Free Standard AU & NZ Shipping For All Book Orders Over $80!
Register      Login
Emu Emu Society
Journal of BirdLife Australia
RESEARCH ARTICLE

Annual, sexual, size- and condition-related variation in the colour and fluorescent pigment content of yellow crest-feathers in Snares Penguins (Eudyptes robustus)

Kevin J. McGraw A D , Melanie Massaro B C , Trevor J. Rivers A and Thomas Mattern B
+ Author Affiliations
- Author Affiliations

A School of Life Sciences, Arizona State University, Tempe, AZ 85287-4501, USA.

B Department of Zoology, University of Otago, PO Box 56, Dunedin, New Zealand.

C Present address: School of Biological Sciences, University of Canterbury, Private Bag 4800, Christchurch, New Zealand.

D Corresponding author. Email: kevin.mcgraw@asu.edu

Emu 109(2) 93-99 https://doi.org/10.1071/MU08034
Submitted: 11 July 2008  Accepted: 8 December 2008   Published: 26 May 2009

Abstract

Colourful plumages observed in many birds provide ideal systems for investigating the control and function of animal signals, because we can identify the molecular currency (e.g. pigments, tissue structures) and thus the challenges associated with the production of the trait. To date, most attention has been paid to the signalling costs and benefits of the common pigmentary (e.g. carotenoid- and melanin-based) plumage colours. However, in penguins, the colour of feathers of crests or patches of head plumage is based on an unusual fluorescent pigment, presently thought to be in the class of pterin pigments, which are typically found as colourants in other animals like butterflies and amphibians. These yellow-orange colours may be used in sexual or social communication, but to date little is known about the signalling potential of such ornaments. We collected yellow crest-feathers from adult male and female Snares Penguins (Eudyptes robustus) in two years (2002 and 2003) and examined differences in colour and pigment content as a function of year, sex, body size and body condition. Unlike the typical pattern of birds, crests of female Snares Penguins contained higher concentrations of pigments than those of males. In both years, yellower feathers in females contained more yellow pigment. Birds of both sexes grew yellower and more pigment-rich feathers in 2002 – a year in which birds were in better condition – than in 2003. Males with yellower crests also tended to be larger, heavier and in better condition, regardless of year. These results highlight the potential for yellow crests in Snares Penguins to serve as a condition-dependent indicator to conspecifics. Further work is needed to determine whether or not this plumage trait is a signal of social status or attractiveness, as colourful plumage patches appear to be in other penguin species.


Acknowledgements

This study was approved by the New Zealand (NZ) Department of Conservation and the University of Otago Animal Ethics Committee and complies with the current laws of NZ. In particular, we thank the Southland Conservancy from the Department of Conservation for support and permits. We are grateful to L. Davis, who helped with obtaining working permits. We also thank D. Houston, U. Ellenberg, and A. Setiawan for help in the field; M. Toomey for input on analyses of feather pigment; and R. Phillips, K. Buchanan, F. S. Dobson and four anonymous referees for helpful comments on the manuscript. Field trips to the Snares Islands were financially supported by the Yellow-eyed Penguin Trust and the University of Otago. During manuscript preparation, funding was provided to KJM and TJR by the School of Life Sciences and College of Liberal Arts and Sciences at Arizona State University and to MM by the New Zealand Foundation for Research, Science, and Technology.


References

Amundsen, T. (2000). Why are female birds ornamented? Trends in Ecology & Evolution 15, 149–155.
Crossref | GoogleScholarGoogle Scholar | Andersson M. (1994). ‘Sexual Selection.’ (Princeton University Press: Princeton, NJ.)

Bradford-Grieve, J. M. , Probert, P. K. , Nodder, S. N. , Thompson, D. , Hall, J. , Hanchet, S. , Boyd, P. , Zeldis, J. , Baker, A. N. , Best, H. A. , Broekhuizen, N. , Childerhouse, S. , Clark, M. , Hadfield, M. , Safi, K. , and Wilkinson, I. (2003). Pilot trophic model for subantarctic water over the Southern Plateau, New Zealand: a low biomass, high transfer efficiency system. Journal of Experimental Marine Biology and Ecology 289, 223–262.
Crossref | GoogleScholarGoogle Scholar | Dale J. (2006). Intraspecific variation in coloration, In ‘Bird Coloration. Vol. II. Function and Evolution’. (Eds G. E. Hill and K. J. McGraw.) pp. 36–86. (Harvard University Press: Cambridge, MA.)

Dobson, F. S. , Nolan, P. M. , Nicolaus, M. , Bajzak, C. , Coquel, A. S. , and Jouventin, P. (2008). Comparison of color and body condition between early and late breeding king penguins. Ethology 114, 925–933.
Crossref | GoogleScholarGoogle Scholar | Hill G. E. , and McGraw K. J. (2006a). ‘Bird Coloration. Vol. I. Mechanisms and Measurements.’ (Harvard University Press: Cambridge, MA.)

Hill G. E. , and McGraw K. J. (2006b). ‘Bird Coloration. Vol. II. Function and Evolution.’ (Harvard University Press: Cambridge, MA.)

Jones, I. L. , and Hunter, F. M. (1999). Experimental evidence for mutual inter- and intrasexual selection favouring a crested auklet ornament. Animal Behaviour 57, 521–528.
Crossref | GoogleScholarGoogle Scholar | PubMed | Jouventin P. (1982). ‘Visual and Vocal Signals in Penguins, Their Evolution and Adaptive Characters.’ (Paul Parey: Berlin.)

Jouventin, P. , Nolan, P. M. , Ornborg, J. , and Dobson, F. S. (2005). Ultraviolet beak spots in King and Emperor Penguins. Condor 107, 144–150.
Crossref | GoogleScholarGoogle Scholar | Ligon J. D. (1999). ‘The Evolution of Avian Breeding Systems.’ (Oxford University Press: Oxford, UK.)

Linville, S. U. , and Breitwisch, R. (1997). Carotenoid availability and plumage coloration in a wild population of northern cardinals. Auk 114, 796–800.
Mattern T. (2006). Marine ecology of offshore and inshore foraging penguins: the Snares penguin Eudyptes robustus and Yellow-eyed penguin Megadyptes antipodes. Ph.D. Thesis, University of Otago, Dunedin, New Zealand.

McGraw, K. J. (2004). Not all red, orange, and yellow animal colors are carotenoid-based: the need to couple biochemical and behavioral studies of color signals. Proceedings of the Indian National Science Academy B 70, 593–598.
Montgomerie R. (2006). Analyzing colors. In ‘Bird Coloration. Vol. I. Mechanisms and Measurements.’ (Eds G. E. Hill and K. J. McGraw.) pp. 90–147. (Harvard University Press: Cambridge, MA.)

Nolan, P. M. , Dobson, F. S. , Dresp, B. , and Jouventin, P. (2006). Immunocompetence is signaled by ornamental colour in king penguins, Aptenodytes patagonicus. Evolutionary Ecology Research 8, 1325–1332.


O’Donald, P. (1980). Sexual selection by female choice in a monogamous bird: Darwin’s theory corroborated. Heredity 45, 201–217.
Crossref | GoogleScholarGoogle Scholar |

Otter, K. , and Ratcliffe, L. (1999). Relationship of bib size to age and sex in the black-capped chickadee. Journal of Field Ornithology 70, 567–577.


Parker, T. H. , and Ligon, J. D. (2003). Female mating preferences in red junglefowl: a meta-analysis. Ethology Ecology and Evolution 15, 63–72.


Saks, L. , McGraw, K. J. , and Horak, P. (2003). How feather colour reflects its carotenoid content. Functional Ecology 17, 555–561.
Crossref | GoogleScholarGoogle Scholar |

Schulte-Hostedde, A. I. , Zinner, B. , Millar, J. S. , and Hickling, G. J. (2005). Restitution of mass-size residuals: validating body condition indices. Ecology 86, 155–163.
Crossref | GoogleScholarGoogle Scholar |

Shawkey, M. D. , and Hill, G. E. (2005). Carotenoids need structural colours to shine. Biology Letters 1, 121–124.
Crossref | GoogleScholarGoogle Scholar | CAS | PubMed |

Shawkey, M. D. , Hill, G. E. , McGraw, K. J. , Hood, W. R. , and Huggins, K. (2006). An experimental test of the contributions and condition dependence of microstructure and carotenoids in yellow plumage coloration. Proceedings of the Royal Society of London. Series B: Biological Sciences 273, 2985–2991.
Crossref | GoogleScholarGoogle Scholar | CAS |

Stonehouse, B. (1971). The Snares Islands penguin Eudyptes robustus. Ibis 113, 1–7.
Crossref | GoogleScholarGoogle Scholar |

Torok, J. , Hegyi, G. , and Garamszegi, L. (2003). Depigmented wing patch size is a condition-dependent indicator of viability in male collared flycatchers. Behavioral Ecology 14, 382–388.
Crossref | GoogleScholarGoogle Scholar |

Warham, J. (1974). The breeding biology and behaviour of the Snares crested penguin. Journal of the Royal Society of New Zealand 4, 63–108.