An analogous scenario may apply to the evolution of constitutive polyembryony in Dasypus armadillos (Loughry et al., 1998). In these species, the initial reproductive bottleneck is an oddly configured uterus with only one blastocyst implantation site. Polyembryonic divisions early in a female’s pregnancy then give rise to multiple clonemate offspring that will be housed within her later-enlarged uterus. Thus, for parasitic wasps and armadillos alike, polyembryony might be interpreted as an opportunistic reproductive

tactic that makes the best of the available situation for both parental and offspring genetic fitness. In each case, a severe constraint on offspring numbers exists at the outset of each ‘pregnancy’, but a spacious developmental niche (host caterpillar and female uterus, respectively) arises later that can be exploited by multiple polyembryos. check details Furthermore, for the co-housed siblings, competition should be minimized and

cooperation fostered because the broodmates are also clonemates (Hamilton, 1964; Hardy, 1995; Giron et al., 2004). If these speculations about the adaptive significance of polyembryony are correct, they might conform to the broader notion that polyembryony tends to evolve when offspring have more information about optimal clutch size than do their parents (Godfray, 1994; Craig et al., 1997). When progeny are in the best position to assess the environmental resources available to them, polyembryony would be selectively advantageous to them BIBW2992 (as well as to the genetic fitness of their parents) if the polyembryos can adjust the extent of their clonal proliferation

accordingly. In any event, constitutive polyembryony again illustrates how biological oddities can instruct broader evolutionary thought. This last point about clonality provides an obvious segue into the next section that will expand on the topic MCE of hermaphroditism. Inbreeding (the mating of kin) tends to decrease genetic variation in a sexual pedigree and in the extreme becomes another potential evolutionary route to ‘clonality’. Selfing is a most intense form of inbreeding. Consider, for example, the mangrove killifish (Kryptolebias marmoratus), nature’s only hermaphroditic vertebrate that routinely mates with itself (self-fertilizes). Each mature dual-sex individual houses an internal ovotestis that simultaneously produces ova and sperm that unite within the fish’s body before the zygotes are shed to inaugurate the next generation of self-fertilizers. When continued generation after generation, selfing soon leads to the emergence of genetic strains each composed of multiple individuals so genetically uniform as to be, in effect, clonally identical (Harrington & Kallman, 1968; Turner et al., 1992; Mackiewicz et al., 2006a).