Lifetime fitness and changing life history traits in Red-cockaded Woodpeckers

Garcia, Victoria

22 December 2014

As environmental change continues and increases, understanding how species will respond to change and how these responses may affect populations will be important for conserving and managing species. Red-cockaded Woodpeckers (Picoides borealis) are well-studied and provide an ideal system in which to examine ecological and evolutionary questions related to life histories because monitoring them accurately is relatively easy, their behavior is well-described and structured. In this study, I examined the following questions using long-term data (1980-2013) from two study sites in North Carolina: 1) what traits contribute most to lifetime fitness, 2) how have traits changed over time and how is climate change influencing life history, and 3) to what extent are traits that contribute to fitness and that are changing over time heritable in this species. I found that a multitude of factors contribute to different aspects of fitness, including: parental age and hatch date affecting survival to year one and probability of attaining breeding status; and lay date, clutch size, age at first reproduction, and variance in clutch size affecting lifetime fitness. I also found that many traits were changing over time including lay date, clutch size, partial brood loss, and survival to year one. These traits were strongly influenced by local climate variables at each study site, but it is not clear that climate has changed over time at the study sites to account for all the observed changes in life history traits. Habitat improvement has also played a role as evidenced by increased fledgling production in terms of raw numbers (without accounting for covariates). I also found that lay date, clutch size, and partial brood loss had low heritabilities after accounting for other random and fixed effects. These results indicate that Red-cockaded Woodpeckers at these two study sites are shifting traits successfully in response to changing conditions, and that these changes are in the direction that increases aspects of fitness. These shifts indicate that individuals are plastic with respect to these traits, but most of the variance in traits was related to external habitat-associated factors rather than additive genetic variance or environmental × genotype interactions. / Ph. D.

individual fitness

lifetime reproductive success

inbreeding

climate change

animal model

Inbreeding avoidance and the effects of inbreeding on adult prairie voles (<i>Microtus ochrogaster</i>)

Lucia, Kristen E.

16 August 2011

No description available.

Behavioral Sciences

Conservation

Ecology

Zoology

kin discrimination

kin recognition

inbreeding

inbreeding avoidance

lifetime reproductive success

parental care

Genetic, socio-ecological and fitness correlates of extra-group paternity in the European badger (Meles meles)

Annavi, Geetha

January 2012

The evolution of extra-group paternity (EGP) is a contentious issue in evolutionary biology. This thesis examines the factors and adaptive benefits driving EGP in a high-density, group-living population of European badgers (Meles meles). To improve power to assign parentage, I isolated and characterised 21 new polymorphic microsatellite markers. I genotyped 83% of 1410 badger trapped 1987‒2010 using 35 autosomal microsatellite markers. Maternity and paternity were assigned at 80% confidence ca. 82% of individuals. 48% of paternities were extra-group, where 85% were attributable to neighbouring-group males and EGP was detected in 47% of litters; thus badger social group do not correspond with a breeding unit. I tested whether indirect genetic benefits explain these high EGP rates. (1) ‘Good-gene-as-heterozygosity Hypothesis’: Paternal heterozygosity, but not maternal or an individual’s own heterozygosity, associated positively with first-year survival probability. Under benign environmental conditions, cubs fathered by more heterozygous males had a higher first year survival probability. Despite this correlation, the EGP rate per litter correlated with neither average nor maximum within-group heterozygosity of candidate fathers. (2) Fitness benefit Hypothesis: Extra-group offspring (EGO) had lower first-year survival probability and lived 1.3 years less than within-group offspring (WGO). Female WGO produced more litters and offspring over their lifetime than female EGO, whereas male EGO produced more offspring than male WGO. (3) Inbreeding avoidance hypothesis: The EGP rate within a litter increased with greater average pair-wise relatedness between mothers and within-group candidate fathers. No inbreeding depression on first-year survival probability was detected, but small sample sizes limited statistical power. Socio-ecologically, at the litter level, EGP correlated negatively with the number of within-group candidate fathers, and positively with neighbouring-group candidate fathers. In conclusion, EGP in badgers may reduce inbreeding and be maintained in the population through a sex-specific antagonistic selection and indirect genetic benefits may occur when the total fitness benefits of producing extra-group sons outweigh the costs of producing extra-group daughters. These indirect genetic benefits only partially explain the evolution of promiscuity in European badgers, highlighting that evolutionary factors underlying promiscuity remain unclear.

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