Mechanism of expression of the overlapping genes of Bacillus subtilis aspartokinase II

The mechanism of expression of the overlapping genes that encode the alpha and beta subunits of aspartokinase II of Bacillus subtilis was studied by specific mutagenesis of the cloned coding sequence. Escherichia coli or B. subtilis VB31 (aspartokinase II-deficient), transformed with plasmids carrying either a deletion of the translation start site and about one-half of the coding region for the larger alpha subunit or a frameshift mutation early in the alpha subunit coding region, produced the smaller beta subunit in the absence of alpha subunit synthesis, indicating that beta subunit is not derived from alpha subunit and that its synthesis does not depend on the alpha subunit translation initiation site. The beta subunit translation start site was identified by oligonucleotide-directed mutagenesis of the putative translation start codon. Modification of the nucleotide sequence encoding methionine residue 247 of the alpha subunit from ATG to either TTA or AAT (but not GTG) abolished beta subunit synthesis but had no effect on the production of alpha subunit. This observation is consistent with peptide chain initiation by N-formylmethionine, which specifically requires an ATG or GTG sequence, and indicates that translation of the beta subunit starts at a site corresponding to Met247 of the alpha subunit. Initial studies on the function of the aspartokinase II subunits, using E. coli as a heterologous host, showed that beta subunit was not essential for the expression of the catalytic function of aspartokinase, measured in vitro and in vivo, nor for its allosteric regulation by L-lysine. Whether the beta subunit has a function specific to B. subtilis needs to be explored in a homologous expression system.     

Statistical analysis of the 5' untranslated region of human mRNA using "Oligo-Capped" cDNA libraries

We constructed 34 types of human "full-length enriched" and "5'-end enriched" cDNA libraries based on the "Oligo-Capping" method. We randomly picked and sequenced 10,000 clones from these libraries. BLAST analysis showed that about 50% of the cDNAs were identical to known genes. Among them, we selected 954 species of cDNA that should represent the entire sequence from the mRNA start sites. Compared with previously reported sequences, they were on average 45 bp longer in the 5'-end. Using these cDNA data, we statistically analyzed the sequence features of the 5'UTR. The average length of the 5'UTR was 125 bp, and there was little correlation with the corresponding mRNA length (correlation coefficient = 0.26). Of the 954 species of 5'UTR, 459 contained no in-frame terminator codon, which is against the common belief. Two hundred seventy-eight species contained at least one ATG codon upstream of the initiator ATG codon. We identified 569 upstream ATGs, in total, 63% of which adequately satisfied Kozak's criteria. These findings are contrary to the typical translation initiation model, which states that translation is initiated from the "first" ATG codon.     

Demonstration of GTG as an alternative initiation codon for the serpin endopin 2B-2

This study demonstrates GTG as a novel, alternative initiation codon for translation of bovine endopin 2B-2, a serpin protease inhibitor. Molecular cDNA cloning revealed the endopin 2B-1 and endopin 2B-2 isoforms that are predicted to inhibit papain and elastase. Notably, GTG was demonstrated as the initiation codon for endopin 2B-2, whereas endopin 2B-1 possesses ATG as its initiation codon. GTG mediated in vitro translation of 46kDa endopin 2B-2. GTG also mediated translation of EGFP by in vitro translation and by expression in mammalian cells. Notably, mutagenesis of GTG to GTC resulted in the absence of EGFP expression in cells. GTG produced a lower level of protein expression compared to ATG. The use of GTG as an initiation codon to direct translation of endopin 2B, as well as the heterologous protein EGFP, demonstrates the role of GTG in the regulation of mRNA translation in mammalian cells. Significantly, further analyses of mammalian genomes based on GTG as an alternative initiation codon may predict new candidate gene products expressed by mammalian and human genomes.     

Interpreting cDNA sequences: Some insights from studies on translation

This review discusses some rules for assessing the completeness of a cDNA sequence and identifying the start site for translation. Features commonly invoked—such as an ATG codon in a favorable context for initiation, or the presence of an upstream in-frame terminator codon, or the prediction of a signal peptide-like sequence at the amino terminus—have some validity; but examples drawn from the literature illustrate limitations to each of these criteria. The best advice is to inspect a cDNA sequence not only for these positive features but also for the absence of certain negative indicators. Three specific warning signs are discussed and documented: (i) The presence of numerous ATG codons upstream from the presumptive start site for translation often indicates an aberration (sometimes a retained intron) at the 5′ end of the cDNA. (ii) Even one strong, upstream, out-of-frame ATG codon poses a problem if the reading frame set by the upstream ATG overlaps the presumptive start of the major open reading frame. Many cDNAs that display this arrangement turn out to be incomplete; that is, the out-of-frame ATG codon is within, rather than upstream from, the protein coding domain. (iii) A very weak context at the putative start site for translation often means that the cDNA lacks the authentic initiator codon. In addition to presenting some criteria that may aid in recognizing incomplete cDNA sequences, the review includes some advice for using in vitro translation systems for the expression of cDNAs. Some unresolved questions about translational regulation are discussed by way of illustrating the importance of verifying mRNA structures before making deductions about translation. Received: 24 April 1996 / Accepted: May 1996     

Nucleotide sequence and transcript analysis of three photosystem II genes from the cyanobacterium Synechococcus sp. PCC7942

The genome of the cyanobacterium Synechococcus sp. PCC7942 contains two genes encoding the D2 polypeptide of photosystem II (PSII), which are designated here as psbDI and psbDII. The psbDI gene, like the psbD gene of plant chloroplasts, is cotranscribed with and overlaps the open reading frame of the psbC gene, encoding the PSII protein CP43. The psbDII gene is not linked to psbC, and appears to be transcribed as a monocistronic message. The two psbD genes encode identical polypeptides of 352 amino acids, which are 86% conserved with the D2 polypeptide of spinach. In plants, the translational start codon of the psbC gene has been reported to be an ATG codon 50 bp upstream from the end of the psbD gene. This triplet is not present in the psbDI sequence of Synechococcus sp., but is replaced by ACG, a codon which is very unlikely to initiate translation. Translation of the psbC gene may begin at a GTG codon which overlap the psbDI open reading frame by 14 bp and is preceded by a block of homology to the 3' end of the 16S ribosomal RNA, a potential ribosome-binding site. There are only two bp differences between the sequences of the two psbD genes; one of these results in substitution in psbDII of GCG for the presumed GTG start codon in psbDI.     

Oligonucleotide Directed Mutagenesis of the E. coli hisS Gene: Introduction of an Ncoi Restriction Site at the Initiating GTG and Cloning of the Mutated Gene to the Expression Vector pKK 233–2

Abstract

Site directed mutagenesis of the E. coli his gene with a double mismatch primer changed the initiation codon GTG to ATG and introduced an Ncol restriction site at the start codon. The promoter-deleted structural gene was cloned to the expression vector pKK 233–2.     

Start codon in the <Emphasis Type="Italic">Bacillus intermedius</Emphasis> gene for serine proteinase

The translation initiation site was determined for Bacillus intermedius aprBi (AN AY754946), coding for extracellular subtilisin-like serine proteinase secreted at the stationary growth phase. Analysis of the aprBi open reading frame revealed three potential translation start sites (TTG, GTG, and ATG). Using the SignalP online freeware program, the probabilities of their functional activity were evaluated. To identify the translation start, modified subtilisin-like protease genes with nucleotide replacements in putative start codons were obtained by oligonucleotide-directed mutagenesis. The expression of these genetic constructs was investigated in protease-deficient strain B. subtilis AJ73. The results indicated that aprBi translation starts from the alternative GTG codon.     

Identification of the initiation codon for the atpB gene in Chlamydomonas chloroplasts excludes translation of a precursor form of the beta subunit of the ATP synthase

The chloroplast atpB gene of Chlamydomonas reinhardtii, which encodes the beta subunit of the ATP synthase, contains three in-frame ATGs that are candidate translation initiation codons. An earlier study revealed that the N terminus of the assembled beta subunit maps at the +2 position with respect to the second in-frame methionine codon (Fiedler et al. 1995). Using chloroplast transformation, we have examined the possibility that either of the two additional in-frame ATG codons is competent for translation initiation. We provide evidence that translation of atpB is initiated exclusively at the second ATG codon. We conclude that the beta subunit is not synthesized with an N-terminal leader before its assembly into a functional ATP synthase complex.     

Point mutations define a sequence flanking the AUG initiator codon that modulates translation by eukaryotic ribosomes

By analyzing the effects of single base substitutions around the ATG initiator codon in a cloned preproinsulin gene, I have identified ACCATGG as the optimal sequence for initiation by eukaryotic ribosomes. Mutations within that sequence modulate the yield of proinsulin over a 20-fold range. A purine in position -3 (i.e., 3 nucleotides upstream from the ATG codon) has a dominant effect; when a pyrimidine replaces the purine in position -3, translation becomes more sensitive to changes in positions -1, -2, and +4. Single base substitutions around an upstream, out-of-frame ATG codon affect the efficiency with which it acts as a barrier to initiating at the downstream start site for preproinsulin. The optimal sequence for initiation defined by mutagenesis is identical to the consensus sequence that emerged previously from surveys of translational start sites in eukaryotic mRNAs. The mechanism by which nucleotides flanking the ATG codon might exert their effect is discussed.     

The translation start signal region of TEM beta-lactamase mRNA is responsible for heat shock-induced repression of amp gene expression in Escherichia coli.

pBR322 contains the amp gene encoding beta-lactamase. When Escherichia coli carrying this plasmid is exposed to heat shock, beta-lactamase synthesis is repressed transiently at the translational level. To identify the DNA element responsible for this translational repression, DNA segments containing the translation start region of the amp gene were excised from pAT153 and fused in frame with the lacZ reading frame in the open reading frame vector pORF1. These constructs were introduced into E. coli, and the effect of heat shock of the cells on the synthesis of beta-galactosidase starting from the amp start codon was examined. As is the case for pBR322-encoded synthesis of beta-lactamase, the synthesis of beta-galactosidase encoded by the fused genes also ceased transiently upon heat shock. It is concluded that the heat shock-induced repression of the amp gene occurs at the initiation step of translation. As far as the present study is concerned, the minimum DNA segment responsible for the repression is AT TGA AAA AGG AAG AGT ATG AG, which includes the Shine-Dalgarno sequence (AAGGA) and the initiation codon (ATG).     

Characterization of a single soybean cDNA encoding cytosolic and glyoxysomal isozymes of aspartate aminotransferase

A soybean cDNA clone, pSAT1, which encodes both the cytosolic and glyoxysomal isozymes of aspartate aminotransferase (AAT; EC 2.6.1.1) was isolated. Genomic Southern blots and analysis of genomic clones indicated pSAT1 was encoded by a single copy gene. pSAT1 contained an open reading frame with ca. 90% amino acid identity to alfalfa and lupin cytosolic AAT and two in-frame start codons, designated ATG1 and ATG2. Alignment of this protein with other plant cytosolic AAT isozymes revealed a 37 amino acid N-terminal extension with characteristics of a peroxisomal targeting signal, designated PTS2, including the modified consensus sequence RL-X₅-HF. The second start codon ATG2 aligned with previously reported start codons for plant cytosolic AAT cDNAs. Plasmids constructed to express the open reading frame initiated by each of the putative start codons produced proteins with AAT activity in Escherichia coli. Immune serum raised against the pSAT1-encoded protein reacted with three soybean AAT isozymes, AAT1 (glyoxysomal), AAT2 (cytosolic), and AAT3 (subcellular location unknown). We propose the glyoxysomal isozyme AAT1 is produced by translational initiation from ATG1 and the cytosolic isozyme AAT2 is produced by translational initiation from ATG2. N-terminal sequencing of purified AAT1 revealed complete identity with the pSAT1-encoded protein and was consistent with the processing of the PTS2. Analysis of cytosolic AAT genomic sequences from several other plant species revealed conservation of the two in-frame start codons and the PTS2 sequence, suggesting that these other species may utilize a single gene to generate both cytosolic and glyoxysomal or peroxisomal forms of AAT.