Initiation factor-independent translation of mRNAs from Gram-positive bacteria

Multiple upstream start codons (AUG) in 5' untranslated region enhance translation efficiency of cry2Ac11 without helper protein

Cry2Ac11, a 65 kDa insecticidal protein produced by Bacillus thuringiensis, shows toxicity against dipteran and lepidopteran larvae. It is encoded by cry2Ac11 gene ( orf3), which is part of an operon comprising orf1, orf2, and orf3. Orf2, a helper protein, helps in proper folding and prevents aberrant aggregation of newly produced molecules. In this study, we have elucidated the effect of different mutations in translation initiation region (TIR), particularly the ribosomal binding site and the start codon (RBS-ATG) on cry2Ac11 gene expression without helper protein. All recombinant constructs were expressed in acrystalliferous B. thuringiensis subsp israelensis 4Q7 under the control of strong chimeric promoter cyt1AP/STAB. Of all the mutants, mut/RBS2, with two consecutive AUGs after the spacer region in TIR, exhibited 89- and 2246-fold higher transcript levels compared with 4Q7-operSalI/RBS ( cry2Ac11 operon) and 4Q7-w-RBS ( cry2Ac11 gene), respectively. The analysis of mut/RBS2 messenger RNA (mRNA) structure in the RBS-AUG region showed the presence of RBS in the single-stranded part of the moderately stable hairpin loop. The high expression efficiency of Cry2Ac11 mutant without helper protein is a cumulative and cooperative result of chimeric promoter cyt1AP/STAB-SD with the optimal context of RBS-AUG region provided by multiple AUGs and stabilizer sequence at 3' ends.

How Changes in Anti-SD Sequences Would Affect SD Sequences in Escherichia coli and Bacillus subtilis

The 3' end of the small ribosomal RNAs (ssu rRNA) in bacteria is directly involved in the selection and binding of mRNA transcripts during translation initiation via well-documented interactions between a Shine-Dalgarno (SD) sequence located upstream of the initiation codon and an anti-SD (aSD) sequence at the 3' end of the ssu rRNA. Consequently, the 3' end of ssu rRNA (3'TAIL) is strongly conserved among bacterial species because a change in the region may impact the translation of many protein-coding genes. Escherichia coli and Bacillus subtilis differ in their 3' ends of ssu rRNA, being GAUCACCUCCUUA3' in E. coli and GAUCACCUCCUUUCU3' or GAUCACCUCCUUUCUA3' in B. subtilis Such differences in 3'TAIL lead to species-specific SDs (designated SD_Ec for E. coli and SD_Bs for B. subtilis) that can form strong and well-positioned SD/aSD pairing in one species but not in the other. Selection mediated by the species-specific 3'TAIL is expected to favor SD_Bs against SD_Ec in B. subtilis, but favor SD_Ec against SD_Bs in E. coli Among well-positioned SDs, SD_Ec is used more in E. coli than in B. subtilis, and SD_Bs more in B. subtilis than in E. coli Highly expressed genes and genes of high translation efficiency tend to have longer SDs than lowly expressed genes and genes with low translation efficiency in both species, but more so in B. subtilis than in E. coli Both species overuse SDs matching the bolded part of the 3'TAIL shown above. The 3'TAIL difference contributes to the host specificity of phages.

Deoxynucleoside kinases encoded by the yaaG and yaaF genes of Bacillus subtilis. Substrate specificity and kinetic analysis of deoxyguanosine kinase with UTP as the preferred phosphate donor

The overlapping yaaG and yaaF genes from Bacillus subtilis were cloned and overexpressed in Escherichia coli. Purification of the gene products showed that yaaG encoded a homodimeric deoxyguanosine kinase (dGK) and that yaaF encoded a homodimeric deoxynucleoside kinase capable of phosphorylating both deoxyadenosine and deoxycytidine. The latter was identical to a previously characterized dAdo/dCyd kinase (Møllgaard, H. (1980) J. Biol. Chem. 255, 8216-8220). The purified recombinant dGK was highly specific toward 6-oxopurine 2'-deoxyribonucleosides as phosphate acceptors showing only marginal activities with Guo, dAdo, and 2',3'-dideoxyguanosine. UTP was the preferred phosphate donor with a Km value of 6 microm compared with 36 microm for ATP. In addition, the Km for dGuo was 0.6 microm with UTP but 6.5 microm with ATP as phosphate donor. The combination of these two effects makes UTP over 50 times more efficient than ATP. Initial velocity and product inhibition studies indicated that the reaction with dGuo and UTP as substrates followed an Ordered Bi Bi reaction mechanism with UTP as the leading substrate and UDP the last product to leave. dGTP was a potent competitive inhibitor with respect to UTP. Above 30 microm of dGuo, substrate inhibition was observed, but only with UTP as phosphate donor.

The effect of ribosomal protein S1 from Escherichia coli and Micrococcus luteus on protein synthesis in vitro by E. coli and Bacillus subtilis

We have designed a set of nine plasmids containing the Bacillus pumilis cat gene with one of three Shine-Dalgarno (SD) sequences (weak, strong or stronger) and one of three initiation codons (AUG, GUG or UUG). These constructions have been used to determine the effect of ribosomal protein S1, SD and initiation codon sequences and Escherichia coli ribosomal protein S1 on translation in vitro by E. coli and B. subtilis ribosomes. Translation of these nine constructions was determined with three types of ribosomes: E. coli containing ribosomal protein S1, E. coli depleted of S1, and B. subtilis which is naturally free of S1. E. coli ribosomes were able to translate all nine transcripts with variable efficiencies. B. subtilis and S1-depleted E. coli ribosomes were similar to each other and differed from non-depleted E. coli ribosomes in that they required strong or stronger SD sequences and were unable to translate any of the weak transcripts. Addition of S1 from either E. coli or Micrococcus luteus, a Gram-positive bacterium, enabled S1-depleted E. coli ribosomes to translate mRNAs with weak SD sequences but had no effect on B. subtilis ribosomes. AUG was the preferred initiation codon for all ribosome types; however, B. subtilis ribosomes showed greater tolerance for the non-AUG codons than either type of E. coli ribosome. The presence of a strong or stronger SD sequence increased the efficiency by which E. coli ribosomes could utilize non-AUG codons.(ABSTRACT TRUNCATED AT 250 WORDS)

The influence of ribosome-binding-site elements on translational efficiency in Bacillus subtilis and Escherichia coli in vivo

A method is described to determine simultaneously the effect of any changes in the ribosome-binding site (RBS) of mRNA on translational efficiency in Bacillus subtilis and Escherichia coli in vivo. The approach was used to analyse systematically the influence of spacing between the Shine-Dalgarno sequence and the initiation codon, the three different initiation codons, and RBS secondary structure on translational yields in the two organisms. Both B. subtilis and E. coli exhibited similar spacing optima of 7-9 nucleotides. However, B. subtilis translated messages with spacings shorter than optimal much less efficiently than E. coli. In both organisms, AUG was the preferred initiation codon by two- to threefold. In E. coli GUG was slightly better than UUG while in B. subtilis UUG was better than GUG. The degree of emphasis placed on initiation codon type, as measured by translational yield, was dependent on the strength of the Shine-Dalgarno interaction in both organisms. B. subtilis was also much less able to tolerate secondary structure in the RBS than E. coli. While significant differences were found between the two organisms in the effect of specific RBS elements on translation, other mRNA components in addition to those elements tested appear to be responsible, in part, for translational species specificity. The approach described provides a rapid and systematic means of elucidating such additional determinants.

Analysis of an mRNA exhibiting anomalous translational specificity

Gene 6 mRNA of Bacillus subtilis phage phi 29 is inefficiently translated under standard in vitro conditions by Escherichia coli, while it is efficiently translated by the in vitro system derived from B. subtilis. This is a rare example of the inability of E. coli to translate mRNA translated by B. subtilis. The ionic condition in the translation systems was the key component in the differential recognition of the gene 6 message by E. coli and B. subtilis ribosomes. Its translation by E. coli ribosomes was preferentially inhibited by moderate levels of KCl, while its translation by B. subtilis ribosomes was unaffected by these concentrations of salt. This preferential inhibition with E. coli ribosomes was observed in vitro as well as in vivo. While not influencing the general phenomenon of preferential inhibition, anion-specific effects were observed in overall protein synthesis. Glutamate and acetate promoted efficient synthesis over a broad range of concentrations, whereas chloride was inhibitory at all concentrations tested.

Cloning of the flagellin gene from Bacillus subtilis and complementation studies of an in vitro-derived deletion mutation

The flagellin promoter and structural gene from Bacillus subtilis I168 was cloned and sequenced. The amino-terminal protein sequence deduced from the coding sequence of the cloned gene was identical to that of the amino terminus of purified flagellin, indicating that the export of this protein is not directed by a posttranslationally processed N-terminal signal peptide. A sequence that was homologous to that of a consensus sigma 28 RNA polymerase recognition site lay upstream of the proposed translational start site. Amplification of this promoter region on a multicopy plasmid resulted in the formation of long, filamentous cells that accumulated flagellin intracellularly. The chromosomal locus containing the wild-type flagellin allele was replaced with a defective allele of the gene (delta hag-633) that contained a 633-base-pair deletion. Transport analysis of various flagellin gene mutations expressed in the hag deletion strain suggest that the extreme C-terminal portion of flagellin is functionally involved in export of the protein.

Molecular and functional properties of protein SS1 from small ribosomal subunits of Streptomyces aureofaciens

Small ribosomal subunits of gram-positive cells of Streptomyces aureofaciens contain an acidic protein designated SS1. Purified protein SS1 has the same mobility in sodium dodecyl sulfate/polyacrylamide gel as ribosomal protein S1 of Escherichia coli (apparent Mr 68 000). Protein SS1 was dissected under mild conditions with trypsin and generated fragments were compared with well-characterized fragments of protein S1. The protein SS1 contains a structure homologous with the C-terminal fragment of protein S1. The affinity of protein SS1 to poly(U) is virtually identical with that of E. coli protein S1. In contrast to protein S1, the addition of SS1 to partially S1-depleted ribosomes of E. coli had no stimulatory effect on poly(U)-directed synthesis of polyphenylalanine. At molar excess of SS1 over ribosomes, the protein had comparable inhibitory effect on polypeptide synthesis as had S1 of E. coli. Ribosomes of S. aureofaciens required about one order of magnitude higher concentration of poly(U) for maximum synthetic activity than did ribosomes of E. coli. The addition of proteins SS1 or S1 to ribosomes of S. aureofaciens had no stimulatory effect on translation of poly(U). Our data indicate that the high-molecular-mass acidic protein SS1 of small ribosomal subunits of S. aureofaciens exhibits only a part of the functional properties of E. coli protein S1.

Expression of the Proteus mirabilis recA gene in Bacillus subtilis is directed by its own promoter

The recA gene of Proteus mirabilis (recApm) has been cloned into the PstI site of the Bacillus promoter-probe plasmid pPL603. When present on this plasmid, the recApm1) gene is expressed in B. subtilis under the control of its own transcriptional and translational signals. It is concluded that the high AT-content of the DNA sequence upstream of the -35 region is of decisive importance for the usage of the recApm promoter by the B. subtilis RNA polymerase. The results are discussed in relation to the expression barriers found to exist for genes from gram-negative bacteria in the gram-positive B. subtilis.

Evidence for the translational attenuation model: ribosome-binding studies and structural analysis with an in vitro run-off transcript of ermC

Several features of the translational attenuation model of ermC regulation were tested. This model predicts two possible secondary structures for the leader of the ermC transcript and requires that the leader contains two Shine-Dalgarno (SD) sequences. The ribosome binding site for a leader peptide (SD1) is predicted to be accessible, whereas that for the rRNA methylase protein that confers erythromycin (Em) resistance (SD2) is sequestered by base pairing. The model suggests that in the presence of inducer (Em), a ribosome stalls while translating the peptide, altering the mRNA conformation, thereby exposing SD2. The results of our ribosome binding studies demonstrate that SD1 is exposed and binds to ribosomes, whereas SD2 is unavailable. Also, the secondary structure of the 5' region of the ermC transcript was analyzed using methidium propyl-EDTA.Fe (II), T1 nuclease, and nucleases from cobra venom and mung bean sprouts as structure probes. Our results support the previously proposed model for folding of ermC mRNA, and demonstrate that SD1 is single-stranded, while SD2 and its neighboring sequences are largely base paired, consistent with the ribosome-binding results.

Expression in Bacillus subtilis of the gene for human urogastrone using synthetic ribosome binding sites

A chemically synthesised gene coding for human urogastrone which was earlier cloned in E. coli (Smith et al. 1982) has now been cloned into expression vectors for Bacillus subtilis. Two types of constructs have been made, one giving production of methionyl-urogastrone and the other giving rise to a methionyl-urogastrone-beta galactosidase fusion polypeptide facilitating quantification of expression levels. The ribosome binding sites used in the expression plasmids are synthetically made oligonucleotides residing on short restriction fragments to allow easy replacement by other ribosome binding sites. Using "shuttle" vectors and constitutive promoters from Bacillus phages phi 105 and SPP1, we were able to detect levels of expression amounting to a few thousand molecules per cell during logarithmic growth in both E. coli and B. subtilis.

Replacement of the Bacillus subtilis subtilisin structural gene with an In vitro-derived deletion mutation

The entire subtilisin structural gene from Bacillus subtilis I168 has been cloned, and its nucleotide sequence has been determined. When expressed on a high-copy-number shuttle vector, a fivefold increase in serine protease activity was observed. The DNA sequence of the gene is 80% homologous to the Bacillus amyloliquefaciens subtilisin structural gene, and the translated mature coding sequence is 85% homologous to the published protein sequence of subtilisin BPN'. The chloramphenicol resistance determinant of a plasmid integrated at the subtilisin locus was mapped by PBS1 transduction and was found to be linked to glyB (83%) and argC (60%), but not with metC or purB . The chromosomal locus containing the wild-type subtilisin allele was replaced with an in vitro-derived allele of the gene (delta apr-684) that contained a 684-base-pair deletion. The technique used for introducing the deletion is a variation of the gene replacement methods used in Saccharomyces cerevisiae and Escherichia coli. When used in B. subtilis, deletion mutants could be directly screened among the transformants. Physiological characterization of the delta apr-684 mutation revealed no discernable effect on the formation of heat-resistant endospores, but strains carrying the mutation produced only 10% of wild-type serine protease activity. A model is presented that outlines the pathway for plasmid integration and deletion formation in B. subtilis.

Early sporulation gene spo0F: nucleotide sequence and analysis of gene product

We have determined the sequence of a 1,162-base-pair DNA fragment containing a spo0F gene which is required for an early stage of sporulation in Bacillus subtilis. The sequence has only one long open reading frame consisting of 173 codons, which has been confirmed to be the spo0F cistron by DNA-mediated transformation and in vitro transcription. In UV-irradiated "maxicells" containing pUBSF13, the plasmid that carries cloned spo0F gene, we have observed the synthesis of a 20-kilodalton polypeptide that is absent from cells carrying a vector plasmid pUB110. The molecular weight of this protein is in agreement with the calculated molecular weight of the spo0F gene product (Mr, 19,065). The putative promoter sequences of spo0F gene were 5' T-A-T-A-A-T 3' at -10 and 5' T-T-G-A-T-T 3' at -35. An octamer sequence, 5' A-A-A-G-G-A-G-G 3', situated 8 base pairs prior to the initiation codon was found to be perfectly complementary with the 3' end of 16S ribosomal RNA. This result offers additional evidence for the proposal by Rabinowitz's group that an extensive mRNA-rRNA interaction is a requirement for efficient translation by B. subtilis ribosomes.

Translational block to expression of the Escherichia coli Tn9-derived chloramphenicol-resistance gene in Bacillus subtilis

The Gram-negative product-encoding Tn9-derived chloramphenicol-resistance (Cmr) gene can be cloned but not phenotypically expressed in Bacillus subtilis. We show that, even when transcribed from B. subtilis promoters, the ribosomal binding site for the Cmr gene does not function well in B. subtilis. The Cmr gene product, chloramphenicol acetyltransferase (CmAcTase; acetyl-CoA:chloramphenicol 3-O-acetyltransferase, EC 2.3.1.28), is detected in B. subtilis when the promoters, ribosomal binding sites, and initiation codons of B. subtilis genes are fused to the Cmr gene. These gene fusions lead to the in vivo production of mRNAs containing B. subtilis translation start signals followed in an open reading frame by the translation start site normally used by Escherichia coli to initiate translation of Cmr mRNA. Both fusion and native CmAcTase proteins are produced in E. coli, but only fusion CmAcTase is produced in B. subtilis. We conclude that the absence of native CmAcTase in B. subtilis is due to inability of the E. coli ribosomal binding site to function well in B. subtilis. Since fusion CmAcTase polypeptides are produced in E. coli, we conclude that these particular B. subtilis regulatory elements function heterologously in E. coli. The absence of a suitable binding site on the Cmr gene for B. subtilis ribosomes is consistent with reports that many E. coli genes are not expressed in B. subtilis and that E. coli mRNA functions poorly in B. subtilis in vitro translation systems. The functioning of B. subtilis regulatory sequences in E. coli is consistent with in vivo and in vitro data showing the expression of B. subtilis genes in E. coli. To confirm the hypothesis that the large CmAcTase proteins are NH2-terminal fusions of native CmAcTase we partially determined the sequence of one CmAcTase fusion protein.