CsrA Participates in a PNPase Autoregulatory Mechanism by Selectively Repressing Translation of pnp Transcripts That Have Been Previously Processed by RNase III and PNPase.

UNLABELLED: Csr is a conserved global regulatory system that represses or activates gene expression posttranscriptionally. CsrA of Escherichia coli is a homodimeric RNA binding protein that regulates transcription elongation, translation initiation, and mRNA stability by binding to the 5' untranslated leader or initial coding sequence of target transcripts. pnp mRNA, encoding the 3' to 5' exoribonuclease polynucleotide phosphorylase (PNPase), was previously identified as a CsrA target by transcriptome sequencing (RNA-seq). Previous studies also showed that RNase III and PNPase participate in a pnp autoregulatory mechanism in which RNase III cleavage of the untranslated leader, followed by PNPase degradation of the resulting 5' fragment, leads to pnp repression by an undefined translational repression mechanism. Here we demonstrate that CsrA binds to two sites in pnp leader RNA but only after the transcript is fully processed by RNase III and PNPase. In the absence of processing, both of the binding sites are sequestered in an RNA secondary structure, which prevents CsrA binding. The CsrA dimer bridges the upstream high-affinity site to the downstream site that overlaps the pnp Shine-Dalgarno sequence such that bound CsrA causes strong repression of pnp translation. CsrA-mediated translational repression also leads to a small increase in the pnp mRNA decay rate. Although CsrA has been shown to regulate translation and mRNA stability of numerous genes in a variety of organisms, this is the first example in which prior mRNA processing is required for CsrA-mediated regulation. IMPORTANCE: CsrA protein represses translation of numerous mRNA targets, typically by binding to multiple sites in the untranslated leader region preceding the coding sequence. We found that CsrA represses translation of pnp by binding to two sites in the pnp leader transcript but only after it is processed by RNase III and PNPase. Processing by these two ribonucleases alters the mRNA secondary structure such that it becomes accessible to the ribosome for translation as well as to CsrA. As one of the CsrA binding sites overlaps the pnp ribosome binding site, bound CsrA prevents ribosome binding. This is the first example in which regulation by CsrA requires prior mRNA processing and should link pnp expression to conditions affecting CsrA activity.

Autogenous regulation of Escherichia coli polynucleotide phosphorylase during cold acclimation by transcription termination and antitermination.

Adaptation of Escherichia coli at low temperature implicates a drastic reprogramming of gene expression patterns. Mechanisms operating downstream of transcription initiation, such as control of transcription termination, mRNA stability and translatability, play a major role in controlling gene expression in the cold acclimation phase. It was previously shown that Rho-dependent transcription termination within pnp, the gene encoding polynucleotide phosphorylase (PNPase), was suppressed in pnp nonsense mutants, whereas it was restored by complementation with wild type allele. Using a tRNA gene as a reporter and the strong Rho-dependent transcription terminator t ( imm ) of bacteriophage P4 as a tester, here we show that specific sites in the 5'-untranslated region of pnp mRNA are required for PNPase-sensitive cold-induced suppression of Rho-dependent transcription termination. We suggest that suppression of Rho-dependent transcription termination within pnp and its restoration by PNPase is an autogenous regulatory circuit that modulates pnp expression during cold acclimation.

Up-regulation of human PNPase mRNA by beta-interferon has no effect on protein level in melanoma cell lines.

Human mitochondrial polynucleotide phosphorylase (hPNPase) is an exoribonuclease localized in mitochondria. The exact physiological function of this enzyme is unknown. Recent studies have revealed the existence of a relationship between induction of hPNPase mRNA and both cellular senescence and growth arrest of melanoma cells following beta-interferon treatment. The aim of this study was to verify whether the augmented hPNPase mRNA level results in increase of the protein level. In several cell lines established from five metastatic melanoma patients we did not find any such correlation. However, an elevated level of hPNPase protein was observed in interferon-induced HeLa and Jurkat cells. This increase was correlated with a slight shortening of poly(A) tails of mitochondrial ND3 transcript.

Overexpression and purification of untagged polynucleotide phosphorylases.

We report here the development of new, straightforward procedures for the purification of bacterial polynucleotide phosphorylases (PNPases). The pnp genes from Streptomyces antibioticus, Streptomyces coelicolor, and Escherichia coli were overexpressed using the vectors pET11 and pET11A in E. coli BL21(DE3)pLysS. The enzymes were purified to apparent homogeneity after phosphorolysis in crude extracts followed by anion exchange and hydrophobic interaction chromatography. Yields of 5-15mg per liter of culture were obtained and the enzymes contained only small amounts of contaminating RNA as estimated from the A(280/260) ratios of purified preparations. All three enzymes were active in both the polymerization and phosphorolysis reactions normally catalyzed by PNPases. Incubation under phosphorolysis conditions but in the absence of potassium phosphate indicated that the enzymes were free of phosphate-independent nuclease activity. We suggest that the approaches described here may be applied generally to the overexpression and purification of eubacterial polynucleotide phosphorylases.

Increased expression of Escherichia coli polynucleotide phosphorylase at low temperatures is linked to a decrease in the efficiency of autocontrol.

Polynucleotide phosphorylase (PNPase) synthesis is translationally autocontrolled via an RNase III-dependent mechanism, which results in a tight correlation between protein level and messenger stability. In cells grown at 18 degrees C, the amount of PNPase is twice that found in cells grown at 30 degrees C. To investigate whether this effect was transcriptional or posttranscriptional, the expression of a set of pnp-lacZ transcriptional and translational fusions was analyzed in cells grown at different temperatures. In the absence of PNPase, there was no increase in pnp-lacZ expression, indicating that the increase in pnp expression occurs at a posttranscriptional level. Other experiments clearly show that increased pnp expression at low temperature is only observed under conditions in which the autocontrol mechanism of PNPase is functional. At low temperature, the destabilizing effect of PNPase on its own mRNA is less efficient, leading to a decrease in repression and an increase in the expression level.

Cold-temperature induction of Escherichia coli polynucleotide phosphorylase occurs by reversal of its autoregulation.

When Escherichia coli cells are shifted to low temperatures (e.g. 15 degrees C), growth halts while the 'cold shock response' (CSR) genes are induced, after which growth resumes. One CSR gene, pnp, encodes polynucleotide phosphorylase (PNPase), a 3'-exoribonuclease and component of the RNA degradosome. At 37 degrees C, ribonuclease III (RNase III, encoded by rnc) cleaves the pnp untranslated leader, whereupon PNPase represses its own translation by an unknown mechanism. Here, we show that PNPase cold-temperature induction involves several post-transcriptional events, all of which require the intact pnp mRNA leader. The bulk of induction results from reversal of autoregulation at a step subsequent to RNase III cleavage of the pnp leader. We also found that pnp translation occurs throughout cold-temperature adaptation, whereas lacZ(+) translation was delayed. This difference is striking, as both mRNAs are greatly stabilized upon the shift to 15 degrees C. However, unlike the lacZ(+) mRNA, which remains stable during adaptation, pnp mRNA decay accelerates. Together with other evidence, these results suggest that mRNA is generally stabilized upon a shift to cold temperatures, but that a CSR mRNA-specific decay process is initiated during adaptation.

Transcriptional and post-transcriptional control of polynucleotide phosphorylase during cold acclimation in Escherichia coli.

Polynucleotide phosphorylase (PNPase, polyribonucleotide nucleotidyltransferase, EC 2.7.7.8) is one of the cold shock-induced proteins in Escherichia coli and pnp, the gene encoding it, is essential for growth at low temperatures. We have analysed the expression of pnp upon cold shock and found a dramatic transient variation of pnp transcription profile: within the first hour after temperature downshift the amount of pnp transcripts detectable by Northern blotting increased more than 10-fold and new mRNA species that cover pnp and the downstream region, including the cold shock gene deaD, appeared; 2 h after temperature downshift the transcription profile reverted to a preshift-like pattern in a PNPase-independent manner. The higher amount of pnp transcripts appeared to be mainly due to an increased stability of the RNAs. The abundance of pnp transcripts was not paralleled by comparable variation of the protein: PNPase steadily increased about twofold during the first 3 h at low temperature, as determined both by Western blotting and enzymatic activity assay, suggesting that PNPase, unlike other known cold shock proteins, is not efficiently translated in the acclimation phase. In experiments aimed at assessing the role of PNPase in autogenous control during cold shock, we detected a Rho-dependent termination site within pnp. In the cold acclimation phase, termination at this site depended upon the presence of PNPase, suggesting that during cold shock pnp is autogenously regulated at the level of transcription elongation.

Proteins associated with RNase E in a multicomponent ribonucleolytic complex.

The Escherichia coli endoribonuclease RNase E is essential for RNA processing and degradation. Earlier work provided evidence that RNase E exists intracellularly as part of a multicomponent complex and that one of the components of this complex is a 3'-to-5' exoribonuclease, polynucleotide phosphorylase (EC 2.7.7.8). To isolate and identify other components of the RNase E complex, FLAG-epitope-tagged RNase E (FLAG-Rne) fusion protein was purified on a monoclonal antibody-conjugated agarose column. The FLAG-Rne fusion protein, eluted by competition with the synthetic FLAG peptide, was found to be associated with other proteins. N-terminal sequencing of these proteins revealed the presence in the RNase E complex not only of polynucleotide phosphorylase but also of DnaK, RNA helicase, and enolase (EC 4.2.1.11). Another protein associated only with epitope-tagged temperature-sensitive (Rne-3071) mutant RNase E but not with the wild-type enzyme is GroEL. The FLAG-Rne complex has RNase E activity in vivo and in vitro. The relative amount of proteins associated with wild-type and Rne-3071 expressed at an elevated temperature differed.

Folding in vivo of bacterial cytoplasmic proteins: role of GroEL.

A general role for chaperonin ring structures in mediating folding of newly translated proteins has been suggested. Here we have directly examined the role of the E. coli chaperonin GroEL in the bacterial cytoplasm by production of temperature-sensitive lethal mutations in this essential gene. After shift to nonpermissive temperature, the rate of general translation in the mutant cells was reduced, but, more specifically, a defined group of cytoplasmic proteins--including citrate synthase, ketoglutarate dehydrogenase, and polynucleotide phosphorylase--were translated but failed to reach native form. Similarly, a monomeric test protein, maltose-binding protein, devoid of its signal domain, was translated but failed to fold to its native conformation. We conclude that GroEL indeed is a machine at the distal end of the pathway of transfer of genetic information, assisting a large and specific set of newly translated cytoplasmic proteins to reach their native tertiary structures.

E.coli polynucleotide phosphorylase expression is autoregulated through an RNase III-dependent mechanism.

It has been previously shown that the pnp messenger RNAs are cleaved by RNase III at the 5' end and that these cleavages induce a rapid decay of these messengers. A translational fusion between pnp and lacZ was introduced into the chromosome of a delta lac strain to study the expression of pnp. In the presence of increased cellular concentrations of polynucleotide phosphorylase, the level of the hybrid beta-galactosidase is repressed, whereas the synthesis rate of the corresponding message is not significantly affected. In the absence of pnp, the level of the hybrid protein increases strongly. Thus, polynucleotide phosphorylase is post-transcriptionally autocontrolled. However, autocontrol is totally abolished in strains where the RNase III site on the pnp message has been deleted or in strains devoid of RNase III. These results suggest that polynucleotide phosphorylase requires RNase III cleavages to autoregulate the translation of its message. Other mutations in the ribosome binding site region support the hypothesis that this 3' to 5' processive enzyme could recognize a specific repressor binding site at the 5' end of pnp mRNA. Implications of these results on the mechanism of regulation and on messenger degradation are discussed.

RNA processing by RNase III is involved in the synthesis of Escherichia coli polynucleotide phosphorylase.

The synthesis of Escherichia coli polynucleotide phosphorylase (PNPase) was examined in a mutant strain defective in the RNA processing enzyme RNase III (Rnc-). We found that the specific activity and the synthesis rate of PNPase were increased in the Rnc- strain by more than three times that in an Rnc+ strain. Such increased synthesis of PNPase was not observed in a mutant strain transformed with a plasmid carrying the rnc+ gene. Quantitative analysis of RNA showed that the transcripts from the pnp gene, which encodes PNPase, were degraded more slowly in the Rnc- strain than in the Rnc+ strain. These results indicate that processing of the transcripts by RNase III is intimately involved in controlling the expression of pnp by affecting the stability of its messenger RNA.