Multiple markers and multiple individuals refine true seal phylogeny and bring molecules and morphology back in line.

Despite decades of study, some aspects of Phocidae (Pinnipedia, Carnivora) phylogeny still remain unresolved. Using the largest novel dataset to date, including all extant phocids and comprising 15 nuclear and 13 mitochondrial genes, we illustrate the utility of including multiple individuals per species in resolving rapid radiations, and provide new insight into phocid phylogeny. In line with longstanding morphological views, Pusa is recovered as monophyletic for the first time with genetic data. The data are also used to explore the relationship between genetic distance and taxonomic rank. Intraspecific sampling also highlights the discrepancy between molecular and morphological rates of evolution within Phocidae.

Pollen-mediated gene flow from transgenic safflower (Carthamus tinctorius L.) intended for plant molecular farming to conventional safflower.

Field experiments were conducted in Chile and western Canada to measure short-distance (0 to 100 m) outcrossing from transgenic safflower (Carthamus tinctorius L.) intended for plant molecular farming to non-transgenic commodity safflower of the same variety. The transgenic safflower used as the pollen source was transformed with a construct for seed-specific expression of a high-value protein and constitutive expression of a gene conferring resistance to the broad-spectrum herbicide glufosinate. Progeny of non-transgenic plants grown in plots adjacent to the transgenic pollen source were screened for glufosinate resistance to measure outcrossing frequency. Outcrossing frequency differed among locations: values closest to the transgenic pollen source (0 to 3 m) ranged from 0.48 to 1.67% and rapidly declined to between 0.0024 to 0.03% at distances of 50 to 100 m. At each location, outcrossing frequency was spatially heterogeneous, indicating insects or wind moved pollen asymmetrically. A power analysis assuming a binomial distribution and a range of alpha values (type 1 error) was conducted to estimate an upper and lower confidence interval for the probable transgenic seed frequency in each sample. This facilitated interpretation when large numbers of seeds were screened from the outcrossing experiments and no transgenic seeds were found. This study should aid regulators and the plant molecular farming industry in developing confinement strategies to mitigate pollen mediated gene flow from transgenic to non-transgenic safflower.

Population structure of ice-breeding seals.

The development of population genetic structure in ice-breeding seal species is likely to be shaped by a combination of breeding habitat and life-history characteristics. Species that return to breed on predictable fast-ice locations are more likely to exhibit natal fidelity than pack-ice-breeding species, which in turn facilitates the development of genetic differentiation between subpopulations. Other aspects of life history such as geographically distinct vocalizations, female gregariousness, and the potential for polygynous breeding may also facilitate population structure. Based on these factors, we predicted that fast-ice-breeding seal species (the Weddell and ringed seal) would show elevated genetic differentiation compared to pack-ice-breeding species (the leopard, Ross, crabeater and bearded seals). We tested this prediction using microsatellite analysis to examine population structure of these six ice-breeding species. Our results did not support this prediction. While none of the Antarctic pack-ice species showed statistically significant population structure, the bearded seal of the Arctic pack ice showed strong differentiation between subpopulations. Again in contrast, the fast-ice-breeding Weddell seal of the Antarctic showed clear evidence for genetic differentiation while the ringed seal, breeding in similar habitat in the Arctic, did not. These results suggest that the development of population structure in ice-breeding phocid seals is a more complex outcome of the interplay of phylogenetic and ecological factors than can be predicted on the basis of breeding substrate and life-history characteristics.

Molecular phylogeny of the Arctoidea (Carnivora): effect of missing data on supertree and supermatrix analyses of multiple gene data sets.

Phylogenetic relationships of 79 caniform carnivores were addressed based on four nuclear sequence-tagged sites (STS) and one nuclear exon, IRBP, using both supertree and supermatrix analyses. We recovered the three major arctoid lineages, Ursidae, Pinnipedia, and Musteloidea, as monophyletic, with Ursidae (bears) strongly supported as the basal arctoid lineage. Within Pinnipedia, Phocidae (true seals) were sister to the Otaroidea [Otariidae (fur seals and sea lions) and Odobenidae (walrus)]. Phocid subfamily and tribal designations were supported, but the otariid subfamily split between fur seals and sea lions was not. All family designations within Musteloidea were strongly supported: Mephitidae (skunks), Ailuridae (monotypic red panda), Mustelidae (weasels, badgers, otters), and Procyonidae (raccoons). A novel hypothesis for the position of the red panda was recovered, placing it as branching after Mephitidae and before Mustelidae+Procyonidae. Within Mustelidae, subfamily taxonomic changes are considered. This study represents the most comprehensive sampling to date of the Caniformia in a molecular study and contains the most complete molecular phylogeny for the Procyonidae. Our data set was also used in an empirical examination of the effect of missing data on both supertree and supermatrix analyses. Sequence for all genes in all taxa could not be obtained, so two variants of the data set with differing amounts of missing data were examined. The amount of missing data did not have a strong effect; instead, phylogenetic resolution was more dependent on the presence of sufficient informative characters. Supertree and supermatrix methods performed equivalently with incomplete data and were highly congruent; conflicts arose only in weakly supported areas, indicating that more informative characters are required to confidently resolve close species relationships.

Genetic analysis reveals demographic fragmentation of grizzly bears yielding vulnerably small populations.

Ecosystem conservation requires the presence of native carnivores, yet in North America, the distributions of many larger carnivores have contracted. Large carnivores live at low densities and require large areas to thrive at the population level. Therefore, if human-dominated landscapes fragment remaining carnivore populations, small and demographically vulnerable populations may result. Grizzly bear range contraction in the conterminous USA has left four fragmented populations, three of which remain along the Canada-USA border. A tenet of grizzly bear conservation is that the viability of these populations requires demographic linkage (i.e. inter-population movement of both sexes) to Canadian bears. Using individual-based genetic analysis, our results suggest this demographic connection has been severed across their entire range in southern Canada by a highway and associated settlements, limiting female and reducing male movement. Two resulting populations are vulnerably small (< or =100 animals) and one of these is completely isolated. Our results suggest that these trans-border bear populations may be more threatened than previously thought and that conservation efforts must expand to include international connectivity management. They also demonstrate the ability of genetic analysis to detect gender-specific demographic population fragmentation in recently disturbed systems, a traditionally intractable yet increasingly important ecological measurement worldwide.

A phylogeny of the Caniformia (order Carnivora) based on 12 complete protein-coding mitochondrial genes.

Evolutionary relationships of the order Carnivora have been extensively studied. However, phylogenetic studies based on different types of data, species samples, and methods of analysis provide contradictory results. Consequently, phylogenetic relationships of Carnivora remain contentious. Here, the sequence of 12 mitochondrial genes (10,842 nucleotides) from a total of 38 carnivore species was used to investigate the phylogeny of the caniform (dog-like) carnivores. An analysis using maximum parsimony, maximum likelihood, and Bayesian approaches provided a unique and well-supported solution to most contentious relationships within Caniformia. The clade Arctoidea was shown to consist of three major monophyletic groups: Pinnipedia, Ursidae, and Musteloidea. Within Pinnipedia, the families Otariidae and Odobenidae formed a clade, sister to Phocidae. Within Musteloidea, there was a sister relationship between true mustelids (i.e., excluding the skunks) and procyonids, and between ailurids and mephitids (skunks). Despite a high level of confidence obtained at most nodes, uncertainty remained about the relative position of the three major arctoid clades.

Genetic differentiation and gene flow among populations of the alpine butterfly, Parnassius smintheus, vary with landscape connectivity.

Levels of gene flow among populations vary both inter- and intraspecifically, and understanding the ecological bases of variation in levels of gene flow represents an important link between the ecological and evolutionary dynamics of populations. The effects of habitat spatial structure on gene flow have received considerable attention; however, most studies have been conducted at a single spatial scale and without background data on how individual movement is affected by landscape features. We examined the influence of habitat connectivity on inferred levels of gene flow in a high-altitude, meadow-dwelling butterfly, Parnassius smintheus. For this species, we had background data on the effects of landscape structure on both individual movement and on small-scale population genetic differentiation. We compared genetic differentiation and patterns of isolation by distance, based on variation at seven microsatellite loci, among three regions representing two levels of connectivity of high-altitude, nonforested habitats. We found that reduced connectivity of habitats, resulting from more forest cover at high altitudes, was associated with greater genetic differentiation among populations (higher estimated FST), a breakdown of isolation by distance, and overall lower levels of inferred gene flow. These observed differences were consistent with expectations based on our knowledge of the movement behaviour of this species and on previous population genetic analyses conducted at the smaller spatial scale. Our results indicate that the role of gene flow may vary among groups of populations depending on the interplay between individual movement and the structure of the surrounding landscape.

Among- and within-patch components of genetic diversity respond at different rates to habitat fragmentation: an empirical demonstration.

Habitat fragmentation is a ubiquitous by-product of human activities that can alter the genetic structure of natural populations, with potentially deleterious effects on population persistence and evolutionary potential. When habitat fragmentation results in the subdivision of a population, random genetic drift then leads to the erosion of genetic diversity from within the resulting subpopulation, random genetic drift then leads to the erosion of genetic diversity from within the resulting subpopulations and greater genetic divergence among them. Theoretical and simulation analyses predict that these two main genetic effects of fragmentation, greater differentiation among resulting subpopulation and reduced genetic diversity within them, will proceed at very different rates. Despite important implications for the interpretation of genetics data from fragmented populations, empirical evidence for this phenomenon has been lacking. In this analysis, we carry out an empirical study in population of an alpine meadow-dwelling butterfly, which have become fragmented increasing forest cover over five decades. We show that genetic differentiation among subpopulations (G(ST)) is most highly correlated with contemporary forest cover, while genetics diversity within subpopulation (expected heterozygosity) is better correlated with the spatial pattern of forest cover 40 years in the past. Thus, where habitat fragmentation has occurred in recent decades, genetic differentiation among subpopulation can be near equilibrium while contemporary measures of within subpopulation diversity may substantially overestimate the equilibrium values that will eventually be attained.

A phylogeny of the extant Phocidae inferred from complete mitochondrial DNA coding regions.

Despite extensive interest in the systematics of Pinnipedia, questions remain concerning phylogenetic relationships within the Phocidae or "true" seals. Relationships within the phocids and their placement relative to the remaining pinnipeds and major lineages of arctoid carnivores were examined using a large molecular data set consisting of 12 mitochondrial protein coding genes. Phylogenetic analysis including 15 extant species of the Phocidae, and representatives of the Otariidae, Odobenidae, Ursidae, Mustelidae, Canidae, and Felidae confirmed the monophyletic origins of the Pinnipedia within the Arctoidea. Slightly more support was found for an ursid affinity of the pinnipeds, however, this relationship remains contentious. The Phocidae were placed as the sister group to a common odobenid-otariid clade. Within the family Phocidae, strong support for the traditionally accepted subfamilies Phocinae (northern seals), and Monachinae (southern seals plus monk seals) was found. In contrast to recent suggestions, a monophyletic Monachus was strongly supported and was placed in a deep branching position within the Monachinae. Evidence from sequence divergence under a maximum likelihood model illustrated that the rarely used tribal distinction within the Monachinae are comparable, in terms of evolutionary distance, to accepted tribal distinctions within the Phocinae. In addition, results suggest that Pagophilus should be accepted as a genus within the Phocini. Sequence divergence between Phoca, Pusa, and Halichoerus is minimal, supporting a taxonomic reclassification of the three genera into an emended genus Phoca, without subgeneric distinctions.

Undesirable evolutionary consequences of trophy hunting.

Phenotype-based selective harvests, including trophy hunting, can have important implications for sustainable wildlife management if they target heritable traits. Here we show that in an evolutionary response to sport hunting of bighorn trophy rams (Ovis canadensis) body weight and horn size have declined significantly over time. We used quantitative genetic analyses, based on a partly genetically reconstructed pedigree from a 30-year study of a wild population in which trophy hunting targeted rams with rapidly growing horns, to explore the evolutionary response to hunter selection on ram weight and horn size. Both traits were highly heritable, and trophy-harvested rams were of significantly higher genetic 'breeding value' for weight and horn size than rams that were not harvested. Rams of high breeding value were also shot at an early age, and thus did not achieve high reproductive success. Declines in mean breeding values for weight and horn size therefore occurred in response to unrestricted trophy hunting, resulting in the production of smaller-horned, lighter rams, and fewer trophies.

A phylogenetic comparison of red deer and wapiti using mitochondrial DNA.

A phylogeny was constructed for red deer/wapiti (Cervus elaphus) subspecies using sequence data from the control region of mitochondrial DNA (mtDNA). The tree was rooted using Cervus nippon (sika deer), Cervus albirostris (Thorold's white-lipped deer), and several Odocoileinae species. A division between the mtDNA haplotypes of red deer (European) and wapiti (Asian/North American) corresponds to subspecies found on opposite sides of the Himalayan Mountains and Gobi, which suggests wapiti should be reconsidered for the status of C. canadensis. Using parsimony and distance analysis, red deer and wapiti are derived from a single recent common ancestor, which is consistent with current taxonomy that recognizes the subspecies of Cervus elaphus as monophyletic group. However, maximum-likelihood analysis using weighted transitional substitutions caused red deer to form a sister group to sika deer (Cervus nippon) and wapiti. A phenetic comparison revealed wapiti also share more nucleotide similarities with sika deer, although approximately 5% sequence divergence separates wapiti, sika, and red deer. Phylogenetic evidence from the cytochrome b sequences corroborated observations from the control region. Observations from this study suggest that the species status of wapiti should be reinstated.

EVOLUTIONARY RELATIONSHIPS AMONG COLONIES OF COLUMBIAN GROUND SQUIRRELS AS SHOWN BY MITOCHONDRIAL DNA.

Mitochondrial DNA (mtDNA) from 71 Columbian ground squirrels (Spermophilus columbianus) collected in 12 locations in western Canada were assayed for restriction-site variation with 10 endonucleases. Five of these endonucleases revealed variant patterns, and the composite genotypes were used to develop a linear transformation series among the mtDNA genotypes. Two of the four clones had a wide distribution, while the remaining two clones were geographically restricted. The mtDNA of Columbian ground squirrels was also compared to two other species of Sciuridae: Richardson's ground squirrels (S. richardsonii) and Arctic ground squirrels (S. parryii). Calculation of divergences from fragment length and restriction-site data indicated that Arctic ground squirrels and Richardson's ground squirrels were more closely related to each other than either was to Columbian ground squirrels. The transformation series among clones within the Columbian ground squirrels was rooted using Richardson's and Arctic ground squirrels as out-groups. From these data, we conclude that the colonization by female founders of Columbian ground squirrel populations occurred after deglaciation along the eastern ranges of the Rocky Mountains, while colonies on the western ranges may have been present before extensive deglaciation occurred, having existed in refugia in northwestern Alberta.