DNA C-值与被子植物入侵性关系的数据统计分析——以中国境内有分布的539种被子植物为例

统计了中国境内有分布的539种被子植物的DNA C-值,分析了它们在不同分类群、生活型、倍性、生活史类型以及在杂草和非杂草类群中的分布情况,主要结果如下:(1)539种被子植物DNA C-值平均为4.06 pg,其中木本植物的DNA C-值平均为1.84 pg,低于草本植物的平均值(5.02 pg);(2)双子叶植物(360种)的DNA C-值平均为2.20 pg,极明显地小于单子叶植物(179种)的平均值(7.80 pg);(3)1年生植物的DNA C-值平均为2.78 pg, 明显小于多年植物的平均DNA C-值(6.65 pg);(4)134种杂草的DNA C-值平均为1.93 pg,明显小于非杂草草本植物的平均值(6.75 pg),含杂草较多的科,平均DNA C-值相对较小;(5)统计的47种入侵杂草的DNA C-值平均为1.76 pg, 略小于134种杂草的平均DNA C-值(1.93 pg),极显著地小于非杂草性草本植物(6.75 pg);(6)以科为单位,不同科的DNA C-值存在着极大的差异;(7) DNA C-值与染色体倍性的关系并不明显,但是,随着倍性的增加,基因组变小;(8) 在同一科、属中,与非杂草相比,典型杂草的DNA C-值往往偏小;(9)总体上杂草或杂草性强的植物,它们的DNA C-值比非杂草性植物的要小.但是,也还存在一些例外,例如野燕麦(Avena fatua)的DNA C-值就高达14.15 pg,而相反,十字花科和葫芦科的一些非杂草栽培植物,却具有很低的DNA C-值.结论:DNA C-值在预测外来物种的入侵性方面具有一定的应用价值,但是,由于在木本植物和草本植物之间、单子叶与双子叶植物之间、一年生和多年生植物之间,特别是在不同的科之间,植物的DNA C-值较明显的差异,因此,根据DNA C-值预测外来物种的入侵性,应该严格地限于同一科(或属)内的相关物种间的比较.     

物种形成基因及其功能

什么是物种?新物种是如何形成的？这些问题是生命科学研究的重大问题.物种的形成是在生殖隔离的基础上某些新的生物学性状的形成和保留,是生物进化的最基本过程,其实质是基因结构突变的积累与功能的分化. 地理隔离使群体中的基因不能交流,基因突变也会影响个体间交配趣向,从而造成交配隔离或者交配后杂合体的基因组不亲和、杂交不育甚至杂交不活,使不同的群体逐渐分化为新物种. 随着分子生物学与基因组学的飞速发展,进化生物学家已经发现一些与物种形成有关的基因-物种形成基因（speciation genes）,鉴定并了解这些基因的功能,不仅能使我们在分子水平上理解新物种形成的实质和规律、而且对于我们突破种间屏障进行远缘杂交育种也有重要的理论指导意义.本文综述了目前对几个物种形成基因及其功能的研究进展,为该领域的进一步研究提供资料.     

基于生物学物种定义探讨物种形成理论与验证的研究进展

物种形成是进化生物学研究的一个永恒主题, 由于生物群体进化是连续和动态的, 物种界限变得难于界定。本文首先讨论了3种地理物种形成模式(同域、邻域及异域), 并分析了近期报道的研究证据。其次, 评述了合子后生殖隔离机制的分子遗传基础和应用群体基因组数据分析的证据, 包括BDMI模型(Bateson-Dobzhansky-Muller incompatibility)、QTLs (quantitative trait loci)、霍尔丹法则及大X染色体效应。最后, 探讨了交配系统作为合子前隔离机制之一与物种形成的关系, 认为近交或自交通过扩大种群遗传结构分化, 增强不同交配系统的种群间不对称基因渐渗, 或种群间无基因渐渗等途径, 促进新物种形成。已知植物交配系统的演化更倾向于从异交(或自交不亲和)向自交(或近交亲和)方式, 花性状和基因组的分化推动形成所谓的自交综合征, 研究交配系统驱动或强化物种形成模式对认识植物物种形成机制有重要意义。     

植物物种形成的模式与机制

物种形成是指由已有的物种通过各种进化机制进化出新物种的过程。持续不断的物种形成产生了地球上灿烂的生物物种多样性。然而,研究人员对物种形成的模式与机制的了解却非常有限。一直以来,谱系分裂被认为是最重要的物种形成模式,但在植物中,谱系融合,即通过杂交形成新物种的过程,也是一个非常重要的物种形成模式。经过几十年的研究才逐渐认识到,生殖隔离是差异适应和遗传漂变的副产品,而不是物种形成的前提。相比合子形成后隔离,合子形成前的隔离在物种形成过程中更早地发挥作用。合子形成前的隔离,尤其是生态地理的隔离是植物中最重要的隔离机制。一些基于QTLs分析的研究发现,基因组中的少数主效位点在物种形成中起了关键作用,并且这些位点往往受到自然选择的作用。适应性辐射往往发生在隆起的山脉和新形成的岛屿上,很可能与这些地方能够提供很多可利用的生态位有关。最新的物种形成理论认为,基因是物种形成的基本单位,不同的物种可以在非控制物种差异适应性状的位点上存在基因流。这一观点为植物物种形成的研究提供了新的思路。随着植物物种形成研究的深入,越来越多植物物种形成基因被分离,包括花色素苷合成通路和S-基因座上的一些关键基因,揭示了植物物种形成的分子机制。前期的研究主要集中在模式植物和农作物上,许多生态上非常有趣的非模式植物还未得到广泛的研究。在未来的研究中,还需要更多来自非模式植物的例子以全面理解植物物种形成的多样化机制。     

长三角及邻近地区138种草本植物DNA C-值测定及其生物学意义

为了评估DNA C-值和基因组大小(genome size)在植物入侵性评估中的价值,应用流式细胞仪测定了长三角及邻近地区138种草本植物的核DNA含量,其中111种为首次报道。在此基础上比较了不同植物类群这两个值的差异,特别是入侵性与非入侵性植物这两个值的差异。结果表明:(1)138种草本植物平均DNA C-值为1.55 pg,最大者是最小者的37.17倍。127个类群平均基因组大小为1.08 pg,最大者是最小者的34.11倍;(2)统计了菊科(Asteraceae)、禾本科(Poaceae)、石竹科(Caryophyllaceae)、十字花科(Brassicaceae)、玄参科(Scrophulariaceae)、蓼科(Polygonaceae)、唇形科(Labiatae)和伞形科(Umbelliferae)的DNA C-值和基因组大小,发现禾本科植物的这两个值显著地大于其他7个科(P0.01)。单子叶的DNA C-值和基因组极显著地大于双子叶植物(P0.01);(3)杂草比非杂草具有更低的DNA C-值(P0.01)和基因组大小(P0.001);与DNA C-值相比,基因组大小在这两个类群之间的差异更为明显(P0.001),这种现象也体现在菊科植物中。随着基因组(X1)和DNA C-值(X2)由大变小,植物的杂草性(入侵性,Y)由弱变强,两者关系分别符合:Y=2.2334-1.2847 ln(X1)(r=0.4612,P0.01)和Y=2.4421-0.7234 ln(X2)(r=0.2522,P0.01),DNA C-值和基因组大小可以作为植物入侵性评估的一个指标;(4)多倍体杂草的基因组极明显地小于二倍体杂草(P0.01),前者为后者的0.63倍。在非杂草中,多倍体基因组比二倍体的略小,前者仅为后者的0.84倍,差异不显著(P0.5)。菊科植物中多倍体杂草的基因组也显著地小于二倍体杂草(P0.1)。基因组变小和多倍体化相结合,进一步增强了植物的入侵性。在多倍体植物入侵性评估中,基因组大小比DNA C-值更有价值。     

新疆阜康荒漠红砂种群构件结构与环境因子的灰色关联度分析

 以构件理论为基础,运用灰色关联度分析技术,对新疆阜康荒漠红砂(Reaumuria soongorica)自然种群构件结构及其与环境因子的关系进行了研究。结果表明：1）植株冠幅是表征红砂生长情况的重要指标,随着红砂植株冠幅的增大,植株高度明显增加,而且植株冠幅与植株的一级分枝     

基于流式细胞术的乌饭树核DNA含量(2C-值)测定

核DNA含量(2C-值)是描述植物生物多样性的一个重要特征参数。该研究利用流式细胞仪检测越橘属植物乌饭树核DNA含量,建立了适合乌饭树的流式细胞术测定方法:以野生乌饭树的嫩叶为材料,以已知核DNA含量的水稻品种‘日本晴’为内标,采用GPB解离液,细胞核悬液加入50μL獉mL-1碘化丙啶染色5 min即可上机检测。结果表明:(1) 9个乌饭树单株的核DNA含量平均值为(1.22±0.03) pg,最小值为1.18 pg,最大值为1.27 pg。(2)检测结果与已知的越橘属二倍体植株的2C-值含量相似,且不同地理来源的单株DNA含量没有显著差异(P0.05),推测这9个单株为二倍体植株。(3)测定的乌饭树核DNA含量(2C-值)可丰富越橘属植物的C-值库;基于流式细胞术建立的乌饭树核DNA含量测定方法可为该属其他植物的相关研究提供借鉴。     

用核酸杂交法检查北京地区幼儿园正常儿童尿中人巨细胞病毒DNA

以克隆的人巨细胞病毒(Human Cytomegalovirus,简称HCMV)DNA片段做探针,用核酸杂交方法检查了50例北京地区幼儿园正常儿童的尿标本。查出HCMV DMA阳性者24例,占48％。在两个群体和两个年龄组之间,阳性检出率有显著性差异。利用探针可查出同源DNA5～10pg,而不与其它病毒或细胞DNA杂交。标记不同的探针,使用不同的固定方法,其敏感性不同。此法可在分子水平上查出HCMV基因,比分离病毒更迅速敏感。     

生态物种形成及其研究进展

物种形成是基本的进化过程, 也是生物多样性形成的基础。自然选择可以导致新物种的产生。生态物种形成是指以生态为基础的歧化选择使不同群体分化产生生殖隔离的物种形成过程。本文首先回顾了生态物种形成的研究历史, 并详细介绍了生态物种形成的3个要素, 即歧化选择的来源、生殖隔离的形式以及关联歧化选择与生殖隔离的遗传机制。歧化选择的来源主要包括不同的环境或生态位、不同形式的性选择, 以及群体间的相互作用。生殖隔离的形式多种多样, 我们总结了合子前和合子后隔离的遗传学机制以及在生态物种形成中起到的作用。控制适应性性状的基因与导致生殖隔离的基因可以通过基因多效性或连锁不平衡相互关联起来。借助于第二代测序技术, 研究者可以对生态物种形成的遗传学与基因组学基础进行研究。此外, 本文还总结了生态物种形成领域最新的研究进展, 包括平行进化的全基因组基础, 以及基因流影响群体分化的理论基础。通过归纳比较由下至上和由上至下这两种不同的研究思路, 作者认为这两种思路的结合可以为生态物种形成基因的筛选提供更有力也更精确的方法。同时, 作者还提出生态物种形成的研究应该基于更好的表型描述以及更完整的基因组信息, 研究的物种也应该具有更广泛的代表性。     

为什么在物种概念上难以达成共识?

生物学家通常认为物种是生命多样性的基本单位。然而, 尽管近一个世纪以来生物学家们不断地讨论物种概念问题, 但到目前为止仍然难以形成共识。大多数生物学家关注如何定义物种主要是因为它有非常重要的实践意义, 所以, 不同学者提出的物种概念在很大程度上是基于实践应用上的可操作性, 并且其视角难免受其专业见地以及对形成新物种的进化过程的认识所影响。物种代表了进化过程的一个阶段, 而且不同的“物种”可能处于物种形成这个进化过程的不同阶段。鉴于“定义”实际上是一种类似协议的约定或界定, 任何定义都是一种带有局限性的概括, 因此我们可能很难建立一个与分类实践中千变万化的情况都能完全匹配协调的物种定义。已经提出来的那些物种概念或定义都有其合理性, 但是也没有一个是完美无缺的。认识到这一点很重要, 否则就可能会因为固执地坚持某一特定的物种概念而在物种界定和进化研究中自觉或不自觉地引入错误甚至制造混乱。     

Divergence and hybridization in the desert plant Reaumuria soongarica

Speciation is widely accepted to be a complex and continuous process. Due to complicated evolutionary histories, desert plants are ideal model systems to understand the process of speciation along a continuum. Here, we elucidate the evolutionary history of Reaumuria soongarica (Pall.) Maxim., a typical desert plant that is wildly distributed across arid central Asia. Based on variation patterns present at nine nuclear loci in 325 individuals (representing 41 populations), we examined the demographic history, patterns of gene flow, and degree of ecological differentiation among wild R. soongarica. Our findings indicate that genetic divergence between the ancient western and eastern lineages of R. soongarica occurred approximately 0.714 Mya, probably due to the Kunlun–Yellow River tectonic movement and the Naynayxungla glaciation. Later, multiple hybridization events between the western and eastern lineages that took place between 0.287 and 0.543 Mya, and which might have been triggered by the asynchronous historical expansion of the western and eastern deserts, contributed to the formation of a hybrid northern lineage. Moreover, despite continuing gene flow into this population from its progenitors, the northern lineage maintained its genetic boundary by ecological differentiation. The northern lineage could be an incipient species, and provides an opportunity to study the continuous process of speciation. This study suggests that two opposite evolutionary forces, divergence and hybridization, coexisting in the continuous speciation of the desert plant R. soongarica in a short time. Moreover, we provide evidence that this continuous speciation process is affected by geological events, climatic change, and ecological differentiation.     

To hybridize or not to hybridize: what separates two genetic lineages of the Chalk‐hill Blue Polyommatus coridon (Lycaenidae,Lepidoptera) along their secondary contact zone throughout eastern Central Europe?

As a consequence of postglacial range expansion, hybrid zones evolved where different genetic lineages met. In this study, we analysed the Chalk‐hill Blue Polyommatus coridon all along the contact zone of two expansive lineages. This zone stretches from the sandy areas of north‐eastern Germany, along the mountain ranges of the German–Czech border and throughout the eastern Alps. We studied allozymes (19 loci) of 38 populations (1542 individuals) and compared these data sets against 15 populations of the western and 15 populations of the eastern lineages and found different degrees of hybridization. Thus, the calcareous regions of Thuringia and Sachsen‐Anhalt were mostly colonized by the western lineage. The middle mountain ranges between Bavaria and Bohemia represented a strong barrier blocking further expansion and thus completely impeding hybridization in this region. More intense hybridization was detected in the populations of the eastern Alps, especially in the north‐eastern part, where the Danube most probably acted as an expansion corridor for both lineages followed by intensive hybridization. In the south‐eastern Alps, hybrid populations were mostly detected in the easternmost parts and along the larger river valley of Drava and Mur; pure western populations dominated in the other areas of this region. These results show that the degree of hybridization along a contact zone is correlated with the ecological demands of a species and the regional physical geographic circumstances. This finding was proved for the Chalk‐hill Blue in our study but is also the most likely scenario in most animal and plant species.     

Limited hybridization along a large contact zone between two genetic lineages of the butterfly Erebia medusa (Satyrinae, Lepidoptera) in Central Europe

Genetic lineages evolving during glacial isolation frequently come into contact as the result of postglacial range expansions. Hybridization often occurs along these contact zones. In Europe, the high mountain systems of the Alps and Pyrenees are well known for their hybrid belts. This article studies the contact zone of the Woodland Ringlet Erebia medusa in a Hercynian mountain area in the Czech-German border region not exceeding 1500 m a.s.l. Hybrid populations between an eastern and a western genetic lineage were detected by amova -based tests, principal component analysis and neighbour joining analysis. Over most of the range of the Czech-German Border Mts, the ridges separate the western and the eastern genetic lineage from each other. However, two important hybrid areas were detected: (1) the watershed of the Ohře river in the north-west of that area, a major valley system passing through these mountains and (2) the high plateaux of the Šumava Mts in the south-east, an extended area of high elevation. The location of hybrid populations in geographical vicinity to non-hybrid populations and the generally low F _IS (2.1%) make reduced fitness of hybrid individuals little likely. The hybrid populations have intermediate genetic diversity between the genetically poor western and the genetically rich eastern lineage populations.     

Africa goes Europe: The complete phylogeography of the marbled white butterfly species complex Melanargia galathea/M. lachesis (Lepidoptera: Satyridae)

Climatic oscillations influence the distribution of species in time. Thermophilic species survived the ice ages in refugia around the Mediterranean. Northern Africa is one of the possibly important refugia. In this study we test the genetic differentiation between northern African and European populations, using the marbled white butterfly species complex, Melanargia galathea/M. lachesis, as a model. We studied 18 allozyme loci in 876 individuals from 23 populations representing a major part of Europe (northern Spain to Romania) and the western part of northern Africa (Atlas Mountains). The African populations resemble the European ones in allelic richness; their genetic diversity is higher than in Europe. Cluster analysis discriminated five European genetic groups: M. lachesis, a western European lineage, and three eastern European lineages. However, the African samples did not form a separate cluster within this phenogram, but clustered randomly within the Balkan/southeastern European groups. The genetic differentiation among the African populations (F_ST 8.8%) was higher than that within any of the European lineages (F_ST 2.6–5.5%). The high genetic diversity and the relatively strong differentiation of the four African populations sampled in a comparatively limited area of the Atlas Mountains indicate that the most probable origin of M. galathea is northern Africa, with its sibling species, M. lachesis, evolving in parallel in Iberia. Most probably, M. galathea colonised Europe first during the Eem interglacial, some 130 ky ago. Since M. lachesis must have existed on the Iberian peninsula during that period already, M. galathea should have reached Europe via Italy. The genetic differentiation to distinct groups in Europe most probably evolved during the following Würm glacial period.     

Evolutionary history of the Dactylorhiza maculata polyploid complex (Orchidaceae)

Taxonomic complexity may be associated with migration history and polyploidy. We used plastid and nuclear DNA markers to investigate the evolutionary history of the systematically challenging Dactylorhiza maculata polyploid complex. A total of 1833 individuals from 298 populations from throughout Europe were analysed. We found that gene flow was limited between the two major taxa, diploid ssp. fuchsii (including ssp. saccifera) and tetraploid ssp. maculata. A minimum of three autotetraploid lineages were discerned: (1) southern/western ssp. maculata; (2) northern/eastern ssp. maculata; and (3) Central European ssp. fuchsii. The two ssp. maculata lineages, which probably pre‐date the last glaciation, form a contact zone with high genetic diversity in central Scandinavia. Intermediate plastid haplotypes in the contact zone hint at recombination. Central Europe may have been a source area for the postglacial migration for the southern/western lineage of ssp. maculata, as well as for ssp. fuchsii. The northern/eastern lineage of ssp. maculata may have survived the LGM in central Russia west of the Urals. The tetraploid lineage of ssp. fuchsii is indistinguishable from diploid ssp. fuchsii, and is probably of postglacial origin. The Mediterranean region and the Caucasus have not contributed to the northward migration of either ssp. fuchsii or ssp. maculata. © 2010 The Linnean Society of London, Biological Journal of the Linnean Society, 2010, 101 , 503–525.     

Fragmented habitats and Pleistocene climate shaped diversification of the hoary bamboo rat (Rhizomys pruinosus) in the mountainous plateau of SW China

The southwest mountainous region of China has been characterized as one of the worldwide biodiversity hotspots, but mechanisms underlying diversification of organisms in this region are still not clear. We assessed whether fragmented mountainous habitats and Pleistocene climate changes impacted the genetic diversity and diversification patterns of the hoary bamboo rat (Rhizomys pruinosus Blyth), a widely distributed species of rodent in SW China. Genetic diversity analyses were undertaken based on four mitochondrial DNA regions and 12 nuclear microsatellite loci (simple sequence repeats), representing 153 individuals from 24 populations across SW China. Moreover, we investigated correlations between genotype and geographical components, and predicted species distribution models for R. pruinosus under the historical and present climate conditions. Both mitochondrial DNA and simple sequence repeat markers revealed substantial genetic diversity and strong differentiation between populations. Phylogeographical analyses revealed two phylogenetic clades that were consistent with their geographical distributions (eastern and western clades). We inferred that the divergence of R. pruinosus was largely driven by Quaternary climatic oscillations and regionally fragmented mountainous habitats with environmental and geographical heterogeneity. Overall, our study revealed diversification patterns of R. pruinosus—patterns that may be shared by small alpine vertebrates in SW China.     

Genetic structure, introgression, and a narrow hybrid zone between northern and California spotted owls (Strix occidentalis)

The northern spotted owl (Strix occidentalis caurina) is a threatened subspecies and the California spotted owl (Strix occidentalis occidentalis) is a subspecies of special concern in the western United States. Concern for their continued viability has arisen because of habitat loss caused by timber harvesting. The taxonomic status of the northern subspecies has been the subject of continuing controversy. We investigated the phylogeographical and population genetic structure of northern and California spotted owls with special reference to their region of contact. Mitochondrial DNA (mtDNA) control region sequences confirmed the existence of two well-differentiated lineages connected by a narrow hybrid zone in a region of low population density in north central California. Maximum-likelihood estimates indicated bidirectional gene flow between the lineages but limited introgression outside the region of contact. The lengths of both the mtDNA hybrid zone and the reduced density patch were similar and slightly exceeded estimates of natal dispersal distances. This suggests that the two subspecies were in secondary contact in a hybrid zone trapped by a population density trough. Consequently, the zone of interaction is expected to be geographically stable. We discovered a third, rare clade of haplotypes, which we interpreted to be a result of incomplete lineage sorting; those haplotypes result in a paraphyletic northern spotted owl with respect to the California spotted owl. A congeneric species, the barred owl (Strix varia), occasionally hybridizes with spotted owls; our results indicated an upper bound for the frequency of barred owl mtDNA haplotypes in northern spotted owl populations of 3%.     

Positioning the Red Deer (Cervus elaphus) Hunted by the Tyrolean Iceman into a Mitochondrial DNA Phylogeny

In the last years several phylogeographic studies of both extant and extinct red deer populations have been conducted. Three distinct mitochondrial lineages (western, eastern and North-African/Sardinian) have been identified reflecting different glacial refugia and postglacial recolonisation processes. However, little is known about the genetics of the Alpine populations and no mitochondrial DNA sequences from Alpine archaeological specimens are available. Here we provide the first mitochondrial sequences of an Alpine Copper Age Cervus elaphus. DNA was extracted from hair shafts which were part of the remains of the clothes of the glacier mummy known as the Tyrolean Iceman or Ötzi (5,350–5,100 years before present). A 2,297 base pairs long fragment was sequenced using a mixed sequencing procedure based on PCR amplifications and 454 sequencing of pooled amplification products. We analyzed the phylogenetic relationships of the Alpine Copper Age red deer''s haplotype with haplotypes of modern and ancient European red deer. The phylogenetic analyses showed that the haplotype of the Alpine Copper Age red deer falls within the western European mitochondrial lineage in contrast with the current populations from the Italian Alps belonging to the eastern lineage. We also discussed the phylogenetic relationships of the Alpine Copper Age red deer with the populations from Mesola Wood (northern Italy) and Sardinia.     

Two species of the Rhodiola yunnanensis species complex distributed around the Sichuan Basin of China: Speciation in a ring?

A ring species consists of two reproductively isolated forms connected by a chain of intergrading populations encircling a geographic barrier. The mountains encircling the Sichuan Basin in southwestern China harbor great species diversity and endemism, and they are candidate regions for ring species. Here, we examined a potential ring species complex with a ring distribution surrounding the Sichuan Basinand the reproductive barrier between sibling species Rhodiola yunnanensis and R. henryi of the R. yunnanensis complex. In this study, we test the hypothesis that R. yunnanensis and R. henryi diverged by the ring-species model using an amplicon sequencing strategy targeting the introns of 27 single-copy nuclear genes and 14 chloroplast DNA sequences. Our studies indicated that the R. yunnanensis complex is monophyletic, originates at the late Miocene, and forms its current ring distribution pattern after the LIG. In addition, clear genetic intergradation was not found among R. henryi populations within the distribution ring. All these findings suggest that the divergence of two sibling species was not driven by the geographic isolation, and they were not originated from the ring-species model; however, the basin-surrounding distribution pattern and reproductive barrier between them meet some criteria for being a ring species.     

Phylogeography and postglacial dispersal of arctic charr Salvelinus alpinus in North America

Restriction fragment length polymorphism analysis of mitochondrial DNA (mtDNA) was used to reconstruct postglacial dispersal routes of arctic charr Salvelinus alpinus in North America. Twelve of 35 restriction enzymes detected polymorphisms among representative populations, revealing two distinct lineages with an estimated nucleotide divergence of 1.32%. Subsequent screening of 869 fish from 54 populations with four diagnostic restriction enzymes showed that these lineages have largely allopatric distributions, suggesting their dispersal from separate northern and eastern glacial refugia. In addition, geographical and genetic structure among eastern populations suggested the existence of a second eastern refuge. Among the three lineages, the most divergent (Arctic) lineage occurred from Alaska east to northern Labrador. Quebec, New Brunswick, and New England were colonized by a second (Laurentian) lineage, and Labrador by a third group. Contact between refugial groups was only detected in two Labrador populations. The Arctic lineage was highly differentiated from eastern North American and European haplotypes, and probably diverged during the early Pleistocene. By contrast, the Laurentian and Labrador groups were similar to Old World charr, suggesting a shared ancestry during the mid-Pleistocene. In addition, the close relationship between Labrador and Laurentian charr indicates their probable divergence during the Wisconsinan glaciation.