的一个较好的指标。木根麦冬中亲代居群的观察杂合度大大高于子代居群,这个结果表明大量的纯合子在从种子到成株的过程中被淘汰。大量的纯合子被淘汰可能时由于隐性致死或有害等位基因纯合的结果,自交以及有亲缘关系的个体之间交配使有害等位基因与致死等位基因纯合,从而使一个远交种中出现自交衰退,过量的纯合子被淘汰是自交衰退的直接后果。
Resumo:
种间杂交在自然界中普遍存在。杂交可以为群体带来多方面的遗传改变,具有重要的进化生物学意义。越来越多的证据表明,同倍性杂交物种形成是一种重要物种形成途径,在动、植物物种进化中扮演着重要的角色。同倍性杂交物种形成意味着一个稳定的、可育的、与亲本种间形成生殖隔离的杂种群体建立起来,但不改变染色体的数目。这种生殖隔离被认为是通过快速的染色体重组、生态分化、或空间分离形成的。对于现存杂交种的对比分析和对同倍性杂交物种形成的理论模拟都表明,适应性分化和生态转变在同倍性杂交物种形成中起着至关重要的作用。来自于生态成种的研究也表明生态选择自身就可以导致生殖隔离的形成和新物种的形成。尽管如此,我们对同倍性杂交物种形成过程的研究仍然较多地关注于染色体重组及相应的遗传效应;对于自然选择,特别是生态选择在同倍性杂交成种过程中的作用模式缺乏全面地了解。 本研究以同倍性杂交种-高山松为研究对象,利用地理信息学技术、基于天然群体取样的性状对比分析和人工杂交手段,全面地定量描述了高山松及其亲本种间的生态分化、生态转变下的天然群体生殖适应性、以及生态选择下的形态变异和种间杂交可配性。以此探讨了高山松的杂交成种过程,生态转变和自然选择的重要性以及它们与杂交种适应性、形态变异和生殖隔离之间的关系。利用地理信息学手段,对高山松及其亲本种间的生态分化对比分析表明:高山松与其亲本种间形成了明显的生态转变;在自然选择的作用下,高山松已经具备了对于青藏高原东南缘横断山区高山地带独特的生态适应性;相对于亲本种,它的适应性特征体现为混合型,在某些性状上它高出亲本种的适应性,在另一些性状上,它体现出居中、较低或者类似于亲本种适应性;高山松适生区由于地形地貌的复杂性,往往不连续,呈间断状。基于四个反映结实效率的性状、小孢子母细胞减数分裂异常现象及花粉萌发率在种间的对比分析表明,这些反映生殖状态的指标,在三个种及群体间并没有显著差异;相对于亲本种的天然群体,居于青藏高原的高山松群体,表现出了正常的授粉效率和生殖适应性。高山松天然群体正常的生殖效率表明,它经历了生态转变过程中的选择作用,已经具备了在新生境下,繁殖发展下去的生殖适应性。 在大规模群体取样的基础上,通过对反映植物个体发育和营养状态的球果和针叶形态性状的对比分析,我们发现,高山松及其亲本种间的形态变异存在以下特征:第一,绝大多数性状,在种间和种内群体间都存在着显著的差异,并且大部分性状的差异主要体现在种间;第二,高山松在大部分形态性状上介于两个亲本种之间,少数性状表现为超亲分离、类似于某个亲本或无种间差别;第三,在多数性状上,和亲本种相比,高山松群体都拥有较大的变异幅度。第四,在临近亲本种的群体中,高山松的形态特征更类似于所临近的亲本种。上述形态变异特征及其与气象、土壤、经纬度、海拔等因子间普遍的相关性,意味着生态选择在高山松成种过程中起了重要作用。总的来说,形态性状变异的总体模式揭示出:高山松在选择作用下的遗传和表型的精炼过程中已经形成了自身适应于高原环境的、稳定而有效的形态发育模式和资源利用方式,甚至是恰当的防御机制。 本研究通过云南松×油松的单交实验和油松×高山松部分双列杂交实验,检验了高山松及其亲本种间的杂交可配性。结果表明,就平均水平而言,高山松及其亲本种间的种间杂交结实可配性低于种内杂交,但个别种间杂交组合的结实可配性可能高于种间杂交;高山松及其亲本种间正在或已经形成了部分的合子后生殖障碍;现存的高山松群体及其亲本种间的生态地理隔离可能是很有效的生殖隔离形式,一方面做为合子前生殖隔离,它能避免种间相互传粉、阻碍种间杂交的发生,另一方面做为合子后生殖隔离,它能清除掉可能存在的劣势回交产物。 综合已有的证据,我们提出了高山松同倍性杂交物种形成模型:高山松的同倍性杂交成种是与青藏高原隆升过程以及隆升过程中所产生的全新生态空间紧密相关的;青藏高原隆升导致了生态环境的剧变,创造了全新的生态位,在选择的作用下,拥有综合了双亲遗传基础的杂种基因型开始占领这个全新的生态位;在分化的生态选择的持续作用下,杂种基因型在新的生境下稳定下来,形成了独立于亲本种的资源利用方式、形态特征和繁育系统,具备了完善的生殖和生态适应性;此时,一个与亲本种间以生态隔离存在的同倍性杂交种-高山松形成了;随着分化的生态选择的持续进行,高山松与亲本种间的内在生殖隔离不断加强。
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SOX3 has been suggested to play significant roles in gametogenesis and gonad differentiation of vertebrates, but the exact cellular localization evidence is insufficient and controversial. In this study, a protogynous hermaphrodite fish Epinephelus coioides is selected to analyze EcSox3 differential expression and the expression pattern in both processes of oogenesis and spermatogenesis by utilizing the advantages that gonad development undergoes transition from ovary to intersexual gonad and then to testis, and primordial germ cells and different stage cells during oogenesis and spermatogenesis are synchronously observed in the transitional gonads. The detailed and clear immunofluoresence localization indicates that significantly differential expression and dynamic changes of Sox3 occur in the progresses of gametogenesis and sex reversal, and EcSOX3 protein exists in the differentiating primordial germ cells, oogonia, and different stage oocytes of ovaries, and also in the differentiating primordial germ cells and the Sertoli cells of testis. One important finding is that the EcSox3 expression is a significant time point for enterable gametogenesis of primordial germ cells because EcSOX3 is obviously expressed and localized in primordial germ cells. As EcSox3 continues to express, the EcSOX3-positive primordial germ cells develop toward oogonia and then oocytes, whereas when EcSox3 expression is ceased, the EcSOX3-positive primordial germ cells develop toward spermatogonia. Therefore, the current finding of EcSOX3 in the differentiating primordial germ cells again confirms the potential regulatory role in oogenesis and germ cell differentiation. The data further suggest that SOX3, as a transcription factor, might have more important roles in oogenesis than in spermatogenesis.
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Parasitoids are the most important natural enemies of many insect species. Larvae of many Drosophila species can defend themselves against attack by parasitoids through a cellular immune response called encapsulation. The paper reviews recent studies of the evolutionary biology and ecological genetics of resistance in Drosophila, concentrating on D. melanogaster. The physiological basis of encapsulation, and the genes known to interfere with resistance are briefly summarized. Evidence for within- and between-population genetic variation in resistance from isofemale line, artificial selection and classical genetic studies are reviewed. There is now firm evidence that resistance is costly to Drosophila, and the nature of this cost is discussed, and the possibility that it may involve a reduction in metabolic rate considered. Comparative data on encapsulation and metabolic rates across seven Drosophila species provides support for this hypothesis. Finally, the possible population and community ecological consequences of evolution in the levels of host resistance are examined.
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Conselho Nacional de Desenvolvimento Científico e Tecnológico (CNPq)
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Comparing introduced to ancestral populations within a phylogeographical context is crucial in any study aiming to understand the ecological genetics of an invasive species. Zaprionus indianus is a cosmopolitan drosophilid that has recently succeeded to expand its geographical range upon three continents (Africa, Asia and the Americas). We studied the distribution of mitochondrial DNA (mtDNA) haplotypes for two genes (CO-I and CO-II) among 23 geographical populations. mtDNA revealed the presence of two well-supported phylogenetic lineages (phylads), with bootstrap value of 100%. Phylad I included three African populations, reinforcing the African-origin hypothesis of the species. Within phylad II, a distinct phylogeographical pattern was discovered: Atlantic populations (from the Americas and Madeira) were closer to the ancestral African populations than to Eastern ones (from Madagascar, Middle East and India). This means that during its passage from endemism to cosmopolitanism, Z. indianus exhibited two independent radiations, the older (the Eastern) to the East, and the younger (the Atlantic) to the West. Discriminant function analysis using 13 morphometrical characters was also able to discriminate between the two molecular phylads (93.34 +/- 1.67%), although detailed morphological analysis of male genitalia using scanning electron microscopy showed no significant differences. Finally, crossing experiments revealed the presence of reproductive barrier between populations from the two phylads, and further between populations within phylad I. Hence, a bona species status was assigned to two new, cryptic species: Zaprionus africanus and Zaprionus gabonicus, and both were encompassed along with Z. indianus and Zaprionus megalorchis into the indianus complex. The ecology of these two species reveals that they are forest dwellers, which explains their restricted endemic distribution, in contrast to their relative cosmopolitan Z. indianus, known to be a human-commensal. Our results reconfirm the great utility of mtDNA at both inter- and intraspecific analyses within the frame of an integrated taxonomical project.
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Most lizards feed on a variety of food items that may differ dramatically in their physical and behavioral characteristics. Several lizard families are known to feed upon hard-shelled prey (durophagy). Yet, specializations toward true molluscivory have been documented for only a few species. As snails are hard and brittle food items, it has been suggested that a specialized cranial morphology, high bite forces, and an adapted feeding strategy are important for such lizards. Here we compare head and skull morphology, bite forces, and feeding kinematics of a snail-crushing teiid lizard (Dracaena guianensis) with those in a closely related omnivorous species (Tupinambis merianae). Our data show that juvenile D. guianensis differ from T. merianae in having bigger heads and greater bite forces. Adults, however, do not differ in bite force. A comparison of feeding kinematics in adult Dracaena and Tupinambis revealed that Dracaena typically use more transport cycles, yet are more agile in manipulating snails. During transport, the tongue plays an important role in manipulating and expelling shell fragments before swallowing. Although Dracaena is slow, these animals are very effective in crushing and processing hard-shelled prey. J. Exp. Zool. 317A:371381, 2012. (c) 2012 Wiley Periodicals, Inc.
