ABSTRACT
Common marmosets are members of the family Callitrichidae, South American primates characterized by highly social group living and cooperative breeding. In this study we analysed 1112 base pairs (bp) of the mitochondrial control region in 59 Callithrix jacchus individuals, sampled mainly from two geographically distinct field sites in N.E. Brazil. Analysis of molecular variation revealed a highly significant genetic structuring of haplotypes between social groups and between populations. Examination of matrilineal genetic structure within social groups revealed that seven of nine recorded breeding pairs were from different maternal lineages, indicating assortative mating and outbreeding. In addition to the breeders, at least six of 10 groups contained adult individuals from different matrilines, with five haplotypes present in one social group of nine animals. Groups of mixed lineages raise questions about potential reproductive conflicts of interest, and the extent of kin-selected altruism in the evolution and maintenance of cooperative breeding in this species.
Subject(s)
Callithrix/genetics , Genetics, Population , Phylogeny , Animals , Brazil , Callithrix/physiology , DNA, Mitochondrial/genetics , Haplotypes , Likelihood Functions , Sexual Behavior, Animal/physiologyABSTRACT
Infanticide has been observed in many different species [1], including common marmosets [2-4], due to sexual selection, reproductive strategies or resource competition [3, 5, 6], which may ultimately lead to exploitation (cannibalism) [1, 7]. Wild callithrichids have a very flexible mating system, including monogamy, polygynandry, polyandry and polygyny [4, 8, 9], with Monteiro da Cruz [10] finding all these patterns within the same population. This results from the high degree of deforestation of their habitat [4], but non-monogamous groups cannot ensure successful rearing of infants, since helpers are crucial and should be present in high numbers [11]. In this study, we show for the first time that cannibalism can follow infanticide, and we hypothesise that it is a result of both competition for scarce resources and the need for animal protein, exacerbated by forest degradation.