Mutations in the processing site of the precursor of ribulose-1,5-bisphosphate carboxylase/oxygenase small subunit: effects on import,processing, assembly and stability

The small subunit (SSU) of Rubisco is synthesized in the cytosol in a precursor form. Upon import into the chloroplast, it is proteolytically processed at a Cys-Met bond to yield the mature form of the protein. To assess the importance of the Met residue for recognition and processing by the stromal peptidase, we substituted this residue with either Thr, Arg or Asp. The mutant precursor proteins were imported into isolated chloroplasts, and the products of the import reactions were analyzed. Mutants containing Thr or Arg residues at the putative processing site were processed to a single peptide, comigrating with the wild-type protein. N-terminal radio-sequencing revealed that these mutants were processed at the Cys-Thr and the Cys-Arg bond, respectively. After import of the Asp-containing mutant, four processed forms of the protein were observed. Analysis of the most abundant one, co-migrating with the wild-type protein, demonstrated that this species was also a product of correct processing, at the Cys-Asp bond. All the correctly processed peptides were found to be associated with the holoenzyme of Rubisco, and remained stable within the chloroplast, like the wild-type protein. The results of this study, together with previous ones, suggest that proper recognition and processing of the SSU precursor are more affected by residues N-terminal to the processing site than by the residue on the C-terminal side of this site.     

Nuclear suppression of a mitochondrial RNA splice defect: nucleotide sequence and disruption of the MRS3 gene

Summary A mitochondrial RNA splice defect in the first intron of the COB gene (bI1) can be suppressed by a dominant nuclear mutation SUP-101. Starting with a gene bank of yeast nuclear DNA from a SUP-101 suppressor strain cloned in the YEp13 plasmid, we have isolated a recombinant plasmid which exerts a suppressor activity similar to the SUP-101 allele. The N3(2) insert of this plasmid contains an open reading frame (ORF) of 1014 bp which is transcribed to a 12 S RNA. Deletion of the 5 end of this ORF and its upstream sequences abolishes the suppressor activity. The N3(2) insert thus carries a functional gene (called MRS3) which can suppress a mitochondrial splice defect. The chromosomal equivalent of the cloned gene has been mapped to chromosome 10. Disruption of this chromosomal gene has no phenotypic effect on wild-type cells.     

The glucose repression and RAS-cAMP signal transduction pathways of Saccharomyces cerevisiae each affect RNA processing and the synthesis of a reporter protein

Previously we reported that mutations in the Saccharomyces cerevisiae REG1 gene encoding a negative regulator of glucose-repressible genes, suppress the RNA processing defects and temperature-sensitive growth of rna1-1 and prp cells. This result and the fact that growth on non-glucose carbon sources also suppresses rna1-1 led us to propose that RNA processing and export of RNA from the nucleus are responsive to carbon source regulation. To understand how carbon source affects these processes, we used p70, an antigen regulated by REGI and by glucose availability, as a reporter. We found that the response of p70 to glucose availability is mediated by both the SNFI-SSN6-dependent glucose repression and the RAS-cAMP pathways. These results led us to test whether the RAS-cAMP pathway interacts with RNA1. We found that suppression of rnal-1 appears to be mediated, at least in part, by the RAS-cAMP pathway.     

Exoribonuclease R in Mycoplasma genitalium can carry out both RNA processing and degradative functions and is sensitive to RNA ribose methylation

Mycoplasma genitalium, a small bacterium having minimal genome size, has only one identified exoribonuclease, RNase R (MgR). We have purified MgR to homogeneity, and compared its RNA degradative properties to those of its Escherichia coli homologs RNase R (EcR) and RNase II (EcII). MgR is active on a number of substrates including oligoribonucleotides, poly(A), rRNA, and precursors to tRNA. Unlike EcR, which degrades rRNA and pre-tRNA without formation of intermediate products, MgR appears sensitive to certain RNA structural features and forms specific products from these stable RNA substrates. The 3'-ends of two MgR degradation products of 23S rRNA were mapped by RT-PCR to positions 2499 and 2553, each being 1 nucleotide downstream of a 2'-O-methylation site. The sensitivity of MgR to ribose methylation is further demonstrated by the degradation patterns of 16S rRNA and a synthetic methylated oligoribonucleotide. Remarkably, MgR removes the 3'-trailer sequence from a pre-tRNA, generating product with the mature 3'-end more efficiently than EcII does. In contrast, EcR degrades this pre-tRNA without the formation of specific products. Our results suggest that MgR shares some properties of both EcR and EcII and can carry out a broad range of RNA processing and degradative functions.     

Regions of Intermolecular Complementarity in Escherichia coli 16S rRNA,mRNA, and tRNA Molecules

The results of computer analysis of complementarity regions in the sequences of E. coli 16S rRNA, mRNAs and tRNAs are reported in this article. The potential regions of intermolecular RNA–RNA hybridization, or clinger fragments, in 16S rRNA, which are complementary to the sites frequently occurring in mRNAs and tRNAs, were found. Major clinger fragments on 16S rRNA are universal for genes that belong to different functional groups. Our results show there are adaptations of the structural organization of the 16S rRNA molecule to messenger and transport RNA sequences. RNA interaction with clinger fragments may contribute to upregulation of the translation process through increasing the local concentration of mRNAs and tRNAs in the vicinity of the ribosome and their proper positioning, as well as decrease the efficiency of translation through nonspecific mRNA–16SrRNA interactions.