植物保护遗传学

从遗传多样性、系统发育和地理系统发育角度对当前保护遗传学在植物保护中的作用进行了探讨。在植物保护过程中,要考虑多群遗传多样性的大小,在就地和迁地保护的过程要减少近交和远交衰退影响,并可利用遗传标记为提供关于种群大小、基因流动等方面的信息。系统发育和地理系统发育的研究在于了解物种进化的历史,以确定物种保护单元。同时结合两个具体生态学问题（生境片段化和外来种）对当前植物保护遗传学的研究进行了介绍,揭示了保护遗传学在植物保护上重要作用和不可取代性,为今后研究提供参考。     

The use of agent-based modelling of genetics in conservation genetics studies

Animal Landscape and Man Simulation System a genetically explicit agent-based model was used to obtain measures for the genetic and demographic status of simulated populations. This investigation aimed to test the applicability of this approach for assessing the effect of environmental perturbations on populations’ temporal and spatial dynamics. This was achieved by assessing how three simple scenarios with increasing degree of environmental disturbance, simulated by populations bottlenecks repeated at different intervals, affected the genetic and demographic characteristics of the simulated population. Model outputs from a simplified landscape scenario concurred with theoretical expectations validating the model in a qualitative way. Differences in medians, means and coefficient of variation of the observed (H_o) and expected heterozygosity (H_e), population census size (N), effective population size (N_e), inbreeding coefficient (F) and N_e/N ratio were observed for simulated populations. Impacts occurred rapidly after simulated bottleneck events and genetic estimates were less variable, and therefore more reliable, than demographic estimates. Precise genetic consequences of the bottlenecks repeated at different intervals, and resulting population perturbations, are a complex balance between effects on population sub-structure, size and founding events. Agent-based models are appropriate tools to simulate these interactions, being sufficiently flexible to mimic real population processes under a range of environmental conditions. Such models incorporating explicit genetics provide a promising new approach to evaluate the impact of environmental changes on genetic composition of populations.     

生态遗传学在生物多样性保护中的作用

本文就生态遗传学在生物多样性保护中的作用问题谈了几点看法。首先陈述了生态遗传学的性质,它是种群生态学和种群遗传学的结合,研究种群层次上正在进行着的进化;其次列举了生态遗传学的基本内容,说明生态遗传学是生物多样性研究和保护不可缺少的基本知识。最后举两个实例阐明生态遗传学在生物多样性保护中的具体应用。     

Genomics and conservation genetics

In large part, the relevance of genetics to conservation rests on the premise that neutral marker variation in populations reflects levels of detrimental and adaptive genetic variation. Despite its prominence, this tenet has been difficult to evaluate, until now. As we discuss here, genome sequence information and new technological and bioinformatics platforms now enable comprehensive surveys of neutral variation and more direct inferences of detrimental and adaptive variation in species with sequenced genomes and in 'genome-enabled' endangered taxa. Moreover, conservation schemes could begin to consider specific pathological genetic variants. A new conservation genetic agenda would utilize data from enhanced surveys of genomic variation in endangered species to better manage functional genetic variation.     

植物保护遗传学研究进展

保护遗传学是过用遗传学的原理和研究手段,以生物多样性尤其是遗传多样性的研究和保护为核心的一门新兴学科,近几十年来,遗传学研究在生物多样性保护的理论和实践中发挥着越来越重要的作用。本文简要回顾了保护遗传学的发展历史,研究方向和涉及的概念,着重介绍了植物保护遗传学研究所取得的一些进展,包括植物系统发育重建和保护单元的确定,遗传多样性与物种和群体适应性之间的关系,群体遗传结构与保护策略的制定以及植物遗传资源的鉴定和利用等方面的内容,并强调保护遗传学研究是未来生物多样性和保护生物学研究中一个亟待加强的研究领域。     

Quantitative genetics in conservation biology

Most of the major genetic concerns in conservation biology, including inbreeding depression, loss of evolutionary potential, genetic adaptation to captivity and outbreeding depression, involve quantitative genetics. Small population size leads to inbreeding and loss of genetic diversity and so increases extinction risk. Captive populations of endangered species are managed to maximize the retention of genetic diversity by minimizing kinship, with subsidiary efforts to minimize inbreeding. There is growing evidence that genetic adaptation to captivity is a major issue in the genetic management of captive populations of endangered species as it reduces reproductive fitness when captive populations are reintroduced into the wild. This problem is not currently addressed, but it can be alleviated by deliberately fragmenting captive populations, with occasional exchange of immigrants to avoid excessive inbreeding. The extent and importance of outbreeding depression is a matter of controversy. Currently, an extremely cautious approach is taken to mixing populations. However, this cannot continue if fragmented populations are to be adequately managed to minimize extinctions. Most genetic management recommendations for endangered species arise directly, or indirectly, from quantitative genetic considerations.     

Genetic structure, conservation genetics and evidence of speciation by range expansion in shy and white-capped albatrosses

Six variable microsatellite loci were used to examine genetic structuring in the closely related shy albatross (Thalassarche cauta) and white-capped albatross (T. steadi). First, levels of genetic differentiation between the species, and among three populations within each species, were analysed using amova, FST and RST. We found high levels of genetic structuring and detected many unshared alleles between the species, which provide strong evidence against any contemporary gene flow between them. Within each species, shy albatross populations were found to be genetically distinct whereas white-capped albatross populations were undifferentiated, which implies that dispersal events are much rarer in the former than in the latter. These results formed the basis for the recommendation that the three white-capped albatross populations (as a whole) and each shy albatross population be treated as separate units for conservation. Second, levels of genetic diversity and allelic patterns in shy and white-capped albatrosses were assessed for whether they support earlier mtDNA results suggesting that shy albatrosses arose through range expansion of white-capped albatrosses. All measures indicated lower genetic diversity within shy albatrosses than within white-capped albatrosses and upheld the hypothesis that shy albatrosses were founded by white-capped albatrosses.     

Stress and adaptation in conservation genetics

Stress, adaptation and evolution are major concerns in conservation biology. Stresses from pollution, climatic changes, disease etc. may affect population persistence. Further, stress typically occurs when species are placed in captivity. Threatened species are usually managed to conserve their ability to adapt to environmental changes, whilst species in captivity undergo adaptations that are deleterious upon reintroduction into the wild. In model studies using Drosophila melanogaster, we have found that; (a) inbreeding and loss of genetic variation reduced resistance to the stress of disease, (b) extinction rates under inbreeding are elevated by stress, (c) adaptive evolutionary potential in an increasingly stressful environment is reduced in small population, (d) rates of inbreeding are elevated under stressful conditions, (e) genetic adaptation to captivity reduces fitness when populations are reintroduced into the 'wild', and (f) the deleterious effects of adaptation on reintroduction success can be reduced by population fragmentation.     

Applying QTL analysis to conservation genetics

Both analytical and molecular tools currently exist that can be used to prolifically apply quantitative trait loci (QTL) analysis to the study of natural populations. In this communication, we review and exemplify the use of QTL mapping tools and genetic modeling for conservation geneticists. We simulate populations inspired by relevant cases that can be encountered in the field and analyze them using the recently developed flexible intercross analysis (FIA) method. We then reanalyze these results with the also recently developed natural and orthogonal interactions (NOIA) model of genetic effects. Next, we further exemplify the potential of genetic modeling for the interpretation of the output of QTL analyses by reviewing studies on hybrids between wild individuals and their domesticated relatives. Based on the results here presented we emphasize several points that are pertinent in conservation genetics including (i) the advantages of FIA as a powerful tool to be applied to line crosses in which the parental lines are not inbred, (ii) the importance of obtaining estimates of genetic effects that are adequate to address the research issue under consideration, (iii) the versatility of genetic modeling, particularly NOIA, to dissect complex genetic architectures and (iv) the possibility of using currently available methods to address non-equilibrium multiallelic systems.     

A sturgeon view on conservation genetics

The order of Acipenseriformes (sturgeon and paddlefishes) contains the economic most valuable species in world trade: the producers of black caviar. Mainly because of their high economic value, sturgeon and paddlefishes were and are the goal of many conservation programs worldwide. In this review, I present some of the main conclusions that can be drawn from previous conservation efforts. My review is divided into two parts. The first part deals with species identification methods, which are necessary for international trade control (Convention on International Trade in Endangered Species of Wild Fauna and Flora). Considering the outcome of all previous forensic studies, I conclude, firstly, it is necessary to use large sample sizes to avoid misinterpretation of possible diagnostic substitutions, and, secondly, the combination of both DNA types (mitochondrial and nuclear markers) is recommended for correct species identification. The second part deals with the influence of restocking/release programs on native populations. The outcome of previous stocking efforts indicates that, in most cases, stocking with nonnative specimens is economically nonsense because most translocation efforts failed. In addition, in cases where such efforts were successful, they influenced negatively the genotypic structure (inbreeding and outbreeding depressions) of native populations. In fact, nonnative stocking does jeopardize adaptation and blurs the genetic differences used to discriminate populations. Furthermore, if it is necessary to release individuals to avoid extinction, released specimens should be as young as possible (homing fidelity).     

The genetics of host-pathogen coevolution: implications for genetic resource conservation

The results of long-term studies of coevolution in the Hordeum vulgare-Rhynchosporium secalis pathosystem are summarized. The genetic systems of barley (host) and R. secalis (pathogen) are complementary: Gene-for-gene interactions among loci affect many traits, leading to self-regulating adjustments over generations between host and pathogen populations. Different pathotypes differ widely in their ability to damage the host, and different host-resistance alleles differ widely in their ability to protect the host from the pathogen. Among 29 resistance loci in the specific host population studied, several played major roles in providing stable resistance, but many had net detrimental effects on the yield and reproductive ability of the host. Resistance alleles that protected against the most damaging pathotypes increased sharply in frequency in the host populations. It is concluded that the evolutionary processes that take place in genetically variable populations propagated under conditions of cultivation can be highly effective in increasing the frequency of desirable alleles and useful multilocus genotypes. This enhances the value of the evolving populations as sources of genetic variability in breeding for disease resistance and other characters that affect adaptedness.     

Inbreeding and conservation genetics in whitebark pine

Whitebark pine (Pinus albicaulisEngelm.) is threatened across its native rangeby an exotic fungal pathogen introduced withinthe last century. Mortality has beenextensive, and projected potential range shiftsbased on impending climate change have revealedfurther pressures to survival and adaptationfor this long-lived, high-elevation conifer. Quantifying genetic variation and the matingsystem of whitebark pine in its northern rangeprovides a basis for effective conservationmeasures. Isozyme analysis of vegetative budtissue revealed high expected heterozygosity(0.262), moderate population differentiation(F_ST = 0.061) and highly significantcorrelations between observed heterozygosityand geographic variables (R² = 0.36,latitude; R² = 0.30 longitude), supportingthe hypothesis that this species recolonizedits current northern range following glacialretreat from several refugia in the Washingtonand Oregon Cascades and in the northernRockies. Mating system analysis based onsimultaneous isozyme analyses of embryo andhaploid megagametophyte tissues foundrelatively high levels of consanguineous matingand selfing for a conifer (t _m =0.73) within populations. Avian seeddistribution by the Clark's nutcracker (Nucifragia columbiana Wilson) appears to bethe overriding factor influencing geneticpatterns: being a mutualistic seed disperser,caches comprised of related seeds develop intoclumped stands with strong family substructure. While it is a critical wildlife habitatcomponent, lack of commercial utilization hasmade in situ adaptation the primaryconservation focus. Encouraging regenerationsuccess and nutcracker caching by maintainingnatural fire regimes will provide anecosystem-based conservation solution; however,in the Rocky Mountains between 52° N and47° N, disease-resistant individualsshould be located and propagated in order toensure long-term survival of the species inhigh pathogen hazard areas.     

微卫星分子标记在濒危动物保护遗传学研究中的应用

微卫星DNA广泛分布于真核生物基因组中,具有多态性高、共显性遗传、选择中性、易于操作等特点,是一种极具应用价值的分子遗传标记,近年来在濒危动物保护遗传学研究中得到越来越多的应用。微卫星DNA高度多态性提供的高分辨率遗传信启,使其不仅适合个体水平的亲子鉴定与交配系统研究,而且也已成为种群遗传结构与多样性分析的有效分子标记。微卫星分析所需的DNA量极少,用非损伤性方法获取的极少量样品或陈旧样品就能用于有效分析,方便了濒危动物野外调查工作的开展,并且可以利用年代久远的馆藏历史标本揭示种群的重要历史进程。另外,某些微卫星DNA大小在近缘物种间可相互区分,这使得部分物种的DNA分子鉴别将更为简便。但微卫星分子标记的座位筛选和特异引物开发耗时费力,一定程度上限制了其广泛应用。针对不同的研究目的选择合适的分子标记方法将有助于更好的揭示问题本质。     

Geographical genetics and the conservation of forest trees

Trees are key ecosystem engineers. Many analyses of the genetic diversity of forest trees over substantial parts of their distributional ranges are appearing. These studies are of relevance for forest and landscape management, the inventory of botanical genetic resources and the conservation biology of rare, endemic, relictual, and endangered tree species. This review focuses on (i) recent investigations of the influence of human disturbances, (ii) comparative analyses of closely related and hybridizing species, (iii) reconstructions of refugia and of the spread of tree populations during the postglacial, (iv) studies of both range-wide and range-edge genetic patterns, and (v) assessments of the role of tree genetic diversity in the face of future climate warming. There is a need to include more tropical and austral trees in genetic analyses, as most studies have dealt with the relatively species-poor Palaearctic and Nearctic regions. Further studies are also needed on the role of tree genetic diversity in variations in phenology, resistance to insect defoliators and fungal pathogens, reactions to increased CO₂ and ozone concentrations, growth, mortality rates and other traits. Most macroecological and scaling patterns of species richness still need to be studied for genetic diversity. Open research questions in this rapidly evolving field involve invasion biology, island biogeography, and urban ecology. There is a need for more knowledge transfer from the many studies of tree genetic diversity to the day-to-day management of trees and forests.     

Phylogeographical structure and conservation genetics of wild grapevine

The distribution of Vitis vinifera subsp. silvestris, the wild grapevine subspecies of Vitis vinifera L., has been dramatically reduced in its major sites of diffusion, at first by the spread, over the last 150 years, of pathogens from North America and, more recently, with fragmentation of habitat and disbranching by humans. In this work, 418 wild grapevine samples, belonging to 78 populations, were collected in their main Mediterranean distribution areas, including the Caucasus area, and the extent of their genetic variability evaluated by analysing plastid microsatellite DNA polymorphism. Results show low haplotype diversity value, with five haplotypes detected within the analysed populations. The highest within-population haplotypic diversity, with the presence of all five detected haplotypes, was found in the Caucasus regions and in the central regions of Italy. The distribution of all detected haplotypes suggests the Caucasian region as the possible center of origin of Vitis vinifera subsp. silvestris. A principal plastid lineage was found to be fixed in several locations, in the Northernmost European countries and in the Southern island of Sardinia. These results draw attention to two different refugium sites in the Mediterranean basin and suggest that conservation priority should be given to grapevine populations still preserved in hotspots of these regions.     

Quantitative conservation genetics of wild and managed bees

Quantitative genetic traits provide insights into the evolutionary potential of populations, as heritability estimates measure the population’s ability to respond to global changes. Although wild and managed bees are increasingly threatened by the degradation of natural habitats and climate change, risking plant biodiversity and agriculture production, no study has yet performed a systematic review of heritability estimates across the group. Here we help fill this knowledge gap, gathering all available heritability estimates for ants, bees, and wasps, evaluating which factors affect these estimates and assessing the reported genetic correlations between traits. Using a model selection approach to analyze a dataset of more than 800 heritability estimates, we found that heritability is influenced by trait type, with morphological traits exhibiting the highest heritability estimates, and defense and metabolism-related traits showing the lowest estimates. Study system, sociality degree, experimental design, estimation type (narrow or broad-sense heritability), and sample size were not found to affect heritability estimates. Results remained unaltered when correcting for phylogenetic inertia, and when analyzing social bees separately. Genetic correlations between honeybee traits revealed both positive coefficients, usually for traits in the same category, and negative coefficients, suggesting trade-offs among other traits. We discuss these findings and highlight the importance of maintaining genetic variance in fitness-related traits. Our study shows the importance of considering heritability estimates and genetic correlations when designing breeding and conservation programs. We hope this meta-analysis helps identify sustainable breeding approaches and conservation strategies that help safeguard the evolutionary potential of wild and managed bees.