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2 - The ontogeny of sexual dimorphism: the implications of longitudinal vs. cross-sectional data for studying heterochrony in mammals

Published online by Cambridge University Press:  10 August 2009

Rebecca Z. German
Affiliation:
Department of Biological Sciences, University of Cincinnati, Cincinnati, OH 45221-0006, USA
Fred Anapol
Affiliation:
University of Wisconsin, Milwaukee
Rebecca Z. German
Affiliation:
University of Cincinnati
Nina G. Jablonski
Affiliation:
California Academy of Sciences, San Francisco
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Summary

Introduction

As the name suggests, studies of sexual dimorphism began with a focus on morphological differences between the sexes (Darwin 1871). Current use of the term “dimorphism” and current studies of sexual dimorphism have expanded to include ecological, behavioral, and physiological differences between the sexes (Harvey and Clutton-Brock, 1985). Charles Oxnard (1987) brought his unique quantitative perspective to the investigation of sexual dimorphism, showing that studies, particularly quantitative studies, of differences between the sexes in morphology are meaningful and not outdated. His work has provided inspiration for this chapter, which examines the role that data and analysis play in understanding evolution. As Oxnard identified multiple dimorphisms among taxa along morphological axes, this study examines heterochronic variation among taxa to show that different ontogenetic trajectories produced analogous multiple dimorphisms. Crucial to Oxnard's work, and to the results presented here, are matches among question, data, and method.

Studies of sexual dimorphism and growth

Most research addressing questions of growth and sexual dimorphism examines the ontogeny of that dimorphism, focusing on how growth produces adult differences (see German and Stewart, 2002 for review). A slight shift in focus to the sexual dimorphism of ontogeny, or the way the sexes grow, will generate alternative questions, centering on the differences in growth itself (e.g., Watts and Gavan, 1982; Glassman et al., 1984; Coelho, 1985; Watts, 1986).

Growth in mammals has a number of distinguishing characteristics that make comparisons of growth between two groups difficult, whether they are sexes or species. Mammalian growth is nonlinear.

Type
Chapter
Information
Shaping Primate Evolution
Form, Function, and Behavior
, pp. 11 - 23
Publisher: Cambridge University Press
Print publication year: 2004

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References

Alberch, P., Gould, S. J., Oster, G. F., and Wake, D. B. (1979). Size and shape in ontogeny and phylogeny. Paleobiol., 5, 296–317CrossRefGoogle Scholar
Brooks, M. J. (1991). The ontogeny of sexual dimorphism: quantitative models and a case study in labrisomid blennies. Syst. Zool., 40, 271–283CrossRefGoogle Scholar
Cock, A. G. (1966). Genetical aspects of metrical growth and form in animals. Q. Rev. Biol., 41, 131–190CrossRefGoogle ScholarPubMed
Coelho, A. M. (1985). Baboon dimorphism: growth in weight, length and adiposity from birth to 8 years of age. In: Nonhuman Primate Models for Human Growth and Development, ed. E. Watts. New York, NY: Alan R. Liss
Darwin, C. (1871). The Descent of Man and Selection in Relation to Sex. London: Murray
Diggle, P., Heagerty, P., Liang, K.-Y., and Zeger, S. (2002). Analysis of Longitudinal Data. 2nd edn. Oxford: Oxford University Press
German, R. Z. and Stewart, S. A. (2002). Sexual dimorphism and ontogeny in primates. In: Human Evolution Through Developmental Change, ed. N. Minugh-Purvis and K. J. McNamara. Baltimore, MD: Johns Hopkins University Press
Glassman, D. M., Coelho, A. M., Carey, K. D. and Bramblett, C. A. (1984). Weight growth in savannah baboons: a longitudinal study from birth to adulthood. Growth, 48, 425–433Google Scholar
Harvey, P. H. and Clutton-Brock, T. H. (1985). Life history variation in primates. Evolution, 39, 559–581CrossRefGoogle ScholarPubMed
Jolicouer, P. and Pirlot, P. (1988). Asymptotic growth and complex allometry of the brain and body in the white rat. Growth Devel. Age, 52, 3–10Google Scholar
Jolicoeur, P., Pontier, J., Pernin, M-O., and Sempe, M. (1988). A lifetime asymptotic growth curve for human height. Biometrics, 44, 995–1003CrossRefGoogle ScholarPubMed
Kirsch, J. A. W., Bleiweiss, R. E., Dickerman, A. W., and Reig, O. A. (1993). DNA/DNA hybridization studies of carnivorous marsupials. III. Relationships among species of Didelphis (Didelphidae). J. Mammal. Evol., 1, 75–97CrossRefGoogle Scholar
Koops, W. J. (1986). Multiphasic growth curve analysis. Growth, 50, 169–177Google ScholarPubMed
Laird, A. K., Tyler, S. A., and Barton, A. D. (1965). Dynamics of normal growth. Growth, 29, 233–248Google ScholarPubMed
Marubini, E. and Milani, S. (1985). Approaches to the analysis of longitudinal data. In: Human Growth, ed. F. Falkner and J. M. Tanner, 2nd edn. New York, NY: Plenum Press
Maunz, M and German, R. Z. (1996). Sexual dimorphism and craniofacial heterochrony in the short-tailed opossum (Monodelphis domestica). J. Mammal., 77, 992–1005CrossRefGoogle Scholar
Maunz, M. and German, R. Z. (1997). Ontogeny and limb bone scaling in two new world marsupials: Monodelphis domestica and Didelphis virginiana. J. Morphol., 231, 117–1303.0.CO;2-B>CrossRefGoogle ScholarPubMed
McCance, R. A. and Widdowson, E. M. (1986). Glimpses of comparative growth and development. In: Human Growth, ed. F. Falkner and J. M. Tanner. 2nd edn, New York, NY: Plenum PressCrossRef
McKinney, M. L. and McNamara, K. (1991). Heterochrony: the Evolution of Ontogeny. New York, NY: Plenum Press
Miller, J. P. and German, R. Z. (1999). Protein malnutrition affects the growth trajectories of the craniofacial skeleton but not final adult size in rats. J. Nutrition, 129, 2061–2069CrossRefGoogle Scholar
Oxnard, C. E. (1987). Fossils, Teeth and Sex. Hong Kong: Hong Kong University Press
Patton, J. L., dos Reis, S. F., and da Silva, M. N. F. (1996). Relationships among didelphid marsupials based on cytochrome b gene. J. Mammal. Evol., 3, 3–29CrossRefGoogle Scholar
Russell, E. M. (1982). Patterns of parental care and parental investment in marsupials. Biol. Rev., 52, 423–486CrossRefGoogle Scholar
Shea, B. T. (1986). Ontogenetic approaches to sexual dimorphism in anthropoids. In: Sexual Dimorphism in Living and Fossil Primates, ed. M. Pickford and B. Chiarelli. Florence: SedicesimoCrossRef
Stewart, S. A. and German, R. Z. (1999). Sexual dimorphism and ontogenetic allometry of soft tissues in Rattus norvegicus. J. Morph., 242, 57–663.0.CO;2-5>CrossRefGoogle ScholarPubMed
Tanner, J. M. (1986). Use and abuse of growth standards. In: Human Growth, ed. F. Falkner and J. M. Tanner. 2nd edn, New York, NY: Plenum PressCrossRef
Watts, E. S. (1986). Evolution of the human growth curve. In: Human Growth, ed. F. Falkner and J. M. Tanner. 2nd edn. New York, NY: Plenum PressCrossRef
Watts, E. S. and Gavan, J. A. (1982). Postnatal growth of nonhuman primates: the problem of the adolescent spurt. Hum. Biol., 54, 53–70Google ScholarPubMed
Zeger, S. L. and Harlow, S. D. (1987). Mathematical models from laws of growth to tools for biologic analysis: fifty years of Growth. Growth, 51, 1–21Google Scholar

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