Characterization of the ksgA gene of Escherichia coli determining kasugamycin sensitivity

In the plasmid pUC8ksgA7, the coding region of the ksgA gene is preceded by the lac promoter (Plac) and a small open reading frame (ORF). This ORF of 15 codons is composed of nucleotides derived from the lacZ gene, a multiple cloning site and the ksgA gene itself. The reading frame begins with the ATG initiation codon of lacZ and ends a few nucleotides beyond the ATG start codon of ksgA. The ksgA gene is not preceded by a Shine-Dalgarno (SD) signal. Cells transformed with pUC8ksgA7 produce active methylase, the product of the ksgA gene. Introduction of an in-phase TAA stop codon in the small ORF abolishes methylase production in transformed cells. On the plasmid pUC8ksgA5, which contains the entire ksgA region, the promoter of the ksgA gene was found to reside in a 380 base pair Bgl1-Pvu2 restriction fragment, partly overlapping the ksgA gene, by two independent methods. Cloning of this fragment in front of the galK gene in plasmid pKO1 stimulates galactokinase activity in transformants and its insertion into the expression vector pKL203 makes beta-galactosidase synthesis independent of the presence of Plac. The sequence of the Bgl1-Pvu2 fragment was determined and a putative promoter sequence identified. An SD signal could not be distinguished at a proper distance upstream from the ksgA start codon. Instead, an ORF of 13 codons starting with ATG in tandem with an SD signal and ending 4 codons ahead of the ksgA gene was identified. This suggests that translation of the ORF is required for expression of the ksgA gene.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dual translational initiation sites control function of the lambda S gene.

Lysis gene S of phage lambda has a 107 codon reading frame beginning with the codons Met1-Lys2-Met3. Genetic data have suggested that translational initiation occurs at both Met1 and Met3, generating two polypeptides, S107 and S105 respectively. We have proposed a model in which the proper scheduling of lysis depends on the partition of translational initiations between the two start codons. Here, using in vitro methods, we show that two stem-loop structures, one immediately upstream of the reading frame and a second approximately 10 codons within the gene, control the partitioning event. Utilizing primer-extension inhibition or 'toeprinting', we show that the two S start codons are served by two adjacent Shine-Dalgarno sequences. Moreover, the timing of lysis supported by the wild-type and a number of mutant alleles in vivo can be correlated with the ratio of ternary complex formation over Met1 and Met3 in vitro. Thus the regulation of the S gene is unique in that the products of two adjacent in-frame initiation events have opposing function.     

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.     

Molecular mechanism of stop codon recognition by eRF1: a wobble hypothesis for peptide anticodons

We propose that the amino acid residues 57/58 and 60/61 of eukaryotic release factors (eRF1s) (counted from the N-terminal Met of human eRF1) are responsible for stop codon recognition in protein synthesis. The proposal is based on amino acid exchanges in these positions in the eRF1s of two ciliates that reassigned one or two stop codons to sense codons in evolution and on the crystal structure of human eRF1. The proposed mechanism of stop codon recognition assumes that the amino acid residues 57/58 interact with the second and the residues 60/61 with the third position of a stop codon. The fact that conventional eRF1s recognize all three stop codons but not the codon for tryptophan is attributed to the flexibility of the helix containing these residues. We suggest that the helix is able to assume a partly relaxed or tight conformation depending on the stop codon recognized. The restricted codon recognition observed in organisms with unconventional eRF1s is attributed mainly to the loss of flexibility of the helix due to exchanged amino acids.     

Codon replacement in the PGK1 gene of Saccharomyces cerevisiae: experimental approach to study the role of biased codon usage in gene expression.

The coding sequences of genes in the yeast Saccharomyces cerevisiae show a preference for 25 of the 61 possible coding triplets. The degree of this biased codon usage in each gene is positively correlated to its expression level. Highly expressed genes use these 25 major codons almost exclusively. As an experimental approach to studying biased codon usage and its possible role in modulating gene expression, systematic codon replacements were carried out in the highly expressed PGK1 gene. The expression of phosphoglycerate kinase (PGK) was studied both on a high-copy-number plasmid and as a single copy gene integrated into the chromosome. Replacing an increasing number (up to 39% of all codons) of major codons with synonymous minor ones at the 5' end of the coding sequence caused a dramatic decline of the expression level. The PGK protein levels dropped 10-fold. The steady-state mRNA levels also declined, but to a lesser extent (threefold). Our data indicate that this reduction in mRNA levels was due to destabilization caused by impaired translation elongation at the minor codons. By preventing translation of the PGK mRNAs by the introduction of a stop codon 3' and adjacent to the start codon, the steady-state mRNA levels decreased dramatically. We conclude that efficient mRNA translation is required for maintaining mRNA stability in S. cerevisiae. These findings have important implications for the study of the expression of heterologous genes in yeast cells.     

The Crithidia fasciculata RNH1 gene encodes both nuclear and mitochondrial isoforms of RNase H

The Crithidia fasciculata RNH1 gene encodes an RNase H, an enzyme that specifically degrades the RNA strand of RNA–DNA hybrids. The RNH1 gene is contained within an open reading frame (ORF) predicted to encode a protein of 53.7 kDa. Previous work has shown that RNH1 expresses two proteins: a 38 kDa protein and a 45 kDa protein which is enriched in kinetoplast extracts. Epitope tagging of the C-terminus of the RNH1 gene results in localization of the protein to both the kinetoplast and the nucleus. Translation of the ORF beginning at the second in-frame methionine codon predicts a protein of 38 kDa. Insertion of two tandem stop codons between the first ATG codon and the second in-frame ATG codon of the ORF results in expression of only the 38 kDa protein and the protein localizes specifically to the nucleus. Mutation of the second methionine codon to a valine codon prevents expression of the 38 kDa protein and results in exclusive production of the 45 kDa protein and localization of the protein only in the kinetoplast. These results suggest that the kinetoplast enzyme results from processing of the full-length 53.7 kDa protein. The nuclear enzyme appears to result from translation initiation at the second in-frame ATG codon. This is the first example in trypanosomatids of the production of nuclear and mitochondrial isoforms of a protein from a single gene and is the only eukaryotic gene in the RNase HI gene family shown to encode a mitochondrial RNase H.     

Aminoglycosides decrease glutathione peroxidase-1 activity by interfering with selenocysteine incorporation

Cellular glutathione peroxidase is a key intracellular antioxidant enzyme that contains a selenocysteine residue at its active site. Selenium, a selenocysteine incorporation sequence in the 3'-untranslated region of the glutathione peroxidase mRNA, and other translational cofactors are necessary for "read-through" of a UGA stop codon that specifies selenocysteine incorporation. Aminoglycoside antibiotics facilitate read-through of premature stop codons in prokayotes and eukaryotes. We studied the effects of G418, an aminoglycoside, on cellular glutathione peroxidase expression and function in mammalian cells. Insertion of a selenocysteine incorporation element along with a UGA codon into a reporter construct allows for read-through only in the presence of selenium. G418 increased read-through in selenium-replete cells as well as in the absence of selenium. G418 treatment increased immunodetectable endogenous or recombinant glutathione peroxidase but reduced the specific activity of the enzyme. Tandem mass spectrometry experiments indicated that G418 caused a substitution of l-arginine for selenocysteine. These data show that G418 can affect the biosynthesis of this key antioxidant enzyme by promoting substitution at the UGA codon.     

Efficiencies of translation in three reading frames of unusual non-ORF sequences isolated from phage display.

An unusual nucleotide sequence, called H10, was previously isolated by biopanning with a random peptide library on filamentous phage. The sequence encoded a peptide that bound to the growth hormone binding protein. Despite the fact that the H10 sequence can be expressed in Escherichia coli as a fusion to the gene III minor coat protein of the M13 phage, the sequence contained two TGA stop codons in the zero frame. Several mutant derivatives of the H10 sequence carried not only a stop codon, but also showed frameshifts, either +1 or -1 in individual isolates, between the H10 start and the gene III sequences. In this work, we have subcloned the H10 sequence and three of its derivatives (one requiring a +1 reading frameshift for expression, one requiring a -1 reading frameshift, and one open reading frame) in gene fusions to a reporter beta-galactosidase gene. These sequences have been cloned in all three reading frames relative to the reporter. The non-open reading frame constructs gave (surprisingly) high expression of the reporter (10-40% of control vector expression levels) in two out of the three frames. A site-directed mutant of the TGA stop codon (to TTA) in the +1 shifter greatly reduced the frameshift and gave expression primarily in the zero frame. By contrast, a site-directed mutant of the TGA in the -1 shifter had little effect on the pattern of expression, and alteration of the first TGA (of two) in H10 itself paradoxically reduced expression by half. We believe these phenomena to reflect a translational recoding mechanism in which ribosomes switch reading frames or read past stop codons upon encountering a signal encoded in the nucleotide sequence of the mRNA, because both the open reading frame derivative (which has six nucleotide changes from parental H10) and the site-directed mutant of the +1 shifter, primarily expressed the reporter only in the zero frame.     

The lethal lambda S gene encodes its own inhibitor.

The 107 codon reading frame of the lambda lysis gene S begins with the codon sequence Met1-Lys2-Met3..., and it has been demonstrated in vitro that both Met codons are used for translational starts. Furthermore, the partition of initiation events at the two start codons strongly affects the scheduling of lysis. We have presented a model in which the longer product, S107, acts as an inhibitor of the shorter product, S105, the lethal lysis effector, despite the fact that the two molecules differ only in the Met-Lys residues at the amino terminus of S107. Using immunological and biochemical methods, we show in this report that the two predicted protein products, S105 and S107, are detectable in vivo as stable, membrane-bound molecules. We show that S107 acts as an inhibitor in trans, and that its inhibitory function is entirely defined by the positively charged Lys2 residue. Moreover, our data show that energy poisons abolish the inhibitory function of S107 and simultaneously convert S107 into a lysis effector. We propose a two step model for the lethal action of gene S: first, induction of the S gene results in the accumulation of S105 and S107 molecules in mixed oligomeric patches in the cytoplasmic membrane; second, S monomers rearrange by lateral diffusion within the patch to form an aqueous pore. The R gene product, a transglycosylase, is released through the pore to the periplasm, resulting in destruction of the peptidoglycan and bursting of the cell. According to this model, the lateral diffusion step is inhibited by the energized state of the membrane.(ABSTRACT TRUNCATED AT 250 WORDS)     

Molecular cloning and DNA sequencing of the Escherichia coli K-12 ald gene encoding aldehyde dehydrogenase.

The gene ald, encoding aldehyde dehydrogenase, has been cloned from a genomic library of Escherichia coli K-12 constructed with plasmid pBR322 by complementing an aldehyde dehydrogenase-deficient mutant. The ald region was sequenced, and a single open reading frame of 479 codons specifying the subunit of the aldehyde dehydrogenase enzyme complex was identified. Determination of the N-terminal amino acid sequence of the enzyme protein unambiguously established the identity and the start codon of the ald gene. Analysis of the 5'- and 3'-flanking sequences indicated that the ald gene is an operon. The deduced amino acid sequence of the ald gene displayed homology with sequences of several aldehyde dehydrogenases of eukaryotic origin but not with microbial glyceraldehyde-3-phosphate dehydrogenase.