Sex- and context-specific associations between personality and a measure of fitness but no link with life history traits

The pace of life syndrome hypothesis posits that personality traits (i.e., consistent individual differences in behaviour) are linked to life history and fitness. Specifically, fast-paced individuals are predicted to be proactive (i.e., active and aggressive) with an earlier age at first reproduction, a shorter lifespan, and a higher fecundity than slow-paced individuals. Environmental conditions and sex differences may be important in maintaining behavioural and life history variation in populations and may influence the covariance of personality with life history or lifetime fitness. However, these effects are rarely tested together. We investigated whether the occurrence of a resource pulse (called a mast year) during adulthood altered the associations between personality and life history traits or lifetime offspring production in adult North American red squirrels (Tamiasciurus hudsonicus). Despite accounting for environmental context during adulthood, we found no evidence of an overall pace-of-life syndrome in this population as personality was not associated with age at first reproduction or longevity in either sex. Males and females had similar activity levels, but females were more aggressive, potentially due to the fitness benefits of protecting their offspring from predation. In all females regardless of mast experience, there was no association between activity and lifetime pup production but there was a positive association between aggression and lifetime pup production. In males that experienced a mast there was a positive association between lifetime pup production and both activity and aggression. In males that did not experience a mast, there was no association between activity and lifetime pup production but a negative association between aggression and lifetime pup production. Lifetime recruit production in either sex was not influenced by activity or aggression regardless of mast experience. Overall, our results suggest that the infrequent occurrence of mast years may contribute to maintaining variation in personality traits in red squirrels.

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Heritability and genetic correlations of personality, life history and morphology in the grey mouse lemur ( Microcebus murinus )

Royal Society Open Science ◽

10.1098/rsos.190632 ◽

2019 ◽

Vol 6 (10) ◽

pp. 190632 ◽

Cited By ~ 1

Author(s):

Pauline B. Zablocki-Thomas ◽

Anthony Herrel ◽

Caitlin J. Karanewsky ◽

Fabienne Aujard ◽

Emmanuelle Pouydebat

Keyword(s):

Life History ◽

Personality Traits ◽

Maternal Effects ◽

Morphological Traits ◽

Life History Traits ◽

Genetic Correlations ◽

Microcebus Murinus ◽

Phenotypic Traits ◽

Pace Of Life ◽

Sources Of Variation

The recent interest in animal personality has sparked a number of studies on the heritability of personality traits. Yet, how the sources variance these traits can be decomposed remains unclear. Moreover, whether genetic correlations with life-history traits, personality traits and other phenotypic traits exist as predicted by the pace-of-life syndrome hypothesis remains poorly understood. Our aim was to compare the heritability of personality, life-history and morphological traits and their potential genetic correlations in a small primate ( Microcebus murinus ). We performed an animal model analysis on six traits measured in a large sample of captive mouse lemurs ( N = 486). We chose two personality traits, two life-history traits and two morphological traits to (i) estimate the genetic and/or environmental contribution to their variance, and (ii) test for genetic correlations between these traits. We found modest narrow-sense heritability for personality traits, morphological traits and life-history traits. Other factors including maternal effects also influence the sources of variation in life-history and morphological traits. We found genetic correlations between emergence latency on the one hand and radius length and growth rate on the other hand. Emergence latency was also genetically correlated with birth weight and was influenced by maternal identity. These results provide insights into the influence of genes and maternal effects on the partitioning of sources of variation in personality, life-history and morphological traits in a captive primate model and suggest that the pace-of-life syndrome may be partly explained by genetic trait covariances.

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Personality and the emergence of the pace-of-life syndrome concept at the population level

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.2010.0208 ◽

2010 ◽

Vol 365 (1560) ◽

pp. 4051-4063 ◽

Cited By ~ 669

Author(s):

Denis Réale ◽

Dany Garant ◽

Murray M. Humphries ◽

Patrick Bergeron ◽

Vincent Careau ◽

...

Keyword(s):

Life History ◽

Personality Traits ◽

Related Species ◽

Life History Traits ◽

Population Level ◽

Closely Related Species ◽

Ecological Conditions ◽

Pace Of Life ◽

Physiological Differences ◽

Personality Studies

The pace-of-life syndrome (POLS) hypothesis specifies that closely related species or populations experiencing different ecological conditions should differ in a suite of metabolic, hormonal and immunity traits that have coevolved with the life-history particularities related to these conditions. Surprisingly, two important dimensions of the POLS concept have been neglected: (i) despite increasing evidence for numerous connections between behavioural, physiological and life-history traits, behaviours have rarely been considered in the POLS yet; (ii) the POLS could easily be applied to the study of covariation among traits between individuals within a population. In this paper, we propose that consistent behavioural differences among individuals, or personality, covary with life history and physiological differences at the within-population, interpopulation and interspecific levels. We discuss how the POLS provides a heuristic framework in which personality studies can be integrated to address how variation in personality traits is maintained within populations.

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Life-history variation of drosophila subobscura under lead pollution depends on population history

Genetika ◽

10.2298/gensr1403693k ◽

2014 ◽

Vol 46 (3) ◽

pp. 693-703 ◽

Cited By ~ 1

Author(s):

Bojan Kenig ◽

Aleksandra Patenkovic ◽

Marko Andjelkovic ◽

Marina Stamenkovic-Rada

Keyword(s):

Heavy Metal ◽

Life History ◽

Metal Contamination ◽

Life History Traits ◽

Heavy Metal Contamination ◽

Developmental Time ◽

Drosophila Subobscura ◽

Life History Variation ◽

Laboratory Conditions ◽

Coefficients Of Variation

Contamination represents environmental stress that can affect genetic variability of populations, thus influencing the evolutionary processes. In this study, we evaluate the relationship between heavy metal contamination (Pb) and phenotypic variation, assessed by coefficients of variation (CV) of life-history traits. To investigate the consequences of population origin on variation of life history traits in Drosophila subobscura in response to different laboratory conditions we compared populations from relatively polluted and unpolluted environments. Prior to experiment, flies from natural populations were reared for two generations in standard Drosophila laboratory conditions. Afterwards, all flies were cultured on three different media: one medium without lead as the control, and the other two with different concentrations of lead. Coefficients of variation (CV) of life- history traits (fecundity, egg-to-adult viability and developmental time) were analyzed on flies sampled in generations F2, F5 and F8 from these three groups. In later generations samples from both polluted and unpolluted environments showed the increased fecundity variation on media with lead. This increase is expressed more in population from unpolluted environment. On contrary, population from unpolluted environment had increased variation of developmental time in earlier, F2 generation, compared to the population from polluted environment. Our results showed that the response to heavy metal contamination depends on the evolutionary history of the populations regarding habitat pollution.

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Loci, genes, and gene networks associated with life history variation in a model ecological organism,Daphnia pulex(complex)

10.1101/436733 ◽

2018 ◽

Author(s):

Jacob W. Malcom ◽

Thomas E. Juenger ◽

Mathew A. Leibold

Keyword(s):

Gene Expression ◽

Genetic Variation ◽

Life History ◽

Molecular Basis ◽

Life History Traits ◽

Evolutionary Dynamics ◽

Daphnia Pulex ◽

Life History Trait ◽

Life History Variation ◽

Trait Variation

ABSTRACTBackgroundIdentifying the molecular basis of heritable variation provides insight into the underlying mechanisms generating phenotypic variation and the evolutionary history of organismal traits. Life history trait variation is of central importance to ecological and evolutionary dynamics, and contemporary genomic tools permit studies of the basis of this variation in non-genetic model organisms. We used high density genotyping, RNA-Seq gene expression assays, and detailed phenotyping of fourteen ecologically important life history traits in a wild-caught panel of 32Daphnia pulexclones to explore the molecular basis of trait variation in a model ecological species.ResultsWe found extensive phenotypic and a range of heritable genetic variation (~0 < H2< 0.44) in the panel, and accordingly identify 75-261 genes—organized in 3-6 coexpression modules—associated with genetic variation in each trait. The trait-related coexpression modules possess well-supported promoter motifs, and in conjunction with marker variation at trans- loci, suggest a relatively small number of important expression regulators. We further identify a candidate genetic network with SNPs in eight known transcriptional regulators, and dozens of differentially expressed genes, associated with life history variation. The gene-trait associations include numerous un-annotated genes, but also support several a priori hypotheses, including an ecdysone-induced protein and several Gene Ontology pathways.ConclusionThe genetic and gene expression architecture ofDaphnialife history traits is complex, and our results provide numerous candidate loci, genes, and coexpression modules to be tested as the molecular mechanisms that underlieDaphniaeco-evolutionary dynamics.

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Palaeohistology reveals a slow pace of life for the dwarfed Sicilian elephant

Scientific Reports ◽

10.1038/s41598-021-02192-4 ◽

2021 ◽

Vol 11 (1) ◽

Author(s):

Meike Köhler ◽

Victoria Herridge ◽

Carmen Nacarino-Meneses ◽

Josep Fortuny ◽

Blanca Moncunill-Solé ◽

...

Keyword(s):

Life History ◽

Body Mass ◽

Growth Period ◽

Extended Period ◽

Island Rule ◽

Rule Based ◽

Age At First Reproduction ◽

Slow Pace ◽

First Reproduction ◽

Adaptive Shifts

AbstractThe 1-m-tall dwarf elephant Palaeoloxodon falconeri from the Pleistocene of Sicily (Italy) is an extreme example of insular dwarfism and epitomizes the Island Rule. Based on scaling of life-history (LH) traits with body mass, P. falconeri is widely considered to be ‘r-selected’ by truncation of the growth period, associated with an early onset of reproduction and an abbreviated lifespan. These conjectures are, however, at odds with predictions from LH models for adaptive shifts in body size on islands. To settle the LH strategy of P. falconeri, we used bone, molar, and tusk histology to infer growth rates, age at first reproduction, and longevity. Our results from all approaches are congruent and provide evidence that the insular dwarf elephant grew at very slow rates over an extended period; attained maturity at the age of 15 years; and had a minimum lifespan of 68 years. This surpasses not only the values predicted from body mass but even those of both its giant sister taxon (P. antiquus) and its large mainland cousin (L. africana). The suite of LH traits of P. falconeri is consistent with the LH data hitherto inferred for other dwarfed insular mammals. P. falconeri, thus, not only epitomizes the Island Rule but it can also be viewed as a paradigm of evolutionary change towards a slow LH that accompanies the process of dwarfing in insular mammals.

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Density Dependence, Evolutionary Optimization, and the Diversification of Avian Life Histories

The Condor ◽

10.1093/condor/102.1.9 ◽

2000 ◽

Vol 102 (1) ◽

pp. 9-22 ◽

Cited By ~ 15

Author(s):

Robert E. Ricklefs

Keyword(s):

Life History ◽

Life Table ◽

Life Histories ◽

Life History Traits ◽

Evolutionary Ecology ◽

Reproductive Rate ◽

Empirical Modeling ◽

Adult Survival ◽

Life History Variation ◽

Evolutionary Response

Abstract Although we have learned much about avian life histories during the 50 years since the seminal publications of David Lack, Alexander Skutch, and Reginald Moreau, we still do not have adequate explanations for some of the basic patterns of variation in life-history traits among birds. In part, this reflects two consequences of the predominance of evolutionary ecology thinking during the past three decades. First, by blurring the distinction between life-history traits and life-table variables, we have tended to divorce life histories from their environmental context, which forms the link between the life history and the life table. Second, by emphasizing constrained evolutionary responses to selective factors, we have set aside alternative explanations for observed correlations among life-history traits and life-table variables. Density-dependent feedback and independent evolutionary response to correlated aspects of the environment also may link traits through different mechanisms. Additionally, in some cases we have failed to evaluate quantitatively ideas that are compelling qualitatively, ignored or explained away relevant empirical data, and neglected logical implications of certain compelling ideas. Comparative analysis of avian life histories shows that species are distributed along a dominant slow-fast axis. Furthermore, among birds, annual reproductive rate and adult mortality are directly proportional to each other, requiring that pre-reproductive survival is approximately constant. This further implies that age at maturity increases dramatically with increasing adult survival rate. The significance of these correlations is obscure, particularly because survival and reproductive rates at each age include the effects of many life-history traits. For example, reproductive rate is determined by clutch size, nesting success, season length, and nest-cycle length, each of which represents the outcome of many different interactions of an individual's life-history traits with its environment. Resolution of the most basic issues raised by patterns of life histories clearly will require innovative empirical, modeling, and experimental approaches. However, the most fundamental change required at this time is a broadening of the evolutionary ecology paradigm to include a variety of alternative mechanisms for generating patterns of life-history variation.

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Sex-specific pace-of-life syndromes

Behavioral Ecology ◽

10.1093/beheco/arz055 ◽

2019 ◽

Vol 30 (4) ◽

pp. 1096-1105 ◽

Cited By ~ 2

Author(s):

Joe A Moschilla ◽

Joseph L Tomkins ◽

Leigh W Simmons

Keyword(s):

Life History ◽

Metabolic Rate ◽

Risk Taking ◽

Life History Traits ◽

Significant Negative Correlation ◽

Covariance Structures ◽

Field Crickets ◽

Pace Of Life ◽

Specific Trait ◽

Trait Covariance

Abstract The pace-of-life syndrome (POLS) hypothesis considers an animal’s behavior, physiology, and life history as nonindependent components of a single integrated phenotype. However, frequent deviations from the expected correlations between POLS traits suggest that these relationships may be context, and potentially, sex dependent. To determine whether the sexes express distinct POLS trait covariance structures, we observed the behavior (mobility, latency to emerge from a shelter), physiology (mass-specific metabolic rate), and life history (life span, development time) of male and female Australian field crickets (Teleogryllus oceanicus). Path analysis modeling suggested that POLS trait covariation differed between the sexes. Although neither sex displayed the complete integration of traits predicted by the POLS hypothesis, females did display greater overall integration with a significant negative correlation between metabolic rate and risk-taking behavior but with life-history traits varying independently. In males, however, there was no clear association between traits. These results suggest that T. oceanicus do indeed display sex-specific trait covariance structures, emphasizing the importance of acknowledging sex in assessments of POLS.

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Variability of breeding resource partitioning in a lacertid lizard at field scale

Animal Biology ◽

10.1163/15707563-00002523 ◽

2017 ◽

Vol 67 (2) ◽

pp. 81-92

Author(s):

Marta Biaggini ◽

Claudia Corti

Keyword(s):

Life History ◽

Human Activities ◽

Life History Traits ◽

Environmental Variability ◽

Egg Mass ◽

Life History Variation ◽

Field Scale ◽

Starting Point ◽

Intensively Managed ◽

The Impact

Human activities cause increasingly deep alterations to natural environments. Yet, the effects on vertebrates with low dispersal capacity are still poorly investigated, especially at field scale. Life history variation represents one means by which species can adapt to a changing environment. Among vertebrates, lizards exhibit a high degree of variation in life-history traits, often associated with environmental variability. We examined the female breeding output ofPodarcissiculus(Lacertidae) inside agricultural habitats, to test whether different cultivation and management influence the life-history traits of this species. Interestingly, we recorded variability of female breeding output at a very fine scale, namely among adjacent vineyards and olive orchards under different management levels. Lizards displayed the lowest breeding effort in the almost unmanaged sites, while clutch mass, relative fecundity and mean egg mass slightly increased in more intensively managed sites. However, in the most intensive cultivations we detected a life-history trade-off, where eggs from larger clutches tended to be relatively smaller than eggs from smaller clutches. This pattern suggests that agriculture can influence lizard reproductive output, partly favouring it in the presence of medium intensity cultivation but causing, in the most intensively managed sites, some environmental constraints that require a peculiar partitioning of the breeding resources. Even though further studies are needed to clarify the mechanisms driving the observed pattern, our results can be considered a starting point for evaluating the analysis of lizard breeding features as a tool to assess the impact of human activities, at least in agricultural environments.

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The Evolution of Life History Parameters in Teleosts

Canadian Journal of Fisheries and Aquatic Sciences ◽

10.1139/f84-114 ◽

1984 ◽

Vol 41 (6) ◽

pp. 989-1000 ◽

Cited By ~ 253

Author(s):

Derek A. Roff

Keyword(s):

Growth Rate ◽

Life History ◽

Life History Theory ◽

Larval Survival ◽

Reasonable Assumption ◽

Natural Mortality ◽

Age At First Reproduction ◽

Life History Parameters ◽

First Case ◽

First Reproduction

Empirical studies have shown that in teleosts there is a significant correlation between the life history parameters, age at first reproduction, natural mortality, and growth rate. In this paper 1 hypothesize that these correlations are the result of evolutionary adjustments due to the trade-off between reproduction, growth, and survival. A simple and reasonable assumption is that the costs of reproduction are sufficient to cause the ltmt function to decrease. A simple expression relating the age at first reproduction is derived from this assumption. This formula accounts for a statistically significant portion (60.6%) of the variation in age at first reproduction in 30 stocks of fish. To extend the model to predict the distribution of life history parameters across all teleosts, an explicit cost function is incorporated. The model is analyzed with respect to two fitness measures, the expected lifetime fecundity and malthusian parameter, r. In the first case it is shown that the optimal age at maturity, T, depends only on the natural mortality rate (M) and the growth rate (k). In the second case, T is a function of k and the logarithm of a parameter, In C; the latter is a product of egg and larval survival, maximum body length (Lx), and the proportionality coefficient of the fecundity/length function. Difficulties of measuring egg and larval survival make the testing of the latter case difficult for particular species. However, this method provides a simple formula for the computation of r; this is shown generally to be approximately zero, thereby adding strength to the assumptions of the first analysis. The distribution patterns of T on k and M on k are predicted and compared with the observed pattern. In general, the predictions are validated: however, certain combinations of k and ln C are shown to occur very infrequently. The prediction of such "empty" regions of the parameter space remains a challenge for future development of life history theory.

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Life history variation in plants: an exploration of the fast-slow continuum hypothesis

Philosophical Transactions of the Royal Society B Biological Sciences ◽

10.1098/rstb.1996.0117 ◽

1996 ◽

Vol 351 (1345) ◽

pp. 1341-1348 ◽

Cited By ~ 113

Keyword(s):

Life History ◽

Life Histories ◽

Sexual Maturity ◽

Life History Traits ◽

Continuum Hypothesis ◽

Adult Mortality ◽

Life Cycles ◽

Differential Mortality ◽

Life History Variation ◽

Net Reproductive Rate

Several empirical models have attempted to account for the covariation among life history traits observed in a variety of organisms. One of these models, the fast-slow continuum hypothesis, emphasizes the role played by mortality at different stages of the life cycle in shaping the large array of life history variation. Under this scheme, species can be arranged from those suffering high adult mortality levels to those undergoing relatively low adult mortality. This differential mortality is responsible for the evolution of contrasting life histories on either end of the continuum. Species undergoing high adult mortality are expected to have shorter life cycles, faster development rates and higher fecundity than those experiencing lower adult mortality. The theory has proved accurate in describing the evolution of life histories in several animal groups but has previously not been tested in plants. Here we test this theory using demographic information for 83 species of perennial plants. In accordance with the fast-slow continuum, plants undergoing high adult mortality have shorter lifespans and reach sexual maturity at an earlier age. However, demographic traits related to reproduction (the intrinsic rate of natural increase, the net reproductive rate and the average rate of decrease in the intensity of natural selection on fecundity) do not show the covariation expected with longevity, age at first reproducion and life expectancy at sexual maturity. Contrary to the situation in animals, plants with multiple meristems continuously increase their size and, consequently, their fecundity and reproductive value. This may balance the negative effect of mortality on fitness, thus having no apparent effect in the sign of the covariation between these two goups of life history traits.

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