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.     

Ectopic RNase E sites promote bypass of 5'-end-dependent mRNA decay in Escherichia coli

In Escherichia coli, 5'-terminal stem-loops form major impediments to mRNA decay, yet conditions that determine their effectiveness or the use of alternative decay pathway(s) are unclear. A synthetic 5'-terminal hairpin stabilizes the rpsT mRNA sixfold. This stabilization is dependent on efficient translational initiation and ribosome transit through at least two-thirds of the coding sequence past a major RNase E cleavage site in the rpsT mRNA. Insertion of a 12-15 residue 'ectopic' RNase E cleavage site from either the rne leader or 9S pre-rRNA into the 5'-non-coding region of the rpsT mRNA significantly reduces the stabilizing effect of the terminal stem-loop, dependent on RNase E. A similar insertion into the rpsT coding sequence is partially destabilizing. These findings demonstrate that RNase E can bypass an interaction with the 5'-terminus, and exploit an alternative 'internal entry' pathway. We propose a model for degradation of the rpsT mRNA, which explains the hierarchy of protection afforded by different 5'-termini, the use of internal entry for bypass of barriers to decay, 'ectopic sites' and the role of translating ribosomes.     

Transfer RNA cleavages by onconase reveal unusual cleavage sites

Onconase, a protein from amphibian eggs and a homologue of pancreatic ribonuclease (RNase) superfamily, is cytotoxic, exhibits antitumor and antiviral activity, and is in phase III clinical trials. It has been shown to predominantly target cellular tRNA on its entry into mammalian cells (Saxena, S. K., Sirdeshmukh, R., Ardelt, W., Mikulski, S. M., Shogen, K., and Youle, R. J. (2002) J. Biol. Chem. 277, 15142-15146). Cleavage site mapping using natural tRNA substrates, in vitro, revealed predominant cleavage sites at UG and GG residues. Cleavages at UG or the less intense cleavages at CG sites are consistent with the known base specificity of onconase. However, predominance of cleavages at selected G-G bonds is unusual for a homologue of pancreatic RNases. Interestingly, in at least three of the four tRNA substrates studied, the predominant cleavages mapped in the triplet UGG located in the context of the variable loop or the D-arm of the tRNA. The cleavage specificity of onconase observed by us thus indicates another special feature of this enzyme, which may be relevant to its cellular actions.     

Both temperature and medium composition regulate RNase E processing efficiency of the rpsO mRNA coding for ribosomal protein S15 of Escherichia coli

Cleavage by RNase E is believed to be the rate-limiting step in the degradation of many RNAs. These cleavages are modulated by 5' end-phosphorylation, folding and translation of the mRNA in question. Here, we present data suggesting that these cleavages are also regulated by environmental conditions. We report that rpsO mRNA, 15 minutes after a shift to 44 degrees C, is stabilized in cells grown in minimal medium. This stabilization is correlated with a reduction in the efficiency of the RNase E cleavage which initiates its decay. We also observe the appearance of RNA fragments previously detected following RNase E inactivation and a defect in the adaptation of RNase E concentration. These observations, coupled to the fact that RNase E overproduction slightly reduces the accumulation of the rpsO mRNA, suggest that this stabilization is caused in part by a limitation in RNase E concentration. An increase in the steady-state level of rpsT mRNA is also observed following a shift to 44 degrees C in minimal medium; however, processing of the 9 S rRNA precursor is not affected under these conditions. We thus propose that RNase E concentration changes in the cell in response to environmental conditions and that these changes can selectively affect the processing and the stability of individual mRNAs. Our data also indicate that the efficiency of cleavage of the rpsO mRNA by RNase E is modified by other factor(s) which remain to be identified.     

RNase III cleavage demonstrates a long range RNA: RNA duplex element flanking the hepatitis C virus internal ribosome entry site

Here, we show that Escherichia coli Ribonuclease III cleaves specifically the RNA genome of hepatitis C virus (HCV) within the first 570 nt with similar efficiency within two sequences which are ~400 bases apart in the linear HCV map. Demonstrations include determination of the specificity of the cleavage sites at positions C²⁷ and U³³ in the first (5′) motif and G⁴³⁹ in the second (3′) motif, complete competition inhibition of 5′ and 3′ HCV RNA cleavages by added double-stranded RNA in a 1:6 to 1:8 weight ratio, respectively, 50% reverse competition inhibition of the RNase III T7 R1.1 mRNA substrate cleavage by HCV RNA at 1:1 molar ratio, and determination of the 5′ phosphate and 3′ hydroxyl end groups of the newly generated termini after cleavage. By comparing the activity and specificity of the commercial RNase III enzyme, used in this study, with the natural E.coli RNase III enzyme, on the natural bacteriophage T7 R1.1 mRNA substrate, we demonstrated that the HCV cuts fall into the category of specific, secondary RNase III cleavages. This reaction identifies regions of unusual RNA structure, and we further showed that blocking or deletion of one of the two RNase III-sensitive sequence motifs impeded cleavage at the other, providing direct evidence that both sequence motifs, besides being far apart in the linear RNA sequence, occur in a single RNA structural motif, which encloses the HCV internal ribosome entry site in a large RNA loop.     

Determinants in the rpsT mRNAs recognized by the 5′‐sensor domain of RNase E

RNase E plays a central role in processing virtually all classes of cellular RNA in many bacterial species. A characteristic feature of RNase E and its paralogue RNase G, as well as several other unrelated ribonucleases, is their preference for 5′‐monophosphorylated substrates. The basis for this property has been explored in vitro. At limiting substrate, cleavage of the rpsT mRNA by RNase E (residues 1–529) is inefficient, requiring excess enzyme. The rpsT mRNA is cleaved sequentially in a 5′ to 3′ direction, with the initial cleavage(s) at positions 116/117 or 190/191 being largely driven by direct entry, independent of the 5′‐terminus or the 5′‐sensor domain of RNase E. Generation of the 147 nt 3′‐limit product requires sequential cleavages that generate 5′‐monophosphorylated termini on intermediates, and the 5′‐sensor domain of RNase E. These requirements can be bypassed with limiting enzyme by deleting a stem‐loop structure adjacent to the site of the major, most distal cleavage. Alternatively, this specific cleavage can be activated substantially by a 5′‐phosphorylated oligonucleotide annealed 5′ to the cleavage site. This finding suggests that monophosphorylated small RNAs may destabilize their mRNA targets by recruiting the 5‐sensor domain of RNase E ‘in trans’.     

Mutational analysis of an RNA internal loop as a reactivity epitope for Escherichia coli ribonuclease III substrates

The enzymatic cleavage of double-stranded (ds) RNA is an obligatory step in the maturation and decay of many cellular and viral RNAs. The primary agents of dsRNA processing are members of the ribonuclease III (RNase III) superfamily, which are highly conserved in eukaryotic and bacterial cells. Escherichia coli RNase III participates in the maturation of the ribosomal RNAs and in the maturation and decay of cellular and phage mRNAs. E. coli RNase III-dependent cleavage events can regulate gene expression by controlling mRNA stability and translational activity. RNase III recognizes its substrates and selects the scissile phosphodiester(s) by recognizing specific RNA sequence and structural elements, termed reactivity epitopes. Some E. coli RNase III substrates contain an internal loop, in which is located the single scissile phosphodiester. The specific features of the internal loop that establish the pattern of single-strand cleavage are not known. A mutational analysis of the asymmetric [4 nt/5 nt] internal loop of the phage T7 R1.1 substrate reveals that cleavage reactivity is largely independent of internal loop sequence. Instead, the [4/5] asymmetry per se is the primary determinant of cleavage of a single bond within the 5 nt strand of the internal loop. The T7 R1.1 internal loop lacks elements of local tertiary structure, as revealed by sensitivity to cleavage by terbium ion and by the ability of the internal loop to destabilize a small model duplex. The internal loop functions as a discrete structural element in that the pattern of cleavage can be controlled by the specific type of asymmetry. The implications of these findings are discussed in light of RNase III substrate function as a gene regulatory element.     

Sok antisense RNA from plasmid R1 is functionally inactivated by RNase E and polyadenylated by poly(A) polymerase I

The hok/sok system of plasmid R1, which mediates plasmid stabilization by the killing of plasmid-free cells, codes for two RNA species, Sok antisense RNA and hok mRNA. Sok RNA, which is unstable, inhibits translation of the stable hok mRNA. The 64 nt Sok RNA folds into a single stem-loop domain with an 11 nt unstructured 5' domain. The initial recognition reaction between Sok RNA and hok mRNA takes place between the 5' domain and the complementary region in hok mRNA. In this communication we examine the metabolism of Sok antisense RNA. We find that RNase E cleaves the RNA 6 nt from its 5' end and that this cleavage initiates Sok RNA decay. The RNase E cleavage occurs in the part of Sok RNA that is responsible for the initial recognition of the target loop in hok mRNA and thus leads to functional inactivation of the antisense. The major RNase E cleavage product (denoted pSok_-6) is rapidly degraded by polynucleotide phosphorylase (PNPase). Thus, the RNase E cleavage tags pSok₋₆ for further rapid degradation by PNPase from its 3' end. We also show that Sok RNA is polyadenylated by poly(A) polymerase I (PAP I), and that the poly(A)-tailing is prerequisite for the rapid 3'-exonucleolytic degradation by PNPase.     

Degradation of apolipoprotein II mRNA occurs via endonucleolytic cleavage at 5'-AAU-3'/5'-UAA-3' elements in single-stranded loop domains of the 3'-noncoding region

Degradation intermediates of the estrogen-regulated apolipoprotein (apo) II mRNA were identified by S1 nuclease mapping and primer extension analysis. S1 mapping of poly(A)-RNA detected a series of mRNAs truncated at specific sites in the 3'-noncoding region. Many of these sites were also detected by primer extension analysis indicating that truncated molecules resulted from endonucleolytic cleavage in the 3'-noncoding region. Identical cleavage sites were seen with RNA from estrogen-treated animals or from animals withdrawn from hormone under conditions where apoII mRNA degraded in the slow (t1/2 = 13 h) or rapid (t1/2 = 1.5 h) decay mode. No differences were seen in poly(A) tail length or heterogeneity among these conditions. These results indicate that the estrogen-induced alteration in apoII mRNA turnover does not involve a new pathway of degradation, but, more likely, involves an increased targeting of the mRNA for degradation by a preexisting pathway. These data are consistent with a mechanism in which the initial step in apoII mRNA degradation is an endonucleolytic cleavage in the 3'-noncoding region without prior removal of the poly(A) tail. The endonucleolytic cleavage sites occurred predominantly at 5'-AAU-3' or 5'-UAA-3' trinucleotides found in single-stranded domains in a secondary structure model of the naked mRNA (Hwang, S-P. L., Eisenberg, M., Binder, R., Shelness, G. S., and Williams, D. L. (1989) J. Biol. Chem. 264, 8410-8418). The structure of the 3'-noncoding region in polyribosomal messenger ribonucleoprotein was examined by titrations of liver homogenates with dimethyl sulfate and cobra venom RNase. The results suggest that the typical cleavage site is a 5'-AAU-3' or 5'-UAA-3' trinucleotide in an accessible single-stranded loop domain. Single-stranded domains alone or accessible domains alone are not sufficient for cleavage. Similarly, 5'-AAU-3' or 5'-UAA-3' trinucleotides alone are not sufficient for cleavage. Localization of these trinucleotides to accessible single-stranded domains in the polyribosomal messenger ribonucleoprotein may provide the specificity for cleavage during targeted degradation.     

Spermidine biosynthesis in Saccharomyces cerevisiae. Biosynthesis and processing of a proenzyme form of S-adenosylmethionine decarboxylase

We have cloned and sequenced the Saccharomyces cerevisiae gene for S-adenosylmethionine decarboxylase. This enzyme contains covalently bound pyruvate which is essential for enzymatic activity. We have shown that this enzyme is synthesized as a Mr 46,000 proenzyme which is then cleaved post-translationally to form two polypeptide chains: a beta subunit (Mr 10,000) from the amino-terminal portion and an alpha subunit (Mr 36,000) from the carboxyl-terminal portion. The protein was overexpressed in Escherichia coli and purified to homogeneity. The purified enzyme contains both the alpha and beta subunits. About half of the alpha subunits have pyruvate blocking the amino-terminal end; the remaining alpha subunits have alanine in this position. From a comparison of the amino acid sequence deduced from the nucleotide sequence with the amino acid sequence of the amino-terminal portion of each subunit (determined by Edman degradation), we have identified the cleavage site of the proenzyme as the peptide bond between glutamic acid 87 and serine 88. The pyruvate moiety, which is essential for activity, is generated from serine 88 during the cleavage. The amino acid sequence of the yeast enzyme has essentially no homology with S-adenosylmethionine decarboxylase of E. coli (Tabor, C. W., and Tabor, H. (1987) J. Biol. Chem. 262, 16037-16040) and only a moderate degree of homology with the human and rat enzymes (Pajunen, A., Crozat, A., J?nne, O. A., Ihalainen, R., Laitinen, P. H., Stanley, B., Madhubala, R., and Pegg, A. E. (1988) J. Biol. Chem. 263, 17040-17049); all of these enzymes are pyruvoyl-containing proteins. Despite this limited overall homology the cleavage site of the yeast proenzyme is identical to the cleavage sites in the human and rat proenzymes, and seven of the eight amino acids adjacent to the cleavage site are identical in the three eukaryote enzymes.     

Configuration of beta-globin messenger RNA in rabbit reticulocytes. Identification of sites exposed to endogenous and exogenous nucleases

Masked and exposed sites in rabbit beta-globin messenger RNA were identified through S1 nuclease mapping of RNase T1 cleavage sites. Sites exposed to this enzyme were compared in deproteinized polysomal RNA and in mRNA in its native configuration in reticulocyte extracts. The analysis showed that most of the 3' non-coding region is well accessible to the enzyme, both in deproteinized RNA and in the cell extract. A possible protecting function for the poly(A) sequence is suggested by the fact that molecules with very short poly(A) segments were cleaved preferentially in this region. The G residues in the 5' non-coding region were inaccessible to RNase T1. A highly sensitive site adjacent to the initiation AUG codon was evident in the deproteinized RNA. This site was far less accessible to the enzyme in the mRNA associated with ribosomes in the cell extract. The first 150 nucleotides in the coding region showed very little susceptibility to digestion by the enzyme, in deproteinized RNA as well as in the cell extracts. Preparations of untreated mRNA showed the occurrence of truncated molecules, apparently generated by cleavage by endogenous nucleases. These cleavages were most prevalent in the two non-coding regions. They occurred at sites containing A-U sequences in the 3' non-coding region, and at sites with different sequences in the 5' non-coding region. Incubation of cell extracts at 37 degrees C did not cause any increase in these endogenous cleavages. It is suggested that they may have been generated in the intact cells, possibly as part of the mRNA degradation process in maturing reticulocytes.     

Single-strand DNA cleavages by eukaryotic topoisomerase II

A new purification method for eukaryotic type II DNA topoisomerase (EC 5.99.1.3) is described, and the avian enzyme has been purified and characterized. An analysis of the cleavage reaction has revealed that topoisomerase II can be trapped as a DNA-enzyme covalent complex containing DNA with double-stranded and single-stranded breaks. The data indicate that DNA cleavage by topoisomerase II proceeds by two asymmetric single-stranded cleavage and resealing steps on opposite strands (separated by 4 bp) with independent probabilities of being trapped upon addition of a protein denaturant. Single-strand cleavages were directly demonstrated at both strong and weak topoisomerase II sites. Thus, a match to the vertebrate topoisomerase II consensus sequence (sequence; see text) (N is any base, and cleavage occurs between -1 and +1) [Spitzner, J.R., & Muller, M.T. (1988) Nucleic Acids Res. 16, 5533-5556)] does not predict whether a cleavage site will be single stranded or double stranded; however, sites cleaved by topoisomerase II that contain two conserved consensus bases (G residue at +2 and T at +4) generally yield double-strand cleavage whereas recognition sites lacking these two consensus elements yield single-strand cleavages. Finally, single-strand cleavages with topoisomerase II do not appear to be an artifact caused by damaged enzyme molecules since topoisomerase II in freshly prepared, crude extracts also shows the property of single-strand cleavages.     

Purification and characterization of ribonuclease M and mRNA degradation in Escherichia coli

A previously unreported endoribonuclease has been identified in Escherichia coli, which has a preference for hydrolysis of pyrimidine-adenosine (Pyd-Ado) bonds in RNA. It was purified about 7000-fold to give a single band after SDS/polyacrylamide gel electrophoresis; the eluted protein gave the same RNase specificity. The sizes of the native and denatured enzymes agreed suggesting that the enzyme exists as a monomer of approximately 26 kDa. It is called RNase M. The only other reported broadly specific endoribonuclease in E. coli is RNase I, a periplasmic enzyme. Based on differences in charge, heat stability and substrate specificity, it was clear that RNase M is not RNase I. The specificity of RNase M was remarkably similar to that of pancreatic RNase A even though the two enzymes differ in charge characteristics and size. Earlier studies had shown that mRNA from the lactose operon of E. coli is hydrolyzed in vivo primarily between Pyd-Ado bonds [Cannistraro et al. (1986) J. Mol. Biol. 192, 257-274] We propose that this major RNase activity accounts for these cleavages observed in vivo and that it is the endonuclease for mRNA degradation in E. coli.