Phylogenetic relationships of Sakhalin taimen Parahucho perryi inferred from PCR-RFLP analysis of mitochondrial DNA

RFLP analysis of three amplified mtDNA fragments (Cytb/D-loop, ND1/ND2, and ND3/ND4L/ND4) was performed in the following taxa: Parahucho perryi, Hucho taimen, Brachymystax lenok, B. tumensis, Salmo salar, Salvelinus leucomaenis, and S. levanidovi. For mtDNA of P. perryi, a substantial decrease in the haplotype and nucleotide diversity was observed as a result of random genetic drift, caused by a reduction in the effective population size. Nucleotide divergence estimates between the mtDNA haplotypes were determined. Sakhalin taimen P. perryi was found to be approximately equally diverged from S. salar and from the charrs of the genus Salvelinus, by 11.0 and 10.0%, respectively. The divergence between P. perryi and H. taimen constituted 14.6%, between P. perryi and lenoks of the genus Brachymystax, 14.2%, and between H. taimen and Brachymystax, 7.7%. The analysis of possible phylogenetic relationships of the mtDNA from P. perryi among the group of taxa examined confirmed validity of the genus Parahucho. Phylogenetic reconstructions performed showed that robustness of the trees constructed for the complex of phylogenetically informative characters over three mtDNA fragments was considerably higher than that of the trees constructed for individual genes.     

Genetc divergence and phylogeny of the Salmoninae based on allozyme data

The data on 31–37 allozyme loci in 21 species of nine salmonid genera are used for phylogenetic analysis by seven distance methods and several variants of cladistic analysis. Monophyletic origin for all genera and three sub-families of the Salmonidae is corroborated. The closest phylogenetic relationships are characteristic of Parasalmo and Oncorhynchus (bootstrap support is 88–99%), Brachymystax and Hucho (68–97%), and the clade ( Brachymystax + Hucho )+ Salmo (up to 85%). The patterns of phylogenetic relationships in the group Salmo-Parasalmo-Oncorhynchus are analogous to those in the group Parahucho-Hucho-Brachymystax. The position of Parahucho in phylogenetic trees of the Salmoninae is extremely unstable, although it is most likely associated with the clade ( Brachymystax + Hucho)+Salmo ) or Salvelinus. When using the out group analysis, Salvelinus appears as the earliest branch of the Salmoninae tree, whereas if the molecular clock is assumed, the basal position is occupied by Oncorhynchus. However, the latter genus is probably characterized by a substantially increased rate of molecular evolution.     

Phylogeny of salmonids (Salmoniformes, Salmonidae) and its molecular dating: analysis of nuclear RAG1 gene

The phylogenetic relationships among 26 species of salmonid fishes (family Salmonidae) were studied using the RAG1 gene as phylogenetic marker. No unambiguous relationships between thymallins, coregonins, and salmonins it was possible to establish. It seems likely, that divergence of these lineages took place during rather short time interval (about 3 to 4 million years). The thymallins are thought to be the first radiated lineage. The genera of the subfamily Salmoninae form two distinct monophyletic groups, represented by (1) Brachymystax and Hucho and (2) Salmo, Parahucho, Salvelinus, Parasalmo and Oncorhynchus. Ancestral forms of these two evolutionary lineages could diverge at the Oligocene-Miocene boundary (about 24 million years ago). It is suggested that diversification of the main lineages within the second group was rather rapid, and took place in middle Miocene (about 19-16 million years ago). Moreover, the lineages of Salvelinus, Parasalmo and Oncorhynchus were the latest to diverge. It seems likely that divergence of the Prosopium and Corergouns ancestral lineages occurred during the same time interval.     

川陕哲罗鲑Cyt b基因克隆及其在鲑亚科中的系统发育关系

采用聚合酶链式反应克隆川陕哲罗鲑Hucho bleekeri线粒体细胞色素b基因 (Cyt b),首次报道该基因的全长序列(1140 bp,GenBank 登录号FJ597623),并与鲑亚科中其他5属14个物种的Cyt b基因进行同源性比较,分析了碱基组成和变异情况,以白鲑亚科的白鲑Coregonus lavaretus作为外群构建了ML、NJ和MP系统发育树.遗传距离和分子系统学分析表明,川陕哲罗鲑与细鳞鲑属的细鳞鱼Brachymystax lenok之间的遗传距离相对较小(8.47%),在系统发育树上两者聚在一起,提示川陕哲罗鲑与细鳞鱼存在较近的亲缘关系,该结果与以往的形态学分类不相符.     

Phylogenetic relationship of mitochondrial DNA in salmonids of the subfamily Salmoninae: analysis of the cytochrome b gene sequences

On the basis of comparison of the cytochrome b gene nucleotide sequences from genetic databases, the possible phylogenetic relationships of mitochondrial DNA (mtDNA) among all major lineages of Salmoninae (Brachymystax, Parahucho, Salvelinus, Salmo, Parasalmo, and Oncorhynchus) were examined. Three different phylogenetic methods (UPGMA, NJ, and ML) yielded phylogenetic trees of essentially the same topology: (((Brachymystax, Parahucho), Salvelinus, Salmo), (Parasalmo, Oncorhynchus)). The results obtained using the maximum parsimony method were less clear. Apparently, the divergence of the main salmonid lineages occurred during a relatively short time period; hence, the number of synapomorphs marking the order of their divergence was extremely low. This may account for the relative failure to use the maximum parsimony method of phylogenetic reconstruction. The problem of concordance of mtDNA and species phylogenetic schemes is discussed. Their discrepancy in salmonids may be caused by interspecific introgressive hybridization.     

Comparative mtDNA sequence (control region, ATPase 6 and NADH‐1) divergence in Hucho taimen(Pallas) across four Siberian river basins

Hucho taimen from eight populations spanning four drainage basins (Amur, Lena, Enisei and Khatanga) were analysed for nucleotide sequence variation across three mitochondrial genes (ATP6, NADH‐1 and control region). Samples of H. hucho , Brachymystax lenok (sharp‐snouted and blunt‐snouted forms) and Parahucho perryi were also included for comparison. Nucleotide variation across a total of 1826 base pairs in H. taimen revealed shared haplotypes between the Amur and Lena basins, further supporting a previous hypothesis of late to post‐Pleistocene hydrological exchange between these now disjunct basins. In contrast to an earlier study using the control region alone, clear phylogeographic structure was seen at a large geographic scale, reflected by two phylogroups, one corresponding to the Amur and Lena basins, and the other to the Enisei and Khatanga basins. Comparative rates of divergence revealed considerably faster and less heterogeneous substitution rates for the two coding genes, especially at interspecific levels compared to the mtDNA control region.     

Phylogenetic relationships of Sakhalin taimen <Emphasis Type="Italic">Parahucho perryi</Emphasis> inferred from PCR-RFLP analysis of mitochondrial DNA

RFLP analysis of three amplified mtDNA fragments (Cytb/D-loop, ND1/ND2, and ND3/ND4L/ND4) was performed in the following taxa: Parahucho perryi, Hucho taimen, Brachymystax lenok, B. tumensis, Salmo salar, Salvelinus leucomaenis, and S. levanidovi. For mtDNA of P. perryi, a substantial decrease in the haplotype and nucleotide diversity was observed as a result of random genetic drift, caused by a reduction in the effective population size. Nucleotide divergence estimates between the mtDNA haplotypes were determined. Sakhalin taimen P. perryi was found to be approximately equally diverged from S. salar and from the charrs of the genus Salvelinus, by 11.0 and 10.0%, respectively. The divergence between P. perryi and H. taimen constituted 14.6%, between P. perryi and lenoks of the genus Brachymystax, 14.2%, and between H. taimen and Brachymystax, 7.7%. The analysis of possible phylogenetic relationships of the mtDNA from P. perryi among the group of taxa examined confirmed validity of the genus Parahucho. Phylogenetic reconstructions performed showed that robustness of the trees constructed for the complex of phylogenetically informative characters over three mtDNA fragments was considerably higher than that of the trees constructed for individual genes.     

The incomplete history of mitochondrial lineages between two rockfishes, Sebastes longispinis and Sebastes hubbsi (Scorpaeniformes: Scorpaenidae)

The genetic divergence between two closely related rockfishes, Sebastes longispinis and Sebastes hubbsi, was inferred from both mitochondrial DNA (mtDNA) sequence variations and amplified fragment length polymorphism (AFLP) markers. The two species were placed into two distinct clades in a neighbour-joining tree based on the AFLP data, clearly indicating that they represented separate species. Although this evidence, together with a previous morphological study, revealed clear differences between the two species, no obvious clustering of haplotypes by species was detected in the minimum spanning network inferred from sequence variations in the mtDNA control region (c. 500 base pairs). In fact, the significant Φ(ST) estimates indicated only a restriction of gene flow between the two species. Uncorrected pairwise sequence differences in mtDNA between two species were small (1·8% at maximum, on the lower end of the range of control region divergence between previously studied sister species pairs), suggesting their speciation event as having been fairly recent. The incongruent results of AFLP and mtDNA phylogenies suggested incomplete lineage sorting and introgression of mtDNA in the course of the evolution of the two species. Differences in their main distributional ranges and the small level of sequence divergence in mtDNA suggests that speciation and dispersal may have been associated with glacio-eustatic sea level fluctuations between the Japanese Archipelago and the Korean Peninsula during the past 0·4 million years.     

The Lactate Dehydrogenase Gene <Emphasis Type="Italic">LDH-C1</Emphasis>, a New Molecular Marker for Phylogenetic Analysis of Salmonid Fishes (Salmoniformes: Salmonidae)

We tested the locus of the nuclear lactate dehydrogenase gene (LDH-C1) as a phylogenetic marker in specimens of 11 salmonid genera (Thymallus, Coregonus, Hucho, Brachymystax, Salmo, Salmothymus, Acantholingua, Parahucho, Salvelinus, Parasalmo, and Oncorhynchus). All the sequences were veraciously clustered according to their taxonomic affiliation at the species and genus levels. It is shown that used complex of characters contains a phylogenetic signal that represents specific information about the phylogenesis process. This allows us to recommend the LDH-C1 locus to specify the phylogeny of salmonids in the combined analysis of several independent nuclear genes and mitochondrial DNA.     

Phylogeny of salmonids (salmoniformes: Salmonidae) and its molecular dating: Analysis of mtDNA data

Phylogenetic relationships among 41 species of salmonid fish and some aspects of their diversification-time history were studied using the GenBank and original mtDNA data. The position of the root of the Salmonidae phylogenetic tree was uncertain. Among the possible variants, the most reasonable seems to be that in which thymallins are grouped into the same clade as coregonins and the lineage of salmonins occupied a basal position relative to this clade. The genera of Salmoninae formed two distinct clades, i.e., (Brachymystax, Hucho) and (Salmo, Parahucho, (Salvelinus, (Parasalmo, Oncorhynchus)). Furthermore, the genera Parasalmo and Oncorhynchus were reciprocally monophyletic. The congruence of Salmonidae phylogenetic trees obtained using different types of phylogenetic markers is discussed. According to Bayesian dating, ancestral lineages of salmonids and their sister esocoids diverged about 106 million years ago. Sometime after, probably 100–70 million years ago, the salmonid-specific whole genome duplication took place. The divergence of salmonid lineages on the genus level occurred much later, within the time interval of 42–20 million years ago. The main wave of the diversification of salmonids at the species level occurred during the last 12 million years. The possible effect of genome duplication on the Salmonidae diversification pattern is discussed.     

Phylogeny of Mitochondrial DNA in Salmonids of the Subfamily Salmoninae: Analysis of the Cytochrome b Gene Sequences

On the basis of comparison of the cytochrome b gene nucleotide sequences from genetic databases, the possible phylogenetic relationships of mitochondrial DNA (mtDNA) among all major lineages of Salmoninae (Brachymystax, Parahucho, Salvelinus, Salmo, Parasalmo, and Oncorhynchus) were examined. Three different phylogenetic methods (UPGMA, NJ, and ML) yielded phylogenetic trees of essentially the same topology: (((Brachymystax, Parahucho), Salvelinus, Salmo), (Parasalmo, Oncorhynchus)). The results obtained using the maximum parsimony method were less clear. Apparently, the divergence of the main salmonid lineages occurred during a relatively short time period; hence, the number of synapomorphs marking the order of their divergence was extremely low. This may account for the relative failure to use the maximum parsimony method of phylogenetic reconstruction. The problem of concordance of mtDNA and species phylogenetic schemes is discussed. Their discrepancy in salmonids may be caused by interspecific introgressive hybridization.     

Mitochondrial phylogenetics and evolution of mysticete whales

The phylogenetic relationships among baleen whales (Order: Cetacea) remain uncertain despite extensive research in cetacean molecular phylogenetics and a potential morphological sample size of over 2 million animals harvested. Questions remain regarding the number of species and the monophyly of genera, as well as higher order relationships. Here, we approach mysticete phylogeny with complete mitochondrial genome sequence analysis. We determined complete mtDNA sequences of 10 extant Mysticeti species, inferred their phylogenetic relationships, and estimated node divergence times. The mtDNA sequence analysis concurs with previous molecular studies in the ordering of the principal branches, with Balaenidae (right whales) as sister to all other mysticetes base, followed by Neobalaenidae (pygmy right whale), Eschrichtiidae (gray whale), and finally Balaenopteridae (rorquals + humpback whale). The mtDNA analysis further suggests that four lineages exist within the clade of Eschrichtiidae + Balaenopteridae, including a sister relationship between the humpback and fin whales, and a monophyletic group formed by the blue, sei, and Bryde's whales, each of which represents a newly recognized phylogenetic relationship in Mysticeti. We also estimated the divergence times of all extant mysticete species, accounting for evolutionary rate heterogeneity among lineages. When the mtDNA divergence estimates are compared with the mysticete fossil record, several lineages have molecular divergence estimates strikingly older than indicated by paleontological data. We suggest this discrepancy reflects both a large amount of ancestral polymorphism and long generation times of ancestral baleen whale populations.     

Phylogenetic relationships among the subfamily Coregoninae as revealed by mitochondrial DNA restriction analysis

Mitochondria1 DNA (mtDNA) restriction analysis was used to assess phylogenetic patterns among 21 taxa of the subfamily Coregoninae. The genus Prosopium formed a very distinct group differing by 10% (sequence divergence estimate) from other species. Coregonus and Stenodus species were closely related, diverging by sequence divergence estimates of less than 5.6%. These species split into two major sister groups. One comprised all 'true whitefish' (subgenus Coregonus ) and four cisco species (subgenus Leucichrhys ). The most distant species within this assemblage was the Acadian whitefish ( C. huntsmani ). The other group included all other cisco species and also the Inconnu ( Stenodus leucichthys ). These results supported a polyphyletic origin of the ciscoes, and did not support Stenodus as a sister taxon of the genus Coregonus . The levels of sequence divergence observed suggested that most extant coregonines radiated during the Pleistocene.     

Molecular genetic evidence for reproductive isolation between sympatric populations of smelt Osmerus in Lake Utopia, south-western New Brunswick, Canada

Two morphologically and ecologically distinct forms of smelt, Osmerus, reside sympatrically in Lake Utopia, south-western New Brunswick, Canada. The ‘normal-sized’ form matures at greater than 200 mm standard length, averages about 31–33 gill rakers, and spawns in lake outlets. By contrast, the ‘dwarf-sized’ form matures at less than 150 mm standard length, averages 34–36 gill rakers, and spawns in small streams 3–5 weeks later than the normal form. We tested whether these sympatric forms represented ecological polymorphism within a single population or two reproductively isolated demes by assaying variation within and between forms by mitochondrial DNA (mtDNA) restriction site and nuclear minisatellite DNA analyses. Analysis of smelt mtDNA with twelve restriction enzymes resolved ten composite genotypes (differing by an average 0.27% sequence divergence) which differed markedly in frequency between the forms. Net percentage sequence divergence between the forms was O.l6%. A Wagner parsimony/ bootstrapping analysis of the restriction site presence/absence matrix, however, suggested that there were no significant distinctions between dwarf and normal smelt based on the phylogeny of composite genotypes. Hybridization studies of genomic DNA digests with a minisatellite probe indicated both that nuclear restriction fragment differentiation and the frequency of specific fragments differed significantly between the forms. Significant genetic differentiation between the sympatric forms demonstrates that they are distinct gene pools and reproductively isolated. Our molecular evidence for reproductive isolation between dwarf and normal smelt in Lake Utopia, coupled with the persistent morphological and ecological differentiation between them, argues strongly that they are behaving as distinct species. The Lake Utopia Osmerus populations provide further illustration of the potential for rapid differentiation to the level of biological species in postglacial environments.     

A comparative description of mitochondrial DNA differentiation in selected avian and other vertebrate genera

Levels of mitochondrial DNA (mtDNA) sequence divergence between species within each of several avian (Anas, Aythya, Dendroica, Melospiza, and Zonotrichia) and nonavian (Lepomis and Hyla) vertebrate genera were compared. An analysis of digestion profiles generated by 13-18 restriction endonucleases indicates little overlap in magnitude of mtDNA divergence for the avian versus nonavian taxa examined. In 55 interspecific comparisons among the avian congeners, the fraction of identical fragment lengths (F) ranged from 0.26 to 0.96 (F = 0.46), and, given certain assumptions, these translate into estimates of nucleotide sequence divergence (p) ranging from 0.007 to 0.088; in 46 comparisons among the fish and amphibian congeners, F values ranged from 0.00 to 0.36 (F = 0.09), yielding estimates of P greater than 0.070. The small mtDNA distances among avian congeners are associated with protein-electrophoretic distances (D values) less than approximately 0.2, while the mtDNA distances among assayed fish and amphibian congeners are associated with D values usually greater than 0.4. Since the conservative pattern of protein differentiation previously reported for many avian versus nonavian taxa now appears to be paralleled by a conservative pattern of mtDNA divergence, it seems increasingly likely that many avian species have shared more recent common ancestors than have their nonavian taxonomic counterparts. However, estimates of avian divergence times derived from mtDNA- and protein-calibrated clocks cannot readily be reconciled with some published dates based on limited fossil remains. If the earlier paleontological interpretations are valid, then protein and mtDNA evolution must be somewhat decelerated in birds. The empirical and conceptual issues raised by these findings are highly analogous to those in the long-standing debate about rates of molecular evolution and times of separation of ancestral hominids from African apes.      

Isolation and characterization of Brachymystax lenok microsatellite loci and cross‐species amplification in Hucho spp. and Parahucho perryi

We isolated and characterized eight polymorphic microsatellite markers for Brachymystax lenok (Pallas, 1773) from genomic libraries enriched for (GATA)_n, (GACA)_n and (ATG)_n microsatellites. The number of alleles per locus ranged from two to 17. Heterozygosity ranged from 0.2 to 0.95. In addition, cross‐species amplification was successful for seven loci in Hucho hucho, eight in H. taimen and seven in Parahucho perryi.     

Genetic relationships among the shads (Alosa) revealed by mitochondrial DNA analysis

We surveyed restriction site differences in mitochondrial DNA. (mtDNA) among five species of shad ( Alosa ) from North America and Europe. Allis shad, Alosa alosa and twaite shad, Alosa fallax shared two divergent genotype groups, suggesting that the two forms are either a single species, or are distinct species that have hybridized. Phenetic and cladistic analyses of the relationships among the mitochondrial genotypes defined two groups of shad, corresponding to the subgenera, Alosa and Pomolobus . The mean estimated sequence divergence between the mtDNAs of these two groups of shad was 6.5%. Taken in conjunction with fossil data, this divergence estimate suggests that the rate of mtDNA divergence between the two subgenera has been almost 10-fold lower than the 'conventional' clock calibration for mtDNA.     

Mitochondrial DNA evolution at a turtle's pace: evidence for low genetic variability and reduced microevolutionary rate in the Testudines.

Evidence is compiled suggesting a slowdown in mean microevolutionary rate for turtle mitochondrial DNA (mtDNA). Within each of six species or species complexes of Testudines, representing six genera and three taxonomic families, sequence divergence estimates derived from restriction assays are consistently lower than expectations based on either (a) the dates of particular geographic barriers with which significant mtDNA genetic clades appear associated or (b) the magnitudes of sequence divergence between mtDNA clades in nonturtle species that otherwise exhibit striking phylogeographic concordance with the genetic partitions in turtles. Magnitudes of the inferred rate slowdowns average eightfold relative to the "conventional" mtDNA clock calibration of 2%/Myr sequence divergence between higher animal lineages. Reasons for the postulated deceleration remain unknown, but two intriguing correlates are (a) the exceptionally long generation length most turtles and (b) turtles' low metabolic rate. Both factors have been suspected of influencing evolutionary rates in the DNA sequences of some other vertebrate groups. Uncertainities about the dates of cladogenetic events in these Testudines leave room for alternatives to the slowdown interpretation, but consistency in the direction of the inferred pattern, across several turtle species and evolutionary settings, suggests the need for caution in acceptance of a universal mtDNA-clock calibration for higher animals.     

Spawning behaviour of Sakhalin taimen, <Emphasis Type="Italic">Parahucho perryi</Emphasis>, from northern Hokkaido,Japan

A video camera mounted in an underwater housing and remotely operated was used to monitor the behaviour of five different Sakhalin taimen (Parahucho perryi), females and attendant males spawning in three coastal tributary streams in Northern Hokkaido, Japan. Based on three complete and two incomplete spawnings, we describe in detail for the first time the complete spawning behavioural repertoire of this species. The Sakhalin taimen was originally placed within Hucho, then removed from that genus based on morphological, life history and molecular data. Our study supports that removal—none of the behavioural traits we recorded clustered Parahucho with Hucho uniquely. Similarities between the two genera were all plesiomorphic traits that are widespread throughout the salmonines. The immediate behaviour right after spawning was found to be a major difference between Hucho and Parahucho. Like female Oncorhynchus and Salmo, Sakhalin taimen females cover their eggs by beats of their tails immediately after spawning. This is different from the “rest, then cover” behaviour shown by Siberian taimen (Hucho taimen) as well as lenok (Brachymystax lenok), supporting again that the Sakhalin taimen be removed from Hucho and placed in its own genus.     

Genealogical concordance and the specific status of Peromyscus sejugis

Peromyscus sejugis, a peripheral isolate of Peromyscus maniculatus, is a threatened taxon endemic to 2 small islands in the Sea of Cortés. Although its insularity makes the specific recognition of P. sejugis inherently problematic, resolution of this problem has important conservation implications. To evaluate the specific validity and evolutionary history of P. sejugis, we compared sequence variation (ND3/ND4L/ND4) in mtDNA for both island populations of P. sejugis with that for 8 populations of P. maniculatus from mainland Baja California. Each island population of P. sejugis had a single haplotype (0.7% sequence divergence), whereas 11 different haplotypes (mean sequence divergence = 0.68%) were obtained for the populations of P. maniculatus. The mean sequence divergence between the populations of the 2 species was 2.0%. Nested clade analysis supports the conclusion that P. sejugis is an insular isolate of P. maniculatus from mainland Baja California. Although our analysis confirms a low level of mtDNA divergence between P. sejugis and P. maniculatus from Baja California, the genealogical concordance of morphological, chromosomal, microsatellite, and mtDNA haplotype distinctiveness supports the conclusion that the 2 island populations of P. sejugis constitute independent evolutionarily significant units and together represent a phylogenetic species distinct from the P. maniculatus from Baja California.