Inhibition of the aminoacylation of selected tRNA molecules by an estrogen-regulated factor on uterine ribosomes. Regulation of aminoacylation of tRNA by estrogens

Polypeptide composition of the 8S form of prolyl-tRNA synthetase from rat liver

Rat liver Fraction X containing the 24S complex of nine aminoacyl-tRNA synthetases, including prolyl-tRNA synthetase, was centrifuged on a 15-35% sucrose density gradient to obtain the 8S form of prolyl-tRNA synthetase. The enzyme was purified on a prolyldiaminohexyl-Sepharose 4B affinity column, specifically binding prolyl-tRNA synthetase to Sepharose-bound proline. After SDS-polyacrylamide gel electrophoresis, two peptides of 58 and 61 kDa were detected in the peak of prolyl-tRNA synthetase activity eluted from the affinity column. The 58 and 61 kDa peptides were also present in the 24S complex containing prolyl-tRNA synthetase activity isolated on the sucrose density gradient.

Isolation and characterization of an estrogen-regulated ribosome-associated inactivator of tRNA aminoacylation in the uterus

Estradiol (E2) induces an increase in the peptide elongation rate of isolated uterine ribosomes assayed in a cell-free protein synthesis system. An inhibitory factor, extracted from ribosomes of E2-deprived rats, was found to inhibit the peptide elongation reaction by acting on certain tRNAs to render them incapable of binding to aminoacyl-tRNA synthetases, thus reducing the availability of specific aminoacylated tRNAs required for the sequential translation of the codons in mRNA. The uterine ribosome-associated tRNA inactivator (RATI) has been partially purified and monoclonal antibodies (MABs) to RATI have been prepared. Specificity of the MABs for RATI was indicated by the inactivation of RATI in vitro by the anti-RATI MABs. RATI selectively inactivates deacylated, but not acylated, tRNAs and the inactivation does not appear to involve nuclease cleavage of the tRNA. Within 1 h after E2 treatment 50% of both RATI activity and immunoreactivity were lost from the uterine ribosome extracts, suggesting that E2 regulation of tRNA reutilization may occur through dissociation of RATI from the ribosomal site of tRNA deacylation or alteration in the structure of RATI resulting in inactivation both biologically and immunologically. We propose that RATI may function as an E2-regulatable 'switch' mechanism which inactivates, delays or defers the aminoacylation of certain tRNAs in the absence of E2 and which participates in the regulation of protein synthesis at the translational level by creating rate-limiting levels of certain tRNAs in the E2-deprived uterus.

Depressed translational activity in the androgen sensitive levator ani muscle of the rat

The androgen-dependent levator ani (LA) muscle of the rat provides a suitable model to explore the molecular mechanism of steroid hormone action in target tissues. The objective of the present series of experiments was to study the effect of gonadectomy (GDX) and androgen replacement therapy on the in vitro protein synthetic capacity of the LA muscle. The incorporation of labeled methionine into the contractile protein fraction of the LA muscle maintained in organ culture decreases in a time-dependent manner following GDX. Translation of total polyadenylated mRNA in the rabbit reticulocyte translation system revealed that the decrease in protein synthetic capacity was not associated with differences in the template activity of the mRNA derived from GDX tissue. However, when polyribosomes were used to direct the same in vitro synthesis system, a significant time-dependent loss of translational activity was observed following GDX. The polyribosomes of the LA muscle of control and GDX rats were shown to contain equivalent amount of rRNA and mRNA of comparable translation efficiency. Collectively the results of these experiments indicate that the decrease in protein synthetic capacity of the LA muscle in androgen deficient rats is due, in part, to a repression of the translation process associated to the functional integrity of polyribosomes.

Estradiol regulation of reactions involved in turnover of the amino acid acceptor terminus of tRNA in the rat uterus

Estradiol (E2) increases the specific amino acid acceptor activity of rat uterine tRNAs by increasing the proportion of certain tRNAs with intact and functional 3'-CCA acceptor termini. Activities of tRNA nucleotidyltransferase and 3'-exoribonuclease which synthesize and degrade this terminus, respectively, were measured and neither enzyme was modified by hormone treatment. Since cytidine triphosphate (CTP) levels are below reported Km values for nucleotidyltransferase, changes in CTP concentrations may regulate nucleotidyltransferase activity. An E2-induced 3-fold increase was seen in CTP synthetase activity (conversion of uridine triphosphate, UTP, into CTP). Uterine CTP levels in controls are minute (9 nmol/uterus, approx. 90 microM), and are increased 2.5-fold in E2(12 h)-treated rats. The rate of incorporation of [3H]UTP into the 3'-CCA terminus of tRNA was measured as coupled CTP synthetase-nucleotidyltransferase reactions and a 2.5-fold increase in incorporation occurred 8-12 h after E2 treatment. Injection of azaserine, (inhibitor of CTP synthetase) reduced E2-induced increases in CTP levels, CTP synthetase activity, and leucine acceptor activity of tRNAs. These results indicate that E2 regulates CTP levels by modulation of CTP synthetase activity, and that regulation of synthesis and/or repair of the 3'-CCA terminus of tRNA is proportional to E2-induced uterine cytosolic CTP levels.