Abstract
Two competing hypotheses have been proposed for the function of the Y chromosomal fertility factors in Drosophila, which form giant lampbrush loops during the primary spermatocyte stage. The first hypothesis suggests a conventional coding function, the second proposes an unconventional gene function mediated through protein binding by nascent transcripts. Therefore, we studied the genetics and cytogenetics of the two Y chromosomal fertility genes A and C of Drosophila hydei (which form the lampbrush loops threads and pseudonucleolus) in order to test the validity of these different hypotheses. Both lampbrush loops bind specific proteins, which are recognized by different antisera. Absence of either of the lampbrush loops does not interfere with the synthesis of the antigens but completely prevents the binding of the particular antigen to other lampbrush loops. Absence of the loops also does not interfere with the postmeiotic presence and localization of the particular antigen. Deletion (or inactivation) of either of the lampbrush loops threads or pseudonucleolus causes sterility of the male flies as do other male-sterile alleles of both fertility genes, which do not affect the morphology of the lampbrush loops. The phenotypic effects of these mutations on sperm morphogenesis are identical for all various male-sterile alleles of each of the fertility genes A and C, regardless of whether a particular allele leaves the loop intact, modifies that loop, or deletes (or inactivates) the loop completely. Finally, the isolation of fertile Y chromosomal mutations which modify the morphology of the lampbrush loops demonstrates that it is possible to uncouple loop morphology and genetic function. These findings do not support the hypothesis that the binding of proteins to a lampbrush loop has a substantial impact on spermiogenesis.
