Messenger RNA conformation and ribosome selection of translational reinitiation sites in the lac repressor mRNA

In the early region of the Escherichia coli lac repressor mRNA, the pattern of cleavage by nucleases specific for single or double-stranded RNA confirms the presence of secondary structures previously proposed to influence the pattern of translational reinitiation. These are positioned so as to mask a potential restart site centered on an in-phase GUG triplet corresponding to repressor amino acid position Val38. Our finding that a restart polypeptide initiated at the Val38 GUG codon is observed only in situations that that preclude base-pairing of adjacent mRNA sequences establishes a functional role for these structures in vivo. This evidence for structure, considered with the overall pattern of reinitiation events, suggests that local mRNA conformation is the major determinant that dictates ribosomal selection of restart sites within the early region of the repressor cistron.     

Functional analysis of lac repressor restart sites in translational initiation and reinitiation

To define some of the features that influence ribosomal recognition of translational restart sites in the lac repressor mRNA, recombinant DNA methods have been used to construct lacI-Z fusions in which lacZ gene expression is dependent upon initiation or reinitiation within lacI mRNA sequences. Reinitiation efficiencies, as assessed by beta-galactosidase levels in strains bearing such plasmids, appear to be determined by at least three features of the RNA between the termination codon and reinitiation codon: the presence of competing out-of-frame AUG or GUG triplets, the distance between termination and reinitiation points, and the extent to which restart sequences remain accessible to ribosomes. While some of the restart sites are used with substantial efficiency for reinitiation, they do not function detectably as primary initiators if placed at the 5' end of the lacZ mRNA. This finding concurs with our observation that relative to the wild-type initiator region, which is recovered in quantitative yield from in vitro initiation reactions, ribosome protection of the four restart sites occurs at more than 100-fold lower efficiencies. In part, the lack of initiation activity is rationalized by the striking potential these sequences have for forming stable secondary structures that sequester elements essential for ribosome binding. However, the differential functioning of the restart sites in primary initiation versus reinitiation must also reflect real differences in the mechanisms operative in the two events.     

Transient idling of posttermination ribosomes ready to reinitiate protein synthesis

The fate of ribosomes between termination and initiation during protein synthesis is very basic, yet poorly understood. Here we found that translational reinitiation of the alkaline phosphatase gene occurs in Escherichia coli from an internal methionine codon when the authentic translation is prematurely terminated at a nonsense codon that is within seven codons upstream of the reinitiation codon (which we refer to as "reinitiation window"). Changing the reading frame downstream of the stop codon did not abolish the reinitiation, while inactivating the upstream initiation codon abolished the reinitiation. Moreover, depletion of the ribosome recycling factor (RRF), which disassembles posttermination ribosomes in conjunction with elongation factor G, did not influence the observed reinitiation. These findings suggest that posttermination ribosomes can undergo a transient idling state ready to reinitiate protein synthesis even in the absence of the Shine-Dalgarno (SD) sequence within the reinitiation window by evading disengagement from the mRNA.     

A quantitative model for translational control of the GCN4 gene of Saccharomyces cerevisiae

Expression of the GCN4 gene of Saccharomyces cerevisiae is regulated at the translational level by short open reading frames (uORFs) present in the leader sequence of its mRNA. Under conditions of amino acid sufficiency, these sequences restrict the flow of initiating ribosomes to the GCN4 AUG start codon. Mutational analysis of GCN4 has led to a model in which ribosomes must translate the 5'-proximal uORF1 and reassemble an initiation complex in order to translate GCN4. This reassembly process is thought to be rapid when amino acids are abundant, such that reinitiation occurs at uORF2, uORF3, or uORF4. Reinitiation at these sites prevents translation of GCN4, presumably because ribosomes dissociate from the mRNA following termination at uORFs 2 to 4. Because of reduced initiation factor activity under starvation conditions, a substantial fraction of ribosomal subunits scanning downstream from uORF1 are not ready to reinitiate when they reach uORFs 2 to 4, but become competent to do so while scanning the additional sequences between uORF4 and GCN4. Examination of the effects of point mutations in the ATG codons of the different uORFs suggests a quantitative model for this control mechanism that describes the probability of reinitiation as a function of the distance scanned downstream from uORF1. This model accounts for the phenotypes of a number of deletion and insertion mutations that alter the intercistronic spacing between the uORFs and GCN4. The correspondence between observed and predicted results implies that the differential rates of reinitiation at GCN4 versus uORFs 2 to 4 are determined largely by the different scanning times required to reach each of these start sites following translation of uORF1. In addition, it supports the notion that an increased scanning-time requirement for reinitiation in amino acid-starved cells forms the basis for translational derepression of GCN4 expression.     

Translational reinitiation in the rIIB cistron of bacteriophage T4

During translation of the bacteriophage T4 rIIB gene messenger RNA, premature termination sometimes results in translational reinitiation. The nucleotide sequence surrounding the true initiating AUG of the rIIB message has been determined recently. We have identified potential reinitiation codons within this sequence and determined which of these codons are utilized in reinitiation events. We have used the sequence to reinterpret the x reinitiation event described by Sarabhai & Brenner (1967).     

When cells stop making sense: effects of nonsense codons on RNA metabolism in vertebrate cells.

It appears that no organism is immune to the effects of nonsense codons on mRNA abundance. The study of how nonsense codons alter RNA metabolism is still at an early stage, and our current understanding derives more from incidental vignettes than from experimental undertakings that address molecular mechanisms. Challenges for the future include identifying the gene products and RNA sequences that function in nonsense mediated RNA loss, resolving the cause and consequences of there apparently being more than one cellular site and mechanism for nonsense-mediated RNA loss, and understanding how these sites and mechanisms are related to both constitutive and specialized pathways of pre-mRNA processing and mRNA decay.     

Effects of release factor context at UAA codons in Escherichia coli.

In Escherichia coli, nonsense suppression at UAA codons is governed by the competition between a suppressor tRNA and the translational release factors RF1 and RF2. We have employed plasmids carrying the genes for RF1 and RF2 to measure release factor preference at UAA codons at 13 different sites in the lacI gene. We show here that the activity of RF1 and RF2 varies according to messenger context. RF1 is favored at UAA codons which are efficiently suppressed. RF2 is preferred at poorly suppressed sites.     

Context Effects on Nonsense Codon Suppression in ESCHERICHIA COLI

The influence of mRNA context on nonsense codon suppression has been studied by suppression measurements at one site in the Escherichia coli trpE gene and at two sites in the trpA gene. The ratio of suppression efficiencies of amber and ochre codons at each site (homotopic pairs) has been compared using ochre suppressing derivatives of tRNATyr. This ratio is independent of differential effects of the inserted amino acid on enzyme function. We have found that mRNA context can change the ratio of suppression efficiencies of homotopic nonsense codons at the three sites in the trp gene system over a ten-fold range. The causes of such variation, and, in particular the effect of certain adjacent nucleotides on nonsense codon suppression are considered.     

Introns are cis effectors of the nonsense-codon-mediated reduction in nuclear mRNA abundance.

The translation of human triosephosphate isomerase (TPI) mRNA normally terminates at codon 249 within exon 7, the final exon. Frameshift and nonsense mutations of the type that cause translation to terminate prematurely at or upstream of codon 189 within exon 6 reduce the level of nuclear TPI mRNA to 20 to 30% of normal by a mechanism that is not a function of the distance of the nonsense codon from either the translation initiation or termination codon. In contrast, frameshift and nonsense mutations of another type that cause translation to terminate prematurely at or downstream of codon 208, also within exon 6, have no effect on the level of nuclear TPI mRNA. In this work, quantitations of RNA that derived from TPI alleles in which nonsense codons had been generated between codons 189 and 208 revealed that the boundary between the two types of nonsense codons resides between codons 192 and 195. The analysis of TPI gene insertions and deletions indicated that the positional feature differentiating the two types of nonsense codons is the distance of the nonsense codon upstream of intron 6. For example, the movement of intron 6 to a position downstream of its normal location resulted in a concomitant downstream movement of the boundary between the two types of nonsense codons. The analysis of intron 6 mutations indicated that the intron 6 effect is stipulated by the 88 nucleotides residing between the 5' and 3' splice sites. Since the deletion of intron 6 resulted in only partial abrogation of the nonsense codon-mediated reduction in the level of TPI mRNA, other sequences within TPI pre-mRNA must function in the effect. One of these sequences may be intron 2, since the deletion of intron 2 also resulted in partial abrogation of the effect. In experiments that switched introns 2 and 6, the replacement of intron 6 with intron 2 was of no consequence to the effect of a nonsense codon within either exon 1 or exon 6. In contrast, the replacement of intron 2 with intron 6 was inconsequential to the effect of a nonsense codon in exon 6 but resulted in partial abrogation of a nonsense codon in exon 1.     

Regulation of c-myc mRNA decay by translational pausing in a coding region instability determinant

A 249-nucleotide coding region instability determinant (CRD) destabilizes c-myc mRNA. Previous experiments identified a CRD-binding protein (CRD-BP) that appears to protect the CRD from endonuclease cleavage. However, it was unclear why a CRD-BP is required to protect a well-translated mRNA whose coding region is covered with ribosomes. We hypothesized that translational pausing in the CRD generates a ribosome-deficient region downstream of the pause site, and this region is exposed to endonuclease attack unless it is shielded by the CRD-BP. Transfection and cell-free translation experiments reported here support this hypothesis. Ribosome pausing occurs within the c-myc CRD in tRNA-depleted reticulocyte translation reactions. The pause sites map to a rare arginine (CGA) codon and to an adjacent threonine (ACA) codon. Changing these codons to more common codons increases translational efficiency in vitro and increases mRNA abundance in transfected cells. These data suggest that c-myc mRNA is rapidly degraded unless it is (i) translated without pausing or (ii) protected by the CRD-BP when pausing occurs. Additional mapping experiments suggest that the CRD is bipartite, with several upstream translation pause sites and a downstream endonuclease cleavage site.     

Effects of intercistronic length on the efficiency of reinitiation by eucaryotic ribosomes.

Simian virus 40-based plasmids that direct the synthesis of preproinsulin during short-term transfection of COS cells have been used to probe the mechanism of reinitiation by eucaryotic ribosomes. Earlier studies from several laboratories had established that the ability of ribosomes to reinitiate translation at an internal AUG codon depends on having a terminator codon in frame with the preceding AUG triplet and upstream from the intended restart site. In the present studies, the position of the upstream terminator codon relative to the preproinsulin restart site has been systematically varied. The efficiency of reinitiation progressively improved as the intercistronic sequence was lengthened. When the upstream "minicistron" terminated 79 nucleotides before the preproinsulin start site, the synthesis of proinsulin was as efficient as if there were no upstream AUG codons. A mechanism is postulated that might account for this result, which is somewhat surprising inasmuch as bacterial ribosomes reinitiate less efficiently as the intercistronic gap is widened.     

Synonymous codon usage in Escherichia coli: selection for translational accuracy

In many organisms, selection acts on synonymous codons to improve translation. However, the precise basis of this selection remains unclear in the majority of species. Selection could be acting to maximize the speed of elongation, to minimize the costs of proofreading, or to maximize the accuracy of translation. Using several data sets, we find evidence that codon use in Escherichia coli is biased to reduce the costs of both missense and nonsense translational errors. Highly conserved sites and genes have higher codon bias than less conserved ones, and codon bias is positively correlated to gene length and production costs, both indicating selection against missense errors. Additionally, codon bias increases along the length of genes, indicating selection against nonsense errors. Doublet mutations or replacement substitutions do not explain our observations. The correlations remain when we control for expression level and for conflicting selection pressures at the start and end of genes. Considering each amino acid by itself confirms our results. We conclude that selection on synonymous codon use in E. coli is largely due to selection for translational accuracy, to reduce the costs of both missense and nonsense errors.     

Gene selective suppression of nonsense termination using antisense agents

An estimated one third of all inherited genetic disorders and many forms of cancer are caused by premature (nonsense) termination codons. Aminoglycoside antibiotics are candidate drugs for a large number of such genetic diseases; however, aminoglycosides are toxic, lack specificity and show low efficacy in this application. Because translational termination is an active process, we considered that steric hindrance by antisense sequences could trigger the ribosome's "default mode" of readthrough when positioned near nonsense codons. To test this hypothesis, we performed experiments using plasmids containing a luciferase reporter with amber, ochre and opal nonsense mutations within the luxB gene in Escherichia coli. The nonspecific termination inhibitors gentamicin and paromomycin and six antisense peptide nucleic acids (PNA) spanning the termination region were tested for their potential to suppress the luxB mutation. Gentamicin and paromomycin increased luciferase activity up to 2.5- and 10-fold, respectively. Two of the PNAs increased Lux activity up to 2.5-fold over control levels, with no significant effect on cell growth or mRNA levels. Thus, it is possible to significantly suppress nonsense mutations within target genes using antisense PNAs. The mechanism of suppression likely involves enhanced readthrough, but this requires further investigation. Nonsense termination in human cells may also be susceptible to suppression by antisense agents, providing a new approach to address numerous diseases caused by nonsense mutations.     

Third position base changes in codons 5' and 3' adjacent UGA codons affect UGA suppression in vivo

The base sequence around nonsense codons affects the efficiency of nonsense codon suppression. Published data, comparing different nonsense sites in a mRNA, implicate the two bases downstream of the nonsense codon as major determinants of suppression efficiency. However, the results we report here indicate that the nature of the contiguous upstream codon can also affect nonsense suppression, as can the third (wobble) base of the contiguous downstream codon. These conclusions are drawn from experiments in which the two Ser codons UCU233 and UCG235 in a nonsense mutant form (UGA234) of the trpA gene in Escherichia coli have been replaced with other Ser codons by site-directed mutagenesis. Suppression of these trpA mutants has been studied in the presence of a UGA nonsense suppressor derived from glyT. We speculate that the non-site-specific effects of the two adjacent downstream bases may be largely at the level of the termination process, whereas more site-specific or codon-specific effects may operate primarily on the activity of the suppressor tRNA.