Interaction of the regulatory protein NicR1 with the promoter region of the pAO1-encoded 6-hydroxy-D-nicotine oxidase gene of Arthrobacter oxidans

The D,L-nicotine catabolism of the Gram-positive soil bacterium Arthrobacter oxidans is linked to the presence within the cells of the 160 kb catabolic plasmid pAO1. pAO1-cured cells lost the catabolic enzymes and reintroduction of pAO1 by electroporation into cured cells reestablished the nic+ phenotype. DNA band shift assays with extracts from cured and pAO1+ cells suggested that pAO1 encodes the regulatory protein NicR1. Footprint analysis revealed that two homologous palindromes (IR1 and IR2), present in the 5'-regulatory region of the 6-HDNO gene, were protected from DNase I digestion. Binding of NicR1 to the palindromes is symmetrical, co-operative, and stronger to IR1 containing the 6-HDNO gene promoter than to IR2. Site-directed mutagenesis revealed that steric constraints and sequence requirements for NicR1-binding are located exclusively in the palindromic sequences. Deletions and insertions in the interpalindromic region and in the 6-HDNO promoter -10 sequence had no effect on the binding characteristics of NicR1 to the 6-HDNO regulatory region. Acting as a repressor, NicR1 prevents binding of the E. coli RNA-polymerase to the consensus sigma 70 promoter in vitro. However, the interaction of NicR1 with the 6-HDNO promoter region in extracts of nicotine-induced cells from various growth stages did not differ from that observed with extracts of nicotine-uninduced cells.     

Binding of FAD to 6-hydroxy-D-nicotine oxidase apoenzyme prevents degradation of the holoenzyme.

Expression of the 6-hydroxy-D-nicotine oxidase (6-HDNO) gene from Arthrobacter oxidans cloned into Escherichia coli showed a marked temperature-dependence. Transformed E. coli cells grown at 30 degrees C exhibited a several-fold higher 6-HDNO activity than did cells grown at 37 degrees C. This effect did not depend on the promoter used for expression of the cloned gene in E. coli, nor was it an effect of 6-HDNO mRNA instability at 37 degrees C. Studies performed in vivo and in vitro revealed that an increased susceptibility of apo-6-HDNO to proteolytic attack at 37 degrees C was responsible for the observed phenomenon. Extracts from cells grown at 37 degrees C showed on Western blots a decrease in immunologically detectable 6-HDNO polypeptide when compared with extracts from cells grown at 30 degrees C. The 6-HDNO polypeptide is covalently modified by attachment of the cofactor FAD to a histidine residue. It could be shown that covalent flavinylation of the apoenzyme in vitro, i.e. formation of holoenzyme, by incubation of cell extracts with FAD and phosphoenolpyruvate protected the 6-HDNO polypeptide from degradation at 37 degrees C. Of a variety of proteinase inhibitors tested only the cysteine-proteinase inhibitor L-3-trans-carboxyoxiran-2-carbonyl-L-leucylagmatine (E64) prevented degradation, by up to 70%, of the apoenzyme.     

Plasmid pAO1 of Arthrobacter oxidans encodes 6-hydroxy-D-nicotine oxidase: cloning and expression of the gene in Escherichia coli

Summary The 160 kb plasmid pAO1 from Arthrobacter oxidans (Brandsch and Decker 1984) was subcloned in Escherichia coli with the aid of the plasmid vectors pUR222 and pBR322. Screening of the recombinant clones for enzyme activity revealed that the flavoenzyme 6-hydroxy-d-nicotine oxidase (6-HDNO), one of the enzymes of the nicotine-degradative pathway in A. oxidans, is encoded on pAO1. Immunoprecipitation of ³⁵S-methionine-labelled E. coli cells with 6-HDNO-specific antiserum and expression of recombinant plasmid DNA in E. coli maxicells revealed that 6-HDNO is made as a 52,000 dalton protein, approximately 4,500 daltons larger than 6-HDNO from A. oxidans. The 6-HDNO activity was constitutively expressed in E. coli cells, possibly from an A. oxidans promoter, as shown by subcloning of the 6-HDNO gene in pBR322, using the expression vector pKK223-3 and the promoter probe vector pCB192.     

Isolation and identification of fxsA, an Escherichia coli gene that can suppress F exclusion of bacteriophage T7.

A selection for mutants of Escherichia coli that survive coexpression of bacteriophage T7 gene 10 and plasmid F pifA has allowed the identification of a newly defined genetic locus, fxsA. fxsA is located at 94.1 min on the E. coli chromosome; the gene is monocistronic and non-essential for growth. Overexpression of fxsA is necessary for resistance to the toxicity of T7 gene 10 in the presence of pifA; the original mutant strain contains a promoter-up mutation, changing a G residue to the "invariant" T in the -10 hexamer of a sigma(70)promoter. This chromosomal mutation causes a 25-fold increase in the level of fxsA mRNA. The initiation codon of fxsA is shown to be UUG, and the FxsA protein is then deduced to consist of 158 amino acid residues. A similar mutant selection that demanded cell survival to a challenge of T7 gene 1.2 and pifA also resulted in the isolation of the identical promoter-up mutation that affects expression of fxsA. The increased levels of FxsA resulting from the promoter-up mutation allow phage T7 to avoid exclusion by the F plasmid, presumably by protecting the cell from premature death due to gene 10 or to gene 1.2 expression in the presence of the PifA protein.     

Rare initiation codons are regulators of expression of the rpoC gene

Translation of the rpoC genes in Escherichia coli and Salmonella typhimurium is known to start from the GUG codon. Now, using toeprint analysis we have shown UUG to be the initiation codon of the Pseudomonas putida rpoC gene. IF3 does not seem to proofread initiation at the UUG codon. The rpoC genes of P. putida, E. coli, and S. typhimurium, which use rare start codons, have strong SD-domains AGGAGG (P. p.) and GGGAG (E. c., S. t.), optimal seven-nucleotide spacing between SD and start codons, and good second codon AAA. We suggest that rpoC presents an infrequent case of the regulation of translation initiation by selecting the start codon.     

A mutant Escherichia coli sigma 70 subunit of RNA polymerase with altered promoter specificity

A mutation is described that alters the promoter specificity of sigma 70, the primary sigma factor of Escherichia coli RNA polymerase. In strains carrying both the mutant and wild-type sigma gene (rpoD), the mutant sigma causes a large increase in the activity of mutant P22 ant promoters with A.T or C.G instead of the wild-type, consensus G.C base-pair at position -33, the third position of the consensus -35 hexamer 5'-TTGACA-3'. There is little or no effect on the activities of the wild-type and 23 other mutant ant promoters, including one with T.A at -33. The mutant sigma also activates E. coli lac promoters with A.T or C.G, but not T.A, at the corresponding position. The rpoD mutation (rpoD-RH588) changes a CGT codon to CAT. The corresponding change in sigma 70 is Arg588----His. This residue is in a region that is conserved among most sigma factors, a region that is also homologous with the helix-turn-helix motif of DNA-binding proteins. These results suggest that this region of sigma 70 is directly involved in recognition of the -35 hexamer.     

Expression of tetanus toxin fragment C in E. coli: high level expression by removing rare codons.

Tetanus toxin fragment C had been previously expressed in Escherichia coli at 3-4% cell protein. The codon bias for tetanus toxin in Clostridium tetani is very different from that of highly expressed homologous genes in E. coli, resulting in the presence of many rare E. coli codons in the sequence encoding fragment C. We have replaced the coding sequence by sequence optimized for codon usage in E. coli, and show that the expression of fragment C is increased. Although the level of mRNA also increased this appeared to be a secondary consequence of more efficient translation. Complete sequence replacement increased expression to approximately 11-14% cell protein but only after the promoter strength had been improved.     

On the role of the Escherichia coli RNA polymerase sigma 70 region 4.2 and alpha-subunit C-terminal domains in promoter complex formation on the extended -10 galP1 promoter

Bacterial promoters of the extended -10 class contain a single consensus element, and the DNA sequence upstream of this element is not critical for promoter activity. Open promoter complexes can be formed on an extended -10 Escherichia coli galP1 promoter at temperatures as low as 6 degrees C, when complexes on most promoters are closed. Here, we studied the contribution of upstream contacts to promoter complex formation using galP1 and its derivatives lacking the extended -10 motif and/or containing the -35 promoter consensus element. A panel of E. coli RNA polymerase holoenzymes containing two, one, or no alpha-subunit C-terminal domains (alpha CTD) and either wild-type sigma 70 subunit or sigma 70 lacking region 4.2 was assembled and tested for promoter complex formation. At 37 degrees C, alpha CTD and sigma 70 region 4.2 were individually dispensable for promoter complex formation on galP1 derivatives with extended -10 motif. However, no promoter complexes formed when both alpha CTD and sigma 70 region 4.2 were absent. Thus, in the context of an extended -10 promoter, alpha CTD and sigma 70 region 4.2 interactions with upstream DNA can functionally substitute for each other. In contrast, at low temperature, alpha CTD and sigma 70 region 4.2 interactions with upstream DNA were found to be functionally distinct, for sigma 70 region 4.2 but not alpha CTD was required for open promoter complex formation on galP1 derivatives with extended -10 motif. We propose a model involving sigma 70 region 4.2 interaction with the beta flap domain that explains these observations.     

Translational efficiency of a non-AUG initiation codon is significantly affected by its sequence context in yeast

Previous studies have shown that translation of mrna for yeast glycyl-tRNA synthetase is alternatively initiated from UUG and a downstream AUG initiation codon. Evidence presented here shows that unlike an AUG initiation codon, efficiency of this non-AUG initiation codon is significantly affected by its sequence context, in particular the nucleotides at positions -3 to -1 relative to the initiation codon. A/A/R (R represents A Or G) and C/G/C appear to be the most and least favorable sequences at these positions, respectively. Mutation of the native context sequence -3 to -1 from AAA to CGC reduced translation initiation from the UUG codon up to 32-fold and resulted in loss of mitochondrial respiration. although an AUG initiation codon is, in general, unresponsive to context changes in yeast, an AAA (-3 to -1) to CGC mutation still reduced its initiating activity up to 8-fold under similar conditions. these results suggest that sequence context is more important for translation initiation in yeast than previously appreciated.     

Cooperative effects by the initiation codon and its flanking regions on translation initiation

The purine-rich Shine-Dalgarno (SD) sequence located a few bases upstream of the mRNA initiation codon supports translation initiation by complementary binding to the anti-SD in the 16S rRNA, close to its 3' end. AUG is the canonical initiation codon but the weaker UUG and GUG codons are also used for a minority of genes. The codon sequence of the downstream region (DR), including the +2 codon immediately following the initiation codon, is also important for initiation efficiency. We have studied the interplay between these three initiation determinants on gene expression in growing Escherichia coli. One optimal SD sequence (SD(+)) and one lacking any apparent complementarity to the anti-SD in 16S rRNA (SD(-)) were analyzed. The SD(+) and DR sequences affected initiation in a synergistic manner and large differences in the effects were found. The gene expression level associated with the most efficient of these DRs together with SD(-) was comparable to that of other DRs together with SD(+). The otherwise weak initiation codon UUG, but not GUG, was comparable with AUG in strength, if placed in the context of two of the DRs. The +2 codon was one, but not the only, determinant for this unexpectedly high efficiency of UUG.