Sexual conflict over breeding substrate causes female expulsion and offspring loss in a cichlid fish

Females of the Lake Tanganyika cichlid Lamprologus callipterusexclusively breed in empty snail shells that males collect intheir territories. Male–male competition for shells issevere, leading to frequent shell stealing and territory takeover.As a consequence, males have breeding females in their shellsthat spawned with competitors. In this field study, we investigatedboth naturally occurring and experimentally induced encountersof territorial males with females that had spawned with othermales. We found that the breeding success of females that weretaken over by a different male was significantly reduced. Behavioralobservations after experimental shell relocation further showedthat males recognized females that they had not spawned with:males directed more exploration and manipulation behavior towardsuch shells compared with controls. Reoccupation rate of emptiedexperimental shells was significantly higher than that of unmanipulatedempty shells. This indicates that shell stealing and nest takeover,followed by female expulsion, contribute to the reproductivesuccess of L. callipterus males. We also found that female matechoice reduces expulsion risk: females preferred to mate withlarge males, and male size correlated with dominance. We concludethat the limited availability of breeding substrate is a keydeterminant of both intrasexual competition and intersexualconflict in this species.     

Paternal inheritance of growth in fish pursuing alternative reproductive tactics

In species with indeterminate growth, age‐related size variation of reproductive competitors within each sex is often high. This selects for divergence in reproductive tactics of same‐sex competitors, particularly in males. Where alternative tactics are fixed for life, the causality of tactic choice is often unclear. In the African cichlid Lamprologus callipterus, large nest males collect and present empty snail shells to females that use these shells for egg deposition and brood care. Small dwarf males attempt to fertilize eggs by entering shells in which females are spawning. The bourgeois nest males exceed parasitic dwarf males in size by nearly two orders of magnitude, which is likely to result from greatly diverging growth patterns. Here, we ask whether growth patterns are heritable in this species, or whether and to which extent they are determined by environmental factors. Standardized breeding experiments using unrelated offspring and maternal half‐sibs revealed highly divergent growth patterns of male young sired by nest or dwarf males, whereas the growth of female offspring of both male types did not differ. As expected, food had a significant modifying effect on growth, but neither the quantity of breeding substrate in the environment nor ambient temperature affected growth. None of the environmental factors tested influenced the choice of male life histories. We conclude that in L. callipterus growth rates of bourgeois and parasitic males are paternally inherited, and that male and female growth is phenotypically plastic to only a small degree.     

Complete mitochondrial DNA replacement in a Lake Tanganyika cichlid fish

We used nuclear and mitochondrial DNA (mtDNA) sequences from specimens collected throughout Lake Tanganyika to clarify the evolutionary relationship between Lamprologus callipterus and Neolamprologus fasciatus . The nuclear data support the reciprocal monophyly of these two shell-breeding lamprologine cichlids. However, mtDNA sequences show that (i) L. callipterus includes two divergent and geographically disjunct (North–South) mtDNA lineages; and that (ii) N. fasciatus individuals cluster in a lineage sister group to the northern lineage of L. callipterus . The two mtDNA lineages of L. callipterus diverged c . 684 kya to 1.2 Ma, coinciding with a major water level low stand in Lake Tanganyika, which divided the lake into isolated sub-lakes. This suggests that the two mtDNA lineages originated as the result of the separation of L. callipterus populations in different sub-basins. The incongruent phylogenetic position of N. fasciatus can best be explained by an ancient unidirectional introgression from L. callipterus into N. fasciatus. Remarkably, our data indicate that this event resulted in the complete mtDNA replacement in N. fasciatus . Our data suggest that hybridization occurred soon after the divergence of the two L. callipterus mtDNA lineages, probably still during the water level low stand, and that subsequently the invading mtDNA lineage spread throughout the lake.