A polysomal ribonuclease involved in the destabilization of albumin mRNA is a novel member of the peroxidase gene family.

We have purified an approximately 60 kDa endoribonuclease from Xenopus liver polysomes with properties expected for a messenger RNase involved in the estrogen-regulated destabilization of serum protein mRNAs (Dompenciel et al., 1995, J Biol Chem 270:6108-6118). The present report describes the cloning of this protein and its identification as a novel member of the peroxidase gene family. This novel enzyme, named polysomal RNase 1, or PMR-1 has 57% sequence identity with myeloperoxidase, and like that protein, appears to be processed from a larger precursor. Unlike myeloperoxidase, however, PMR-1 lacks N-linked oligosaccharide, heme, and peroxidase activity. Western blot and immunoprecipitation experiments using epitope-specific antibodies to the derived protein sequence confirm the identity of the cloned cDNA to the protein originally isolated from polysomes. The 80 kDa pre-PMR-1 expressed in a recombinant baculovirus was not processed to the 60 kDa form in Sf9 cells and lacks RNase activity. However, the baculovirus-expressed mature 60-kDa form of the enzyme has RNase activity. The recombinant protein is an endonuclease that shows selectivity for albumin versus ferritin mRNA. While it does not cleave at consensus APyrUGA elements, recombinant PMR-1 generates the same minor cleavage products from albumin mRNA as PMR-1 purified from liver. Finally, we show estrogen induces only a small increase in the amount of PMR-1. This result is consistent with earlier data suggesting estrogen activates mRNA decay through a posttranslational pathway.

Cleavage properties of an estrogen-regulated polysomal ribonuclease involved in the destabilization of albumin mRNA.

Previous work from this laboratory [Dompenciel,R.E., Garnepudi,V.R. and Schoenberg,D.R. (1995)J. Biol. Chem.270, 6108-6118] described the purification and properties of an estrogen-regulated endonuclease isolated from Xenopus liver polysomes that is involved in the destabilization of albumin mRNA. The present study mapped cleavages made by this enzyme onto the secondary structure of the portion of albumin mRNA bearing the major cleavage sites. The predominant cleavages occur in the overlapping APyrUGA sequence AUUGACUGA present in a single-stranded loop region, and in AUUGA located within a bulged AU-rich stem. A structural mutation which converted the major loop cleavage site to a hairpin bearing one APyrUGA element eliminated cleavage at the intact site. This confirms that the polysomal RNase is specific for single-stranded RNA. Additional point mutations in the major loop characterized the nucleoside sequence requirements for cleavage. Finally, snake venom exonuclease was used to demonstrate the polysomal RNase generates products with a 3' hydroxyl. Binding of an estrogen-induced protein to a portion of the 3'UTR of vitellogenin mRNA may be involved in its stabilization by estrogen [Dodson,R.E. and Shapiro,D.J. (1994)Mol. Cell. Biol.14, 3130-3138]. The core binding site for this protein bears the sequence APyrUGA, suggesting that stabilization may be accomplished by occlusion of a cleavage site for the polysomal RNase.

Purification and characterization of an estrogen-regulated Xenopus liver polysomal nuclease involved in the selective destabilization of albumin mRNA.

A previous report from this laboratory described an estrogen-regulated endoribonuclease activity on Xenopus liver polysomes which had properties one might expect for a messenger ribonuclease involved in the regulated destabilization of albumin mRNA (Pastori, R. L., Moskaitis, J. E., and Schoenberg, D. R. (1991) Biochemistry 30, 10490-10498). This report describes the purification and properties of this ribonuclease. The purified nuclease fraction contained a doublet of 62 and 64 kDa and a small amount of a 40-kDa peptide. In situ analysis on both denaturing and nondenaturing gels using an albumin transcript as substrate showed all three proteins possess nuclease activity. Peptide mapping and Western blot with a polyclonal antiserum showed the 62- and 64-kDa peptides to be isoforms, and the 40-kDa peptide to be a degradation product of the larger species. Two-dimensional gel electrophoresis further separated the 62- and 64-kDa species into three pairs of proteins, with isoelectric points of 9.6, 9.8, and 9.8. The purified ribonuclease rapidly degraded a full-length albumin transcript, yet had no effect on either a full-length albumin antisense transcript or full-length ferritin transcript. A number of properties of the purified nuclease were characterized, including the effects of salt, divalent cations, EDTA, sulfhydryl reagents, and temperature. Treatment of the polysomal nuclease with micrococcal nuclease had no effect, indicating that this enzyme does not require an RNA cofactor for activity. Finally, primer extension mapped the major cleavage site to an overlapping repeated sequence APyrUGA, with cleavage between and adjacent to the two pyrimidine residues generating fragments with 5'-hydroxyls.

Spider silkglands contain a tissue-specific alanine tRNA that accumulates in vitro in response to the stimulus for silk protein synthesis.

The large ampullate glands of the orb-web spider, Nephila clavipes provide massive amounts of fibroin throughout the lifetime of the adult female. We have developed methods to culture the glands and manipulate their biosynthetic activity. This has allowed us to monitor a series of molecular events that precede silk production in glands excised from appropriately stimulated animals. In this paper, we demonstrate that prior to the transient dramatic production of fibroin, such glands accumulate large amounts of tRNAs cognate to the abundant amino acids in spider silk. One of these, alanine tRNA, appears to consist of two isoaccepting forms--one constitutive, and the other silkgland specific. Moreover, the silkgland-specific form appears to accumulate preferentially in response to stimulation. This phenomenon of tissue-specific tRNA production appears similar to that found in the silkglands of Bombyx mori, but the spider system has the unique property of permitting manipulation in vitro. Thus, it provides an unusual opportunity to study the mechanism of regulated tRNA synthesis.