The social status of the male Nile tilapia (Oreochromis niloticus) influences testis structure and gene expression.

Dominant and territorial behaviour are known social phenomena in cichlids and social stress influences reproduction and growth. The gonadotropic hormones trigger spermatogenesis and subordinate males have typically lower levels of gonadotropins than dominant males. In this study, we compared testis morphology and gene expression of dominant and subordinate Nile tilapia males (d- and s-males) in socially stable communities. The d-males had the highest gonadosomatic index but they were not the largest animals in the majority of studied cases. Long-term d-males showed large groups of Leydig cells and hyperplasia of the tunica albuginea due to numerous cytochrome-P450-11ß-hydroxylase (Cyp11b) expressing myoid cells. Increased Cyp11b expression in d-males was reflected by elevated 11-ketotestosterone plasma values. However, immunofluorescence microscopy and expression analysis of selected genes revealed that most s-males conserved their capability for spermatogenesis and are, therefore, ready for reproduction when the social environment changes. Moreover, in s-males gene expression analysis by quantitative RT-PCR showed increased transcript levels for germ line-specific genes (vasa, sox2 and dmc1) and Sertoli-specific genes (amh, amhrII and dmrt1) whereas gene expression of key factors for steroid production (sf1 and cyp11b) were reduced. The Nile tilapia is a promising model to study social cues and gonadotropic signals on testis development in vertebrates.

Characterization of the self-cleaving effector protein NopE1 of Bradyrhizobium japonicum.

NopE1 is a type III-secreted protein of the symbiont Bradyrhizobium japonicum which is expressed in nodules. In vitro it exhibits self-cleavage in a duplicated domain of unknown function (DUF1521) but only in the presence of calcium. Here we show that either domain is self-sufficient for cleavage. An exchange of the aspartic acid residue at the cleavage site with asparagine prevented cleavage; however, cleavage was still observed with glutamic acid at the same position, indicating that a negative charge at the cleavage site is sufficient. Close to each cleavage site, an EF-hand-like motif is present. A replacement of one of the conserved aspartic acid residues with alanine prevented cleavage at the neighboring site. Except for EDTA, none of several protease inhibitors blocked cleavage, suggesting that a known protease-like mechanism is not involved in the reaction. In line with this, the reaction takes place within a broad pH and temperature range. Interestingly, magnesium, manganese, and several other divalent cations did not induce cleavage, indicating a highly specific calcium-binding site. Based on results obtained by blue-native gel electrophoresis, it is likely that the uncleaved protein forms a dimer and that the fragments of the cleaved protein oligomerize. A database search reveals that the DUF1521 domain is present in proteins encoded by Burkholderia phytofirmans PsNJ (a plant growth-promoting betaproteobacterium) and Vibrio coralliilyticus ATCC BAA450 (a pathogenic gammaproteobacterium). Obviously, this domain is more widespread in proteobacteria, and it might contribute to the interaction with hosts.