Identification of a nucleotide sequence conserved in Lactococcus lactis bacteriophages

A genetic element which is conserved in the genomes of numerous Lactococcus lactis bacteriophage isolates has been identified and its nucleotide sequence determined. Approximately 95-99% of all L. lactis bacteriophages collected over a period of six years from two geographically distinct sources carry this conserved DNA fragment. Genetic variation in other regions of the genomes of these bacteriophages is exhibited by changes in the overall restriction patterns. The complete nt sequence for a 1.6-kb region from nine independent L. lactis bacteriophage isolates was determined and only five changes in the nt sequence were observed within a span of 1536 bp. This region has a single large 1356-bp open reading frame (ORF) coding for a 51-kDa protein. Three out of the five changes occur in a 187-bp region, 5' to this large ORF. The two additional changes are found within the 1356-bp ORF, which results in two amino acid substitutions that do not, however, change the net charge of the protein. The encoded protein is extremely charged and shares some homology with yeast translation initiation factor. In addition, there is a potential zinc-binding domain within this protein, similar to those observed in genes from bacteriophages T4 and T7.     

真核细胞中多重表达框mRNA的选择性翻译起始

扫描模型和遗漏扫描模型是真核生物mRNA翻译起始的两种主要机制,但其仍存在某些例外情况,如对具有多顺反子结构的mRNA,选择性翻译起始的发生机制目前仍不清楚.本研究基于GFP蛋白开放表达框(ORF)构建了一系列重组表达载体,用以转录在移码翻译顺序及同一翻译顺序下,AUG起始密码子处于不同序列背景,以及间隔不同距离的多顺反子结构mRNA.通过转染人Bel 7402细胞系,研究了这些多顺反子结构mRNA的翻译起始模式.结果表明,在移码翻译顺序下,多顺反子mRNA可翻译出对应的不同蛋白质,而在同一翻译顺序下,GFP蛋白表达框中的多个AUG密码子,仅有首位起始密码子可发挥作用,提示核糖体在从首位起始密码子开始翻译的同时,可能会有部分核糖体继续向下扫描并识别下游的起始密码子,而这种选择性的翻译起始效率,主要取决于密码子所处的序列背景及间隔距离等因素.     

Determinants on tmRNA for initiating efficient and precise trans-translation: some mutations upstream of the tag-encoding sequence of Escherichia coli tmRNA shift the initiation point of trans-translation in vitro.

tmRNA facilitates a novel translation, trans-translation, in which a ribosome can switch between translation of a truncated mRNA and the tmRNA's tag sequence. The mechanism underlying resumption of translation at a definite position is not known. In the present study, the effects of mutations around the initiation point of the tag-encoding sequence of Escherichia coli tmRNA on the efficiency and the frame of tag translation were assessed by measuring the incorporations of several amino acids into in vitro poly (U)-dependent tag-peptide synthesis. One-nucleotide insertions within the tag-encoding region did not shift the frame of tag translation. Any 1-nt deletion within the span of -5 to -1, but not at -6, made the frame of tag translation heterologous. Positions at which a single base substitution caused a decrease of trans-translation efficiency were concentrated within the span of -4 to -2. In particular, an A-4 to C-4 mutation seriously damaged the trans-translation, although this mutant retained normal aminoacylation and ribosome-binding abilities. A possible stem and loop structure around this region was not required for transtranslation. It was concluded that the tag translation requires the primary sequence encompassing -6 to +11, in which the central 3 nt, A-4, G-3, and U-2, play an essential role. It was also found that several base substitutions within the span of -6 to -1 extensively shifted the tag-initiation point by -1.     

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     

MACSE: Multiple Alignment of Coding SEquences accounting for frameshifts and stop codons

Until now the most efficient solution to align nucleotide sequences containing open reading frames was to use indirect procedures that align amino acid translation before reporting the inferred gap positions at the codon level. There are two important pitfalls with this approach. Firstly, any premature stop codon impedes using such a strategy. Secondly, each sequence is translated with the same reading frame from beginning to end, so that the presence of a single additional nucleotide leads to both aberrant translation and alignment.We present an algorithm that has the same space and time complexity as the classical Needleman-Wunsch algorithm while accommodating sequencing errors and other biological deviations from the coding frame. The resulting pairwise coding sequence alignment method was extended to a multiple sequence alignment (MSA) algorithm implemented in a program called MACSE (Multiple Alignment of Coding SEquences accounting for frameshifts and stop codons). MACSE is the first automatic solution to align protein-coding gene datasets containing non-functional sequences (pseudogenes) without disrupting the underlying codon structure. It has also proved useful in detecting undocumented frameshifts in public database sequences and in aligning next-generation sequencing reads/contigs against a reference coding sequence.MACSE is distributed as an open-source java file executable with freely available source code and can be used via a web interface at: http://mbb.univ-montp2.fr/macse.     

Nucleotide sequence and genome organization of foot-and-mouth disease virus.

A continuous 7802 nucleotide sequence spanning the 94% of foot and mouth disease virus RNA between the 5'-proximal poly(C) tract and the 3'-terminal poly(A) was obtained from cloned cDNA, and the total size of the RNA genome was corrected to 8450 nucleotides. A long open reading frame was identified within this sequence starting about 1300 bases from the 5' end of the RNA genome and extending to a termination codon 92 bases from its polyadenylated 3' end. The protein sequence of 2332 amino acids deduced from this coding sequence was correlated with the 260 K FMDV polyprotein. Its processing sites and twelve mature viral proteins were inferred from protein data, available for some proteins, a predicted cleavage specificity of an FMDV encoded protease for Glu/Gly(Thr, Ser) linkages, and homologies to related proteins from poliovirus. In addition, a short unlinked reading frame of 92 codons has been identified by sequence homology to the polyprotein initiation signal and by in vitro translation studies.     

Genomic splice-site analysis reveals frequent alternative splicing close to the dominant splice site

Alternative pre-mRNA splicing may be the most efficient and widespread mechanism to generate multiple protein isoforms from single genes. Here, we describe the genomic analysis of one of the most frequent types of alternative pre-mRNA splicing, alternative 5'- and 3'-splice-site selection. Using an EST-based alternative splicing database recording >47,000 alternative splicing events, we determined the frequency and location of alternative 5'- and 3'-splice sites within the human genome. The most common alternative splice sites used in the human genome are located within 6 nucleotides (nt) of the dominant splice site. We show that the EST database overrepresents alternative splicing events that maintain the reading frame, thus supporting the concept that RNA quality-control steps ensure that mRNAs that encode for potentially harmful protein products are destroyed and do not serve as templates for translation. The most frequent location for alternative 5'-splice sites is 4 nt upstream or downstream from the dominant splice site. Sequence analysis suggests that this preference is a consequence of the U1 snRNP binding sequence at the 5'-splice site, which frequently contains a GU dinucleotide 4 nt downstream from the dominant splice site. Surprisingly, approximately 50% of duplicated 3'-YAG splice junctions are subject to alternative splicing. This high probability of alternative 3'-splice-site activation in close proximity of the dominant 3'-splice site suggests that the second step of the splicing may be prone to violate splicing fidelity.     

The nucleotide sequence of the PRI1 gene related to DNA primase in Saccharomyces cerevisiae.

The PRI1 gene of Saccharomyces cerevisiae encodes for the p48 polypeptide of DNA primase. We have determined the nucleotide sequence of a 1,965 bp DNA fragment containing the PRI1 locus. The entire coding sequence of the gene lies within an open reading frame, and there are 409 amino acids in the single polypeptide protein if translation is assumed to start at the first ATG in this frame. The 5' and 3' end-points of PRI1 mRNA have been determined by S1 mapping and primer extension analysis. The primary structure and the codon usage of PRI1 suggest that this essential gene is poorly expressed in yeast cells.     

Expression of the split gene cob in yeast: Evidence for a precursor of a “maturase” protein translated from intron 4 and preceding exons

Intron 4 (14) of the split gene cob in mitochondrial DNA contains a long open reading frame in phase with the preceding exon. Mutations in this intron block the excision of the 14 sequence from the cob precursor RNA and, at the same time, generate a series of new polypeptides, parts of which apparently result from translation of 14 sequences. We sequenced six mutations clustered in the upstream part of the open reading frame, about 340 bp from the exon-intron boundary (box9 cluster). Four are base pair exchanges in the same triplet of this region; these form the polypeptides typical for 14 plus a trans-acting product encoded by 14, as shown by complementation studies. The other two mutations—a -2 bp deletion at the same site, causing frameshift with a chain-terminating codon within a few triplets, and a base pair exchange at a nearby site-affect both the formation of 14 typical translation products and the trans-acting function. These results on box9 mutants combined with results on box7 mutants suggest that an 14-encoded “maturase” protein (apparent molecular weight, 27,000) is cleaved off a precursor protein (apparent molecular weight, 55,000) encoded by exon sequences B1 to B4 and the intron open reading frame. We further discuss the role of the box9 nucleotide sequence in the maturation of cob-specific RNA.     

The tmRNA Website: invasion by an intron

tmRNA (also known as 10Sa RNA or SsrA) plays a central role in an unusual mode of translation, whereby a stalled ribosome switches from a problematic mRNA to a short reading frame within tmRNA during translation of a single polypeptide chain. Research on the mechanism, structure and biology of tmRNA is served by the tmRNA Website, a collection of sequences for tmRNA and the encoded proteolysis-inducing peptide tags, alignments, careful documentation and other information; the URL is http://www.indiana.edu/~tmrna. Four pseudoknots are usually present in each tmRNA, so the database is rich with information on pseudoknot variability. Since last year it has doubled (227 tmRNA sequences as of September 2001), a sequence alignment for the tmRNA cofactor SmpB has been included, and genomic data for Clostridium botulinum has revealed a group I (subgroup IA3) intron interrupting the tmRNA T-loop.     

Effects of elongation on the translation of a reovirus bicistronic mRNA

The S1 species of reovirus mRNA contains two overlapping open reading frames. Both are utilized in either virus-infected or S1 DNA transfected mammalian cells, resulting in two different polypeptides from a single mRNA. Consistent with ribosome scanning, expression of the downstream reading frame was increased by sequence changes that diminished the consensus around the upstream initiator site. However, the upstream product was not decreased by the same changes, suggesting that its synthesis is rate-limited at elongation. The results suggest a model for regulating bicistronic mRNA translation in which the ribosomes in one reading frame interfere with the movement of ribosomes in the other frame due to different rates of elongation.     

The signal recognition particle receptor alpha subunit assembles co-translationally on the endoplasmic reticulum membrane during an mRNA-encoded translation pause in vitro.

Many proteins, including the alpha subunit of the signal recognition particle receptor (SR alpha), are targeted within the cell by poorly defined mechanisms. A 140 residue N-terminal domain of SR alpha targets and anchors the polypeptide to the endoplasmic reticulum membrane by a mechanism independent of the pathway involving the signal recognition particle. To investigate the mechanism of membrane anchoring, translation pause sites on the SR alpha mRNA were used to examine the targeting of translation intermediates. A strong pause site at nucleotide 507 of the mRNA open reading frame corresponded with the shortest nascent SR alpha polypeptide able to assemble on membranes. An mRNA sequence at this pause site that resembles a class of viral -1 frameshift sequences caused translation pausing when transferred into another mRNA context. Site-directed mutagenesis of the mRNA greatly reduced translation pausing without altering the polypeptide sequence, demonstrating unambiguously a role for this mRNA sequence in translation pausing. SR alpha polypeptides synthesized from the non-pausing mRNA were impaired in co-translational membrane anchoring. Furthermore, co-translational membrane assembly of SR alpha appears to anchor polysomes translating SR alpha to membranes.     

Target-specific arrest of mRNA translation by antisense 2'-O-alkyloligoribonucleotides.

We describe a novel experimental approach to investigate mRNA translation. Antisense 2'-O-allyl oligoribonucleotides (oligos) efficiently arrest translation of targeted mRNAs in rabbit reticulocyte lysate and wheat germ extract while displaying minimal non-specific effects on translation. Oligo/mRNA-hybrids positioned anywhere within the 5' UTR or the first approximately 20 nucleotides of the open reading frame block cap-dependent translation initiation with high specificity. The thermodynamic stability of hybrids between 2'-O-alkyl oligos and RNA permits translational inhibition with oligos as short as 10 nucleotides. This inhibition is independent of RNase H cleavage or modifications which render the mRNA untranslatable. We show that 2'-O-alkyl oligos can also be employed to interfere with cap-independent internal initiation of translation and to arrest translation elongation. The latter is accomplished by UV-crosslinking of psoralen-tagged 2'-O-methyloligoribonucleotides to the mRNA within the open reading frame. The utility of 2'-O-alkyloligoribonucleotides to arrest translation from defined positions within an mRNA provides new approaches to investigate mRNA translation.     

Genomic structure of the large RNA segment of infectious bursal disease virus.

The larger RNA segment of infectious bursal disease virus (IBDV: Australian strain 002-73) has been characterized by cDNA cloning and nucleotide sequence analysis. We believe IBDV is the first birnavirus to be sequenced and so have confirmed the coding region by N-terminal amino acid sequence analysis of intact viral proteins and several tryptic peptide fragments. The large RNA segment encodes in order the 37-kDa, 28-kDa and 32-kDa proteins within a continuous open reading frame and the primary translation product appears to be subsequently processed into the mature viral proteins. The large protein precursor is still processed into the 32-kDa host protective immunogen when expressed as a fusion protein in E. coli. These results are in marked contrast to the predictions from in vitro translation data that birnavirus genomes are expressed as polycistronic templates. We can now propose that birnaviruses, in particular IBDV, possess monocistronic segments and that the precursor is proteolytically processed in vivo. The sequence data presented for the 32-kDa host protective immunogen may provide the basic information needed for the production of an effective subunit vaccine against this commercially important virus.     

CCC CGA is a weak translational recoding site in Escherichia coli

Previously published experiments had indicated unexpected expression of a control vector in which a beta-galactosidase reporter was in the +1 reading frame relative to the translation start. This control vector contained the codon pair CCC CGA in the zero reading frame, raising the possibility that ribosomes rephased on this sequence, with peptidyl-tRNA(Pro) pairing with CCC in the +1 frame. This putative rephasing might also be exacerbated by the rare CGA Arg codon in the second position due to increased vacancy of the ribosomal A-site. To test this hypothesis, a series of site-directed mutants was constructed, including mutations in both the first and second codons of this codon pair. The results show that interrupting the continuous run of C residues with synonymous codon changes essentially abolishes the frameshift. Further, changing the rare Arg codon to a common Arg codon also reduces the frequency of the frameshift. These results provide strong support for the hypothesis that CCC CGA in the zero frame is indeed a weak translational frameshift site in Escherichia coli, with a 1-2% efficiency. Because the vector sequence also contains another CCC triplet in the +1 reading frame starting within the next codon after the CGA, our data also support possible contribution to expression of a +7 nucleotide ribosome hop into the same +1 reading frame. We also confirm here a previous report that CCC UGA is a translational frameshift site, in these experiments, with about 5% efficiency.     

Translation of Sindbis virus mRNA: analysis of sequences downstream of the initiating AUG codon that enhance translation.

Alphaviruses, particularly Sinbis virus and Semliki Forest virus, are proving to be useful vectors for the expression of heterologous genes. In infected cells, these self-replicating vectors (replicons) transcribe a subgenomic mRNA that codes for a heterologous protein instead of the structural proteins. We reported recently that translation of the reporter gene lacZ is enhanced 10-fold when the coding sequences of this gene are fused downstream of and in frame with the 5' half of the capsid gene (I. Frolov and S. Schlesinger, J. Virol. 68:8111-8117, 1994). The enhancing sequences, located downstream of the AUG codon that initiates translation of the capsid protein, have a predicted hairpin structure. We have mutated this region by making changes in the codons which do not affect the protein sequence but should destabilize the putative hairpin structure. These changes caused a decrease in the accumulation of the capsid-beta-galactosidase fusion protein. When these alterations were inserted into the capsid gene in the context of the intact Sindbis virus genome, they led to a decrease in the rate of virus formation but did not affect the final yield. We also altered the original sequence to one that has 12 contiguous G.C base pairs and should form a stable hairpin. The new sequence was essentially as effective as the original had been in enhancement of translation and in the rate of virus formation. The position of the predicted hairpin structure is important for its function; an insertion of 9 nucleotides or a deletion of 9 nucleotides decreased the level of translation. The insertion of a hairpin structure at a particular location downstream of the initiating AUG appears to be a way that alphaviruses have evolved to enhance translation of their mRNA, and, as a consequence, they produce high levels of the structural proteins which are needed for virus assembly. This high level of translation requires an intracellular environment in which host cell protein synthesis is inhibited.