Translation Initiation Signals Research Articles

1R0900 数量化法によるmRNAの翻訳開始信号の解析 : +4から+6位置の塩基の信号強度に与える効果(22.生命情報科学,一般演題,日本生物物理学会第40回年会)

1R0900 数量化法によるmRNAの翻訳開始信号の解析 : +4から+6位置の塩基の信号強度に与える効果(22.生命情報科学,一般演題,日本生物物理学会第40回年会)

Multiple mechanisms for degradation of bacteriophage T4 soc mRNA.

The dmd gene of bacteriophage T4 is required for regulation of mRNA stability in a stage-dependent manner during infection. When this gene is mutated, late genes are globally silenced because of rapid degradation of mRNAs. To investigate the mechanism of such mRNA degradation, we analyzed the late gene soc transcripts. The degradation of soc mRNA was remarkably stabilized when its ability to be translated was impaired; either disruption of translation initiation signals or elimination of termination codons was effective in stabilization of soc mRNA and removal of elongation modestly stabilized it. Even in the absence of translation, however, the residual activity was still significant. These results suggested that the degradation of soc transcripts was promoted by two different mechanisms; one is dependent on translation and the other independent of translation. We found several cleavages introduced into soc RNA specifically when the dmd gene was mutated; some of them could be linked to polypeptide chain elongation and termination, suggesting the correlation with ribosomal action, and the others were independent of translation.

Quantification analysis of translation initiation signal in vertebrate mRNAs: effect of nucleotides at positions +4(-)+6 upon efficiency of translation initiation.

Concerning the translation initiation signal in vertebrate mRNAs, a consensus, sequence, (GCC)GCC(A or G) CCATGG, has been proposed, but actual initiation sequences differ from it in a greater or lesser degree. Kozak monitored selection by ribosomes of the first versus second ATG codons as a function of mutations introduced at positions +4, and +6 of the first ATG codon. Codons possessing G at +4 strongly enhanced selection of the first ATG codon. However, ATG codon recognition was unaffected by most mutations in positions and +6. These data were well understood by our quantification analysis.

Selective stimulation of translation of leaderless mRNA by initiation factor 2: evolutionary implications for translation

Translation initiation in bacteria involves a stochastic binding mechanism in which the 30S ribosomal subunit first binds either to mRNA or to initiator tRNA, fMet-tRNA(f)(Met). Leaderless lambda cI mRNA did not form a binary complex with 30S ribosomes, which argues against the view that ribosomal recruitment signals other than a 5'-terminal start codon are essential for translation initiation of these mRNAs. We show that, in Escherichia coli, translation initiation factor 2 (IF2) selectively stimulates translation of lambda cI mRNA in vivo and in vitro. These experiments suggest that the start codon of leaderless mRNAs is recognized by a 30S-fMet-tRNA(f)(Met)-IF2 complex, an intermediate equivalent to that obligatorily formed during translation initiation in eukaryotes. We further show that leaderless lambda cI mRNA is faithfully translated in vitro in both archaebacterial and eukaryotic translation systems. This suggests that translation of leaderless mRNAs reflects a fundamental capability of the translational apparatus of all three domains of life and lends support to the hypothesis that the translation initiation pathway is universally conserved.

Signal-exon trap: a novel method for the identification of signal sequences from genomic DNA.

We describe a genomic DNA-based signal sequence trap method, signal-exon trap (SET), for the identification of genes encoding secreted and membrane-bound proteins. SET is based on the coupling of an exon trap to the translation of captured exons, which allows screening of the exon-encoded polypeptides for signal peptide function. Since most signal sequences are expected to be located in the 5'-terminal exons of genes, we first demonstrate that trapping of these exons is feasible. To test the applicability of SET for the screening of complex genomic DNA, we evaluated two critical features of the method. Specificity was assessed by the analysis of random genomic DNA and efficiency was demonstrated by screening a 425 kb YAC known to contain the genes of four secretory or membrane-bound proteins. All trapped clones contained a translation initiation signal followed by a hydrophobic stretch of amino acids representing either a known signal peptide, transmembrane domain or novel sequence. Our results suggest that SET is a potentially useful method for the isolation of signal sequence-containing genes and may find application in the discovery of novel members of known secretory gene clusters, as well as in other positional cloning approaches.

Functional analysis of heterologous holin proteins in a λΔS genetic background

Holins are small hydrophobic proteins causing non-specific membrane lesions at the end of bacteriophage multiplication, to promote access of the murein hydrolase to their substrate. We have established a λΔS genetic system, which enables functional expression of holins from various phages in an isogenic phage λ background, and allows qualitative evaluation of their ability to support lysis of Escherichia coli cells. Synthesis of Holins is under control of native λ transcription and translation initiation signals, and the temperature-sensitive CIts857 repressor. A number of different holins were tested in this study. The opposing action of phage λ S105 and S107 holin variants in lysis timing could be confirmed, whereas we found evidence for a functionally non-homologous dual translational start motif in the Listeria phage Hol500 holin, i.e., the Hol500-96 polypeptide starting at Met-1 revealed a more distinct lytic activity as compared to the shorter product Hol500-93. The largest holin known, HolTW from a Staphylococcus aureus phage, revealed an early lysis phenotype in the λΔSthf background, which conferred a plaque forming defect due to premature lysis. Mutant analysis revealed that an altered C-terminus and/or a V52L substitution were sufficient to delay lysis and enable plaque formation. These results suggest that the extensively charged HolTW C-terminus may be important in regulation of lysis timing. The gene 17.5 product of E. coli phage T7 was found to support sudden, saltatory cell lysis in the λΔSthf background, which clearly confirms its holin character. In conclusion, λΔSthf offers a useful genetic tool for studying the structure–function relationship of the extremely heterogeneous group of holin protein orthologs.

Functional analysis of heterologous holin proteins in a lambdaDeltaS genetic background.

Holins are small hydrophobic proteins causing non-specific membrane lesions at the end of bacteriophage multiplication, to promote access of the murein hydrolase to their substrate. We have established a lambdaDeltaS genetic system, which enables functional expression of holins from various phages in an isogenic phage lambda background, and allows qualitative evaluation of their ability to support lysis of Escherichia coli cells. Synthesis of Holins is under control of native lambda transcription and translation initiation signals, and the temperature-sensitive CIts857 repressor. A number of different holins were tested in this study. The opposing action of phage lambda S105 and S107 holin variants in lysis timing could be confirmed, whereas we found evidence for a functionally non-homologous dual translational start motif in the Listeria phage Hol500 holin, i.e., the Hol500-96 polypeptide starting at Met-1 revealed a more distinct lytic activity as compared to the shorter product Hol500-93. The largest holin known, HolTW from a Staphylococcus aureus phage, revealed an early lysis phenotype in the lambdaDeltaSthf background, which conferred a plaque forming defect due to premature lysis. Mutant analysis revealed that an altered C-terminus and/or a V52L substitution were sufficient to delay lysis and enable plaque formation. These results suggest that the extensively charged HolTW C-terminus may be important in regulation of lysis timing. The gene 17.5 product of E. coli phage T7 was found to support sudden, saltatory cell lysis in the lambdaDeltaSthf background, which clearly confirms its holin character. In conclusion, lambdaDeltaSthf offers a useful genetic tool for studying the structure-function relationship of the extremely heterogeneous group of holin protein orthologs.

Homology-based gene structure prediction: simplified matching algorithm using a translated codon (tron) and improved accuracy by allowing for long gaps.

Locating protein-coding exons (CDSs) on a eukaryotic genomic DNA sequence is the initial and an essential step in predicting the functions of the genes embedded in that part of the genome. Accurate prediction of CDSs may be achieved by directly matching the DNA sequence with a known protein sequence or profile of a homologous family member(s). A new convention for encoding a DNA sequence into a series of 23 possible letters (translated codon or tron code) was devised to improve this type of analysis. Using this convention, a dynamic programming algorithm was developed to align a DNA sequence and a protein sequence or profile so that the spliced and translated sequence optimally matches the reference the same as the standard protein sequence alignment allowing for long gaps. The objective function also takes account of frameshift errors, coding potentials, and translational initiation, termination and splicing signals. This method was tested on Caenorhabditis elegans genes of known structures. The accuracy of prediction measured in terms of a correlation coefficient (CC) was about 95% at the nucleotide level for the 288 genes tested, and 97. 0% for the 170 genes whose product and closest homologue share more than 30% identical amino acids. We also propose a strategy to improve the accuracy of prediction for a set of paralogous genes by means of iterative gene prediction and reconstruction of the reference profile derived from the predicted sequences. The source codes for the program 'aln' written in ANSI-C and the test data will be available via anonymous FTP at ftp.genome.ad.jp/pub/genomenet/saitama-cc. gotoh@cancer-c.pref.saitama.jp

Reinitiation of protein synthesis in Escherichia coli can be induced by mRNA cis-elements unrelated to canonical translation initiation signals

In Eubacteria, de novo translation of some internal cistrons may be inefficient or impossible unless the 5′ neighboring cistron is also translated (translational coupling). Translation reinitiation is an extreme case of translational coupling in which translation of a message depends entirely on the presence of a nearby terminating ribosome. In this work, the characteristics of mRNA cis-elements inducing the reinitiation process in Escherichia coli have been investigated using a combinatorial approach. A number of novel translational reinitiation sequences (TRSs) were thus identified, which show a wide range of reinitiation activities fully dependent on a translational coupling event and unrelated to the presence/absence of secondary structure or mRNA stability. Moreover, some of the isolated TRSs are similar to intercistronic sequences present in the E. coli genome.

Expression and purification of recombinant proteins by fusion to maltose-binding protein.

The pMAL vectors provide a method for purifying proteins from cloned genes by fusing them to maltose-binding protein (MBP, product of malE), which binds to amylose. The vectors use the tac promoter and the translation initiation signals of MBP to give high-level expression of the fusion, and an affinity purification for MBP to isolate the fusion protein. The pMAL polylinkers carry restriction sites to insert the gene of interest, and encode a site for a specific protease to separate MBP from the target protein after purification. Vectors with or without the malE signal sequence can be used, to express the protein cytoplasmically for the highest level of production or periplasmically to help in proper folding of disulfide-bonded proteins.

Insertion of a foreign gene into the beta-casein locus by Cre-mediated site-specific recombination.

The expression of foreign genes in transgenic animals is generally unpredictable as transgenes are integrated at random after pro-nuclear injection into fertilized oocytes. In many cases, transgene expression is inhibited by neighbouring chromatin structures or by the repeated nature of the multiple transgene copies present at the integration site. A strategy involving homologous and site-specific recombination has been devised by which single copies of a foreign gene can be inserted specifically into the locus of a highly expressed gene. As a first step, a loxP recombination target site is introduced by homologous recombination into a predetermined gene locus such that the loxP sequence is placed next to the promoter region and replaces the translational initiation signal. In a subsequent site-specific recombination reaction, a gene of interest can be integrated into the pre-existing loxP site. This biphasic recombination strategy was used to integrate a luciferase reporter gene into the locus of the murine beta-casein gene in embryonic stem cells.

Reliable and sensitive detection of premature termination mutations using a protein truncation test designed to overcome problems of nonsense-mediated mRNA instability.

The protein truncation test (PTT) is a mutation-detection method used to scan for premature termination (nonsense) mutations. PCR amplification of the DNA or mRNA source material is performed using forward primers containing a T7-promoter sequence and translation initiation signals such that the resultant products can be transcribed and translated in vitro to identify the smaller truncated protein products. mRNA is commonly used as the source material, but success of the PTT and other RNA-based mutation detection methods can be severely compromised by nonsense mutation-induced mRNA decay, a well-documented process that is often overlooked in mutation detection strategies. In this study, we develop an RNA-based PTT that overcomes the problem of mRNA decay by preincubating cells with cycloheximide to stabilise the mutant mRNA. The effectiveness of this method for mutation detection in abundant mRNAs was demonstrated in osteogenesis imperfecta fibroblasts by the protection of type I collagen (COL1A1) mRNA containing nonsense mutations that normally resulted in mutant mRNA degradation. Stabilisation of mutant mismatch repair gene (MLH1) mRNA was also observed in transformed lymphocytes from patients with hereditary nonpolyposis colorectal cancer (HNPCC). Importantly, our strategy also stabilised very low-level (or illegitimate) nonsense-containing transcripts in lymphoblasts from patients with Bethlem myopathy (COL6A1), familial adenomatous polyposis (APC), and breast cancer (BRCA1). The greatly increased sensitivity and reliability of this RT-PCR/PTT protocol has broad applicability to the many genetic diseases in which only blood-derived cells may be readily available for analysis.

The translation initiation signal in E. coli and its control.

A central step in the process of gene expression is the translation of the genetic information - stored in sequences of nucleic acids - into the formation of proteins, the catalysts of almost all processes and actions of life. This step is bound into an array of other steps: transcription, processing, modification and decomposition of mRNA, pre- translationally, and folding, processing, modification, sorting, allosteric activation and degradation of proteins, co- and post-translationally. The process of translation can be subdivided into initiation, elongation and termination, and within these substeps further sequences of events can be distinguished. All these processes, steps, substeps and events are kinetically interrelated and mutually dependent on each other. Especially in prokaryotes, the synthesis of mRNA is connected to its function as template in translation: the nascent mRNA is already used as template. In a similar way, nascent proteins are processed, modified and folded with the help of different enzymes such as peptide deformylase, methionyl-aminopeptidase, other peptidases, chaperones and the surface of the ribosomes (1, 2, 3). Interrupting this array of processive steps for analysis will create artificial situations and might lead to misinterpretations of the events.

Site-specific integration of Agrobacterium T-DNA in Arabidopsis thaliana mediated by Cre recombinase.

In this study Agrobacterium tumefaciens transferred DNA (T-DNA) was targeted to a chromosomally introduced lox site in Arabidopsis thaliana by employing the Cre recombinase system. To this end, Arabidopsis target lines were constructed which harboured an active chimeric promoter-lox-cre gene stably integrated in the plant genome. A T-DNA vector with a promoterless lox -neomycin phosphotransferase (nptII) fusion was targeted to this genomic lox site with an efficiency of 1.2-2.3% of the number of random events. Cre-catalyzed site-specific recombination resulted in restoration of nptII expression by translational fusion of the lox-nptII sequence in the integration vector with the transcription and translation initiation sequences present at the target site, allowing selective enrichment on medium containing kanamycin. Simultaneously, the coding sequence of the Cre recombinase was disconnected from these same transcription and translation initiation signals by displacement, aimed at preventing the efficient reversible excision reaction. Of the site-specific recombinants, 89% were the result of precise integration. Furthermore, approximately 50% of these integrants were single copy transformants, based on PCR analysis. Agrobacterium T-DNA, which is transferred to plant cells as a single-stranded linear DNA structure, is in principle incompatible with Cre-mediated integration. Nevertheless, the results presented here clearly demonstrate the feasibility of the Agrobacterium -mediated transformation system, which is generally used for transformation of plants, to obtain site-specific integration.

Functional and genetic analysis of regulatory regions of coliphage H-19B: location of shiga-like toxin and lysis genes suggest a role for phage functions in toxin release.

Analysis of the DNA sequence of a 17 kb region of the coli lambdoid phage H-19B genome located the genes encoding shiga-like toxin I (Stx-I) downstream of the gene encoding the analogue of the phage lambda Q transcription activator with its site of action, qut at the associated pR' late promoter, and upstream of the analogues of lambda genes encoding lysis functions. Functional studies, including measurement of the effect of H-19B Q action on levels of Stx expressed from an H-19B prophage, show that the H-19B Q acts as a transcription activator with its associated pR'(qut) by promoting readthrough of transcription terminators. Another toxin-producing phage, 933W, has the identical Q gene and pR'(qut) upstream of the stx-II genes. The H-19B Q also activates Stx-II expression from a 933W prophage. An ORF in H-19B corresponding to the holin lysis genes of other lambdoid phages differs by having only one instead of the usual two closely spaced translation initiation signals that are thought to contribute to the time of lysis. These observations suggest that stx-I expression can be enhanced by transcription from pR' as well as a model for toxin release through cell lysis mediated by action of phage-encoded lysis functions. Functional studies show that open reading frames (ORFs) and sites in H-19B that resemble components of the N transcription antitermination systems controlling early operons of other lambdoid phages similarly promote antitermination. However, this N-like system differs significantly from those of other lambdoid phages.

First report on the systematic sequencing of the small genome of Encephalitozoon cuniculi (Protozoa, Microspora): gene organization of a 4.3 kbp region on chromosome I.

Belonging to a large group of parasitic amitochondrial protozoans (Microspora), Encephalitozoon cuniculi infects humans and other mammals. Because of its medical importance and small genome size (2.9 Mbp), we are systematically sequencing its smallest (217 kbp) chromosome. The shotgun cloning strategy now has produced the sequence of randomly dispersed contigs representing more than 180 kbp of this chromosome. The present report describes analysis of the 4.3 kbp contig, which includes the complete coding regions of dihydrofolate reductase (DHFR), thymidylate synthase (TS), and serine hydroxymethyl transferase (SHMT) genes and the partial coding region of an aminopeptidase (AP) gene. In contrast to the other reported protozoan genes, DHFR and TS are encoded by two different open reading frames (ORFs). The SHMT gene is the first one identified in a protozoan and corresponds to the cytosolic form of the enzyme. No introns were detected, and the intergenic noncoding regions do not exceed 50 bp. The mean GC content is close to 60%, and there is a G or C third-base codon bias. Transcription and translation initiation signals also are analyzed, and a model for the mRNA-ssu rRNA interactions is proposed.

PH-dependent growth retardation of Escherichia coli caused by overproduction of Na+/H+ antiporter.

The overproduction of Na+/H+ antiporter NhaA in Escherichia coli caused growth retardation. Quantities and the activity of the antiporter were studied for their causative roles in terms of this retardation. We constructed a series of nhaA-expression plasmids differing in their transcriptional and translational efficiencies. Low-level nhaA expression complemented the defect of an nhaA mutant and allowed the mutant to survive on a high-NaCl or high-LiCl medium. However, when the production of NhaA was strongly induced by the combination of a stronger promoter, an efficient translational initiation signal and a high copy number plasmid, the growth of the cells carrying the plasmid was severely retarded. This growth retardation correlated well with the amount of NhaA protein produced from the plasmids. Surprisingly, the growth retardation caused by overproduction of NhaA was enhanced more extensively at an alkaline pH than at a neutral pH, in which the antiporter activity was stimulated. However, these retardations were also observed for mutant NhaA antiporters without the activity. These results indicated that the growth retardation was due to an overproduction of the antiporter rather than its increased antiporter activity, and also affected by a pH-dependent change in NhaA, possibly its structural change.

A chloride-inducible gene expression cassette and its use in induced lysis of Lactococcus lactis

A chloride-inducible promoter previously isolated from the chromosome of Lactococcus lactis (J. W. Sanders, G. Venema, J. Kok, and K. Leenhouts, Mol. Gen. Genet., in press) was exploited for the inducible expression of homologous and heterologous genes. An expression cassette consisting of the positive-regulator gene gadR, the chloride-inducible promoter Pgad, and the translation initiation signals of gadC was amplified by PCR. The cassette was cloned upstream of Escherichia coli lacZ, the holin-lysin cassette (lytPR) of the lactococcal bacteriophage r1t, and the autolysin gene of L. lactis, acmA. Basal activity of Pgad resulted in a low level of expression of all three proteins. Growth in the presence of 0.5 M NaCl of a strain containing the gadC::lacZ fusion resulted in a 1,500-fold increase of beta-galactosidase activity. The background activity levels of LytPR and AcmA had no deleterious effects on cell growth, but induction of lysin expression by addition of 0.5 M NaCl resulted in inhibition of growth. Lysis was monitored by following the release of the cytoplasmic marker enzyme PepX. Released PepX activity was maximal at 1 day after induction of lytPR expression with 0.1 M NaCl. Induction of acmA expression resulted in slower release of PepX from the cells. The presence of the inducing agent NaCl resulted in the stabilization of osmotically fragile cells.

Isolation of the putative cDNA encoding cholesterol side chain cleavage cytochrome P450 (CYP11A) of the southern stingray ( Dasyatis americana)

Cholesterol side chain cleavage cytochrome P450 (P450scc; CYP11A) catalyzes the first step in the production of steroid hormones. By utilizing degenerate oligonucleotide primers in a reverse transcriptase-coupled polymerase chain reaction (RT-PCR), a specific 252 bp fragment of the putative P450scc was amplified from RNA of interrenal tissue (the adrenal cortex homolog) from the southern stingray ( Dasyatis americana), blacktip shark ( Carcharhinus limbatus), and the spiny dogfish shark ( Squalus acanthias). The amino-acid sequences predicted by these PCR products were 73–90% identical to each other. Using the homologous PCR-generated probe, five positive clones were isolated from a cDNA library constructed from interrenal mRNA of the southern stingray. The longest clone (4619 bp) contained the 3′-untranslated region, including four putative polyadenylation signals. Northern blot analysis of stingray interrenal RNA revealed a single transcript of 4.2 kb in length. The incomplete amino-acid sequence predicted by the open reading frame of the cDNA (514 residues in length) is 48% homologous to the trout form and 39–40% homologous to mammalian forms. Even though the stingray P450scc contains an amino terminus longer than the other forms of P450scc, no translation initiation signal (ATG) was evident within the open reading frame. This report presents the first sequence of cytochrome P450scc from this evolutionary unique taxon of vertebrates.

IS900 targets translation initiation signals in Mycobacterium avium subsp. paratuberculosis to facilitate expression of its hed gene.

The Mycobacterium avium subsp. paratuberculosis (formerly Mycobacterium paratuberculosis) atypical insertion sequence, IS900, encodes a novel gene on the complementary strand to the putative transposase, p43. This gene requires a promoter, ribosome binding site (RBS) and termination codon to be acquired upon insertion into the M. avium subsp. paratuberculosis genome and hence is designated the hed (host expression-dependent) gene of IS900. Analysis of IS900 insertion sites suggests that this element targets translation initiation signals in M. avium subsp. paratuberculosis, specifically inserting between the RBS and start codon of a putative gene sequence. This aligns the hed initiation codon adjacent to a functional RBS and possibly downstream of an active promoter, driving expression of Hed protein. We have confirmed this unique targeting process by detecting expression of hed in M. avium subsp. paratuberculosis at the level of transcription by reverse transcription-PCR. Further, two Hed-specific antibodies detected Hed translation products in Western blots of protein extracts from M. avium subsp. paratuberculosis. A recombinant form of Hed expressed and purified from Escherichia coli will facilitate studies of IS900 transposition and will also be assessed as a diagnostic antigen for M. avium subsp. paratuberculosis disease. Implications of IS900 insertion in M. avium subsp. paratuberculosis pathogenicity are discussed.