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.     

Introduction beyond a species range: a relationship between population origin,adaptive potential and plant performance

The adaptive potential of a population defines its importance for species survival in changing environmental conditions such as global climate change. Very few empirical studies have examined adaptive potential across species'' ranges, namely, of edge vs core populations, and we are unaware of a study that has tested adaptive potential (namely, variation in adaptive traits) and measured performance of such populations in conditions not currently experienced by the species but expected in the future. Here we report the results of a Triticum dicoccoides population study that employed transplant experiments and analysis of quantitative trait variation. Two populations at the opposite edges of the species range (1) were locally adapted; (2) had lower adaptive potential (inferred from the extent of genetic quantitative trait variation) than the two core populations; and (3) were outperformed by the plants from the core population in the novel environment. The fact that plants from the species arid edge performed worse than plants from the more mesic core in extreme drought conditions beyond the present climatic envelope of the species implies that usage of peripheral populations for conservation purposes must be based on intensive sampling of among-population variation.     

Genetic analysis of song dialect populations in Puget Sound white-crowned sparrows

The relationship between cultural variation and biological variationamong natural populations has been the subject of both theoreticaland empirical study. Zonotrichia leucophrys pugetensis is oneof three subspecies of white-crowned sparrow known to form geographicalsong dialects. We investigated whether these dialects correspondto genetic differences among Z. l. pugetensis populations. Wecompared allele frequencies at four microsatellite loci in malesfrom 11 sites spanning six dialects over the subspecies' rangein Oregon and Washington. Cluster analysis and genotype assignmenttests indicated no tendency for sample sites within dialectareas to be genetically more similar than are sites from differentdialect areas. AMOVA tests revealed high within-site variationand low but significant cross-site and cross-dialect-area variation.Finally, genetic distance between sites was not correlated withdialect differences when the effect of geographic distance wascontrolled statistically. We compare our finding of low geneticdifferentiation among Z. l. pugetensis dialect populations toresults of previous studies on Z. l. nuttalli and Z. l. oriantha.Because genetic structuring appears weaker than cultural (songdialect) structure in this species, we discuss the behavioralmechanisms underlying dialect maintenance in the presence ofapparent gene flow.     

Population Variation in Continuously Varying Traits as an Ecological Genetics Problem

The niche variation hypothesis is an adaptive explanation forvariation within populations and for, the differences in variationbetween populations in morphological, physiological or behavioraltraits. It has received only partial support from empiricaltests and has been criticized on theoretical grounds. Recentquantitative genetic models have made an advance by exploringthe effects of mutation, migration, mating pattern and selectionon phenotypic variance. These models are reviewed and theirmost important features are integrated in a new model. In thismodel population variation is in a state of balance betweenthe opposing forces of mutation and immigration, which tendto elevate variation, and selection and possibly genetic drifttending to decrease it. Populations exhibiting different levelsof variation are interpereted as having different equilibriumpoints, and it is the task of empirical studies to determinethe relative magnitudes of the opposing factors. An exampleis given from studies of Darwin's finches. Geospiza fortis variesmore than G. scandens on Isla Daphne Major, Galápagos,in several morphological traits including beak and body size.This is explained, assuming equal mutation rates in the twospecies, as the result of more frequent genetic input to theG. fortis population, through occasional hybridization withimmigrant G. fuliginosa, and relaxed stabilizing selection.Stabilizing selection is less intense on G.fortis than on G.scandens because the G. fortis population has a broader niche;there is both a within-phenotype and betweenphenotype componentto the broad niche of G. fortis. The success of theory in explainingpopulation variation is discussed, and it is concluded thatempirical studies lag far behind theory.     

Allozyme Diversity in Non-social Spiders: Pattern, Process and Conservation Implications

In this article we summarize estimates of genetic variation based on allozymes for 30 non-social spider species. Overall, these species show moderate levels of genetic variability (mean H_o = 6.8%) compared to other invertebrate species surveyed for allozymes, although a number of spiders possess only minimal variation. Fossorial spiders, especially those which are coastal dune dwellers, typically display less variation than other non-social arachnids. In general, differences in heterozygosity estimates between groups of non-social spiders in this article are not confounded by the varying mix of proteins that have been assayed by individual investigators. There is a significant positive relationship between genetic variability and gene flow (Nm), indicating that non-social spider populations which exhibit reduced variability are likely to be genetically isolated. Population bottlenecks, directional selection and environmental homogeneity have all been cited to account for reduced variability in particular non-social spiders. In addition, an analysis using the genus Lutica suggests that low genetic variation may be accompanied by decreased population fitness. Since the potential for evolutionary change is dependent on the existence of genetic variability, our findings indicate that a number of non-social spiders may be at risk in terms of long-term population viability. This conclusion should be verified/extended via a combination of more genetic surveys; genetic and ecological monitoring of populations and their fitnesses in the wild; and experimental studies of the mechanisms underlying fitness differences.     

Genetic variation across species' geographical ranges: the central-marginal hypothesis and beyond

There is growing interest in quantifying genetic population structure across the geographical ranges of species to understand why species might exhibit stable range limits and to assess the conservation value of peripheral populations. However, many assertions regarding peripheral populations rest on the long-standing but poorly tested supposition that peripheral populations exhibit low genetic diversity and greater genetic differentiation as a consequence of smaller effective population size and greater geographical isolation relative to geographically central populations. We reviewed 134 studies representing 115 species that tested for declines in within-population genetic diversity and/or increases in among-population differentiation towards range margins using nuclear molecular genetic markers. On average, 64.2% of studies detected the expected decline in diversity, 70.2% of those that tested for it showed increased differentiation and there was a positive association between these trends. In most cases, however, the difference in genetic diversity between central and peripheral population was not large. Although these results were consistent across plants and animals, strong taxonomic and biogeographical biases in the available studies call for a cautious generalization of these results. Despite the large number of studies testing these simple predictions, very few attempted to test possible mechanisms causing reduced peripheral diversity or increased differentiation. Almost no study incorporated a phylogeographical framework to evaluate historical influences on contemporary genetic patterns. Finally, there has been little effort to test whether these geographical trends in putatively neutral variation at marker loci are reflected by quantitative genetic trait variation, which is likely to influence the adaptive potential of populations across the geographical range.     

Genetic by environmental variation but no local adaptation in oysters (Crassostrea virginica)

Functional trait variation within and across populations can strongly influence population, community, and ecosystem processes, but the relative contributions of genetic vs. environmental factors to this variation are often not clear, potentially complicating conservation and restoration efforts. For example, local adaptation, a particular type of genetic by environmental (G*E) interaction in which the fitness of a population in its own habitat is greater than in other habitats, is often invoked in management practices, even in the absence of supporting evidence. Despite increasing attention to the potential for G*E interactions, few studies have tested multiple populations and environments simultaneously, limiting our understanding of the spatial consistency in patterns of adaptive genetic variation. In addition, few studies explicitly differentiate adaptation in response to predation from other biological and environmental factors. We conducted a reciprocal transplant experiment of first‐generation eastern oyster (Crassostrea virginica) juveniles from six populations across three field sites spanning 1000 km in the southeastern Atlantic Bight in both the presence and absence of predation to test for G*E variation in this economically valuable and ecologically important species. We documented significant G*E variation in survival and growth, yet there was no evidence for local adaptation. Condition varied across oyster cohorts: Offspring of northern populations had better condition than offspring from the center of our region. Oyster populations in the southeastern Atlantic Bight differ in juvenile survival, growth, and condition, yet offspring from local broodstock do not have higher survival or growth than those from farther away. In the absence of population‐specific performance information, oyster restoration and aquaculture may benefit from incorporating multiple populations into their practices.     

Evidence for an outcrossing reproductive strategy in the hermaphroditic heterobranch gastropod Valvata utahensis (valvatidae), with notes on the genetic differentiation of V. utahensis and V. humeralis

The hermaphroditic aquatic heterobranch Valvata utahensis isa federally endangered snail endemic to the Snake River corridorin southern Idaho, USA. Although an appreciable understandingof molluscan taxonomic diversity has been established withinthis ecosystem, little is currently known about the ecologyand life history of many individual species (V. utahensis included).In this study, we used a combined analysis of mitochondrialand nuclear genetic variation within V. utahensis to infer thepredominant mode of reproduction (selfing vs outcrossing) withinnatural populations of this species. Results of this analysisindicated that outcrossing is likely a common reproductive strategy.We discuss our results in the context of conservation and managementefforts for this endangered species. Furthermore, in the courseof performing our investigations, we frequently collected specimensthat were tentatively identified as V. humeralis. Given thatlittle genetic work has previously been performed within thegenus Valvata, we compared genetic data from V. utahensis withdata from V. humeralis to determine whether molecular data supportedmorphological evidence that these two taxa are distinct evolutionaryentities. Results of our analyses clearly revealed strong patternsof genetic differentiation between these two taxa and confirmedthe presence of two sympatric Valvata species within the SnakeRiver system. (Received 25 January 2006; accepted 20 April 2006)     

Epigenetic variation associated with responses to different habitats in the context of genetic divergence in Phragmites australis

The mechanisms underlying heritable phenotypic divergence associated with adaptation in response to environmental stresses may involve both genetic and epigenetic variations. Several prior studies have revealed even higher levels of epigenetic variation than genetic variation. However, few population‐level studies have explored the effects of epigenetic variation on species with high levels of genetic diversity distributed across different habitats. Using AFLP and methylation‐sensitive AFLP markers, we tested the hypothesis that epigenetic variation may contribute to differences in plants occupying different habitats when genetic variation alone cannot fully explain adaptation. As a cosmopolitan invasive species, Phragmites australis (common reed) together with high genetic diversity and remarkable adaptability has been suggested as a model for responses to global change and indicators of environmental fluctuations. We found high levels of genetic and epigenetic diversity and significant genetic/epigenetic structure within each of 12 studied populations sampled from four natural habitats of P. australis. Possible adaptive epigenetic variation was suggested by significant correlations between DNA methylation‐based epigenetic differentiation and adaptive genetic divergence in populations across the habitats. Meanwhile, various AMOVAs indicated that some epigenetic differences may respond to various local habitats. A partial Mantel test was used to tease out the correlations between genetic/epigenetic variation and habitat after controlling for the correlation between genetic and epigenetic variations. We found that epigenetic diversity was affected mostly by soil nutrient availability, suggesting that at least some epigenetic differentiation occurred independently of genetic variation. We also found stronger correlations between epigenetic variation and phenotypic traits than between genetic variation and such traits. Overall, our findings indicate that genetically based differentiation correlates with heterogeneous habitats, while epigenetic variation plays an important role in ecological differentiation in natural populations of P. australis. In addition, our results suggest that when assessing global change responses of plant species, intraspecific variation needs to be considered.     

Evolutionary Physiology of Closely Related Taxa: Analyses of Enzyme Expression

Comparative biochemistry and physiology offer the advantageof specifically defining the functional parameters or traitsthat affect an organism's performance (e.g., amino acids thataffect K_m, enzymes that affect metabolism). By combining thesefunctional determinations with both intraspecific and phylogeneticallyappropriate analyses, comparative biologists can indicate thata trait is biologically important by demonstrating that it isevolving by natural selection. An evolutionary approach maybenefit from the analysis of variation within and among closelyrelated species. The advantages of analyzing closely relatedspecies are that they allow one to identify more definitivelythe derived conditions and suggest why differences arose. Importantly,there is substantial variation in physiological and biochemicaltraits within and among closely related species. For example,among species within a single genus of teleost, Fundulus, thevariation in enzyme expression is similar to the variation seenamong most superorders of teleost. However, most of the variationwithin the genus Fundulus is most readily explained by evolutionarydistance, and thus there is no compelling reason for furtheradaptive hypotheses. Extending this observation, the greaterthe phylogenetic distance between taxa in a comparative study,the more likely there will be a statistically significant differencethat may only represent evolutionary time. The molecular mechanismsaffecting adaptive variation in enzyme expression appear tobe readily altered and may vary within a species or betweenacclimation conditions. Thus, studies among closely relatedorganisms are more likely to identify the specific molecularor biochemical changes responsible for adaptive variation.     

Is MHC diversity a better marker for conservation than neutral genetic diversity? A case study of two contrasting dolphin populations

Genetic diversity is essential for populations to adapt to changing environments. Measures of genetic diversity are often based on selectively neutral markers, such as microsatellites. Genetic diversity to guide conservation management, however, is better reflected by adaptive markers, including genes of the major histocompatibility complex (MHC). Our aim was to assess MHC and neutral genetic diversity in two contrasting bottlenose dolphin (Tursiops aduncus) populations in Western Australia—one apparently viable population with high reproductive output (Shark Bay) and one with lower reproductive output that was forecast to decline (Bunbury). We assessed genetic variation in the two populations by sequencing the MHC class II DQB, which encompasses the functionally important peptide binding regions (PBR). Neutral genetic diversity was assessed by genotyping twenty‐three microsatellite loci. We confirmed that MHC is an adaptive marker in both populations. Overall, the Shark Bay population exhibited greater MHC diversity than the Bunbury population—for example, it displayed greater MHC nucleotide diversity. In contrast, the difference in microsatellite diversity between the two populations was comparatively low. Our findings are consistent with the hypothesis that viable populations typically display greater genetic diversity than less viable populations. The results also suggest that MHC variation is more closely associated with population viability than neutral genetic variation. Although the inferences from our findings are limited, because we only compared two populations, our results add to a growing number of studies that highlight the usefulness of MHC as a potentially suitable genetic marker for animal conservation. The Shark Bay population, which carries greater adaptive genetic diversity than the Bunbury population, is thus likely more robust to natural or human‐induced changes to the coastal ecosystem it inhabits.     

Integration of field and captive studies for understanding the behavioral ecology of the squirrel monkey (Saimiri sp.)

Captive and field studies both provide valuable and complementary information that lead to a better understanding of a species' behavioral ecology. Here, we review studies from wild, captive, and semi-free ranging populations of squirrel monkeys (Saimiri sp.), in order to (a) provide a more current (1985-2010) review of Saimiri behavioral ecology and (b) illustrate that integrating data collected in a variety of settings is an effective approach to addressing ecological questions in primates. Captive environments, such as zoological facilities and research colonies, can be advantageous to researchers by allowing longitudinal studies of behavior and reproduction, as well as providing opportunities for gathering data on life history, because physiological and life history data are known for individual animals. Studies of field populations can provide contextual information regarding the adaptive nature of behaviors that are studied in captivity. Squirrel monkeys are small, neotropical primates that have extensively been used in captive research. As the last in-depth review of Saimiri biology was published in 1985 [Rosenblum & Coe, The squirrel monkey. New York: Academic Press], we review studies since conducted on Saimiri ecology, life history, social behavior, reproduction, and conservation. Our review indicates that there is much variation in socioecology and life history traits between Saimiri species and, surprisingly, also between populations of the same species studied at different locales. In addition, much is known about squirrel monkey reproductive physiology, basic ecology, and vocal communication, but data are still lacking in the fields of life history and some adaptive components and social behavior. In particular, longitudinal studies in the field would be particularly relevant for a genus with a slow life history such as Saimiri. Finally, few data (captive or wild) are available on S. ustus and S. vanzolinii, though at least one of these species is threatened.     

Primary sex ratio adjustment to experimentally reduced male UV attractiveness in blue tits

The study of primary sex ratio adjustment in birds is notoriousfor inconsistency of results among studies. To develop our understandingof avian sex ratio variation, experiments that test a prioripredictions and the replication of previous studies are essential.We tested if female blue tits Parus caeruleus adjust the sexratio of their offspring to the sexual attractiveness of theirmates, as was suggested by a previous benchmark study on thesame species. In 2 years, we reduced the ultraviolet (UV) reflectanceof the crown feathers of males in the period before egg layingto decrease their attractiveness. In contrast to the simpleprediction from sex allocation theory, we found that the overallproportion of male offspring did not differ between broods ofUV-reduced and control-treated males. However, in 1 year, theUV treatment influenced offspring sex ratio depending on thenatural crown UV reflectance of males before the treatment.The last result confirms the pattern found in the previous bluetit study, which suggests that these complex patterns of primarysex ratio variation are repeatable in this bird species, warrantingfurther research into the adaptive value of blue tit sex ratioadjustment to male UV coloration.     

Variation of Nuclear DNA Content in the Biflorus Species of Lonchocarpus (Leguminosae)

This represents the first study of nuclear DNA content in alarge sample (135 spp.) from a tropical arboreal genus, in whicha large proportion of the species were examined (42 spp., 31.1%).Somatic chromosome numbers and 4C-DNA values for 51 taxa ofLonchocarpus are reported. All taxa were diploid with 2 n =22,but their DNA content ranged from 1.92 to 2.86 pg 4C nucleus,corresponding to a 48.95% variation in genome size. In the 74collections studied, no correlation was observed between DNAcontent and habitat altitude. Variation in nuclear DNA contentwas analysed at the level of genus, subgenus, section and subsection.Variation in genome size was also studied within some species,either among widely separated populations or among differentintraspecific taxa. Very little variation in genome size wasdetected between populations, subspecies, and varieties of thesame species. The taxonomic implications of variation in nuclearDNA content are discussed.Copyright 2000 Annals of Botany Company Lonchocarpus (Leguminosae), DNA content, chromosome number.     

Genetic diversity, climatic selection and speciation of Sphincterochila landsnails in Israel

Allozymic variation in proteins encoded by 29 loci was analysed electrophoretically in 364 adult specimens representing 12 populations and five species of the landsnail Sphincterochila in Israel along a north-south general transect of increasing aridity. In addition, geographic variation in three morphological body variables of these snails was also studied. The results indicate that: (i) most loci (86%) are strongly polymorphic; (ii) most loci (65%) display fixation of alternative alleles either within or between species; (iii) most of the variant alleles (51%) are not widespread, and genie differentiation is very high (66%) between populations and species, indicating sharp local and regional geographic differentiation; (iv) clinal patterns are rare or nonexistent; (v) populations of Sphincterochila display average estimates of mean alleles per locus,A=1.53; polymorphism, P (5% criterion) = 0.31; heterozygosity, H=0.07; and genie diversity, He= 0.11; (vi) wide geographic variation within and between species is displayed in A= 1.18-2.07; P=0.11–0.61; H=0.02-0.15, and He = 0.042-0.22. Wright's fixation index, F, ranges from 0.03 to 0.65. (vii) Genie diversity, He, increases southwards with aridity from 0.051 to 0.145. (viii) A differential amount of variation in different functional classes of enzymes follows the Gillespie-Kojima hypothesis, (ix) Coefficients of genetic distance, D, between populations are high, D= 0.34, range 0.09-0.58, and between species, D= 0.27, range 0.12-0.40. D's within species may be higher than between species. Likewise, D's increase clinally southwards, (x) Deviations from Hardy-Weinberg equilibria were found in several loci in some populations and species, (xi) A statistically significant (P< 0.001) amount of morphological variation of body variables exists within and between species. Size between three species increases eastwards and southwards with aridity, (xii) P, H, He, and allozymic variation in several gene loci are significantly correlated with, and predictable by, climatic variables, primarily those related to the moisture index, (xiii) Allozymic and morphological variations are partly correlated, (xiv) Significant microgeographical climatic differentiation was found in three critical tests. The pattern of genetic variation within and between species suggests that: (a) climatic selection plays a conspicuous role in allozymic morphological differentiation into ecologically adaptive patterns; (b) the environmental variation model seems to be a good predictor of genetic variation in Sphincterochila; (c) adaptive radiation of the five species of Sphincterochila in Israel occurred during Pleistocene times in accord with climatic differentiation and apparently involved few changes of structural genes.     

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.     

QUANTITATIVE GENETICS OF SIZE,SHAPE, LIFE-HISTORY,AND FRUIT CHARACTERISTICS OF THE SEED-HETEROMORPHIC COMPOSITE HETEROSPERMA PINNATUM. I. VARIATION WITHIN AND AMONG POPULATIONS

We document phenotypic and genetic variation within and among populations of the seed heteromorphic species Heterosperma pinnatum Cav. (Compositae) in the production of seed morphs and in a variety of life-history and morphological characteristics that might be correlated with seed and head traits. Each trait is found to have significant genetic variance in most or, usually, all populations. Significant among-population genetic variation exists for all traits except number of achenes per head and seedling shape, although some traits have much less genetic variation among than within populations. Number and percentage of intermediate achenes per head, total number of achenes per head, and lengths of central and peripheral achenes had little among-population genetic variation compared to within-population variation. Most traits had slightly less genetic variation among than within populations; however, some traits (percentage of central achenes, length of awns, date that the first flowering head opened, date that the first fruiting head opened, and death date) had more among-population genetic variation. The proportions of achene morphs produced had high broad-sense heritabilities and high among-population genetic variance, except in the case of intermediate achenes. All phenological variables had high among-population genetic variation. Within-population heritabilities were high for dates of first flowering head and fruiting head but low for death date and reproductive interval. Family and population means measured in the greenhouse for traits having high broad-sense heritability or among-population genetic variance were closely correlated with field means for the corresponding families or populations. The amounts of phenotypic variation were similar for traits that were measured in both the field and the greenhouse. These lines of evidence suggest that greenhouse results provide reasonable estimates of genetic variation in the field for this species. Numerous studies have reported variation in the proportion of seed morphs for different heteromorphic-seeded species and have discussed adaptive scenarios for the evolution of seed proportions; however, our investigation is one of only a few that have documented the amount of phenotypic and genetic variation within and among populations.     

棉铃虫外生殖嚣的超微结构及其变异

本文对棉铃虫片Helicoverpa armigera(Hubner)雌雄外生殖器的一般构造和超微结构进行了较细致的研究。并与其近缘种作了比较研究。结果表明：在一般形态方面,棉铃虫种群内个体间变异较大,种群间分化较小：在雄性阳茎端囊的弯折数、大刺数及抱器瓣的长宽比等特征上与近缘种间有一定的重叠。在超微结构方面,种群内个体间、种群间均变异不大,但与近缘种间在雄性阳茎端囊刺构造上却有明显的、间断的差异,这一差异为近缘种的鉴别 提供了新的、可靠的特征。     

Temporally Adaptive Sampling: A Case Study in Rare Species Survey Design with Marbled Salamanders (Ambystoma opacum)

Improving detection rates for elusive species with clumped distributions is often accomplished through adaptive sampling designs. This approach can be extended to include species with temporally variable detection probabilities. By concentrating survey effort in years when the focal species are most abundant or visible, overall detection rates can be improved. This requires either long-term monitoring at a few locations where the species are known to occur or models capable of predicting population trends using climatic and demographic data. For marbled salamanders (Ambystoma opacum) in Massachusetts, we demonstrate that annual variation in detection probability of larvae is regionally correlated. In our data, the difference in survey success between years was far more important than the difference among the three survey methods we employed: diurnal surveys, nocturnal surveys, and dipnet surveys. Based on these data, we simulate future surveys to locate unknown populations under a temporally adaptive sampling framework. In the simulations, when pond dynamics are correlated over the focal region, the temporally adaptive design improved mean survey success by as much as 26% over a non-adaptive sampling design. Employing a temporally adaptive strategy costs very little, is simple, and has the potential to substantially improve the efficient use of scarce conservation funds.     

Contemporary morphological diversification of passerine birds introduced to the Hawaiian archipelago

Species that have been introduced to islands experience novel and strong selection pressures after establishment. There is evidence that exotic species diverge from their native source populations; further, a few studies have demonstrated adaptive divergence across multiple exotic populations of a single species. Exotic birds provide a good study system, as they have been introduced to many locations worldwide, and we often know details concerning the propagule origin, time of introduction, and dynamics of establishment and dispersal within the introduced range. These data make them especially conducive to the examination of contemporary evolution. Island faunas have received intense scrutiny, therefore we have expectations concerning the patterns of diversification for exotic species. We examine six passerine bird species that were introduced to the Hawaiian archipelago less than 150 years ago. We find that five of these show morphological divergence among islands from the time since they were established. We demonstrate that some of this divergence cannot be accounted for by genetic drift, and therefore we must consider adaptive evolution to explain it. We also evaluate evolutionary divergence rates and find that these species are diverging at similar rates to those found in published studies of contemporary evolution in native species.