Environmental Variability, Life-History Covariation and Cohort Effects in the Red-Billed Chough Pyrrhocorax pyrrhocorax

• Published in: The Journal of animal ecology Vol. 72; no. 1; pp. 36 - 46
• Main Authors: Reid, J. M., Bignal, E. M., Bignal, S., McCracken, D. I., Monaghan, P.
• Format: Journal Article
• Language: English
• Published: Oxford, UK British Ecological Society 01.01.2003; Blackwell Science Ltd; Blackwell; Blackwell Publishing Ltd
• Subjects: Animal and plant ecology; Animal ecology; Animal, plant and microbial ecology; Animals; Aves; Biological and medical sciences; Breeding; Breeding seasons; delayed life history effects; Demecology; Ecological genetics; Ecological life histories; Environmental conservation; Fundamental and applied biological sciences. Psychology; Human ecology; life history evolution; Longevity; natal environment; parental investment; Phenotypic traits; reproductive performance; Reproductive success; silver spoon; Vertebrata; United Kingdom; Scotland; Great Britain; Europe; Life history; delayed life history effects; Environmental factor; Life history trait; life history evolution; natal environment; Birth place; Vertebrata; Reproduction; Cohort study; Breeding success; reproductive performance; Intraspecific comparison; Parental investment; Aves; Performance; silver spoon
• ISSN: 0021-8790; 1365-2656
• DOI: 10.1046/j.1365-2656.2003.00673.x

1. The consequences of environmental variability for life-history evolution are predicted to depend on the pattern of covariation amongst life-history traits. Using data from a 20-year study of individually marked red-billed choughs, we investigate the short- and long-term life-history consequences of population-wide variation in reproductive conditions, and demonstrate clear among-cohort variation and covariation in life-history parameters. 2. The mean number of offspring fledging per breeding event varied among years, and was correlated with environmental conditions (temperature and rainfall) during the months preceding breeding. As the variance in breeding performance did not differ among years and choughs did not miss breeding seasons, variation in environmental conditions affected the whole breeding population. Thus the quality of the chough's breeding environment varied amongst years. 3. Juvenile survival, the probability of recruitment to the breeding population and breeding longevity varied amongst cohorts, and these were positively correlated with the quality of the cohort's natal environment. Offspring fledging under good conditions were more likely to survive to breeding age and recruit, and had longer breeding lives than offspring fledging under poor conditions. 4. Age at first breeding varied amongst cohorts, and increased with population size at maturity rather than natal conditions. 5. The total number of offspring that recruits ultimately fledged varied primarily with breeding longevity rather than recruitment age. Thus, the consistent positive covariation amongst life-history traits meant that the total number of offspring fledged by recruits during their breeding life varied amongst cohorts, and was correlated with the quality of a cohort's natal conditions. Choughs fledging under good conditions themselves ultimately fledged more offspring. 6. Such environmentally determined variation in offspring fitness is expected to influence optimal patterns of parental investment. We discuss the predictions that environmental variability should select for investment in adult survival and for reduced reproductive effort in poor years.