The genetic Allee effect: a unified framework for the genetics and demography of small populations

Gloria M. Luque; Chloé Vayssade; Benoît Facon; Thomas Guillemaud; Franck Courchamp; Xavier Fauvergue

doi:10.1002/ecs2.1413

The genetic Allee effect: A unified framework for the genetics and demography of small populations

10.1101/038125 ◽

2016 ◽

Cited By ~ 1

Author(s):

Gloria M. Lucque ◽

Chloé Vayssade ◽

Benoît Facon ◽

Thomas Guillemaud ◽

Franck Courchamp ◽

...

Keyword(s):

Genetic Structure ◽

Population Size ◽

Allee Effect ◽

Small Populations ◽

Allee Effects ◽

Unified Framework ◽

Fitness Components ◽

Individual Fitness ◽

Heated Debate ◽

Underlying Mechanisms

AbstractThe Allee effect is a theoretical model predicting low growth rates and the possible extinction of small populations. Historically, studies of the Allee effect have focused on demography. As a result, underlying processes other than the direct effect of population density on fitness components are not generally taken into account. There has been heated debate about the potential of genetic processes to drive small populations to extinction, but recent studies have shown that such processes clearly impact small populations over short time scales, and some may generate Allee effects. However, as opposed to the ecological Allee effect, which is underpinned by cooperative interactions between individuals, genetically driven Allee effects require a change in genetic structure to link the decline in population size with a decrease in fitness components. We therefore define the genetic Allee effect as a two-step process whereby a decrease in population size leads to a change in population genetic structure, and in turn, to a decrease in individual fitness. We describe potential underlying mechanisms, and review the evidence for this original type of component Allee effect, using published examples from both plants and animals. The possibility of considering demogenetic feedback in light of genetic Allee effects clarifies the analysis and interpretation of demographic and genetic processes, and the interplay between them, in small populations.

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Genetic Allee effects and their interaction with ecological Allee effects

10.1101/061549 ◽

2016 ◽

Author(s):

Meike J. Wittmann ◽

Hanna Stuis ◽

Dirk Metzler

Keyword(s):

Population Size ◽

Inbreeding Depression ◽

Survival Probability ◽

Allee Effect ◽

Extinction Risk ◽

List Type ◽

Small Populations ◽

Allee Effects ◽

Deleterious Mutations ◽

Lethal Equivalents

SummaryIt is now widely accepted that genetic processes such as inbreeding depression and loss of genetic variation can increase the extinction risk of small populations. However, it is generally unclear whether extinction risk from genetic causes gradually increases with decreasing population size or whether there is a sharp transition around a specific threshold population size. In the ecological literature, such threshold phenomena are called “strong Allee effects” and they can arise for example from mate limitation in small populations.In this study, we aim to a) develop a meaningful notion of a “strong genetic Allee effect”, b) explore whether and under what conditions such an effect can arise from inbreeding depression due to recessive deleterious mutations, and c) quantify the interaction of potential genetic Allee effects with the well-known mate-finding Allee effect.We define a strong genetic Allee effect as a genetic process that causes a population’s survival probability to be a sigmoid function of its initial size. The inflection point of this function defines the critical population size. To characterize survival-probability curves, we develop and analyze simple stochastic models for the ecology and genetics of small populations.Our results indicate that inbreeding depression can indeed cause a strong genetic Allee effect, but only if individuals carry sufficiently many deleterious mutations (lethal equivalents) on average and if these mutations are spread across sufficiently many loci. Populations suffering from a genetic Allee effect often first grow, then decline as inbreeding depression sets in, and then potentially recover as deleterious mutations are purged. Critical population sizes of ecological and genetic Allee effects appear to be often additive, but even superadditive interactions are possible.Many published estimates for the number of lethal equivalents in birds and mammals fall in the parameter range where strong genetic Allee effects are expected. Unfortunately, extinction risk due to genetic Allee effects can easily be underestimated as populations with genetic problems often grow initially, but then crash later. Also interactions between ecological and genetic Allee effects can be strong and should not be neglected when assessing the viability of endangered or introduced populations.

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Fear creates an Allee effect: experimental evidence from seasonal populations

Proceedings of The Royal Society B Biological Sciences ◽

10.1098/rspb.2017.0878 ◽

2017 ◽

Vol 284 (1857) ◽

pp. 20170878 ◽

Cited By ~ 10

Author(s):

Kyle H. Elliott ◽

Gustavo S. Betini ◽

D. Ryan Norris

Keyword(s):

Experimental Evidence ◽

Breeding Season ◽

Allee Effect ◽

Generalist Predators ◽

Small Populations ◽

Allee Effects ◽

Wild Mammals ◽

Population Consequences ◽

Type Ii Functional Response

Allee effects driven by predation can play a strong role in the decline of small populations but are conventionally thought to occur when generalist predators target specific prey (i.e. type II functional response). However, aside from direct consumption, fear of predators could also increase vigilance and reduce time spent foraging as population size decreases, as has been observed in wild mammals living in social groups. To investigate the role of fear on fitness in relation to population density in a species with limited sociality, we exposed varying densities of Drosophila melanogaster to mantid predators either during an experimental breeding season or non-breeding season. The presence of mantids in either season decreased the reproductive performance of individuals but only at low breeding densities, providing evidence for an Allee effect. We then used our experimental results to parametrize a mathematical model to examine the population consequences of fear at low densities. Fear tended to destabilize population dynamics and increase the risk of extinction up to sevenfold. Our study provides unique experimental evidence that the indirect effects of the presence of predators can cause an Allee effect and has important consequences for our understanding of the dynamics of small populations.

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Demystifying moderated mediation: A unified framework for investigating conditional mediation effects in psychological research

PsycEXTRA Dataset ◽

10.1037/e633962013-648 ◽

2006 ◽

Cited By ~ 1

Author(s):

Kristopher Preacher ◽

Derek Rucker ◽

Andrew Hayes

Keyword(s):

Moderated Mediation ◽

Psychological Research ◽

Unified Framework ◽

Mediation Effects

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Explaining training induced performance increments and decrements within a unified framework of perceptual learning

Learning & Perception ◽

10.1556/lp.1.2009.1.2 ◽

2009 ◽

Vol 1 (1) ◽

pp. 3-17 ◽

Cited By ~ 3

Author(s):

Nitzan Censor ◽

Dov Sagi

Keyword(s):

Perceptual Learning ◽

Unified Framework

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A unified framework for automated person re-indentification

Transport and Communication Science Journal ◽

10.25073/tcsj.71.7.11 ◽

2020 ◽

Vol 71 (7) ◽

pp. 868-880

Author(s):

Nguyen Hong-Quan ◽

Nguyen Thuy-Binh ◽

Tran Duc-Long ◽

Le Thi-Lan

Keyword(s):

Deep Learning ◽

Video Analysis ◽

Camera Network ◽

Unified Framework ◽

Person Detection ◽

Practical Applications ◽

Detection And Tracking ◽

Analysis System ◽

Bounding Boxes

Along with the strong development of camera networks, a video analysis system has been become more and more popular and has been applied in various practical applications. In this paper, we focus on person re-identification (person ReID) task that is a crucial step of video analysis systems. The purpose of person ReID is to associate multiple images of a given person when moving in a non-overlapping camera network. Many efforts have been made to person ReID. However, most of studies on person ReID only deal with well-alignment bounding boxes which are detected manually and considered as the perfect inputs for person ReID. In fact, when building a fully automated person ReID system the quality of the two previous steps that are person detection and tracking may have a strong effect on the person ReID performance. The contribution of this paper are two-folds. First, a unified framework for person ReID based on deep learning models is proposed. In this framework, the coupling of a deep neural network for person detection and a deep-learning-based tracking method is used. Besides, features extracted from an improved ResNet architecture are proposed for person representation to achieve a higher ReID accuracy. Second, our self-built dataset is introduced and employed for evaluation of all three steps in the fully automated person ReID framework.

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A Unified Model for Photophysical and Electro-Optical Properties of Green Fluorescent Proteins

10.26434/chemrxiv.8772668.v1 ◽

2019 ◽

Author(s):

Chi-Yun Lin ◽

Matthew Romei ◽

Luke Oltrogge ◽

Irimpan Mathews ◽

Steven Boxer

Keyword(s):

Driving Force ◽

Fluorescent Protein ◽

Charge Transfer Band ◽

Photophysical Properties ◽

Polymethine Dyes ◽

Emission Rates ◽

Unified Framework ◽

Underlying Factor ◽

Green Fluorescent ◽

Protein Environment

Green fluorescent protein (GFPs) have become indispensable imaging and optogenetic tools. Their absorption and emission properties can be optimized for specific applications. Currently, no unified framework exists to comprehensively describe these photophysical properties, namely the absorption maxima, emission maxima, Stokes shifts, vibronic progressions, extinction coefficients, Stark tuning rates, and spontaneous emission rates, especially one that includes the effects of the protein environment. In this work, we study the correlations among these properties from systematically tuned GFP environmental mutants and chromophore variants. Correlation plots reveal monotonic trends, suggesting all these properties are governed by one underlying factor dependent on the chromophore's environment. By treating the anionic GFP chromophore as a mixed-valence compound existing as a superposition of two resonance forms, we argue that this underlying factor is defined as the difference in energy between the two forms, or the driving force, which is tuned by the environment. We then introduce a Marcus-Hush model with the bond length alternation vibrational mode, treating the GFP absorption band as an intervalence charge transfer band. This model explains all the observed strong correlations among photophysical properties; related subtopics are extensively discussed in Supporting Information. Finally, we demonstrate the model's predictive power by utilizing the additivity of the driving force. The model described here elucidates the role of the protein environment in modulating photophysical properties of the chromophore, providing insights and limitations for designing new GFPs with desired phenotypes. We argue this model should also be generally applicable to both biological and non-biological polymethine dyes.<br>

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