Lack of concordance between genetic diversity estimates at the molecular and quantitative-trait levels

In many applications of population genetics, particularly in the field of conservation biology, estimates of molecular diversity are used as surrogate indicators of less easily acquired measures of genetic variation for quantitative traits. The general validity of this approach to inferring levels of quantitative genetic variation within populations is called into question by the demonstration that estimates of molecular and quantitative-genetic variation are essentially uncorrelated in natural populations of Daphnia, one of the few organisms for which multiple estimates of both quantities are available. On the other hand, molecular measures of population subdivision seem to give conservatively low estimates of the degree of genetic subdivision at the level of quantitative traits. This suggests that although molecular markers provide little information on the level of genetic variation for quantitative traits within populations, they may be valid indicators of population subdivision for such characters.     

Local adaptation across a climatic gradient despite small effective population size in the rare sapphire rockcress

When assigning conservation priorities in endangered species, two common management strategies seek to protect remnant populations that (i) are the most genetically divergent or (ii) possess the highest diversity at neutral genetic markers. These two approaches assume that variation in molecular markers reflects variation in ecologically important traits and ignore the possibility of local adaptation among populations that show little divergence or variation at marker loci. Using common garden experiments, we demonstrate that populations of the rare endemic plant Arabis fecunda are physiologically adapted to the local microclimate. Local adaptation occurs despite (i) the absence of divergence at almost all marker loci and (ii) very small effective population sizes, as evidenced by extremely low levels of allozyme and DNA sequence polymorphism. Our results provide empirical evidence that setting conservation priorities based exclusively on molecular marker diversity may lead to the loss of locally adapted populations.     

Molecular phylogeography and conservation genetics of Sladenia celastrifolia inferred from chloroplast DNA sequence variation

The genetic variation and structure of Sladenia celastrifolia Kurz, a species of conservation concern, were investigated. Analyses of two chloroplast DNA loci (trnS-trnGand atpB-rbcL intergenic regions) were carried out for 24 populations of S. celastrifolia and five haplotypes were identified. High levels of genetic differentiation (G_ST = 1, F_ST = 1) were detected, which may be a result of limited gene flow caused by geographic isolation. Analysis of molecular variance suggests that the existence of marked phylogeographical structure within the haplotype distribution is probably due to geographic barriers among populations. The haplotype network and mismatch distribution analyses did not detect any signals for recent population expansions in S. celastrifolia. Thus, it can be inferred that the species likely persistedin situ during climatic oscillations. Considering its genetic diversity and uniqueness, conservation strategies are further discussed for this species.     

Considering evolutionary processes in the use of single-locus genetic data for conservation,with examples from the Lepidoptera

The increasing popularity of molecular taxonomy will undoubtedly have a major impact on the practice of conservation biology. The appeal of such approaches is undeniable since they will clearly be an asset in rapid biological assessments of poorly known taxa or unexplored areas, and for discovery of cryptic biodiversity. However, as an approach for diagnosing units for conservation, some caution is warranted. The essential issue is that mitochondrial DNA variation is unlikely to be causally related to, and thus correlated with, ecologically important components of fitness. This is true for DNA barcoding, molecular taxonomy in general, or any technique that relies on variation at a single, presumed neutral locus. Given that natural selection operates on a time scale that is often much more rapid than the rates of mutation and allele frequency changes due to genetic drift, neutral genetic variation at a single locus can be a poor predictor of adaptive variation within or among species. Furthermore, reticulate processes, such as introgressive hybridization, may also constrain the utility of molecular taxonomy to accurately detect significant units for conservation. A survey of published genetic data from the Lepidoptera indicates that these problems may be more prevalent than previously suspected. Molecular approaches must be used with caution for conservation genetics which is best accomplished using large sample sizes over extensive geography in addition to data from multiple loci. Matthew L. Forister, Chris C. Nice and James A. Fordyce contributed equally to this paper.     

从知识创新展望21世纪生物多样性科学

首先简要介绍汤佩松(1983)创新植物学,随后根据其创新思想分析了生物多样性三个层次研究的现状和问题。提出了一个根据DNA 序列变异尺度为标准的新的遗传多样性等级制度。为了避免物种和其他分类群的随意性, 建议以DNA 序列变异作为可操作的分类单元(OTU)和国际上进化上显著单元(ESU)相呼应。下一世纪的分子系统学和分子生态学可能重点研究DNA 变异, 特别是重复序列的变化对生物生命活动的调控, 在分子水平上揭示结构和功能的进化和适应。第三部分讨论Diversitas五个核心课题, 说明分子水平研究和生物技术对生物多样性保护和持续利用的重要性和迫切性。最后评论了" 天人合一" 为代表的反科学主义思潮, 坚持科学进步。     

Amplified fragment length polymorphism (AFLP) analysis of genetic variation in Moringa oleifera Lam

Moringa oleifera is an important multipurpose tree introduced to Africa from India at the turn of this century. Despite limited knowledge of the levels of genetic diversity and relatedness of introduced populations, their utilization as a source of seed for planting is widespread. In order to facilitate reasoned scientific decisions on its management and conservation and prepare for a selective breeding programme, genetic analysis of seven populations was performed using amplified fragment length polymorphism (AFLP) markers. The four pairs of AFLP primers ( Pst I/ Mse I) generated a total of 236 amplification products of which 157 (66.5%) were polymorphic between or within populations. Analysis of molecular variance ( AMOVA ) revealed significant differences between regions and populations, even though outcrossing perennial plants are expected to maintain most variation within populations. A phenetic tree illustrating relationships between populations suggested at least two sources of germplasm introductions to Kenya. The high levels of population differentiation detected suggest that provenance source is an important factor in the conservation and exploitation of M. oleifera genetic resources.     

分子标记在濒危物种保护中的应用

分子标记可揭示种群遗传和进化信息, 为制定濒危物种保护措施、指导恢复实践提供重要依据。本文主要介绍了分子标记在濒危物种保护过程不同环节中的应用, 包括: (1)正确识别保护单元, 如排除隐存种和杂交种的影响; (2)确定优先保护单元, 包括优先保护区域、优先保护物种、优先保护种群等; (3)指导迁地保护; (4)对保护工作的动态监测和评估。文章最后探讨了分子标记应用于保护的发展方向, 如开展长期的种群遗传组成监测、切实应用于保护管理实践、将基因组学等遗传信息用于全球变化背景下保护策略的制定等, 期望为分子标记技术在生物多样性保护的研究和实践中提供参考。     

Conserving marine biodiversity: insights from life-history trait candidate genes in Atlantic cod (Gadus morhua)

Recent technological developments have facilitated an increased focus on identifying genomic regions underlying adaptive trait variation in natural populations, and it has been advocated that this information should be important for designating population units for conservation. In marine fishes, phenotypic studies have suggested adaptation through divergence of life-history traits among natural populations, but the distribution of adaptive genetic variation in these species is still relatively poorly known. In this study, we extract information about the geographical distribution of genetic variation for 33 single nucleotide polymorphisms (SNPs) associated with life-history trait candidate genes, and compare this to variation in 70 putatively neutral SNPs in Atlantic cod (Gadus morhua). We analyse samples covering the major population complexes in the eastern Atlantic and find strong evidence for non-neutral levels and patterns of population structuring for several of the candidate gene-associated markers, including two SNPs in the growth hormone 1 gene. Thus, this study aligns with findings from phenotypic studies, providing molecular data strongly suggesting that these or closely linked genes are under selection in natural populations of Atlantic cod. Furthermore, we find that patterns of variation in outlier markers do not align with those observed at selectively neutral markers, and that outlier markers identify conservation units on finer geographical scales than those revealed when analysing only neutral markers. Accordingly, results also suggest that information about adaptive genetic variation will be useful for targeted conservation and management in this and other marine species.     

Heterozygosity-fitness correlations among wild populations of European tree frog (Hyla arborea) detect fixation load

Quantifying the impacts of inbreeding and genetic drift on fitness traits in fragmented populations is becoming a major goal in conservation biology. Such impacts occur at different levels and involve different sets of loci. Genetic drift randomly fixes slightly deleterious alleles leading to different fixation load among populations. By contrast, inbreeding depression arises from highly deleterious alleles in segregation within a population and creates variation among individuals. A popular approach is to measure correlations between molecular variation and phenotypic performances. This approach has been mainly used at the individual level to detect inbreeding depression within populations and sometimes at the population level but without consideration about the genetic processes measured. For the first time, we used in this study a molecular approach considering both the interpopulation and intrapopulation level to discriminate the relative importance of inbreeding depression vs. fixation load in isolated and non-fragmented populations of European tree frog (Hyla arborea), complemented with interpopulational crosses. We demonstrated that the positive correlations observed between genetic heterozygosity and larval performances on merged data were mainly caused by co-variations in genetic diversity and fixation load among populations rather than by inbreeding depression and segregating deleterious alleles within populations. Such a method is highly relevant in a conservation perspective because, depending on how populations lose fitness (inbreeding vs. fixation load), specific management actions may be designed to improve the persistence of populations.     

Genetic differentiation in endangered Gynostemma pentaphyllum (Thunb.) Makino based on ISSR polymorphism and its implications for conservation

Studies were performed to investigate the genetic variation of 14 natural populations of Gynostemma pentaphyllum (Thunb.) Makino, an outcrossing clonal plant species in China, using inter-simple sequence repeat (ISSR) markers. Fourteen selected primers were used to amplify DNA samples from 140 individuals, and totally 194 loci were detected. The percentage of polymorphic bands (PPBs) showed that the genetic diversity was pretty high at the species level (PPB = 96.39%) but quite low at the population level (PPB = 1.03–25.26%). Shannon's information index (I) and Nei's gene diversity (h) displayed a similar trend to PPB. According to the hierarchical analysis of molecular variance (AMOVA) and Nei's analysis of gene diversity, the percentages of genetic variation among populations were 88.66 and 88.94%, respectively, indicating a high level of inter-population genetic differentiation. The low levels of genetic diversity within populations and high genetic differentiation among populations were assumed to result from the limited gene flow, the clonal nature and genetic drift. Based on the genetic data, effective conservation strategies were proposed for conserving this traditional Chinese medicinal herb. Concerning the management of G. pentaphyllum, we suggested that in situ conservation be an important and practical measure for maintaining the genetic diversity and that a possibly maximum number of populations be conserved. Populations EMS and HLT, in which particularly low levels of genetic variation were characterized, should be given the priority for ex situ conservation.     

Ecological and biogeographical inferences on two sympatric and enigmatic Andean cat species using genetic identification of faecal samples

The carnivore community of the altiplano ecosystem of the high Andes, including the Andean mountain cat (Leopardus jacobita) and pampas cat (Leopardus colocolo), is one of the least studied in the world. We determined the origin of 186 carnivore samples (184 faeces and two skulls) collected above 3000 m above sea level in northern Chile, including 33 from the Andean mountain cat and 75 from the pampas cat using diagnostic molecular genetic sequence variation. We determined for the first time food habits, habitat and physiographic associations, and general patterns of molecular genetic variation of the Andean mountain cat and the pampas cat in Chile. Both species had narrow dietary niches dominated by small rodents and there was a wide overlap in diet composition (0.82), suggesting low levels of prey partitioning between species. The mountain viscacha (Lagidium viscacia) made up a large proportion of the biomass of the diet of both species, especially for the Andean mountain cat (93.9% vs. 74.8% for the pampas cat), underscoring the importance of further research and conservation focus on this vanishing prey species. Although the probability of finding Andean mountain cat scats increased with altitude and slope, there was substantial geographical overlap in distribution between species, revealing that the pampas cat distribution includes high-altitude grassland habitats. The Andean mountain cat had relatively low levels of mitochondrial DNA (mtDNA) genetic variation (two mtDNA haplotypes) compared with the pampas cat (17 mtDNA haplotypes), suggestive of a distinct evolutionary history and relatively smaller historic populations. These insights will facilitate and provide tools and hypotheses for much-needed research and conservation efforts on these species and this ecosystem.     

Patterns of genetic variation in US federal bison herds

Like many wide‐ranging mammals, American bison (Bison bison) have experienced significant range contraction over the past two centuries and are maintained in artificially isolated populations. A basic understanding of the distribution of genetic variation among populations is necessary to facilitate long‐term germplasm preservation and species conservation. The 11 herds maintained within the US federal system are a critically important source of germplasm for bison conservation, as they include many of the oldest herds in the USA and have served as a primary resource for the establishment of private and public herds worldwide. In this study, we used a panel of 51 nuclear markers to investigate patterns of neutral genetic variation among these herds. Most of these herds have maintained remarkably high levels of variation despite the severe bottleneck suffered in the late 1800s. However, differences were noted in the patterns of variation and levels of differentiation among herds, which were compared with historical records of establishment, supplementation, herd size, and culling practices. Although some lineages have been replicated across multiple herds within the US federal system, other lineages with high levels of genetic variation exist in isolated herds and should be considered targets for the establishment of satellite herds. From this and other studies, it is clear that the genetic variation represented in the US federal system is unevenly distributed among National Park Service and Fish and Wildlife Service herds, and that these resources must be carefully managed to ensure long‐term species conservation.     

Genetic variation and cultivar identification in Cymbidium ensifolium

As a popular flowering species with many cultivars, Cymbidium ensifolium (L.) is commercially important in horticulture. However, so far little has been known about genetic diversity and conservation genetics of this species. Understanding of the genetic variation and relationships in cultivars of C.?ensifolium is a prerequisite for development of future germplasm conservation and cultivar improvement. Here we report assessment of genetic variations in C.?ensifolium cultivars using the DNA fingerprinting technique of inter-simple sequence repeats (ISSR). A total of 239 ISSR loci were identified and used for evaluation of genetic variation with a selection of 19 ISSR primers. Among these ISSR loci, 99.16% were polymorphic with wide genetic variation as shown by Nei??s gene diversity (H?=?0.2431) among 85 tested cultivars. ISSR fingerprinting profiles showed that each cultivar had its characteristic DNA pattern, indicating unequivocal cultivar identification at molecular level. Eighteen cultivar-specific ISSR markers were identified in seven cultivars. The cultivar Sijiwenhan was confirmed as hybrid by four ISSR primers. Several cultivars with same name but different geographical origins were distinguished based on their ISSR profiles. A dendrogram generated with ISSR markers could group 73 of 85 cultivars into four major clusters. Further analysis of ISSR variation revealed that about 69% of total genetic variation in this species is due to genetic divergence inside geographical groups. Our results suggest that both germplasm collection and in?situ conservation are important for future planning of C.?ensifolium species conservation.     

Genetic variation in Costa Rican populations of the tropical timber species Cedrela odorata L., assessed using RAPDs

Cedrela odorata L. (Spanish cedar), an economically important timber species native to the American tropics, is the focus of increasing conservation concern due to high rates of deforestation within its native range. To assess the extent of the genetic diversity within and between populations of this species, samples were obtained from 10 widely dispersed populations within Costa Rica and analysed for random amplified polymorphic DNA (RAPD) variation. Fourteen 10-mer primers were used to generate 97 polymorphic RAPD bands. Presence/absence data for all bands were subjected to a pairwise genetic distance analysis, according to Jaccard's coefficient, then neighbour-joining cluster analysis was performed on these distances, as was an analysis of molecular variance ( AMOVA ), to assess levels of differentiation between populations and regions, and Shannon's Diversity Index was used to quantify levels of diversity within and between populations. Results indicated highly significant genetic differentiation ( P < 0.004, AMOVA ) between populations originating from the North Pacific and Atlantic/South Pacific regions of Costa Rica, with 35.3% of the total variation attributable to a difference between these areas. Little differentiation was recorded between populations from within the same region ( P = 0.757, AMOVA ), and 65.1% of the total variance was attributable to variation within populations. Estimated values for within-population diversity, calculated as H _pop/ H _sp by means of Shannon's Diversity Index, were found to vary greatly between primers, but the overall within-population component of genetic diversity was 0.45. Possible reasons for the high degree of intraspecific genetic variation within this species are discussed and the implications of these results for the conservation and use of its genetic resources are described.     

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.     

Genetic diversity and population structure in the Barrens Topminnow (<Emphasis Type="Italic">Fundulus julisia</Emphasis>): implications for conservation and management of a critically endangered species

The Barrens Topminnow (Fundulus julisia) has undergone a rapid and dramatic decline. In the 1980s, at least twenty localities with Barrens Topminnows were known to exist in the Barrens Plateau region of middle Tennessee; currently only three areas with natural (not stocked) populations remain. The long-term survival of the Barrens Topminnow will depend entirely on effective management and conservation efforts. Captive propagation and stocking of captive-reared juveniles to suitable habitats have successfully established a handful of self-sustaining populations. However, very little is known about the genetic composition of source and introduced populations including levels of genetic diversity and structuring of genetic variation. Here we use both mitochondrial sequence data and genotypes from 14 microsatellite loci to examine patterns of genetic variation among ten sites, including all sites with natural populations and a subset of sites with introduced (stocked) populations of this species. Mitochondrial sequence analysis reveals extremely low levels of variation within populations and fixed differences between drainages. Microsatellite genotype data shows higher levels of genetic variability and a molecular signature consistent with a recent history of population bottlenecks. Measures of genetic diversity at microsatellite loci including allelic richness are similar within source and introduced populations. Bayesian assignment tests and analysis of molecular variation (AMOVA) support two distinct populations, consistent with drainage boundaries. Results from AMOVA analysis also suggest low levels of genetic connectivity between isolated populations within the same drainage. Here we propose two distinct evolutionary significant units (ESUs) and two management units that reflect this population substructure and warrant consideration in future management efforts.     

Phosphoglucose isomerase (<Emphasis Type="Italic">Pgi</Emphasis>) performance and fitness effects among Arthropods and its potential role as an adaptive marker in conservation genetics

The development of conservation genomics will be greatly aided by the use of neutral as well as adaptive molecular markers. Identifying novel adaptive molecular markers that have general application across diverse taxa is challenging, especially in Arthropods where few if any examples of balanced polymorphisms exist that are shared across species. A review of literature on the Pgi gene provides strong evidence for population level fitness consequences of genetic variation in this gene, across very diverse lineages of Arthropods. While these observations demonstrate the potential of using Pgi as an adaptive molecular marker, this gene is fundamentally different from the adaptive markers MHC and SI. Rather than providing insights into individual genetic health, Pgi appears to have a role in conservation genetics by providing insights into gene by environment interactions, local adaptation and evolutionary significant units, and potentially even morphologically cryptic dispersal phenotypes. These findings argue for studying Pgi variation in more species, as it appears central to the goals of conservation genomics.     

双壳纲动物核糖体RNA 18S-ITS1序列及其在分子系统发育研究中的应用

测定了双壳纲不同科、属、种及种内共11个个体的核糖体RNA 18S-ITS1序列。结果表明,该序列在种间存在很高的多态性,长度从558bp到784bp不等,碱基差异百分比在10．7％～61．7％之间,ITS1序列同源性很低,有片段的插入与缺失。种间18S部分序列碱基差异百分比在0．9％～23．7％之间,变化主要是碱基的转换。用邻接法(NJ)构建了8个种的18S部分序列(约240bp)的系统发育树,与传统形态学分类结果相符。马氏珠母贝(Pinctada martrtensi)4个不同地域个体间的序列差异百分比在0．6％～1．9％之间。分析指出：18S基因可以作为双壳纲动物高阶元系统发育的分子标记;ITS1序列种间变化很大,可以应用于该纲物种的分类及鉴别．在亲缘关系相近种及种内变异相对较小,但核苷酸变异位点信息量丰富,可用于属内种间、亚种和群体间的遗传多样性研究。     

Population genetic structure of the tropical tree species Aegiphila sellowiana (Lamiaceae)

The Tibagi River, located in southern Brazil, is associated with a significant degree of environmental heterogeneity, along its 550 km extension. There is concern about the integrity of this river's ecosystem, as human interference has been increasing. Aegiphila sellowiana (Lamiaceae) is an important pioneer tree species, commonly found near rivers; the fruit is consumed by avifauna. We studied this species along three ecological gradients, comprising the upper, middle, and lower regions of the Tibagi River basin. The genetic structure of nine subpopulations of A. sellowiana distributed along these gradients was investigated using RAPDs. Moderate levels of gene diversity (ranging from 0.091 to 0.132) were identified, inferred by a traditional approach and a Bayesian model-based method. The F-statistic, G(ST) parameters and molecular variance analysis showed high genetic differentiation among the three regions (39.5 to 50.26%). Analysis of molecular variance revealed high levels of genetic variation between populations (50.26%), while lower values of genetic variation (ranging from 9.56 to 16.35%) were seen between subpopulations within the upper, middle, and lower regions of the Tibagi River basin. The validity of these results was confirmed by principal coordinate analysis. Linear regression analysis showed significant correlations (r = 0.621, P = 0.0001) between the genetic and geographical distances. The differences observed in genetic variation between regions are probably due to habitat fragmentation; for conservation purposes, we recommend that at least one subpopulation from each region of the Tibagi River should be maintained.