Your search keyword '"METAPOPULATION (Ecology)"' showing total 30 results

1. Perturbation drives changing metapopulation dynamics in a top marine predator.

Author

Carroll, Emma L., Hall, Ailsa, Olsen, Morten Tange, Onoufriou, Aubrie B., Gaggiotti, Oscar E., and Russell, Debbie JF

Subjects

*TOP predators, *METAPOPULATION (Ecology), *GENE flow, *BIOLOGICAL extinction, *MICROSATELLITE repeats

Abstract

Metapopulation theory assumes a balance between local decays/extinctions and local growth/new colonisations. Here we investigate whether recent population declines across part of the UK harbour seal range represent normal metapopulation dynamics or are indicative of perturbations potentially threatening the metapopulation viability, using 20 years of population trends, location tracking data (n = 380), and UK-wide, multi-generational population genetic data (n = 269). First, we use microsatellite data to show that two genetic groups previously identified are distinct metapopulations: northern and southern. Then, we characterize the northern metapopulation dynamics in two different periods, before and after the start of regional declines (pre-/peri-perturbation). We identify source–sink dynamics across the northern metapopulation, with two putative source populations apparently supporting three likely sink populations, and a recent metapopulation-wide disruption of migration coincident with the perturbation. The northern metapopulation appears to be in decay, highlighting that changes in local populations can lead to radical alterations in the overall metapopulation's persistence and dynamics. [ABSTRACT FROM AUTHOR]

Published

2020

2. 7000 years of turnover: historical contingency and human niche construction shape the Caribbean’s Anthropocene biota.

Author

Kemp, Melissa E., Mychajliw, Alexis M., Wadman, Jenna, and Goldberg, Amy

Subjects

*BIOTIC communities, *BIOLOGICAL extinction, *HABITAT modification, *ECOSYSTEM management, *SPECIES diversity, *MODERN society, *METAPOPULATION (Ecology)

Abstract

The human-mediated movement of species across biogeographic boundaries—whether intentional or accidental—is dramatically reshaping the modern world. Yet humans have been reshaping ecosystems and translocating species for millennia, and acknowledging the deeper roots of these phenomena is important for contextualizing present-day biodiversity loss, ecosystem functioning and management needs. Here, we present the first database of terrestrial vertebrate species introductions spanning the entire anthropogenic history of a system: the Caribbean. We employ this approximately 7000-year dataset to assess the roles of historical contingency and priority effects in shaping present-day community structure and conservation outcomes, finding that serial human colonization events contributed to habitat modifications and species extinctions that shaped the trajectories of subsequent species introductions by other human groups. We contextualized spatial and temporal patterns of species introductions within cultural practices and population histories of Indigenous, colonial and modern human societies, and show that the taxonomic and biogeographic diversity of introduced species reflects diversifying reasons for species introductions through time. Recognition of the complex social and economic structures across the 7000-year human history of the Caribbean provides the necessary context for interpreting the formation of an Anthropocene biota. [ABSTRACT FROM AUTHOR]

Published

2020

3. Towards a predictive conservation biology: the devil is in the behaviour.

Author

Sæther, Bernt-Erik and Engen, Steinar

Subjects

*POPULATION viability analysis, *POPULATION dynamics, *CONSERVATION biology, *GENETIC drift, *METAPOPULATION (Ecology), *ECOSYSTEM dynamics, *ENDANGERED species

Abstract

One of the most important challenges in conservation biology is to predict the viability of populations of vulnerable and threatened species. This requires that the demographic stochasticity strongly affecting the ecological and evolutionary dynamics of especially small populations is correctly estimated and modelled. Here, we summarize theoretical evidence showing that the demographic variance in population dynamics is a key parameter determining the probability of extinction and also is directly linked to the magnitude of the genetic drift in the population. The demographic variance is dependent on the mating system, being larger in a polygynous than in monogamous populations. Understanding factors affecting intersexual differences in mating success is therefore essential in explaining variation in the demographic variance. We hypothesize that the strength of sexual selection, for example, quantified by the Bateman gradient, may be a useful predictor of the magnitude of the demographic stochasticity and hence the genetic drift in the population. We provide results from a field study of moose that support this claim. Thus, including central principles from behavioural ecology may increase the reliability of population viability analyses through an improvement of our understanding of factors affecting stochastic influences on population dynamics and evolutionary processes. This article is part of the theme issue 'Linking behaviour to dynamics of populations and communities: application of novel approaches in behavioural ecology to conservation'. [ABSTRACT FROM AUTHOR]

Published

2019

4. From individual movement behaviour to landscape-scale invasion dynamics and management: a case study of lionfish metapopulations.

Author

Tamburello, Natascia, Ma, Brian O., and Côté, Isabelle M.

Subjects

*METAPOPULATION (Ecology), *PTEROIS volitans, *POPULATION dynamics, *INTRODUCED species, *CASCADE connections, *BEHAVIOR

Abstract

Modelling the dynamics of small, interconnected populations, or metapopulations, can help pinpoint habitat patches that are critical for population persistence in patchy habitats. For conservation purposes, these patches are typically earmarked for protection, but for invasive species management, these patches could be targeted to hasten the populations' demise. Here, we show how metapopulation modelling, coupled with an understanding of size-dependent dispersal behaviour, can be used to help optimize the distribution of limited resources for culling specific populations of invasive Indo-Pacific lionfish (Pterois volitans) in the western Atlantic. Through simulation using fitted model parameters, we derive three insights that can inform management. First, culling lionfish from target patches reduces the probability of lionfish occupancy at surrounding patches. Second, this effect depends on patch size and connectivity, but is strongest at the local scale and decays with distance. Finally, size-dependent dispersal in lionfish means that size-selective culling can change both a population's size distribution and dispersal potential, with cascading effects on network connectivity, population dynamics and management outcomes. By explicitly considering seascape structure and movement behaviour when allocating effort to the management of invasive species, managers can optimize resource use to improve management outcomes. This article is part of the theme issue 'Linking behaviour to dynamics of populations and communities: application of novel approaches in behavioural ecology to conservation'. [ABSTRACT FROM AUTHOR]

Published

2019

5. Microparasite dispersal in metapopulations: a boon or bane to the host population?

Author

Tadiri, Christina P., Fussmann, Gregor F., and Scott, Marilyn E.

Subjects

*METAPOPULATION (Ecology), *HOST-parasite relationships, *PARASITE antigens, *GUPPIES, *WILDLIFE conservation

Abstract

Although connectivity can promote host species persistence in a metapopulation, dispersal may also enable disease transmission, an effect further complicated by the impact that parasite distribution may have on host-parasite population dynamics. We investigated the effects of connectivity and initial parasite distribution (clustered or dispersed) on microparasite-host dynamics in experimental metapopulations, using guppies and Gyrodactylus turnbulli. We created metapopulations of guppies divided into four subpopulations and introduced either a low level of parasites to all subpopulations (dispersed) or a high level of parasites to one subpopulation (clustered). Controlled migration among subpopulations occurred every 10 days. In additional trials, we introduced low or high levels of parasites to isolated populations. Parasites persisted longer in metapopulations than in isolated populations. Mortality was lowest in isolated populationswith low-level introductions. The interaction of connectivity and initial parasite distribution influenced parasite abundance. With low-level introductions, connectivity helped the parasite persist longer but had little effect on the hosts. With high levels, connectivity also benefited the hosts, lowering parasite burdens. These findings have implications for disease management and species conservation. [ABSTRACT FROM AUTHOR]

Published

2018

6. Eco-evolutionary dynamics, density-dependent dispersal and collective behaviour: implications for salmon metapopulation robustness.

Author

Yeakel, Justin D., Gibert, Jean P., Gross, Thilo, Westley, Peter A. H., and Moore, Jonathan W.

Subjects

*METAPOPULATION (Ecology), *COLLECTIVE behavior, *SALMON, *FISH behavior, *MIGRATORY fishes

Abstract

The spatial dispersal of individuals plays an important role in the dynamics of populations, and is central to metapopulation theory. Dispersal provides connections within metapopulations, promoting demographic and evolutionary rescue, but may also introduce maladapted individuals, potentially lowering the fitness of recipient populations through introgression of heritable traits. To explore this dual nature of dispersal, we modify a well-established eco-evolutionary model of two locally adapted populations and their associated mean trait values, to examine recruiting salmon populations that are connected by density-dependent dispersal, consistent with collective migratory behaviour that promotes navigation.When the strength of collective behaviour isweak such that straying is effectively constant,we showthat a low level of straying is associated with the highest gains in metapopulation robustness and that high straying serves to erode robustness. Moreover, we find that as the strength of collective behaviour increases, metapopulation robustness is enhanced, but this relationship depends on the rate at which individuals stray. Specifically, strong collective behaviour increases the presence of hidden lowdensity basins of attraction, which may serve to trap disturbed populations, and this is exacerbated by increased habitat heterogeneity. Taken as a whole, our findings suggest that density-dependent straying and collective migratory behaviour may help metapopulations, such as in salmon, thrive in dynamic landscapes. Given the pervasive eco-evolutionary impacts of dispersal on metapopulations, these findings have important ramifications for the conservation of salmon metapopulations facing both natural and anthropogenic contemporary disturbances. [ABSTRACT FROM AUTHOR]

Published

2018

7. From single steps to mass migration: the problem of scale in the movement ecology of the Serengeti wildebeest.

Author

Torney, Colin J., Hopcraft, J. Grant C., Morrison, Thomas A., Couzin, Iain D., and Levin, Simon A.

Subjects

*GNUS, *ANIMAL mechanics, *COLLECTIVE behavior, *ANIMAL migration, *METAPOPULATION (Ecology), *RADIO collars

Abstract

A central question in ecology is how to link processes that occur over different scales. The daily interactions of individual organisms ultimately determine community dynamics, population fluctuations and the functioning of entire ecosystems. Observations of these multiscale ecological processes are constrained by various technological, biological or logistical issues, and there are often vast discrepancies between the scale at which observation is possible and the scale of the question of interest. Animal movement is characterized by processes that act over multiple spatial and temporal scales. Second-by-second decisions accumulate to produce annual movement patterns. Individuals influence, and are influenced by, collective movement decisions, which then govern the spatial distribution of populations and the connectivity of meta-populations. While the field of movement ecology is experiencing unprecedented growth in the availability of movement data, there remain challenges in integrating observations with questions of ecological interest. In this article, we present the major challenges of addressing these issues within the context of the Serengeti wildebeest migration, a keystone ecological phenomena that crosses multiple scales of space, time and biological complexity. This article is part of the theme issue 'Collective movement ecology'. [ABSTRACT FROM AUTHOR]

Published

2018

8. Adaptation to fragmentation: evolutionary dynamics driven by human influences.

Author

Cheptou, Pierre-Olivier, Hargreaves, Anna L., Bonte, Dries, and Jacquemyn, Hans

Subjects

*ANTHROPOGENIC effects on nature, *METAPOPULATION (Ecology), *EVOLUTIONARY developmental biology, *BIOLOGICAL evolution, *GENETICS, *BIOLOGICAL adaptation

Abstract

Fragmentation--the process by which habitats are transformed into smaller patches isolated from each other--has been identified as a major threat for biodiversity. Fragmentation has well-established demographic and population genetic consequences, eroding genetic diversity and hindering gene flow among patches. However, fragmentation should also select on life history, both predictably through increased isolation, demographic stochasticity and edge effects, and more idiosyncratically via altered biotic interactions. While species have adapted to natural fragmentation, adaptation to anthropogenic fragmentation has received little attention. In this review, we address how and whether organisms might adapt to anthropogenic fragmentation. Drawing on selected case studies and evolutionary ecology models, we show that anthropogenic fragmentation can generate selection on traits at both the patch and landscape scale, and affect the adaptive potential of populations. We suggest that dispersal traits are likely to experience especially strong selection, as dispersal both enables migration among patches and increases the risk of landing inthe inhospitable matrix surrounding them. We highlight that suites of associated traits are likely to evolve together. Importantly, we show that adaptation will not necessarily rescue populations from the negative effects of fragmentation, and may even exacerbate them, endangering the entire meta population. This article is part of the themed issue 'Human influences on evolution, and the ecological and societal consequences'. [ABSTRACT FROM AUTHOR]

Published

2017

9. Explaining the geographical origins of seasonal influenza A (H3N2).

Author

Wen, Frank, Cobey, Sarah, and Bedford, Trevor

Subjects

*INFLUENZA A virus, H3N2 subtype, *BIOLOGICAL evolution, *ECOLOGY, *EPIDEMIOLOGY, *METAPOPULATION (Ecology), *DEATH rate

Abstract

Most antigenically novel and evolutionarily successful strains of seasonal influenza A (H3N2) originate in East, South and Southeast Asia. To understand this pattern, we simulated the ecological and evolutionary dynamics of influenza in a host metapopulation representing the temperate north, tropics and temperate south. Although seasonality and air traffic are frequently used to explain global migratory patterns of influenza, we find that other factors may have a comparable or greater impact. Notably, a region’s basic reproductive number (R0) strongly affects the antigenic evolution of its viral population and the probability that its strains will spread and fix globally: a 17–28% higher R0 in one region can explain the observed patterns. Seasonality, in contrast, increases the probability that a tropical (less seasonal) population will export evolutionarily successful strains but alone does not predict that these strains will be antigenically advanced. The relative sizes of different host populations, their birth and death rates, and the region in which H3N2 first appears affect influenza’s phylogeography in different but relatively minor ways. These results suggest general principles that dictate the spatial dynamics of antigenically evolving pathogens and offer predictions for how changes in human ecology might affect influenza evolution. [ABSTRACT FROM AUTHOR]

Published

2016

10. Neonicotinoid insecticides can serve as inadvertent insect contraceptives.

Author

Straub, Lars, Villamar-Bouza, Laura, Bruckner, Selina, Chantawannakul, Panuwan, Gauthier, Laurent, Khongphinitbunjong, Kitiphong, Retschnig, Gina, Troxler, Aline, Vidondo, Beatriz, Neumann, Peter, and Williams, Geoffrey R.

Subjects

*HEXACHLOROCYCLOHEXANES, *NEONICOTINOIDS, *HONEYBEES, *METAPOPULATION (Ecology), *TRAIT intercorrelations

Abstract

There is clear evidence for sublethal effects of neonicotinoid insecticides on non-target ecosystem service-providing insects. However, their possible impact on male insect reproduction is currently unknown, despite the key role of sex. Here, we show that two neonicotinoids (4.5 ppb thiamethoxam and 1.5 ppb clothianidin) significantly reduce the reproductive capacity of male honeybees (drones), Apis mellifera. Drones were obtained from colonies exposed to the neonicotinoid insecticides or controls, and subsequently maintained in laboratory cages until they reached sexual maturity. While no significant effects were observed for male teneral (newly emerged adult) body mass and sperm quantity, the data clearly showed reduced drone lifespan, as well as reduced sperm viability (percentage living versus dead) and living sperm quantity by 39%. Our results demonstrate for the first time that neonicotinoid insecticides can negatively affect male insect reproductive capacity, and provide a possible mechanistic explanation formanaged honeybee queen failure andwild insect pollinator decline. Thewidespread prophylactic use of neonicotinoids may have previously overlooked inadvertent contraceptive effects on non-target insects, thereby limiting conservation efforts. [ABSTRACT FROM AUTHOR]

Published

2016

11. Weather explains high annual variation in butterfly dispersal.

Author

Mikko Kuussaari, Rytteri, Susu, Heikkinen, Risto K., Heliöla, Janne, and von Bagh, Peter

Subjects

*BUTTERFLY migration, *BIOLOGICAL variation, *HABITATS, *METAPOPULATION (Ecology), *TRAIT intercorrelations

Abstract

Weather conditions fundamentally affect the activity of short-lived insects. Annual variation inweather is therefore likely to be an important determinant of their between-year variation in dispersal, but conclusive empirical studies are lacking. We studied whether the annual variation of dispersal can be explained by the flight season's weather conditions in a Clouded Apollo (Parnassius mnemosyne) metapopulation. This metapopulation was monitored using the mark-release-recapture method for 12 years. Dispersal was quantified for each monitoring year using three complementary measures: emigration rate (fraction of individualsmoving between habitat patches), average residence time in the natal patch, and average distance moved. There was much variation both in dispersal and average weather conditions among the years. Weather variables significantly affected the three measures of dispersal and together with adjusting variables explained 79-91% of the variation observed in dispersal. Different weather variables became selected in the models explaining variation in three dispersal measures apparently because of the notable intercorrelations. In general, dispersal rate increased with increasing temperature, solar radiation, proportion of especially warm days, and butterfly density, and decreased with increasing cloudiness, rainfall, and wind speed. These results help to understand and model annually varying dispersal dynamics of species affected by global warming. [ABSTRACT FROM AUTHOR]

Published

2016

12. Variability in primary productivity determines metapopulation dynamics.

Author

Fernández, Néstor, Román, Jacinto, and Delibes, Miguel

Subjects

*HABITATS, *METAPOPULATION (Ecology), *POPULATION dynamics, *COLONIZATION (Ecology), *ECOLOGICAL research, *BIOTIC communities

Abstract

Temporal variability in primary productivity can change habitat quality for consumer species by affecting the energy levels available as food resources. However, it remains unclear how habitat-quality fluctuations may determine the dynamics of spatially structured populations, where the effects of habitat size, quality and isolation have been customarily assessed assuming static habitats. We present the first empirical evaluation on the effects of stochastic fluctuations in primary productivity--a major outcome of ecosystem functions--on the meta population dynamics of a primary consumer. A unique 13-year dataset from an herbivore rodent was used to test the hypothesis that inter-annual variations in primary productivity determine spatiotemporal habitat occupancy patterns and colonization and extinction processes. Inter-annual variability in productivity and in the growing season phenology significantly influenced habitat colonization patterns and occupancy dynamics. These effects lead to changes in connectivity to other potentially occupied habitat patches, which then feed back into occupancy dynamics. According to the results, the dynamics of primary productivity accounted for more than 50% of the variation in occupancy probability, depending on patch size and landscape configuration. Evidence connecting primary productivity dynamics and spatiotemporal population processes has broad implications for metapopulation persistence in fluctuating and changing environments. [ABSTRACT FROM AUTHOR]

Published

2016

13. Linking extinction-colonization dynamics to genetic structure in a salamander metapopulation.

Author

Bradley J., Cosentino, Christopher A., Phillips, Robert L., Schooley, Winsor H., Lowe, and Marlis R., Douglas

Subjects

*BIOLOGICAL extinction, *COLONIZATION (Ecology), *SALAMANDERS, *METAPOPULATION (Ecology), *GENE frequency, *POPULATION genetics, *WETLANDS

Abstract

Theory predicts that founder effects have a primary role in determining metapopulation genetic structure. However, ecological factors that affect extinction–colonization dynamics may also create spatial variation in the strength of genetic drift and migration. We tested the hypothesis that ecological factors underlying extinction–colonization dynamics influenced the genetic structure of a tiger salamander (Ambystoma tigrinum) metapopulation. We used empirical data on metapopulation dynamics to make a priori predictions about the effects of population age and ecological factors on genetic diversity and divergence among 41 populations. Metapopulation dynamics of A. tigrinum depended on wetland area, connectivity and presence of predatory fish. We found that newly colonized populations were more genetically differentiated than established populations, suggesting that founder effects influenced genetic structure. However, ecological drivers of metapopulation dynamics were more important than age in predicting genetic structure. Consistent with demographic predictions from metapopulation theory, genetic diversity and divergence depended on wetland area and connectivity. Divergence was greatest in small, isolated wetlands where genetic diversity was low. Our results show that ecological factors underlying metapopulation dynamics can be key determinants of spatial genetic structure, and that habitat area and isolation may mediate the contributions of drift and migration to divergence and evolution in local populations. [ABSTRACT FROM AUTHOR]

Published

2012

14. On valuing patches: estimating contributions to metapopulation growth with reverse-time capture-recapture modelling.

Author

Jamie S., Sanderlin, Peter M., Waser, James E., Hines, and James D., Nichols

Subjects

*METAPOPULATION (Ecology), *KANGAROO rats, *POPULATION genetics, *ESTIMATION theory, *BIOLOGICAL variation, *POPULATION biology

Abstract

Metapopulation ecology has historically been rich in theory, yet analytical approaches for inferring demographic relationships among local populations have been few. We show how reverse-time multi-state capture–recapture models can be used to estimate the importance of local recruitment and interpopulation dispersal to metapopulation growth. We use 'contribution metrics' to infer demographic connectedness among eight local populations of banner-tailed kangaroo rats, to assess their demographic closure, and to investigate sources of variation in these contributions. Using a 7 year dataset, we show that: (i) local populations are relatively independent demographically, and contributions to local population growth via dispersal within the system decline with distance; (ii) growth contributions via local survival and recruitment are greater for adults than juveniles, while contributions involving dispersal are greater for juveniles; (iii) central populations rely more on local recruitment and survival than peripheral populations; (iv) contributions involving dispersal are not clearly related to overall metapopulation density; and (v) estimated contributions from outside the system are unexpectedly large. Our analytical framework can classify metapopulations on a continuum between demographic independence and panmixia, detect hidden population growth contributions, and make inference about other population linkage forms, including rescue effects and source–sink structures. Finally, we discuss differences between demographic and genetic population linkage patterns for our system. [ABSTRACT FROM AUTHOR]

Published

2012

15. Spatial heterogeneity in the effects of climate and density-dependence on dispersal in a house sparrow metapopulation.

Author

Henrik, Pärn, Thor Harald, Ringsby, Henrik, Jensen, and Bernt-Erik, Sæther

Subjects

*CLIMATE change, *ENGLISH sparrow, *BIRD dispersal, *METAPOPULATION (Ecology), *FRAGMENTED landscapes, *HABITATS, *DATA analysis

Abstract

Dispersal plays a key role in the response of populations to climate change and habitat fragmentation. Here, we use data from a long-term metapopulation study of a non-migratory bird, the house sparrow (Passer domesticus), to examine the influence of increasing spring temperature and density-dependence on natal dispersal rates and how these relationships depend on spatial variation in habitat quality. The effects of spring temperature and population size on dispersal rate depended on the habitat quality. Dispersal rate increased with temperature and population size on poor-quality islands without farms, where house sparrows were more exposed to temporal fluctuations in weather conditions and food availability. By contrast, dispersal rate was independent of spring temperature and population size on high-quality islands with farms, where house sparrows had access to food and shelter all the year around. This illustrates large spatial heterogeneity within the metapopulation in how population density and environmental fluctuations affect the dispersal process. [ABSTRACT FROM AUTHOR]

Published

2012

16. Connectivity dominates larval replenishment in a coastal reef fish metapopulation.

Author

Saenz-Agudelo, Pablo, Jones, Geoffrey P., Thorrold, Simon R., and Planes, Serge

Subjects

*REEF fishes, *FISH larvae, *METAPOPULATION (Ecology), *MICROSATELLITE repeats, *LARVAL dispersal, *MARINE parks & reserves

Abstract

Direct estimates of larval retention and connectivity are essential to understand the structure and dynamics of marine metapopulations, and optimize the size and spacing of reserves within networks of marine-protected areas (MPAs). For coral reef fishes, while there are some empirical estimates of self-recruitment at isolated populations, exchange among sub-populations has been rarely quantified. Here, we used microsatellite DNA markers and a likelihood-based parentage analysis to assess the relative magnitude of self-recruitment and exchange among eight geographically distinct sub-populations of the panda clownfish Amphiprion polymnus along 30 km of coastline near Port Moresby, Papua New Guinea. In addition, we used an assignment/exclusion test to identify immigrants arriving from genetically distinct sources. Overall, 82 per cent of the juveniles were immigrants while 18 per cent were progeny of parents genotyped in our focal metapopulation. Of the immigrants, only 6 per cent were likely to be genetically distinct from the focal metapopulation, suggesting most of the connectivity is among sub-populations from a rather homogeneous genetic pool. Of the 18 per cent that were progeny of known adults, two-thirds dispersed among the eight sub-populations and only one-third settled back into natal sub-populations. Comparison of our data with previous studies suggested that variation in dispersal distances is likely to be influenced by the geographical setting and spacing of sub-populations. [ABSTRACT FROM AUTHOR]

Published

2011

17. Paradoxical persistence through mixed-system dynamics: towards a unified perspective of reversal behaviours in evolutionary ecology.

Author

Williams, Paul David and Hastings, Alan

Subjects

*STOCHASTIC processes, *METAPOPULATION (Ecology), *CLIMATE change, *ECOLOGICAL models, *ENVIRONMENTAL impact analysis, *HEURISTIC

Abstract

Counterintuitive dynamics of various biological phenomena occur when composite system dynamics differ qualitatively from that of their component systems. Such composite systems typically arise when modelling situations with time-varying biotic or abiotic conditions, and examples range from metapopulation dynamics to population genetic models. These biological, and related physical, phenomena can often be modelled as simple financial games, wherein capital is gained and lost through gambling. Such games have been developed and used as heuristic devices to elucidate the processes at work in generating seemingly paradoxical outcomes across a spectrum of disciplines, albeit in a field-specific, ad hoc fashion. Here, we propose that studying these simple games can provide a much deeper understanding of the fundamental principles governing paradoxical behaviours in models from a diversity of topics in evolution and ecology in which fluctuating environmental effects, whether deterministic or stochastic, are an essential aspect of the phenomenon of interest. Of particular note, we find that, for a broad class of models, the ecological concept of equilibrium reactivity provides an intuitive necessary condition that must be satisfied in order for environmental variability to promote population persistence. We contend that further investigations along these lines promise to unify aspects of the study of a range of topics, bringing questions from genetics, species persistence and coexistence and the evolution of bet-hedging strategies, under a common theoretical purview. [ABSTRACT FROM AUTHOR]

Published

2011

18. Personality-dependent dispersal: characterization, ontogeny and consequences for spatially structured populations.

Author

J. Cote

Subjects

*PERSONALITY, *BIOLOGICAL invasions, *METAPOPULATION (Ecology), *ANIMAL dispersal, *ONTOGENY, *SPATIAL behavior, *POPULATION

Abstract

Dispersal is one of the most fundamental components of ecology, and affects processes as diverse as population growth, metapopulation dynamics, gene flow and adaptation. Although the act of moving from one habitat to another entails major costs to the disperser, empirical and theoretical studies suggest that these costs can be reduced by having morphological, physiological or behavioural specializations for dispersal. A few recent studies on different systems showed that individuals exhibit personality-dependent dispersal, meaning that dispersal tendency is associated with boldness, sociability or aggressiveness. Indeed, in several species, dispersers not only develop behavioural differences at the onset of dispersal, but display these behavioural characteristics through their life cycle. While personality-dependent dispersal has been demonstrated in only a few species, we believe that it is a widespread phenomenon with important ecological consequences. Here, we review the evidence for behavioural differences between dispersers and residents, to what extent they constitute personalities. We also examine how a link between personality traits and dispersal behaviours can be produced and how personality-dependent dispersal affects the dynamics of metapopulations and biological invasions. Finally, we suggest future research directions for population biologists, behavioural ecologists and conservation biologists such as how the direction and the strength of the relationship between personality traits and dispersal vary with ecological contexts. [ABSTRACT FROM AUTHOR]

Published

2010

19. Phylogenetic isolation of host trees affects assembly of local Heteroptera communities.

Author

A. Vialatte

Subjects

*HOSTS (Biology), *TREES, *HEMIPTERA, *BIOTIC communities, *PLANT phylogeny, *BIOLOGICAL evolution, *METAPOPULATION (Ecology)

Abstract

A host may be physically isolated in space and then may correspond to a geographical island, but it may also be separated from its local neighbours by hundreds of millions of years of evolutionary history, and may form in this case an evolutionarily distinct island. We test how this affects the assembly processes of the host's colonizers, this question being until now only invoked at the scale of physically distinct islands or patches. We studied the assembly of true bugs in crowns of oaks surrounded by phylogenetically more or less closely related trees. Despite the short distances (less than 150 m) between phylogenetically isolated and non-isolated trees, we found major differences between their Heteroptera faunas. We show that phylogenetically isolated trees support smaller numbers and fewer species of Heteroptera, an increasing proportion of phytophages and a decreasing proportion of omnivores, and proportionally more non-host-specialists. These differences were not due to changes in the nutritional quality of the trees, i.e. species sorting, which we accounted for. Comparison with predictions from meta-community theories suggests that the assembly of local Heteroptera communities may be strongly driven by independent metapopulation processes at the level of the individual species. We conclude that the assembly of communities on hosts separated from their neighbours by long periods of evolutionary history is qualitatively and quantitatively different from that on hosts established surrounded by closely related trees. Potentially, the biotic selection pressure on a host might thus change with the evolutionary proximity of the surrounding hosts. [ABSTRACT FROM AUTHOR]

Published

2010

20. Rapid viability analysis for metapopulations in dynamic habitat networks.

Author

Martin Drechsler

Subjects

*METAPOPULATION (Ecology), *HABITATS, *LAND use, *LANDSCAPES, *BIODIVERSITY, *SPATIO-temporal variation, *SIMULATION methods & models

Abstract

For land-use planning, numerically fast and easily applicable tools are urgently needed that allow us to assess how landscape structure and dynamics affect biodiversity. To date, such tools exist only for static landscapes. We provide an analytical formula for the mean lifetime of species in fragmented and dynamic habitat networks where habitat patches may be destroyed and created elsewhere. The formula is able to consider both patch size heterogeneity and dynamics additionally to patch number and connectivity. It is validated through comparison with a dynamic and spatially explicit simulation model. It can be used for the optimization of spatio-temporal land-use patterns in real landscapes and for advancing our general understanding of key processes affecting the survival of species in fragmented heterogeneous dynamic landscapes. [ABSTRACT FROM AUTHOR]

Published

2010

21. Both population size and patch quality affect local extinctions and colonizations.

Author

Markus Franzén

Subjects

*BIOLOGICAL extinction, *HABITATS, *COLONIZATION (Ecology), *METAPOPULATION (Ecology), *PLANT populations, *BEES

Abstract

Currently, the habitat of many species is fragmented, resulting in small local populations with individuals occasionally dispersing between the remaining habitat patches. In a solitary bee metapopulation, extinction probability was related to both local bee population sizes and pollen resources measured as host plant population size. Patch size, on the other hand, had no additional predictive power. The turnover rate of local bee populations in 63 habitat patches over 4 years was high, with 72 extinction events and 31 colonization events, but the pollen plant population was stable with no extinctions or colonizations. Both pollen resources and bee populations had strong and independent effects on extinction probability, but connectivity was not of importance. Colonizations occurred more frequently within larger host plant populations. For metapopulation survival of the bee, large pollen plant populations are essential, independent of current bee population size. [ABSTRACT FROM AUTHOR]

Published

2010

22. Environment, but not migration rate, influences extinction risk in experimental metapopulations.

Author

Griffen, Blaine D.

Subjects

*METAPOPULATION (Ecology), *DAPHNIA magna, *BIOLOGICAL extinction & the environment, *ANIMAL migration, *ANIMAL ecology, *POPULATION biology

Abstract

Ecological theory suggests that several demographic factors influence metapopulation extinction risk, including synchrony in population size between subpopulations, metapopulation size and the magnitude of fluctuations in population size. Theoretically, each of these is influenced by the rate of migration between subpopulations. Here we report on an experiment where we manipulated migration rate within metapopulations of the freshwater zooplankton Daphnia magna to examine how migration influenced each of these demographic variables, and subsequent effects on metapopulation extinction. In addition, our experimental procedures introduced unplanned but controlled differences between metapopulations in light intensity, enabling us to examine the relative influences of environmental and demographic factors. We found that increasing migration rate increased subpopulation synchrony. We failed to detect effects of migration on population size and fluctuations in population size at the metapopulation or subpopulation level, however. In contrast, light intensity did not influence synchrony, but was positively correlated with population size and negatively correlated with population fluctuation. Finally, synchrony did not influence time to extinction, while population size and the magnitude of fluctuations did. We conclude that environmental factors had a greater influence on extinction risk than demographic factors, and that metapopulation size and fluctuation were more important to extinction risk than metapopulation synchrony. [ABSTRACT FROM AUTHOR]

Published

2009

23. The effects of connectivity on metapopulation persistence: network symmetry and degree correlations.

Author

Shtilerman, Elad and Stone, Lewi

Subjects

*METAPOPULATION (Ecology), *PATCH dynamics, *COLONIZATION (Ecology), *SYMMETRY (Biology), *DISPERSAL (Ecology)

Abstract

A spatial metapopulation is a mosaic of interconnected patch populations. The complex routes of colonization between the patches are governed by the metapopulation's dispersal network. Over the past two decades, there has been considerable interest in uncovering the effects of dispersal network topology and its symmetry on metapopulation persistence. While most studies find that the level of symmetry in dispersal pattern enhances persistence, some have reached the conclusion that symmetry has at most a minor effect. In this work, we present a new perspective on the debate. We study properties of the in- and out-degree distribution of patches in the metapopulation which define the number of dispersal routes into and out of a particular patch, respectively. By analysing the spectral radius of the dispersal matrices, we confirm that a higher level of symmetry has only a marginal impact on persistence. We continue to analyse different properties of the in-out degree distribution, namely the 'in-out degree correlation' (IODC) and degree heterogeneity, and find their relationship to metapopulation persistence. Our analysis shows that, in contrast to symmetry, the in-out degree distribution and particularly, the IODC are dominant factors controlling persistence. [ABSTRACT FROM AUTHOR]

Published

2015

24. Increasing frequency of low summer precipitation synchronizes dynamics and compromises metapopulation stability in the Glanville fritillary butterfly.

Author

Tack, Ayco J. M., Mononen, Tommi, and Hanski, Ilkka

Subjects

*MELITAEA cinxia, *METAPOPULATION (Ecology), *METEOROLOGICAL precipitation, *INSECTS & climate, *INSECT populations

Abstract

Climate change is known to shift species' geographical ranges, phenologies and abundances, but less is known about other population dynamic consequences. Here, we analyse spatio-temporal dynamics of the Glanville fritillary butterfly (Melitaea cinxia) in a network of 4000 dry meadows during 21 years. The results demonstrate two strong, related patterns: the amplitude of year-to-year fluctuations in the size of the metapopulation as a whole has increased, though there is no long-term trend in average abundance; and there is a highly significant increase in the level of spatial synchrony in population dynamics. The increased synchrony cannot be explained by increasing within-year spatial correlation in precipitation, the key environmental driver of population change, or in per capita growth rate. On the other hand, the frequency of drought during a critical life-history stage (early larval instars) has increased over the years, which is sufficient to explain the increasing amplitude and the expanding spatial synchrony in metapopulation dynamics. Increased spatial synchrony has the general effect of reducing long-term metapopulation viability even if there is no change in average metapopulation size. This study demonstrates how temporal changes in weather conditions can lead to striking changes in spatio-temporal population dynamics. [ABSTRACT FROM AUTHOR]

Published

2015

25. Bacterial adaptation to sublethal antibiotic gradients can change the ecological properties of multitrophic microbial communities.

Author

Friman†, Ville-Petri, Guzman†, Laura Melissa, Reuman, Daniel C., and Bell, Thomas

Subjects

*BACTERIAL adaptation, *ANTIBIOTICS, *POPULATION dynamics, *METAPOPULATION (Ecology), *AUTOCORRELATION (Statistics)

Abstract

Antibiotics leak constantly into environments due to widespread use in agriculture and human therapy. Although sublethal concentrations are well known to select for antibiotic-resistant bacteria, little is known about how bacterial evolution cascades through food webs, having indirect effect on species not directly affected by antibiotics (e.g. via population dynamics or pleiotropic effects). Here, we used an experimental evolution approach to test how temporal patterns of antibiotic stress, as well as migration within metapopulations, affect the evolution and ecology of microcosms containing one prey bacterium, one phage and two protist predators. We found that environmental variability, autocorrelation and migration had only subtle effects for population and evolutionary dynamics. However, unexpectedly, bacteria evolved greatest fitness increases to both antibiotics and enemies when the sublethal levels of antibiotics were highest, indicating positive pleiotropy. Crucially, bacterial adaptation cascaded through the food web leading to reduced predator-to-prey abundance ratio, lowered predator community diversity and increased instability of populations. Our results show that the presence of natural enemies can modify and even reverse the effects of antibiotics on bacteria, and that antibiotic selection can change the ecological properties of multitrophic microbial communities by having indirect effects on species not directly affected by antibiotics. [ABSTRACT FROM AUTHOR]

Published

2015

26. Evaluating the metapopulation consequences of ecological traps.

Author

Hale, Robin, Treml, Eric A., and Swearer, Stephen E.

Subjects

*METAPOPULATION (Ecology), *DISPERSAL (Ecology), *HABITAT selection, *EFFECT of human beings on climate change, *ECOLOGICAL models

Abstract

Ecological traps occur when environmental changes cause maladaptive habitat selection. Despite their relevance to metapopulations, ecological traps have been studied predominantly at local scales. How these local impacts scale up to affect the dynamics of spatially structured metapopulations in heterogeneous landscapes remains unexplored. We propose that assessing the metapopulation consequences of traps depends on a variety of factors that can be grouped into four categories: the probability of encounter, the likelihood of selection, the fitness costs of selection and species-specific vulnerability to these costs. We evaluate six hypotheses using a network-based metapopulation model to explore the relative importance of factors across these categories within a spatial context. Our model suggests (i) traps are most severe when they represent a large proportion of habitats, severely reduce fitness and are highly attractive, and (ii) species with high intrinsic fitness will be most susceptible. We provide the first evidence that (iii) traps may be beneficial for metapopulations in rare instances, and (iv) preferences for natal-like habitats can magnify the effects of traps. Our study provides important insight into the effects of traps at landscape scales, and highlights the need to explicitly consider spatial context to better understand and manage traps within metapopulations. [ABSTRACT FROM AUTHOR]

Published

2015

27. On the evolution of dispersal via heterogeneity in spatial connectivity.

Author

Henriques-Silva, Renato, Boivin, Frédéric, Calcagno, Vincent, Urban, Mark C., and Peres-Neto, Pedro R.

Subjects

*ECOLOGICAL heterogeneity, *ECOSYSTEM dynamics, *METAPOPULATION (Ecology), *BIOLOGICAL extinction, *PARTHENOGENESIS, *PATCH dynamics

Abstract

Dispersal has long been recognized as a mechanism that shapes many observed ecological and evolutionary processes. Thus, understanding the factors that promote its evolution remains a major goal in evolutionary ecology. Landscape connectivity may mediate the trade-off between the forces in favour of dispersal propensity (e.g. kin-competition, local extinction probability) and those against it (e.g. energetic or survival costs of dispersal). It remains, however, an open question how differing degrees of landscape connectivity may select for different dispersal strategies. We implemented an individual-based model to study the evolution of dispersal on landscapes that differed in the variance of connectivity across patches ranging from networks with all patches equally connected to highly heterogeneous networks. The parthenogenetic individuals dispersed based on a flexible logistic function of local abundance. Our results suggest, all else being equal, that landscapes differing in their connectivity patterns will select for different dispersal strategies and that these strategies confer a long-term fitness advantage to individuals at the regional scale. The strength of the selection will, however, vary across network types, being stronger on heterogeneous landscapes compared with the ones where all patches have equal connectivity. Our findings highlight how landscape connectivity can determine the evolution of dispersal strategies, which in turn affects how we think about important ecological dynamics such as metapopulation persistence and range expansion. [ABSTRACT FROM AUTHOR]

Published

2015

28. An evolutionary model explaining the Neolithic transition from egalitarianism to leadership and despotism.

Author

Powers, Simon T. and Lehmann, Laurent

Subjects

*NEOLITHIC Period, *EQUALITY, *LEADERSHIP, *DESPOTISM, *METAPOPULATION (Ecology), *DISPERSAL (Ecology)

Abstract

The Neolithic was marked by a transition from small and relatively egalitarian groups to much larger groups with increased stratification. But, the dynamics of this remain poorly understood. It is hard to see how despotism can arise without coercion, yet coercion could not easily have occurred in an egalitarian setting. Using a quantitative model of evolution in a patch-structured population, we demonstrate that the interaction between demographic and ecological factors can overcome this conundrum. We model the coevolution of individual preferences for hierarchy alongside the degree of despotism of leaders, and the dispersal preferences of followers. We show that voluntary leadership without coercion can evolve in small groups, when leaders help to solve coordination problems related to resource production. An example is coordinating construction of an irrigation system. Our model predicts that the transition to larger despotic groups will then occur when: (i) surplus resources lead to demographic expansion of groups, removing the viability of an acephalous niche in the same area and so locking individuals into hierarchy; (ii) high dispersal costs limit followers' ability to escape a despot. Empirical evidence suggests that these conditions were probably met, for the first time, during the subsistence intensification of the Neolithic. [ABSTRACT FROM AUTHOR]

Published

2014

29. The emergence of the rescue effect from explicit within- and between-patch dynamics in a metapopulation.

Author

Eriksson, Anders, Elías-Wolff, Federico, Mehlig, Bernhard, and Manica, Andrea

Subjects

*METAPOPULATION (Ecology), *BIOLOGICAL extinction, *POPULATION dynamics, *ANIMAL populations, *WILDLIFE conservation

Abstract

Immigration can rescue local populations from extinction, helping to stabilize a metapopulation. Local population dynamics is important for determining the strength of this rescue effect, but the mechanistic link between local demographic parameters and the rescue effect at the metapopulation level has received very little attention by modellers. We develop an analytical framework that allows us to describe the emergence of the rescue effect from interacting local stochastic dynamics. We show this framework to be applicable to a wide range of spatial scales, providing a powerful and convenient alternative to individual-based models for making predictions concerning the fate of metapopulations. We show that the rescue effect plays an important role in minimizing the increase in local extinction probability associated with high demographic stochasticity, but its role is more limited in the case of high local environmental stochasticity of recruitment or survival. While most models postulate the rescue effect, our framework provides an explicit mechanistic link between local dynamics and the emergence of the rescue effect, and more generally the stability of the whole metapopulation. [ABSTRACT FROM AUTHOR]

Published

2014

30. Forest corridors maintain historical gene flow in a tiger metapopulation in the highlands of central India.

Author

Sharma, Sandeep, Dutta, Trishna, Maldonado, Jesús E., Wood, Thomas C., Panwar, Hemendra Singh, and Seidensticker, John

Subjects

*TIGERS, *METAPOPULATION (Ecology), *GENE flow, *GENOTYPE-environment interaction, SATPURA Range (India)

Abstract

Understanding the patterns of gene flow of an endangered species metapopulation occupying a fragmented habitat is crucial for landscape-level conservation planning and devising effective conservation strategies. Tigers (Panthera tigris) are globally endangered and their populations are highly fragmented and exist in a few isolated metapopulations across their range. We used multi-locus genotypic data from 273 individual tigers (Panthera tigris tigris) from four tiger populations of the Satpura-Maikal landscape of central India to determine whether the corridors in this landscape are functional. This 45 000 km[sup 2] landscape contains 17% of India's tiger population and 12% of its tiger habitat. We applied Bayesian and coalescent-based analyses to estimate contemporary and historical gene flow among these populations and to infer their evolutionary history. We found that the tiger metapopulation in central India has high rates of historical and contemporary gene flow. The tests for population history reveal that tigers populated central India about 10 000 years ago. Their population subdivision began about 1000 years ago and accelerated about 200 years ago owing to habitat fragmentation, leading to four spatially separated populations. These four populations have been in migration-drift equilibrium maintained by high gene flow. We found the highest rates of contemporary gene flow in populations that are connected by forest corridors. This information is highly relevant to conservation practitioners and policy makers, because deforestation, road widening and mining are imminent threats to these corridors. [ABSTRACT FROM AUTHOR]

Published

2013