Abstract: | Hybridogenetic reproduction has been demonstrated in both vertebrate and invertebrate unisexual hybrids. Its most peculiar feature is the transmission to the progeny of one invariant genome (hemiclone) through the egg and the replacement of the other by host fathering males. Bacillus hybridogens are the only known example of hemiclonal invertebrates; their comparison to Poeciliopsis and Rana systems helps in understanding peculiar and shared features of vertebrate and insect hybridogenesis. In P. monacha-lucida, the experimental production of non-hybrid progeny through the reunion of the maternal hemiclone with a homospecific paternal genome provided by males of the maternal ancestor leads to inviable or severely impaired sterile specimens, whereas in Rana esculenta viable offspring are the rule. The comparable synthetic B. rossius progeny (Rr) embodying the maternal R hemiclone and a paternal r haploset, appear perfectly viable and fertile, clearly demonstrating compatibility between the two homospecific genomes, and also supporting a lack of deterioration of the R hemiclone. This condition can be ascribed to the recent origin of the hemiclones, and also to the absence of lethal recessives, owing to their most likely derivation from an automictic doubling in the parthenogenetic mechanisms of the maternal ancestor. However, the hybridogenetic system breaks down in the gamete production of the majority of Rr females, since normal allele segregation also occurs in their progeny. These reproductive modes suggest a likely evolutionary dynamic for newly originated hybridogens: to achieve stability, an interruption of reproductive interactions with the maternal ancestor seems necessary. In stick insects, this constraint appears to be fulfilled in both areas of sympatry. The microevolutionary pathway suggested by the ecological scenario also supports the possibility that a shift of hemiclonal stick insect strains to clonality has occurred. |