Emu Emu Society
Journal of BirdLife Australia
RESEARCH ARTICLE

Breeding biology and life-history traits of an Australasian tropical granivore, the Crimson Finch (Neochmia phaeton)

Olga Milenkaya A D , Sarah Legge B C and Jeffrey R. Walters A
+ Author Affliations
- Author Affliations

A Department of Biological Sciences, Virginia Polytechnic Institute and State University, Blacksburg, VA 24061, USA.

B Australian Wildlife Conservancy, Mornington Wildlife Sanctuary, PMB 925, Derby, WA 6728, Australia.

C School for Environmental Research, Charles Darwin University, Darwin, NT 0909, Australia.

D Corresponding author. Email: olm@vt.edu

Emu 111(4) 312-320 https://doi.org/10.1071/MU10088
Submitted: 8 December 2010  Accepted: 30 March 2011   Published: 13 October 2011

Abstract

The evolutionary basis of the latitudinal gradient in clutch-size is a major, unresolved question in life-history theory, the resolution of which is hampered by the lack of proportionate study of southern passerines. Here, we present detailed data on breeding biology and life history for an Australasian tropical granivore, the Crimson Finch (Neochmia phaeton), emphasising aspects of their life history that are atypical of southern passerines. We collected data over three breeding seasons at Mornington Wildlife Sanctuary in north-western Australia. Apparent annual survival of adults was high, at 70–96%. Crimson Finches were multi-brooded and laid 5.08 ± 0.07 eggs per clutch. The rate of nest predation was high, with 59.7% of clutches lost to predation. Thus, Crimson Finch life history contradicts the leading explanation of the clutch-size gradient – that higher rates of nest predation and higher adult survival in southern species select for smaller clutch-sizes. Our findings are more consistent with other explanations of the clutch-size gradient, specifically those involving post-fledging parental care, diet, seasonality and phylogeny. Exploring life histories that differ from the norm may be particularly helpful in understanding latitudinal differences in these strategies.


References

Anders, A. D., and Marshall, M. R. (2005). Increasing the accuracy of productivity and survival estimates in assessing landbird population status. Conservation Biology 19, 66–74.
Increasing the accuracy of productivity and survival estimates in assessing landbird population status.CrossRef | open url image1

Arnaiz-Villena, A., Ruiz-del-Valle, V., Gomez-Prieto, P., Reguera, R., Parga-Lozano, C., and Serrano-Vela, I. (2009). Estrildinae finches (Aves, Passeriformes) from Africa, South Asia and Australia: a molecular phylogeographic study. Open Ornithology Journal 2, 29–36.
Estrildinae finches (Aves, Passeriformes) from Africa, South Asia and Australia: a molecular phylogeographic study.CrossRef | 1:CAS:528:DC%2BD1MXhtFeksr7K&md5=88ab6271538e385511789e5e6985a0f8CAS | open url image1

Arnqvist, G., and Kirpatrick, M. (2005). The evolution of infidelity in socially monogamous passerines: the strength of direct and indirect selection on extrapair copulation behavior in females. American Naturalist 165, S26–S37.
The evolution of infidelity in socially monogamous passerines: the strength of direct and indirect selection on extrapair copulation behavior in females.CrossRef | open url image1

Ashmole, N. P. (1963). The regulation of numbers of tropical oceanic birds. Ibis 103, 458–473. open url image1

Auer, S. K., Bassar, R. D., and Martin, T. E. (2007). Biparental incubation in the Chestnut-vented Tit-babbler Parisoma subcaeruleum: mates devote equal time, but males keep eggs warmer. Journal of Avian Biology 38, 278–283. open url image1

Birkhead, T. R., and Møller, A. P. (1992). Numbers and size of sperm storage and the duration of sperm storage in birds – a comparative study. Biological Journal of the Linnean Society 45, 363–372.
Numbers and size of sperm storage and the duration of sperm storage in birds – a comparative study.CrossRef | open url image1

Briskie, J. V. (1993). Anatomical adaptations to sperm competition in Smiths Longspurs and other polygynandrous passerines. Auk 110, 875–888. open url image1

Carvalho, C. B. V., Macedo, R. H., and Graves, J. A. (2006). Breeding strategies of a socially monogamous neotropical passerine: extra-pair fertilizations, behavior, and morphology. Condor 108, 579–590.
Breeding strategies of a socially monogamous neotropical passerine: extra-pair fertilizations, behavior, and morphology.CrossRef | open url image1

Choudhury, S. (1995). Divorce in birds: a review of the hypotheses. Animal Behaviour 50, 413–429.
Divorce in birds: a review of the hypotheses.CrossRef | open url image1

Ferretti, V., Llambias, P. E., and Martin, T. E. (2005). Life-history variation of a neotropical thrush challenges food limitation theory. Proceedings of the Royal Society of London. Series B. Biological Sciences 272, 769–773.
Life-history variation of a neotropical thrush challenges food limitation theory.CrossRef | open url image1

Flores, S., and Dezzeo, N. (2005). Temporal variations in soil seed number and in seed rain in a forest-savanna sequence in the Gran Sabana, Venezuela. Interciencia 30, 39–43. open url image1

Garamszegi, L. Z., Eens, M., Hurtrez-Bousses, S., and Møller, A. P. (2005). Testosterone, testes size, and mating success in birds: a comparative study. Hormones and Behavior 47, 389–409.
Testosterone, testes size, and mating success in birds: a comparative study.CrossRef | 1:CAS:528:DC%2BD2MXitlCjt7w%3D&md5=d49ef843da3f71845612e960ab229edbCAS | open url image1

Ghalambor, C. K., and Martin, T. E. (2001). Fecundity-survival trade-offs and parental risk-taking in birds. Science 292, 494–497.
Fecundity-survival trade-offs and parental risk-taking in birds.CrossRef | 1:CAS:528:DC%2BD3MXjtVenurw%3D&md5=1e065b50b7b53b1a50138ae9b1d70d76CAS | open url image1

Gill, F. B. (2003). ‘Ornithology.’ 2nd edn. (Freeman: New York.)

Griebeler, E. M., and Böhning-Gaese, K. (2004). Evolution of clutch size along latitudinal gradients: revisiting Ashmole’s hypothesis. Evolutionary Ecology Research 6, 679–694. open url image1

Griebeler, E. M., Caprano, T., and Böhning-Gaese, K. (2010). Evolution of avian clutch size along latitudinal gradients: do seasonality, nest predation or breeding season length matter? Journal of Evolutionary Biology 23, 888–901.
Evolution of avian clutch size along latitudinal gradients: do seasonality, nest predation or breeding season length matter?CrossRef | 1:STN:280:DC%2BC3cvpt12gtQ%3D%3D&md5=ccd82b6b47d7b6b6c6dd403c17b4f2ceCAS | open url image1

Griffith, S. C. (2007). The evolution of infidelity in socially monogamous passerines: neglected components of direct and indirect selection. American Naturalist 169, 274–281.
The evolution of infidelity in socially monogamous passerines: neglected components of direct and indirect selection.CrossRef | open url image1

Griffith, S. C., Owens, I. P. F., and Thuman, K. A. (2002). Extra pair paternity in birds: a review of interspecific variation and adaptive function. Molecular Ecology 11, 2195–2212.
Extra pair paternity in birds: a review of interspecific variation and adaptive function.CrossRef | 1:CAS:528:DC%2BD38XptlSmurY%3D&md5=3faadbe936f4250b630eb32581214a9cCAS | open url image1

Higgins, P. J., Peter, J. M., and Cowling, S. J. (Eds) (2006). ‘Handbook of Australian, New Zealand and Antarctic Birds. Vol. 7: Boatbill to Starlings.’ (Oxford University Press: Melbourne.)

Immelmann, K. (1982). ‘Australian Finches in Bush and Aviary.’ (Angus & Robertson Publishers: London.)

Jetz, W., Sekercioglu, C. H., and Böhning-gaese, K. (2008). The worldwide variation in avian clutch size across species and space. PLoS Biology 6, e303.
The worldwide variation in avian clutch size across species and space.CrossRef | open url image1

Johnston, J. P., Peach, W. J., Gregory, R. D., and White, S. A. (1997). Survival rates of tropical and temperate passerines: a Trinidadian perspective. American Naturalist 150, 771–789.
Survival rates of tropical and temperate passerines: a Trinidadian perspective.CrossRef | 1:STN:280:DC%2BD1cnit1yitw%3D%3D&md5=e5271ce1ed6b9d264e400b49a387aa6cCAS | open url image1

Johnstone, R. E., and Smith, L. A. (1981). Birds of Mitchell Plateau and adjacent coasts and lowland, Kimberley, Western Australia. In ‘Biological Survey of Mitchell Plateau and Admiralty Gulf, Kimberley, Western Australia’. pp. 171–214. (Western Australian Museum: Perth.)

Karr, J. R., Nichols, J. D., Klimkiewiez, M. K., and Brawn, J. D. (1990). Survival rates of birds of tropical and temperate forests: will the dogma survive? American Naturalist 136, 277–291.
Survival rates of birds of tropical and temperate forests: will the dogma survive?CrossRef | open url image1

Kempenaers, B. (1993). The use of a breeding synchrony index. Ornis Scandinavica 24, 84–84.
The use of a breeding synchrony index.CrossRef | open url image1

Lack, D. (1947). The significance of clutch-size. Ibis 89, 302–352.
The significance of clutch-size.CrossRef | open url image1

Lack, D. (1948). The significance of clutch-size. Part III. Some interspecific comparisons. Ibis 90, 25–45.
The significance of clutch-size. Part III. Some interspecific comparisons.CrossRef | open url image1

Lack, D. (1949). Comments on Mr. Skutch’s paper on clutch-size. Ibis 91, 455–458.
Comments on Mr. Skutch’s paper on clutch-size.CrossRef | open url image1

MacArthur, R. H. (1964). Environmental factors affecting bird species diversity. American Naturalist 98, 387–397.
Environmental factors affecting bird species diversity.CrossRef | open url image1

Martin, T. E. (1995). Avian life history evolution in relation to nest sites, nest predation, and food. Ecological Monographs 65, 101–127.
Avian life history evolution in relation to nest sites, nest predation, and food.CrossRef | open url image1

Martin, T. E. (1996). Life history evolution in tropical and southern temperate birds: what do we really know? Journal of Avian Biology 27, 263–272.
Life history evolution in tropical and southern temperate birds: what do we really know?CrossRef | open url image1

Martin, T. E. (2004). Avian life-history evolution has an eminent past: does it have a bright future? Auk 121, 289–301.
Avian life-history evolution has an eminent past: does it have a bright future?CrossRef | open url image1

Martin, T. E., and Briskie, J. V. (2009). Predation on dependent offspring: a review of the consequences for mean expression and phenotypic plasticity in avian life history traits. Annals of the New York Academy of Sciences 1168, 201–217.
Predation on dependent offspring: a review of the consequences for mean expression and phenotypic plasticity in avian life history traits.CrossRef | open url image1

Martin, T. E., Martin, P. R., Olson, C. R., Heidinger, B. J., and Fontaine, J. J. (2000). Parental care and clutch sizes in North and South American birds. Science 287, 1482–1485.
Parental care and clutch sizes in North and South American birds.CrossRef | 1:CAS:528:DC%2BD3cXhsV2qt7c%3D&md5=8ca70561ce01b464c868afe5a7d8e0f9CAS | open url image1

McGregor, R., Whittingham, M. J., and Cresswell, W. (2007). Survival rates of tropical birds in Nigeria, West Africa. Ibis 149, 615–618.
Survival rates of tropical birds in Nigeria, West Africa.CrossRef | open url image1

Moreau, R. E. (1944). Clutch-size: a comparative study with special reference to African birds. Ibis 86, 286–347.
Clutch-size: a comparative study with special reference to African birds.CrossRef | open url image1

Owens, I. P. F., and Bennett, P. M. (1995). Ancient ecological diversification explains life-history variation among living birds. Proceedings of the Royal Society of London. Series B. Biological Sciences 261, 227–232.
Ancient ecological diversification explains life-history variation among living birds.CrossRef | open url image1

Payne, R. B. (2005). ‘Nestling Mouth Markings and Colors of Old World Finches Estrildidae: Mimicry and Coevolution of Nestling Finches and Their Vidua Brood Parasites.’ (University of Michigan Museum of Zoology: Ann Arbor, MI.)

Peach, W. J., Hanmer, D. B., and Oatley, T. B. (2001). Do southern African songbirds live longer than their European counterparts? Oikos 93, 235–249.
Do southern African songbirds live longer than their European counterparts?CrossRef | open url image1

Pyle, P. (1997). ‘Identification Guide to North American Birds. Part I.’ (Slate Creek Press: Bolinas, CA, USA.)

Ricklefs, R. E. (2000). Density dependence, evolutionary optimization, and the diversification of avian life histories. Condor 102, 9–22.
Density dependence, evolutionary optimization, and the diversification of avian life histories.CrossRef | open url image1

Roff, D. A. (1992). ‘The Evolution of Life Histories.’ (Chapman & Hall: New York.)

Rowley, I., and Russell, E. (1991). Demography of passerines in the temperate southern hemisphere. In ‘Bird Population Studies: Relevance to Conservation and Management’. (Eds C. M. Perrins, J. D. Lebreton and G. J. M. Hirons.) pp. 22–44. (Oxford University Press: Oxford, MA.)

Russell, E. M., Yom-Tov, Y., and Geffen, E. (2004). Extended parental care and delayed dispersal: northern, tropical, and southern passerines compared. Behavioral Ecology 15, 831–838.
Extended parental care and delayed dispersal: northern, tropical, and southern passerines compared.CrossRef | open url image1

Sankamethawee, W., Gale, G. A., and Hardesty, B. D. (2009). Post-fledgling survival of the cooperatively breeding Puff-throated Bulbul (Alophoixus pallidus). Condor 111, 675–683.
Post-fledgling survival of the cooperatively breeding Puff-throated Bulbul (Alophoixus pallidus).CrossRef | open url image1

Shephard, M. (1989). ‘Aviculture in Australia: Keeping and Breeding Aviary Birds.’ (Black Cockatoo Press:. Melbourne.)

Skutch, A. F. (1985). Clutch size, nesting success, and predation on nests of neotropical birds. Ornithological Monographs 36, 575–594. open url image1

Slagsvold, T. (1982). Clutch size variation in passerine birds: the nest predation hypothesis. Oecologia 54, 159–169.
Clutch size variation in passerine birds: the nest predation hypothesis.CrossRef | open url image1

Stearns, S. C. (1992). ‘The Evolution of Life Histories.’(Oxford University Press: New York.)

Storr, G. M. (1977). Birds of the Northern Territory. Special Publication 7. Western Australian Museum, Perth.

Stutchbury, B. J. M. (1998). Breeding synchrony best explains variation in extra-pair mating system among avian species. Behavioral Biology and Sociobiology 43, 221–222.
Breeding synchrony best explains variation in extra-pair mating system among avian species.CrossRef | open url image1

Styrsky, J. N., Brawn, J. D., and Robinson, S. K. (2005). Juvenile mortality increases with clutch size in a neotropical bird. Ecology 86, 3238–3244.
Juvenile mortality increases with clutch size in a neotropical bird.CrossRef | open url image1

Todd, M. K. (2002). Nest-site and breeding-season data for the Crimson Finch Neochmia phaeton in Australia. Australian Bird Watcher 19, 161–171. open url image1

Todd, M. K., Felton, A., and Garnett, S. T. (2003). Morphological and dietary differences between common and uncommon subspecies of Crimson Finch, Neochmia phaeton, and Star Finch, Neochmia ruficauda, in northern Australia. Emu 103, 141–148.
Morphological and dietary differences between common and uncommon subspecies of Crimson Finch, Neochmia phaeton, and Star Finch, Neochmia ruficauda, in northern Australia.CrossRef | open url image1

Vriends, M. M., and Heming-Vriends, T. M. (2002). ‘Hancock House Encyclopedia of Estrildid Finches.’ (Hancock House Publishers: Surrey, BC, Canada.)

Webb, E. H. (1902). A singular nesting site. Emu 2, 29. open url image1

White, G. C., and Burnham, K. P. (1999). Program MARK: survival estimation from populations of marked animals. Bird Study 46, 120–139.
Program MARK: survival estimation from populations of marked animals.CrossRef | open url image1

Williams, P. R., Congdon, R. A., Grice, A. C., and Clarke, P. J. (2005). Germinable soil seed banks in a tropical savanna: seasonal dynamics and effects of fire. Austral Ecology 30, 79–90.
Germinable soil seed banks in a tropical savanna: seasonal dynamics and effects of fire.CrossRef | open url image1

Wyndham, E. (1986). Length of birds’ breeding seasons. American Naturalist 128, 155–164.
Length of birds’ breeding seasons.CrossRef | open url image1

Yom-Tov, Y. (1987). The reproductive rates of Australian passerines. Australian Wildlife Research 14, 319–330.
The reproductive rates of Australian passerines.CrossRef | open url image1

Yom-Tov, Y., McCleery, R., and Purchase, D. (1992). The survival rate of Australian passerines. Ibis 134, 374–379.
The survival rate of Australian passerines.CrossRef | open url image1


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