Life history of an invasive and unexploited population of Nile tilapia (Oreochromis niloticus) and geographical variation across its native and non-native ranges

Although the life history traits of Nile tilapia, Oreochromis niloticus have been studied since the early 20^th century, the potential range of life history parameters in unexploited populations and geographical variability in life history traits are still poorly understood. We explored life history traits (age composition, growth rate, mortality, size, and age at maturity) of an invasive and unexploited population in the Tabaru River, Yonaguni-jima Island, southwestern Japan, through comparisons with exploited populations across the species’ global distribution. Analysis of sectioned otoliths from 307 fish revealed that growth and maximum age were sexually dimorphic (females growing less but having greater longevity). Large-scale comparisons with exploited populations revealed that the unexploited Tabaru River population had a greater life span than exploited populations in other regions, but the growth rate was in the middle of the range of observed values. Although a high variation in life history parameters was observed among populations (L _∞, K, maximum age), we found no significant variation in life history traits by latitude or between African and non-African populations. Such a combination of long life span and high variability in life history traits in response to environmental and fishing pressures may aid the success of non-native Nile tilapia in various environments.     

Population Responses to Environmental Change: Life History Variation, Individual-based Models, and the Population Dynamics of Short-lived Organisms

SYNOPSIS. We review two potentially important approaches topredicting the consequences of environmental change for populationsof short-lived organisms. First, we examine the concepts of"feasible life histories" and "feasible demographies" and presentthe results of a set of simulations in which the effects onpopulation growth rate of varying one of the demographic variables(average nest survival, average juvenile survival rates, averageannual adult survival rates, or age-specific fecundity) overa broad range of values while the others are maintained at long-termpopulation average values for the Grapevine Hills, Texas populationof the short-lived lizard Sceloporus merriami. The results ofthese simulations are compared to an analogous set of simulationsfor a Michigan population of the relatively long-lived snappingturtle (Chelydra serpentina, Congdon et al., 1994). The implicationsof differences in feasible demographies and life histories suchas described for these two species are discussed. We also discuss the approach of using individual-based, physiologicallystructured models to predict population response to environmentalvariation and present the results of simulations using a modeldeveloped for predicting population-level effects of operativeenvironmental variation in the lizard S. merriami under twodifferent climate change scenarios. This individual-based, physiologicallystructured model incorporates population-specific data on ecologicalenergetics, thermal and size dependence of digestive physiologyand metabolic rates, energetics of individual growth, allometricrelationships, social structure and mating system, and the dependenceof mortality rates on age, size, and social status of individuals.The data necessary to such models of population response toenvironmental variation can come only from detailed long-termstudies of individual populations.     

Experimental harvest regulations reveal that water availability during spring,not harvest,affects change in a waterfowl population

Population change is regulated by vital rates that are influenced by environmental conditions, demographic stochasticity, and, increasingly, anthropogenic effects. Habitat destruction and climate change threaten the future of many wildlife populations, and there are additional concerns regarding the effects of harvest rates on demographic components of harvested organisms. Further, many population managers strictly manage harvest of wild organisms to mediate population trends of these populations. The goal of our study was to decouple harvest and environmental variability in a closely monitored population of wild ducks in North America, where we experimentally regulated harvest independently of environmental variation over a period of 4 years. We used 9 years of capture–mark–recapture data to estimate breeding population size during the spring for a population of wood ducks in Nevada. We then assessed the effect of one environmental variable and harvest pressure on annual changes in the breeding population size. Climatic conditions influencing water availability were strongly positively related to population growth rates of wood ducks in our study system. In contrast, harvest regulations and harvest rates did not affect population growth rates. We suggest efforts to conserve waterfowl should focus on the effects of habitat loss in breeding areas and climate change, which will likely affect precipitation regimes in the future. We demonstrate the utility of capture–mark–recapture methods to estimate abundance of species which are difficult to survey and test the impacts of anthropogenic harvest and climate on populations. Finally, our results continue to add to the importance of experimentation in applied conservation biology, where we believe that continued experiments on nonthreatened species will be critically important as researchers attempt to understand how to quantify and mitigate direct anthropogenic impacts in a changing world.     

Impact of a mouth parasite in a marine fish differs between geographical areas

Considerable variation exists in parasite virulence and host tolerance which may have a genetic and/or environmental basis. In this article, we study the effects of a striking, mouth‐dwelling, blood‐feeding isopod parasite (Ceratothoa italica) on the life history and physiological condition of two Mediterranean populations of the coastal fish, Lithognathus mormyrus. The growth and hepatosomatic index (HSI) of fish in a heavily human‐exploited population were severely impacted by this parasite, whereas C. italica showed negligible virulence in fish close to a marine protected area. In particular, for HSI, the parasite load explained 34.4% of the variation in HSI in the exploited population, whereas there was no significant relationship (0.3%) between parasite load and HSI for fish in the marine protected area. Both host and parasite populations were not differentiated for neutral genetic variation and were likely to exchange migrants. We discuss the role of local genetic adaptation and phenotypic plasticity, and how deteriorated environmental conditions with significant fishing pressure can exacerbate the effects of parasitism. © 2012 The Linnean Society of London, Biological Journal of the Linnean Society, 2012, 105 , 842–852.     

Culling Versus Density Effects in Management of a Deer Population

Abstract: Wildlife managers often manipulate hunting regulations to control deer populations. However, few empirical studies have examined the level of hunting effort (hunter-days) required to limit population growth and demographic effects through harvesting of females. Moreover, the relative importance of density effects on population growth has not been quantified. We reconstructed a sika deer [Cervus nippon] population over a period of 12 years (1990–2001) using age- and sex-specific harvest data. Using cohort analysis, we analyzed population dynamics, focusing on 1) the relationship between hunting effort and hunting-induced mortality rate, 2) relative contributions of hunting mortality and recruitment of yearlings to annual changes in population growth rate, and 3) annual variation in recruitment rate. Population size increased until 1998 and declined thereafter. The population growth rate changed more in response to annual changes in recruitment rate than hunting mortality rate. Temporal variation in recruitment rate was not controlled by birth rate alone; direct density dependence, intensities of hunting mortality for fawns, and for females (≥2 yr of age), which accounted for the fawn survival rate, were required as factors to explain temporal variation. Density effects on the recruitment rate were not strong enough to regulate the population within the study period; high hunting mortality, with intensive female harvesting, was necessary to prevent population growth. Hunting effort was a good predictor of the hunting mortality rate, and female harvest had a negative effect on the recruitment rate through fawn survival. We suggest that >3,500 hunter-days and prioritization of female harvesting are required to prevent increases in this deer population.     

Comparative Biology of Zebra Mussels in Europe and North America: An Overview

SYNOPSIS. Since the discovery of the zebra mussel, Dreissenapolymorpha, in the Great Lakes in 1988 comparisons have beenmade with mussel populations in Europe and the former SovietUnion. These comparisons include: Population dynamics, growthand mortality rates, ecological tolerances and requirements,dispersal rates and patterns, and ecological impacts. NorthAmerican studies, mostly on the zebra mussel and a few on asecond introduced species, the quagga mussel, Dreissena bugensis,have revealed some similarities and some differences. To dateit appears that North American populations of zebra musselsare similar to European populations in their basic biologicalcharacteristics, population growth and mortality rates, anddispersal mechanisms and rates. Relative to European populationsdifferences have been demonstrated for: (1) individual growthrates; (2) life spans; (3) calcium and pH tolerances and requirements;(4) potential distribution limits; and (5) population densitiesof veligers and adults. In addition, studies on the occurrenceof the two dreissenid species in the Great Lakes are showingdifferences in their modes of life, depth distributions, andgrowth rates. As both species spread throughout North America,comparisons between species and waterbodies will enhance ourability to more effectively control these troublesome species.     

Sustainability of threatened species displayed in public aquaria,with a case study of Australian sharks and rays

Zoos and public aquaria exhibit numerous threatened species globally, and in the modern context of these institutions as conservation hubs, it is crucial that displays are ecologically sustainable. Elasmobranchs (sharks and rays) are of particular conservation concern and a higher proportion of threatened species are exhibited than any other assessed vertebrate group. Many of these lack sustainable captive populations, so comprehensive assessments of sustainability may be needed to support the management of future harvests and safeguard wild populations. We propose an approach to identify species that require an assessment of sustainability. Species at risk of extinction in the wild were considered to be those assessed as threatened (CR, EN or VU) on the IUCN Red List of Threatened Species, or data deficient species that may be at an elevated risk of extinction due to life history traits and habitat associations. We defined sustainable captive populations as self-maintaining, or from a source population that can sustain harvest levels without risk of population declines below sustainable levels. The captive breeding and wild harvest records of at risk species displayed by Australian aquaria were examined as a case study. Two species, largetooth sawfish Pristis pristis and grey nurse shark Carcharias taurus, were found to have unsustainable captive populations and were identified as high priorities for comprehensive sustainability assessments. This review highlights the need for changes in permitting practices and zoo and aquarium record management systems to improve conservation outcomes for captive elasmobranchs.     

Population genetic structure of Titanotrichum oldhamii (Gesneriaceae), a subtropical bulbiliferous plant with mixed sexual and asexual reproduction

• Background and Aims Titanotrichum oldhamii is a monotypicgenus distributed in Taiwan, adjacent regions of China and theRyukyu Isands of Japan. Its conservation status is vulnerableas most populations are small and widely scattered. Titanotrichumhas a mixed system of reproduction with vegetative bulbils andseeds. The aim of this study was to understand the populationgenetic structure of Titanotrichum in relation to its specificreproductive behaviour and to determine possible implicationsfor conservation strategies. • Methods After an extensive inventory of most wild populationsof Titanotrichum in East Asia, samples from 25 populations withinits major distribution were carried out utilizing RAPD and inter-SSRmolecular fingerprinting analysis. • Key Results The findings support the conclusion thatmany populations reproduce predominantly asexually but thatsome genetic variation still exists within populations. However,significant amounts of variation exist between populations,perhaps reflecting population differentiation by drift. Thispartitioning of genetic diversity indicates that the level ofinter-population gene exchange is extremely low. These findingsare consistent with field observations of very limited seedproduction. The Chinese populations are similar to those ofNorthern Taiwan, while the Ryukyu populations fall within therange of variation of the north-central Taiwan populations.The Taiwanese populations are relatively variable and differentiationbetween north, east and south Taiwan is evident. • Conclusions The distribution of Titanotrichum seems tobe consistent with a former land connection between China, Taiwanand the Ryukyu Islands at a glacial maximum during the Quaternary,followed by progressive fragmentation of the populations. North-centralTaiwan is the centre of genetic diversity, possibly due to theproximity of the former land bridge between the regions, togetherwith the variety of suitable habitats in north Taiwan. The significanceof these findings for conservation is discussed.     

Possible Secondary Population-Level Effects of Selective Harvest of Adult Male Muskoxen

Selective harvest regimes are often focused on males resulting in skewed sex-ratios, and for many ungulate species this strategy is sustainable. However, muskoxen (Ovibos moschatus) are very social and mature bulls (≥4 years old), particularly prime-age bulls (6–10 years old), play important roles in predator defense and recruitment. A year-round social structure incorporating large males into mixed-sex groups could make this species more susceptible to the effects of selective harvest if population composition and sex-ratios influence overall survival and reproductive success. Using detailed data collected on the muskox population occupying the Seward Peninsula, Alaska during 2002–2012, we formulated the hypothesis that the selective harvest of mature bulls may be related to documented changes in population composition and growth rates in this species. In addition, we reviewed existing published information from two other populations in Alaska, the Cape Thompson and Northeastern populations, to compare population growth rates among the three areas under differential harvest rates relative to our hypothesis. We found that on the Seward Peninsula, mature bull:adult cow ratios declined 4–12%/year and short-yearling:adult cow ratios (i.e., recruitment) declined 8–9%/year in the most heavily harvested areas. Growth rates in all 3 populations decreased disproportionately after increases in the number of bulls harvested, and calf:cow ratios declined in the Northeastern population as harvest increased. While lack of appropriate data prevented us from excluding other potential causes such as density dependent effects and changes in predator densities, our results did align with our hypothesis, suggesting that in the interest of conservation, harvest of mature males should be restricted until causal factors can be more definitively identified. If confirmed by additional research, our findings would have important implications for harvest management and conservation of muskoxen and other ungulate species with similar life-histories.     

Matrix population models indicate that bark harvest of two medicinal plants in Uganda's Bwindi Impenetrable National Park is sustainable

Balancing forest conservation with resource extraction by local people is challenging. In the mountain forests of Bwindi Impenetrable National Park in Uganda, this was addressed by permitting regulated access to certain forest products in specific areas by authorized local people. However, it remained unclear whether harvest levels were biologically sustainable. Here, we used matrix population models and long‐term data to examine the impacts of bark harvesting on population dynamics of two important medicinal plants, Rytigynia kigeziensis and Ocotea usambarensis, in Bwindi. Only 4% of R. kigeziensis and 3% of O. usambarensis stems (>1.3 m height) showed signs of bark harvest, mostly mild harvesting. We found that the harvested populations of both species appeared stable or will moderately grow in the long run. Modelled population growth rates were mostly determined by survival probabilities. Similarity between the stable stage distributions predicted by the model and observed population structures suggests that our estimated vital rates (growth, recruitment and survival rates) are a reasonable representation of actual values in these populations. Thus, recent harvest levels of R. kigeziensis and O. usambarensis appear sustainable. Nonetheless, monitoring of harvested and unharvested populations by tagging, marking and remeasuring individuals should continue for both species.     

The Sustainability of Wolverine Trapping Mortality in Southern Canada

Range declines, habitat connectivity, and trapping have created conservation concern for wolverines throughout their range in North America. Previous researchers used population models and observed estimates of survival and reproduction to infer that current trapping rates limit population growth, except perhaps in the far north where trapping rates are lower. Assessing the sustainability of trapping requires demographic and abundance data that are expensive to acquire and are therefore usually only achievable for small populations, which makes generalization risky. We surveyed wolverines over a large area of southern British Columbia and Alberta, Canada, used spatial capture-recapture models to estimate density, and calculated trapping kill rates using provincial fur harvest data. Wolverine density averaged 2 wolverines/1,000 km² and was positively related to spring snow cover and negatively related to road density. Observed annual trapping mortality was >8.4%/year. This level of mortality is unlikely to be sustainable except in rare cases where movement rates are high among sub-populations and sizable un-trapped refuges exist. Our results suggest wolverine trapping is not sustainable because our study area was fragmented by human and natural barriers and few large refuges existed. We recommend future wolverine trapping mortality be reduced by ≥50% throughout southern British Columbia and Alberta to promote population recovery. © 2019 The Authors. The Journal of Wildlife Management published by Wiley Periodicals, Inc. on behalf of The Wildlife Society.     

NATURAL GENETIC VARIATION OF LIFE SPAN,REPRODUCTION, AND JUVENILE GROWTH IN DAPHNIA

The evolutionary theory of senescence predicts that high extrinsic mortality in natural populations should select for accelerated reproductive investment and shortened life span. Here, we test the theory with natural populations of the Daphnia pulex-pulicaria species complex, a group of freshwater zooplankton that spans an environmental gradient of habitat permanence. We document substantial genetic variation in demographic life-history traits among parent and hybrid populations of this complex. Populations from temporary ponds have shorter life spans, earlier and faster increases of intrinsic mortality risk, and earlier and steeper declines in fecundity than populations from permanent lakes. We also examine the age-specific contribution to fitness, measured by reproductive value, and to expected lifetime reproduction; these traits decline faster in populations from temporary ponds. Despite having more rapid senescence, pond Daphnia exhibit faster juvenile growth and higher early fitness, measured as population growth rate (r). Among populations within this species complex we observed negative genetic correlations between r and indices of life-history timing, suggesting trade-offs between early- and late-life performance. Our results cannot be explained by a trade-off between survival and fecundity or by nonevolutionary theories of senescence. Instead, our data are consistent with the evolutionary theory of senescence because the genetic variation in life histories we observed is roughly congruent with the temporal scale of environmental change in the field.     

A Population Study to Aid the Selection of Improved Dried Pea (Pisum sativum) Crop Plants

The effect of genotype and plant density, over the range from100 to 277 plants m^–2, on plant to plant variation inprecision sown microplots has been assessed for three ‘leafless’(afafstst) pea (Pisum sativum) lines. This range of plantingdensities did not significantly affect the total above groundbiological yield per unit area of two of the genotypes (BS5and BS4) whereas the biological yield of the third (BS151) declinedat densities above 156 plants m^–2. The differences weredue to changes in seed yield. The effect of planting densityon the variation between plants for biological yield withinthe microplots differed between the genotypes. The distributionpattern of BS4 and BS5 changed from normal to skewed with increaseddensity, while the distribution for BS151 remained skewed atall planting densities. The differences between the three genotypes in the proportionof biological yield partitioned into seed yield (harvest index)on a unit area basis was due almost entirely to the differencesin structure of the plant populations. The maximum level ofpartitioning by individual plants was similar for all threelines. The difference between this maximum for an individualand the crop harvest index therefore represents the area forimprovement of crop harvest index through breeding. It is suggestedthat improvements in dried pea yields will come, therefore,by selecting plants which form more uniform populations withregard to plant size and to the proportion of plant biomasspartitioned into seed (plant harvest index). Pisum sativum, leafless pea, population, genetic variation, distribution patterns, harvest index     

Conservation of genetic diversity in old‐growth forest communities of the southeastern United States

Question: How do studies of the distribution of genetic diversity of species with different life forms contribute to the development of conservation strategies? Location: Old‐growth forests of the southeastern United States. Methods: Reviews of the plant allozyme literature are used to identify differences in genetic diversity and structure among species with different life forms, distributions and breeding systems. The general results are illustrated by case studies of four plant species characteristic of two widespread old‐growth forest communities of the southeastern United States: the Pinus palustris – Aristida stricta (Longleaf pine – wiregrass) savanna of the Coastal Plain and the Quercus – Carya – Pinus (Oak‐hickory‐pine) forest of the Piedmont. Genetic variation patterns of single‐gene and quantitative traits are also reviewed. Results: Dominant forest trees, represented by Pinus palustris(longleaf pine) and Quercus rubra (Northern red oak), maintain most of their genetic diversity within their populations whereas a higher proportion of the genetic diversity of herbaceous understorey species such as Sarracenia leucophylla and Trillium reliquum is distributed among their populations. The herbaceous species also tend to have more population‐to‐population variation in genetic diversity. Higher genetic differentiation among populations is seen for quantitative traits than for allozyme traits, indicating that interpopulation variation in quantitative traits is influenced by natural selection. Conclusion: Developing effective conservation strategies for one or a few species may not prove adequate for species with other combinations of traits. Given suitable empirical studies, it should be possible to design efficient conservation programs that maintain natural levels of genetic diversity within species of conservation interest.     

Harvest of Mississippi River sturgeon drives abundance and reproductive success: a harbinger of collapse?

Within harvested populations, relationships between harvest intensity and reproductive responses are typically unclear, rendering regulatory decisions difficult. Harvest of the commercially important shovelnose sturgeon (Scaphirhynchus platorynchus) is increasing in the upper Mississippi River; standardized seasonal sampling revealed that adult abundance is declining. Relative density of annual cohorts varied negatively with historical harvest intensity (r² = 0.84), suggesting that removal of mature adults is reducing the contribution of cohorts to population density. The results of simulation modeling suggest that this currently unregulated fishery is experiencing both growth and recruitment overfishing. Further, the current proposed multi‐state minimum length regulation was insufficient to maintain a sustainable stock. Only a more conservative minimum length limit (685 mm) produced yields that were sustainable at the current level of mortality and provided room for the fishery to grow. The annual mortality rate of the sympatric, federally endangered pallid sturgeon (S. albus) was similar to that of the shovelnose sturgeon population, raising concerns that harvest‐induced mortality is affecting this congener's vital rates.     

Effects of past and projected river discharge variability on freshwater production in an anadromous fish

相似文献   

Genetic relationships and variation in reproductive strategies in four closely related bromeliads adapted to neotropical 'inselbergs': Alcantarea glaziouana, A. regina, A. geniculata and A. imperialis (Bromeliaceae)

Background and Aims: Bromeliads (Bromeliaceae) adapted to rock outcrops or ‘inselbergs’in neotropical rain forests have been identified as suitableplant models for studying population divergence and speciationduring continental plant radiations. Little is known about geneticrelationships and variation in reproductive strategies withinand among inselberg-adapted species, yet knowledge of theseparameters is important for understanding divergence processesand for conservation planning. Methods: Nuclear microsatellites were used to assess the role of clonalreproduction, estimate genetic diversity and explore geneticrelationships and variation in reproductive strategies for atotal of 15 populations of four closely related Alcantarea inselbergspecies in south-eastern Brazil: A. glaziouana, A. regina, A.geniculata and A. imperialis. Key Results: Clonal propagation is frequent in coastal populations of A.glaziouana and A. regina, but absent in the high-altitude speciesA. geniculata and A. imperialis. Considerable variation in clonaldiversity, gene diversity (H_e), allelic richness, and Wright'sinbreeding coefficient (F_IS) exists within and between speciesof Alcantarea. A Bayesian analysis of coastal inselberg speciesindicated pronounced genetic structure. A neighbor-joining analysisgrouped populations of each species together with moderate bootstrapsupport, except for the high altitude species A. imperialis. Conclusions: The coastal inselberg species A. glaziouana and A. regina tendto propagate asexually via vegetative clonal growth, and bothreproductive strategies and breeding systems vary greatly betweenpopulations and species of Alcantarea. The microsatellite dataindicate a history of hybridization and reticulation involvingthe high-altitude species A. geniculata and A. imperialis inareas of co-occurrence. The results highlight the need to understandsimilarities and differences in reproductive strategies bothwithin and between related species for conservation planningand as a basis for understanding evolutionary processes in tropicalradiations.     

Sources of Variation in Physiological Phenotypes and Their Evolutionary Significance

We offer the thesis that environmental physiologists and evolutionarybiologists can find fertile common ground in the study of howindividual variation in physiological phenotypes originatesand develops. The sources of such individual variation are oftencomplex; the consequences affect how natural selection willact on a suite of traits, of which some may seem, at first glance,far removed from the usual domain of environmental physiology.We illustrate our thesis in two ways. First, we offer two examplesdrawn from studies of thermal tolerance in the poeciliid fishHeterandria formosa. We show how fitness variation can be acomplex function of the gestational temperature and thermaltolerance and how these effects can produce environmentallyinduced variation among populations in thermal tolerance thatmimics a pattern of adaptive variation. Second, we review twocase studies that illuminate how environmental effects on amultivariate phenotype can channel the action of natural selection.The phenotypic plasticity of male life history in Poecilia latipinnain response to temperature embraces a spectrum of traits; theeffects of each one upon fitness will influence the abilityof selection to mold the response of any one of them to temperature.The phenotypic covariances in thermal tolerance and life-historytraits in Heterandria formosa differ slightly between populationsfrom different parts of the species range, apparently becauseof differences between them in thermal sensitivity; this differenceinsures that the multivariate nature of selection will be correspondinglydifferent in those different populations.     

Variation in life history responses of Daphnia to toxic Microcystis aeruginosa

Three clones of Daphnia pulex and two clones of Daphnia longispinawere exposed to toxic Microcystis aeruginosa for 21 days ina lifetable experiment. The growth and reproduction of individualdaphnids were followed daily to study the long-term effectsof toxic Microcystis. Exposure to Microcystis increased mortality,decreased growth, delayed maturation and decreased offspringproduction, indicating nutritional deficiency and toxic effects.We found variation in life history responses between speciesand among clones. Our results suggest that toxic cyanobacteriamay act as a modifying agent in zooplankton communities at boththe species and clonal level.     

A holistic approach to taxonomic evaluation of two closely related endangered freshwater mussel species, the oyster mussel Epioblasma capsaeformis and tan riffleshell Epioblasma florentina walkeri (Bivalvia: Unionidae)

Species in the genus Epioblasma have specialized life historyrequirements and represent the most endangered genus of freshwatermussels (Unionidae) in the world. A genetic characterizationof extant populations of the oyster mussel E. capsaeformis andtan riffleshell E. florentina walkeri sensu late was conductedto assess taxonomic validity and to resolve conservation issuesfor recovery planning. These mussel species exhibit pronouncedphenotypic variation, but were difficult to characterize phylogeneticallyusing DNA sequences. Monophyletic lineages, congruent with phenotypicvariation among species, were obtained only after extensiveanalysis of combined mitochondrial (1396 bp of 16S, cytochrome-b,and ND1) and nuclear (515 bp of ITS-1) DNA sequences. Incontrast, analysis of variation at 10 hypervariable DNA microsatelliteloci showed moderately to highly diverged populations basedon F_ST and R_ST values, which ranged from 0.12 to 0.39 and 0.15to 0.71, respectively. Quantitative variation between specieswas observed in fish-host specificity, with transformation successof glochidia of E. capsaeformis significantly greater (P<0.05)on greenside darter Etheostoma blennioides, and that of E. f.walkeri significantly greater (P<0.05) on fantail darterEtheostoma flabellare. Lengths of glochidia differed significantly(P<0.001) among species and populations, with mean sizesranging from 241 to 272 µm. The texture and colourof the mantle-pad of E. capsaeformis sensu stricto is smoothand bluish-white, whereas that of E. f. walkeri is pustuledand brown, with tan mottling. Based on extensive molecular,morphological and life history data, the population of E. capsaeformisfrom the Duck River, Tennessee, USA is proposed as a separatespecies, and the population of E. f. walkeri from Indian Creek,upper Clinch River, Virginia, USA is proposed as a distinctsubspecies. (Received 23 February 2005; accepted 16 January 2006)