Translational regulation of ribosomal protein S15 drives characteristic patterns of protein‐mRNA epistasis

Do coding and regulatory segments of a gene co‐evolve with each‐other? Seeking answers to this question, here we analyze the case of Escherichia coli ribosomal protein S15, that represses its own translation by specifically binding its messenger RNA (rpsO mRNA) and stabilizing a pseudoknot structure at the upstream untranslated region, thus trapping the ribosome into an incomplete translation initiation complex. In the absence of S15, ribosomal protein S1 recognizes rpsO and promotes translation by melting this very pseudoknot. We employ a robust statistical method to detect signatures of positive epistasis between residue site pairs and find that biophysical constraints of translational regulation (S15‐rpsO and S1‐rpsO recognition, S15‐mediated rpsO structural rearrangement, and S1‐mediated melting) are strong predictors of positive epistasis. Transforming the epistatic pairs into a network, we find that signatures of two different, but interconnected regulatory cascades are imprinted in the sequence‐space and can be captured in terms of two dense network modules that are sparsely connected to each other. This network topology further reflects a general principle of how functionally coupled components of biological networks are interconnected. These results depict a model case, where translational regulation drives characteristic residue‐level epistasis—not only between a protein and its own mRNA but also between a protein and the mRNA of an entirely different protein.     

Translational autocontrol of the Escherichia coli ribosomal protein S15

When rpsO, the gene encoding the ribosomal protein S15 in Escherichia coli, is carried by a multicopy plasmid, the mRNA synthesis rate of S15 increases with the gene dosage but the rate of synthesis of S15 does not rise. A translational fusion between S15 and beta-galactosidase was introduced on the chromosome in a delta lac strain and the expression of beta-galactosidase studied under different conditions. The presence of S15 in trans represses the beta-galactosidase level five- to sixfold, while the synthesis rate of the S15-beta-galactosidase mRNA decreases by only 30 to 50%. These data indicate that S15 is subject to autogenous translational control. Derepressed mutants were isolated and sequenced. All the point mutations map in the second codon of S15, suggesting a location for the operator site that is very near to the translation initiation codon. However, the creation of deletion mutations shows that the operator extends into the 5' non-coding part of the message, thus overlapping the ribosome loading site.     

Two translational initiation sites in the infB gene are used to express initiation factor IF2 alpha and IF2 beta in Escherichia coli.

The gene infB codes for the two forms of translational initiation factor IF2: IF2 alpha (97 300 daltons) and IF2 beta (79 700 daltons). To determine whether the two forms differ at their N terminus, purified IF2 alpha and IF2 beta were subjected to 11 or more steps of Edman degradation. The N-terminal amino acid sequences are completely different, but match perfectly the DNA sequences at the beginning of the infB open reading frame and an in-phase region 471 bp downstream. A fusion was constructed between the proximal half of the infB gene and the lacZ gene lacking the region coding for the first eight amino acids. The fused gene expresses two products of 170 000 and 150 000 daltons, corresponding to the fused proteins IF2 alpha-beta-galactosidase and IF2 beta-beta-galactosidase, which confirms in vivo that the IF2 forms differ at their N terminus. A deletion of the 5'-non-translated region of the fused gene, including the Shine/Dalgarno ribosomal binding site, results in the expression of IF2 beta-beta-galactosidase but not IF2 alpha-beta-galactosidase. This strongly suggests that IF2 beta results from independent translation rather than from a precise proteolytic cleavage of IF2 alpha. Further evidence for initiation of protein synthesis at the putative IF2 alpha and IF2 beta start sites was sought by using an in vitro dipeptide synthesis assay. A DNA fragment containing the entire infB gene was cloned into three plasmid vectors and the resulting recombinant DNAs were used as templates in assays containing fMet-tRNA and various labelled aminoacyl-tRNAs.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of mutations in the GTP-binding domain of IF2 resulting in cold-sensitive growth of Escherichia coli

The infB gene encodes translation initiation factor IF2. We have determined the entire sequence of infB from two cold-sensitive Escherichia coli strains IQ489 and IQ490. These two strains have been isolated as suppressor strains for the temperature-sensitive secretion mutation secY24. The mutations causing the suppression phenotype are located within infB. The only variations from the wild-type (wt) infB found in the two mutant strains are a replacement of Asp409 with Glu in strain IQ489 and an insertion of Gly between Ala421 and Gly422 in strain IQ490. Both positions are located in the GTP-binding G-domain of IF2. A model of the G-domain of E.coli IF2 is presented in. Physiological quantities of the recombinant mutant proteins were expressed in vivo in E.coli strains from which the chromosomal infB gene has been inactivated. At 42 degrees C, the mutants sustained normal cell growth, whereas a significant decrease in growth rate was found at 25 degrees C for both mutants as compared to wt IF2 expressed in the control strain. Circular dichroism spectra were recorded of the wt and the two mutant proteins to investigate the structural properties of the proteins. The spectra are characteristic of alpha-helix dominated structure, and reveal a significant different behavior between the wt and mutant IF2s with respect to temperature-induced conformational changes. The temperature-induced conformational change of the wt IF2 is a two-state process. In a ribosome-dependent GTPase assay in vitro the two mutants showed practically no activity at temperatures below 10 degrees C and a reduced activity at all temperatures up to 45 degrees C, as compared to wt IF2. The results indicate that the amino acid residues, Asp409 and Gly422, are located in important regions of the IF2 G-domain and demonstrate the importance of GTP hydrolysis in translation initiation for optimal cell growth.     

tRNA(Trp) translation of leader peptide codon 12 and other factors that regulate expression of the tryptophanase operon.

Tryptophanase (tna) operon expression in Escherichia coli is induced by tryptophan. This response is mediated by features of a 319-base-pair leader region preceding the major structural genes of the operon. Translation of the coding region (tnaC) for a 24-amino-acid leader peptide is essential for induction. We have used site-directed mutagenesis to investigate the role of the single Trp codon, at position 12 in tnaC, in regulation of the operon. Codon 12 was changed to either a UAG or UGA stop codon or to a CGG arginine codon. Induction by tryptophan was eliminated by any of these changes. Studies with suppressor tRNAs indicated that tRNA(Trp) translation of codon 12 in tnaC is essential for induction of the operon. Reduction of tna expression by a miaA mutation supports a role for translation by tRNA(Trp) in regulation of the operon. Frameshift mutations and suppression that allows translation of tnaC to proceed beyond the normal stop codon result in constitutive tna operon expression. Deletion of a potential site for Rho factor utilization just beyond tnaC also results in partial constitutive expression. These studies suggest possible models for tryptophan induction of tna operon expression involving tRNA(Trp)-mediated frame shifting or readthrough at the tnaC stop codon.     

Tandem translation of Bacillus subtilis initiation factor IF2 in E. coli. Over-expression of infBB.su in E. coli and purification of alpha- and beta-forms of IF2B.su.

The protein synthesis initiation factor, IF2, in Bacillus subtilis has previously been characterized as being present in two forms, alpha and beta, of molecular mass 79 and 68 kDa, respectively, on the basis of their cross-reaction with anti-E. coli IF2 antibodies and by the DNA sequence of the gene for IF2, infBB.su. In this work we have cloned infBB.su in E. coli cells. Two proteins of molecular mass identical to the B. subtilis IF2 alpha and -beta were over-expressed and purified using a new three-step ion-exchange chromatography procedure. The N-terminal amino acid sequence of the two proteins was determined and the results confirmed that the two forms were IF2 alpha and -beta, both encoded by the infB gene. The N-terminal amino acid sequence determined for IF2 beta is Met94-Gln-Asn-Asn-Gln-Phe. The presence of methionine at position 94 shows that this form is, in fact, the result of a second translational initiation in infBB.su mRNA, since the codon at amino acid position 94 is GUG, which is the normal codon for valine, but also known to be an initiator codon. This is a new example of the unusual tandem translation in E. coli of an open mRNA reading frame.