Multiple translational products from a Mycoplasma hyorhinis gene expressed in Escherichia coli.

We analyzed protein expression from a cloned Mycoplasma hyorhinis genomic fragment that produces in Escherichia coli a set of related polypeptides of 110, 100, 65, and 55 kilodaltons from a coding region of just over 3.0 kilobases. Expression of these multiple products resulted from a mechanism operating at the translational level but not from truncation at UGA termination codons, which are known to encode tryptophan in several mycoplasma species. The structural relatedness of the proteins was demonstrated by two-dimensional tryptic peptic mapping, but their generation by posttranslational processing was ruled out by pulse-chase labeling analysis. Examination of proteins expressed from plasmid constructs and tryptic peptide analysis of these polypeptides and the original set of proteins revealed that they share carboxy-terminal regions, an observation inconsistent with truncation at UGA codons. Expression of proteins from this cloned fragment was not dependent on vector sequences and was observed when the coding region was placed under control of a T7 promoter, suggesting that all products were translated from a single message. Expression of related products in mycoplasmas was examined by immunoblot analysis of M. hyorhinis proteins with antiserum against overexpressed recombinant proteins. A single 115-kilodalton mycoplasma protein was detected, which is larger than any of the related proteins expressed in E. coli. Our analysis indicated that translation initiation sites are used in E. coli that are not active in mycoplasmas, thereby defining differences between the translational regulatory signals of mycoplasmas and eubacteria.     

Competition between ribosome and SecA binding promotes Escherichia coli secA translational regulation.

SecA protein, the protein translocation ATPase of Escherichia coli, autogenously regulates its translation during normal protein secretion by binding to a secretion-responsive element located near the 5' end of its gene on geneX-secA mRNA. In order to characterize this autoregulation further, RNA footprinting and primerextension inhibition (toeprinting) studies were carried out with a segment of geneX-secA RNA, 30S ribosomal subunits and tRNAfMet along with purified SecA protein. The results show that ribosome and SecA-binding sites overlap, indicating that a simple competition for binding of geneX-secA mRNA presumably governs the translation initiation step. Further analysis showed that SecA protein was able to specifically dissociate a preformed 30S-tRNAfMet-geneX-secA RNA ternary complex as indicated by the disappearance of its characteristic toeprint after SecA addition. These findings are consistent with secA autoregulation, and they suggest a novel mechanism for the autoregulatory behavior of this complex protein.     

Restoration of a translational stop-start overlap reinstates translational coupling in a mutant trpB''-trpA gene pair of the Escherichia coli tryptophan operon.

The trpB and trpA coding regions of the polycistronic trp mRNA of Escherichia coli are separated by overlapping translation stop and start codons. Efficient translation of the trpA coding region is subject to translational coupling, i.e., maximal trpA expression is dependent on prior translation of the trpB coding region. Previous studies demonstrated that the trpA Shine-Dalgarno sequence (within trpB) and/or the location of the trpB stop codon influenced trpA expression. To examine the effect of stop codon location specifically, we constructed plasmids in which different nucleotide sequences preceding the trpA start codon were retained, and only the reading frame was changed. When trpB translation proceeded in the wild type reading frame and terminated at the normal trpB stop codon, trpA polypeptide levels were elevated over the levels observed when translation stopped before or after the natural trpB stop codon. The proximity of the trpB stop codon to the trpA start codon therefore markedly influences trpA expression.     

Stability of ribosomal protein mRNA and translational feedback regulation in Escherichia coli

Summary It was previously observed that the stability of ribosomal protein (r-protein) mRNA in Escherichia coli decreases under the conditions where its translation is feedback inhibited by repressor r-protein. We have now demonstrated that the stability of mRNA for r-proteins S13, S11 and S4 increases in a strain carrying a mutation in the gene for S4, a translational repressor regulating these r-proteins. The results confirm the previous observations that translational repression increases the decay rate of r-protein mRNA, and in addition, show that the half-life of S13-S4 r-protein mRNA in cells growing under ordinary conditions is significantly shorter than its inherent stability would predict, due to the operation of translational feedback regulation.     

An efficient protocol for linker scanning mutagenesis: analysis of the translational regulation of an Escherichia coli RNA polymerase subunit gene.

A protocol has been developed that is capable of saturating regions hundreds of basepairs in length with linker scanning mutations. The efficacy of this method stems from the design of the linker scanning mutagenesis (LSM) cassette which is composed of a selectable marker flanked by two oligonucleotides, each of which contains a recognition site for a different restriction endonuclease. The cleavage site for one endonuclease is within its recognition site, while the second endonuclease cleaves in the target DNA beyond the end of the cassette. Digestion with these endonucleases and subsequent ligation results in the replacement of 12 bp of the original target sequence with 12 bp of the linker scanning oligonucleotide. We have used this protocol to mutagenize a span of approximately 400 bp surrounding the start site of the gene for the beta subunit (rpoB) of Escherichia coli RNA polymerase. The translation of the beta mRNA has been shown previously to be regulated by the intracellular concentration of either beta or beta'. Analysis of the linker scanning mutations indicates that sequences extending a considerable distance both upstream and downstream of the start site are required for normal translation. Also a site that appears to be involved in translational repression by excess beta' has been identified.     

Gene expression regulation at the translational level: contribution of marine organisms

Gene expression regulation is crucial for organism survival. Each step has to be regulated, from the gene to the protein. mRNA can be stored in the cell without any direct translation. This process is used by the cell to control protein synthesis rapidly at the right place, at the right time. Protein synthesis costs a lot of energy for the cell, so that a precise control of this process is required. Translation initiation represents an important step to regulate gene expression. Many factors that can bind mRNA and recruit different partners are involved in the inhibition or stimulation of protein synthesis. Oceans contain an important diversity of organisms that are used as important models to analyse gene expression at the translational level. These are useful to study translational control in different physiological processes for instance cell cycle (meiosis during meiotic maturation of starfish oocytes, mitosis following fertilization of sea urchin eggs) or to understand nervous system mechanisms (aplysia). All these studies will help finding novel actors involved in translational control and will thus be useful to discover new targets for therapeutic treatments against human diseases.     

Temperature-dependent regulation of the Escherichia coli lpxT gene

The Lipid A moiety of the lipopolysaccharide can be covalently modified during its transport to the outer membrane by different enzymes, among which the LpxT inner membrane protein. LpxT transfers a phosphate group from the undecaprenyl pyrophosphate to the Lipid A, a modification affecting the stability of the outer membrane and its recognition by the host immune system in Enterobacteria. We previously found that the expression of the Pseudomonas aeruginosa lpxT gene, encoding LpxT, is induced in response to a temperature upshift and we proposed that an RNA thermometer was responsible for such regulation. Here we show that the Escherichia coli lpxT orthologous gene is down-regulated upon a temperature upshift and investigated the mechanism of this regulation. We found that the LpxT protein stability is not affected by the temperature change. Conversely, the lpxT mRNA levels strongly decrease upon a shift from 28 to 42 °C. The lack of MicA sRNA, which was previously implicated in lpxT regulation, does not affect lpxT thermal regulation. We identified the lpxTp promoter and demonstrated that lpxTp has temperature-sensitive activity depending on its peculiar −10 region. Moreover, we found that RNase E-dependent degradation of the lpxT mRNA is also modulated by temperature causing a strong destabilization of the lpxT mRNA at 42 °C. In vitro data argue against the involvement of factors differentially expressed at 28 and 42 °C in the temperature–dependent modulation of lpxT mRNA stability.