Photoaffinity labelling of nuclear steroid 5 alpha-reductase of rat ventral prostate

In order to get more information on the molecular structure of the rat prostatic 5 alpha-reductase (3-oxo-5 alpha-steroid: NADP+ 4-ene-oxidoreductase, EC 1.3:1.22) a systematic photoaffinity labelling study has been performed. To irreversibly freeze the status quo of interaction, either testosterone, the physiological ligand, or diazo-MAPD (21-diazo-4-methyl-4-aza-5 alpha-pregnane-3,20-dione), a specific 5 alpha-reductase inhibitor, was irradiated with isolated nuclei or with purified nuclear membranes or with solubilized nuclear membrane proteins and checked for optimal labelling conditions. The principal substances covalently labelled were phospholipids and at a minor ratio proteins. Analysis by SDS-PAGE and autoradiofluorography revealed two labelled polypeptides with molecular weights of 20 kDa and 26 kDa. The following evidence indicates that these polypeptides might be derived from the enzyme 5 alpha-reductase: both proteins are labelled only when specific ligands for 5 alpha-reductase are used; binding can be reduced by the addition of an excess of unlabelled ligand; enzyme activity is irreversibly suppressed when irradiated in the presence of these ligands; only subcellular fractions containing 5 alpha-reductase reveal the labelled proteins; in all 5 alpha-reductase containing preparations with increasing specific activity, independent of the polypeptide pattern, the same proteins are labelled.     

Calcyclin is differentially expressed in rat testicular cells

Immature rat Sertoli cells aggregate and form tubule-like structures when cultured on a monolayer of peritubular myoid cells. In this study, differential gene expression of monocultures and direct cocultures of peritubular cells and Sertoli cells were examined. One of the cDNA clones isolated showed high homology to calcyclin and a microvascular differentiation gene, CEC5, which was reported to be highly homologous to CASK, a membrane-associated guanylate kinase homolog. Sequencing and mRNA analysis of rat calcyclin demonstrated that the gene was differentially expressed and was found only in peritubular cells and cocultures with increased levels. In contrast, CASK was expressed by Sertoli cells, peritubular cells, and cocultures, whereas CEC5 was never found in the testicular somatic cells. Our findings point to a paracrine regulation of calcyclin expression in testicular peritubular fibroblasts which seems to be related to tubular growth.     

Rat Sertoli cells express epithelial but also mesenchymal genes after immortalization with SV40

A new immortal Sertoli cell line from pubertal rat testis was established and characterized. We have generated the clonal line SCIT-C8 expressing established markers for Sertoli cells (SC) like transferrin, clusterin and steel factor/stem cell factor (SCF). Additionally, the immortalized cells express afadin, a protein which is a member of tight and adherens junctions, therefore the cells may be useful for studies of the blood-testis barrier (BTB) in vitro. In contrast to primary SC, the immortalized cells lost expression of androgen receptor and responsiveness to androgens and follicle-stimulating hormone. Surprisingly, we found mRNA expression and protein secretion of the mesenchymal markers, fibronectin and entactin-1, which we also observed for the immortalized SC lines, ASC-17D and 93RS2. In comparison to primary SC, the immortalized cells demonstrated enhanced adhesion in vitro. This correlated with the expression of entactin-1 because adhesion was strongly reduced by antibody perturbation experiments. Additionally, we found the alternatively spliced and primarily muscle cell-specific long variant of TGF-beta2 not only in peritubular cells (PC), but also in the primary and immortalized SC. Furthermore, all immortalized cell lines secreted higher amounts of TGF-beta2 than primary SC. In conclusion, the immortalized SC lines from different developmental stages showed a similar pattern of epithelial and mesenchymal markers.     

Bioactivity of folding intermediates studied by the recovery of enzymatic activity during refolding

The peptide bond preceding proline residues realizes a cis/trans conformational switch with high switching resistance in native proteins and folding intermediates. Therefore, individual isomers have the potential to differ in bioactivity. However, information about isomer-specific bioactivities is difficult to obtain because of the risk of affecting isomeric distribution by bioactivity assay components.Here we present an approach that allows for the measurement of the recovery of enzymatic activities of wild-type RNase T₁ and RNase T₁ variants during refolding under conditions where the population of enzyme-substrate or enzyme-product complexes is negligible. Recovery of enzymatic activity was continuously monitored within the visible range of the spectrum by addition of a fluorescence-labeled nucleotide substrate to the refolding sample. We found that a nonnative trans conformation at Pro39 renders the RNase T₁ almost completely inactive. A folding intermediate having a nonnative trans conformation at Pro55 shows about 46% of the enzymatic activity referred to the native state. Pro55, in contrast to the active site located Pro39, is situated in a solvent-exposed loop region remote from active-site residues. In both cases, peptidyl prolyl cis/trans isomerases accelerate the regain of nucleolytic activity. Our findings show that even if there is a considerable distance between the site of isomerization and the active site, conformational control of the bioactivity of proteins is likely to occur, and that the surface location of prolyl bonds suffices for the control of buried active sites mediated by peptidyl prolyl cis/trans isomerases.     

Expression and localization of PMCA4 in rat testis and epididymis

It has recently been shown in mice that the plasma membrane Ca²⁺-ATPase isoform 4 (PMCA4) is essential for sperm fertilization capacity. We analyzed whether sperm PMCA4 is formed in the rat during spermatogenesis or is synthesized in the epididymis and transferred onto sperm during sperm maturation. We could show that PMCA4 is conserved in sperm from testis to epididymis. In testis, PMCA4 mRNA was restricted to spermatogonia and early spermatocytes, while the PMCA4 protein was detected in spermatogonia, late spermatocytes, spermatids and in epididymal sperm. In epididymis PMCA4 mRNA was localized in basolateral plasma membranes of epithelial cells of the caput, corpus and cauda epididymidis. In contrast, the protein was only detectable in the epithelial cells of the caput, indicating that PMCA4 mRNA is only translated into protein in caput epithelium. In the epididymal corpus and cauda, PMCA4 mRNA and protein, respectively, was localized and in peritubular cells. Furthermore, we detected an identical distribution of PMCA4a and b splice variants in rat testis, epididymal corpus and cauda. In the caput epididymidis, where PMCA4 is located in the epithelium splice variant 4b was more prominent. Further experiments have to clarify the functional importance of the differences in the PMCA4 distribution.     

Regulation of peptide bond cis/trans isomerization by enzyme catalysis and its implication in physiological processes

In some cases, the slow rotational movement underlying peptide bond cis/trans isomerizations is found to control the biological activity of proteins. Peptide bond cis/trans isomerases as cyclophilins, Fk506-binding proteins, parvulins, and bacterial hsp70 generally assist in the interconversion of the polypeptide substrate cis/trans isomers, and rate acceleration is the dominating mechanism of action in cells. We present evidence disputing the hypothesis that some of the molecular properties of these proteins play an auxiliary role in enzyme function.     

SVS II--an androgen-dependent actin-binding glycoprotein in rat semen.

Rat seminal vesicles and the lateral prostate secrete a glycoprotein designated as SVS II in an androgen-dependent manner. SVS II, which has a M(r) of 49,000 and a pI of 10.5, is an actin-binding protein. G- and F-actins cosediment with SVS II at a ratio of 2:1 (actin:SVS II). SVS II affects the kinetics of actin polymerization in the same way as do barbed end capping proteins. Interaction with actin is specific for the skeletal and cardiac muscle isoforms and there is no corresponding interaction with cytoplasmic actins. The binding site is close to the C-terminus of actin. Monospecific polyclonal antibodies directed against the N-terminus of actin cross-react with SVS II, but there is no cross-reaction by a monoclonal antibody directed against a C-terminal epitope on actin. Recent sequence analysis of SVS II shows a sequence of about 14 residues that is repeated 13 times between residues 86 and 298. The consensus sequence based on these repeats is homologous to residues 10 to 25 of actin; this may account for the immunological cross-reactivity. Like actin, SVS II binds and inhibits the activity of DNase I, but SVS II has no effect on the ATPase activity of myosin subfragment 1. Thus, SVS II is an actin-binding protein which retains some properties of actin itself.