Higher reproductive success of small males and greater recruitment of large females may explain strong reversed sexual dimorphism (RSD) in the northern goshawk
详细信息 查看全文
- 作者:L. Pérez-Camacho ; G. García-Salgado ; S. Rebollo ; S. Martínez-Hesterkamp…
- 关键词:Accipiter gentilis ; Bird of prey ; Body size ; Evolution ; Raptor
- 刊名:Oecologia
- 出版年:2015
- 出版时间:February 2015
- 年:2015
- 卷:177
- 期:2
- 页码:379-387
- 全文大小:298 KB
- 参考文献:1. Alerstam T, Rosén M, B?ckman J, Ericson PGP, Hellgren O (2007) Flight speeds among bird species: allometric and phylogenetic effects. PLoS Biol 5:1656-662. doi:10.1371/journal.pbio.0050197 CrossRef
2. Andersson M, Norberg RA (1981) Evolution of reversed sexual size dimorphism and role partitioning among predatory birds, with a size scaling of flight performance. Biol J Linn Soc 15:105-30 CrossRef
3. Bates D, Maechler M, Bolker B (2011) Lme4: linear mixed-effects models using S4 classes. R package version 0.999375-42. me4" class="a-plus-plus">http://CRAN.R-project.org/package=lme4
4. Bortolotti GR, Iko WM (1992) Non-random pairing in American kestrels: mate choice versus intra-sexual competition. Anim Behav 44:811-21 CrossRef
5. Byholm P (2005) Site-specific variation in partial brood loss in northern goshawks. Ann Zool Fenn 42:81-0
6. Byholm P, Rousi H, Sole I (2011) Parental care in nesting hawks: breeding experience and food availability influence the outcome. Behav Ecol 22:609-15 CrossRef
7. Carballeira A, Devesa C, Retuerto R, Santillán E, Ucieda F (1983) Bioclimatología de Galicia. Fundación Pedro Barrié de la Maza Conde de Fenosa, La Coru?a
8. Cramp S, Simmons KEL (1980) The birds of the western Palearctic, vol 2. Oxford University Press, Oxford
9. Figuerola J (1999) A comparative study on the evolution of reversed size dimorphism in monogamous waders. Biol J Linn Soc 67:1-8 CrossRef
10. Hakkarainen H, Korpim?ki E (1991) Reversed sexual size dimorphism in Tengmalm’s owl: is small male size adaptive? Oikos 61:337-46 CrossRef
11. Hakkarainen H, Huhta E, Lahti K, Lundvall P, Mappes T, Tolonen P, Wiehn J (1996) A test of male mating and hunting success in the kestrel: the advantages of smallness. Behav Ecol Sociobiol 39:375-80 CrossRef
12. Johnston RF, Janiga R (1995) The feral pigeon. Oxford University Press, New York
13. Kenward RE (2006) The northern goshawk. T & AD Poyser/A & C Black, London
14. Kostrzewa A, Kostrzewa R (1990) The relationship of spring and summer weather with density and breeding performance of the buzzard / Buteo buteo, goshawk / Accipiter gentilis and kestrel / Falco tinnunculus. Ibis 132:550-59 CrossRef
15. Krüger O (2005) The evolution of reversed sexual size dimorphism in hawks, falcons and owls: a comparative study. Evol Ecol 19:467-86 CrossRef
16. Krüger O, Chakarov N, Nielsen JT, Looft V, Grunkorn T, Struwe-Juhl B, Moller AP (2012) Population regulation by habitat heterogeneity or individual adjustment? J Anim Ecol 81:330-40 CrossRef
17. Ma?osa S (1991) Biologia tròfica, ús de l'hàbitat i biologia de la reproducció de l'astor / Accipiter gentilis (Linneaus, 1758) a La Segarra. Ph.D. dissertaion. Department of Animal Biology, University of Barcelona, Barcelona. http://hdl.handle.net/2445/35908
18. Ma?osa S (1994) Sex and age determination in nestling goshawks / Accipiter gentilis. Butlleti del Grup Catala d'Anellament 11:1-
19. Massemin S, Korpimaki E, Wiehn J (2000) Reversed sexual dimorphism in raptors: evaluation of the hypotheses in kestrels breeding in a temporally changing environment. Oecologia 124:26-2 CrossRef
20. McDonald PG, Olsen PD, Cockburn A (2005) Selection on body size in a raptor with pronounced reversed sexual size dimorphism: are bigger females better? Behav Ecol 16:48-6 medical and Life Sciences - 刊物主题:Life Sciences
Ecology
Plant Sciences - 出版者:Springer Berlin / Heidelberg
- ISSN:1432-1939
文摘
Reversed sexual dimorphism (RSD), which occurs when the female of a species is larger than the male, is the rule for most birds of prey but the exception among other bird and mammal species. The selective pressures that favour RSD are an intriguing issue in animal ecology. Despite the large number of hypotheses proposed to explain the evolution of RSD, there is still no consensus about the mechanisms involved and whether they act on one or both sexes, mainly because few intrapopulation studies have been undertaken and few raptor species have been investigated. Using the strongly size-dimorphic northern goshawk (Accipiter gentilis L.) as a model, we studied a population with one of the highest densities of breeding pairs reported in the literature in order to understand selective pressures that may favour RSD. We evaluated life-history processes, including recruitment of adult breeders and reproductive success, and we explored the mechanisms thought to act on each sex, including hunting efficiency, diet, body condition and mate choice. We found that smaller males produced more fledglings than larger ones, but there was no relationship between size and reproductive success for females. The mean body size of female breeders was larger than that of female fledglings, but male fledglings and breeders did not differ in size. Male body size was related to the type but not to the amount of prey captured during the nestling stage. We conclude that RSD may be favoured in this goshawk population because small males tend to enjoy higher reproductive success and large females greater recruitment. Our results do not support the hypotheses that evolutionary reduction in male size is driven by hunting efficiency, at least during the nestling stage, or the hypotheses that it is driven by greater recruitment. Our findings also suggest that increase in female size is driven by recruitment, rather than by reproductive success as previously postulated.