Cloning, sequencing and expression of the tetraheme cytochrome c(3) from Desulfovibrio gigas.

The gene encoding the tetraheme cytochrome c(3) from Desulfovibrio gigas was cloned and sequenced from a 2.7-kb EcoRI-PstI insert of D. gigas DNA. The derived amino acid sequence showed that the D. gigas cytochrome c(3) is synthesized as a precursor protein with an N-terminal signal peptide sequence of 25 residues and allowed the correction of the previous reported amino acid sequence (Matias et al. Protein Science 5 (1996) 1342-1354). Expression in D. vulgaris (Hildenborough) was possible by conjugal transfer of a recombinant broad-host-range vector pSUP104 containing a SmaI fragment of the D. gigas cytochrome c(3) gene. Biochemical, immunological and spectroscopic analysis of the purified protein showed that the recombinant cytochrome is identical to that isolated from D. gigas.

Identification and developmental expression of a 5'-3' exoribonuclease from Drosophila melanogaster.

In multicellular organisms, very little is known about the role of mRNA stability in development, and few proteins involved in degradation pathways have been characterized. We have identified the Drosophila homologue of XRN1, which is the major cytoplasmic 5'-3' exoribonuclease in Saccharomyces cerevisiae. The protein sequence of this homologue (pacman) has 59% identity to S. cerevisiae XRN1 and 67% identity to the mouse homologue (mXRN1p) in certain regions. Sequencing of this cDNA revealed that it includes a trinucleotide repeat (CAG)9 which encodes polyglutamine. By directly measuring pacman exoribonuclease activity in yeast, we demonstrate that pacman can complement the yeast XRN1 mutation. Northern blots show a single transcript of approximately 5.2 kb which is abundant only in 0-8-h embryos and in adult males and females. In situ hybridization analysis revealed that the pcm transcripts are maternally derived, and are expressed at high levels in nurse cells. During early embryonic syncytial nuclear divisions, pcm transcripts are homogenously distributed. pcm mRNA is expressed abundantly and ubiquitously throughout the embryo during gastrulation, with high levels in the germ band and head structures. After germ band retraction, pcm transcripts are present at much lower levels, in agreement with the Northern results. Our experiments provide the first example of an exoribonuclease which is differentially expressed throughout development.

RNase E can inhibit the decay of some degradation intermediates: degradation of Desulfovibrio vulgaris cytochrome c3 mRNA in E coli.

In Escherichia coli, ribonuclease E (RNase E) is a key endonuclease in mRNA decay. We have analysed the role of E coli RNase E on the degradation of a heterologous cytochrome c3 (cyc) mRNA from Desulfovibrio vulgaris Hildenborough. The decay of the cyc transcript in wild-type and mutant E coli cells was followed and the degradation intermediates analysed by Northern blotting and S1 protection analysis. The half-life of total cyc mRNA intermediates was increased in the RNase E mutant. A number of degradation intermediates were stabilised, and new species arose. However, some species decayed faster in the met5 mutant at the non-permissive temperature, suggesting that RNase E might inhibit their degradation. The results indicate that RNase E is involved in cyc mRNA degradation, and, interestingly, decay of certain intermediates could be reduced by this enzyme activity. This may suggest a functional interaction between RNase E and exonucleases, like polynucleotide phosphorylase.

A new role for RNase II in mRNA decay: striking differences between RNase II mutants and similarities with a strain deficient in RNase E.

The effect of Escherichia coli ribonuclease II and polynucleotide phosphorylase was analysed on the degradation of Desulfovibrio vulgaris cytochrome c3 (cyc) mRNA. In the absence of these exoribonucleolytic activities, cyc mRNA was stabilised but the two enzymes had a different role in its decay. Surprisingly, a temperature-sensitive mutation in ribonuclease II gave a degradation pattern similar to what had been observed in the absence of endoribonuclease E activity. In an RNase II deletion mutant this was not observed. We propose and verify a model in which the temperature-sensitive ribonuclease II interferes with the action of ribonuclease E.

Determinant role of E. coli RNase III in the decay of both specific and heterologous mRNAs.

A comparative analysis of mRNA decay was carried out in Escherichia coli using the wild-type and an isogenic RNase III deletion strain. We have studied the mRNA degradation from the Escherichia coli gene bolA, the Lactococcus lactis biovar diacetylactis citQRP operon and the Desulfovibrio vulgaris Hildenborough gene cyc. As seen by a dramatic stabilization of the specific mRNAs in the mutant strain, RNase III was crucial for the decay process of these three messages. Since RNase III, unlike RNase E, is not essential for bacterial viability we think that there is potential for using RNase III mutant strains to modulate gene expression.

RNase II removes the oligo(A) tails that destabilize the rpsO mRNA of Escherichia coli.

Polyadenylation controls mRNA stability in procaryotes, eucaryotes, and organelles. In bacteria, oligo(A) tails synthesized by poly(A) polymerase I are the targets of the 3'-to-5' exoribonucleases: polynucleotide phosphorylase and RNase II. Here we show that RNase II very efficiently removes the oligo(A) tails that can be used as binding sites by PNPase to start degradation of the rpsO mRNA. Both enzymes are impeded by the secondary structure of the transcription terminator at the 3' end of the mRNA. RNase II mostly generates tailless transcripts harboring 2 unpaired nt downstream of the transcription terminator hairpin, whereas PNPase releases molecules that exhibit a single-stranded stretch of 5-7 nt terminated by a tail of 3-5 As. The rpsO mRNAs whose oligo(A) tails have been removed by RNase II are more stable than oligoadenylated molecules that occur in strains deficient for RNase II. Moreover, the rpsO mRNA is stabilized when RNase II is overproduced. This modulation of mRNA stability by RNase II is only observed when poly(A) polymerase I is active. These in vivo data demonstrate that RNase II protects mRNAs ending by stable terminal hairpins, such as primary transcripts, from degradation by poly(A)-dependent ribonucleases.