Translation at higher than an optimal level interferes with coupling at an intercistronic junction

In pairs of adjacent genes co-transcribed on bacterial polycistronic mRNAs, translation of the first coding region frequently functions as a positive factor to couple translation to the distal coding region. Coupling efficiencies vary over a wide range, but synthesis of both gene products at similar levels is common. We report the results of characterizing an unusual gene pair, in which only about 1% of the translational activity from the upstream gene is transmitted to the distal gene. The inefficient coupling was unexpected because the upstream gene is highly translated, the distal initiation site has weak but intrinsic ability to bind ribosomes, and the AUG is only two nucleotides beyond the stop codon for the upstream gene. The genes are those in the filamentous phage IKe genome, which encode the abundant single-stranded DNA binding protein (gene V) and the minor coat protein that caps one tip of the phage (gene VII). Here, we have used chimeras between the related phage IKe and f1 sequences to localize the region responsible for inefficient coupling. It mapped upstream from the intercistronic region containing the gene V stop codon and the gene VII initiation site, indicating that low coupling efficiency is associated with gene V. The basis for inefficient coupling emerged when coupling efficiency was found to increase as gene V translation was decreased below the high wild-type level. This was achieved by lowering the rate of elongation and by decreasing the efficiency of suppression at an amber codon within the gene. Increasing the strength of the Shine-Dalgarno interaction with 16S rRNA at the gene VII start also increased coupling efficiency substantially. In this gene pair, upstream translation thus functions in an unprecedented way as a negative factor to limit downstream expression. We interpret the results as evidence that translation in excess of an optimal level in an upstream gene interferes with coupling in the intercistronic junction.     

Creation of artificial hybrid operons with partially overlapping genes to achieve an expression of heterologous genes in Escherichia coli cells

A new method of optimization of foreign gene expression in E. coli, based on the construction of hybrid operons with partially overlapping genes is described. The partial overlapping of the translation termination and initiation sites in the formed operon must provide translational coupling of appropriate gene product synthesis. Such an approach has provided the synthesis of human interferon alpha F in E. coli cells under the control of the lacUV5-promotor up to about (3-4).10(7) units per liter of bacterial culture. The reinitiation of the distal gene translation is shown to take place in the intercistronic region. Substitution of the lacUV5 promotor by the more efficient tac one allowed to increase the synthesis level of interferon alpha F to (1-2).10(8) units per liter. The conclusion is made about the equimolarity of distal and proximal to the promotor genes products syntheses when the intercistronic region of E. coli trpE-trpD genes are used for translational coupling.     

Role of the intercistronic region in post-transcriptional control of gene expression in the histidine transport operon of Salmonella typhimurium: involvement of REP sequences

The high-affinity histidine permease of Salmonella typhimurium is encoded by a four-gene operon containing a large intercistronic region located between the first gene (hisJ) and the three distal genes (hisQ, hisM, hisP). The level of expression of hisJ is 30-fold greater than that of hisP. In order to investigate the role of the intercistronic region in intra-operonic control of gene expression, we have isolated MudII-mediated lacZ gene fusions to hisQ, hisM and hisP. We have used these fusions to isolate and analyse mutants that have altered levels of expression of the hisQ gene, the first gene downstream from the intercistronic region. The results indicate that intra-operonic regulation is due to a combination of factors including efficiency of translational initiation, mRNA degradation, and retroregulation of hisJ expression. They also suggest that the REP (Repetitive Extragenic Palindromic) sequences, which are located in the hisJ-hisQ intercistronic region, may interfere with translation of the hisQ gene and affect upstream messenger RNA stability by protecting it from 3' to 5' nuclease degradation (in agreement with data presented by Newbury et al., 1987).     

Translational Coupling during Expression of the Tryptophan Operon of ESCHERICHIA COLI

E. coli trpE polar mutations are 10 time more polar on trpD gene expression than on downstream (trpC, B, or A) gene expression. This effects was shown to be the result of "translational coupling," in which efficient translation of trpE-trpD intercistronic punctuation region consists of overlapping stop and start codons, and the trpE and trpD gene products form a functional complex in the cell. In light observations and characteristics, several models for the mechanism of translational coupling are considered.     

The first and third uORFs in RSV leader RNA are efficiently translated: implications for translational regulation and viral RNA packaging.

Rous sarcoma virus (RSV) RNA leader contains three short upstream open reading frames. We have shown recently that both uORFs 1 and 3 influence in vivo translation of the downstream gag gene and are involved in the virus RNA packaging process. In this report, we have studied the translational events occurring at the upstream AUGs in vivo. We show that (i) the first and third AUGs are efficient translational initiation sites; (ii) ribosomes reinitiate efficiently at AUG3; and (iii) deletions in the intercistronic distance between uORF1 and 3 (which is well conserved among avian strains) prevent ribosome initiation at AUG3, thus increasing translation efficiency at the downstream AUGgag. The roles of the uORFs in translation and packaging are discussed.     

Both RNA editing and RNA cleavage are required for translation of tobacco chloroplast ndhD mRNA: a possible regulatory mechanism for the expression of a chloroplast operon consisting of functionally unrelated genes.

Tobacco chloroplast genes encoding a photosystem I component (psaC) and a NADH dehydrogenase subunit (ndhD) are transcribed as a dicistronic pre-mRNA which is then cleaved into short mRNAs. An RNA protection assay revealed that the cleavage occurs at multiple sites in the intercistronic region. There are two possible initiation codons in the tobacco ndhD mRNA: the upstream AUG and the AUG created by RNA editing from the in-frame ACG located 25 nt downstream. Using the chloroplast in vitro translation system, we found that translation begins only from the edited AUG. The extent of ACG to AUG editing is partial and depends on developmental and environmental conditions. In addition, the in vitro assay showed that the psaC/ndhD dicistronic mRNA is not functional and that the intercistronic cleavage is a prerequisite for both ndhD and psaC translation. Using a series of mutant mRNAs, we showed that an intramolecular interaction between an 8 nt sequence in the psaC coding region and its complementary 8 nt sequence in the 5' ndhD UTR is the negative element for translation of the dicistronic mRNA. A possible mechanism in which the differential expression of the chloroplast operon consists of functionally unrelated genes is discussed.     

Translational control by a long range RNA-RNA interaction; a basepair substitution analysis.

One of the two mechanisms that regulate expression of the replicase cistron in the single stranded RNA coliphages is translational coupling. This mechanism prevents ribosomes from binding at the start of the replicase cistron unless the upstream coat cistron is being translated. Genetic analysis had identified a maximal region of 132 nucleotides in the coat gene over which ribosomes should pass to activate the replicase start. Subsequent deletion studies in our laboratory had further narrowed down the regulatory region to 12 nucleotides. Here, we identify a long-distance RNA-RNA interaction of 6 base pairs as the basis of the translational polarity. The 3' side of the complementarity region is located in the coat-replicase intercistronic region, some 20 nucleotides before the start codon of the replicase. The 5' side encodes amino acids 31 and 32 of the coat protein. Mutations that disrupt the long-range interaction abolish the translational coupling. Repair of basepairing by second site base substitutions restores translational coupling.     

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.     

Efficiency and Frequency of Translational Coupling between the Bacteriophage T4 Clamp Loader Genes

The bacteriophage T4 DNA polymerase holoenzyme is composed of the core polymerase, gene product 43 (gp43), in association with the “sliding clamp” of the T4 system, gp45. Sliding clamps are the processivity factors of DNA replication systems. The T4 sliding clamp comes to encircle DNA via the “clamp loader” activity inherent in two other T4 proteins: 44 and 62. These proteins assemble into a pentameric complex with a precise 4:1 stoichiometry of proteins 44 and 62. Previous work established that T4 genes 44 and 62, which are directly adjacent on polycistronic mRNA molecules, are—to some degree—translationally coupled. In the present study, measurement of the levels (monomers/cell) of the clamp loader subunits during the course of various T4 infections in different host cell backgrounds was accomplished by quantitative immunoblotting. The efficiency of translational coupling was obtained by determining the in vivo levels of gp62 that were synthesized when its translation was either coupled to or uncoupled from the upstream translation of gene 44. Levels of gp44 were also measured to determine the relative stoichiometry of synthesis and the percentage of gp44 translation that was transmitted across the intercistronic junction (coupling frequency). The results indicated a coupling efficiency of ~85% and a coupling frequency of ~25% between the 44-62 gene pair during the course of infection. Thus, translational coupling is the major factor in maintaining the 4:1 stoichiometry of synthesis of the clamp loader subunits. However, coupling does not appear to be an absolute requirement for the synthesis of gp62.     

The role of bases upstream of the Shine-Dalgarno region and in the coding sequence in the control of gene expression in Escherichia coli: translation and stability of mRNAs in vivo

A range of translational initiation regions (TIR) was created by combining synthetic DNA fragments derived from the atpB-atpE intercistronic sequence of Escherichia coli with the cDNA sequence encoding mature human interleukin 2 (IL-2), the E. coli fnr gene, or an fnr::lacZ gene fusion. Both the overall rates of gene expression and the relative concentrations and stabilities of the corresponding mRNA species were estimated in strains bearing the constructs on plasmids. These measurements served as the basis for analyses of the relationship between the structure of the TIR and the true rates of translation that it promotes. The constructs involving the IL-2 cDNA were predicted to allow much less stable secondary structure within the TIR than those involving the N-terminal region of the fnr gene. Thus by combining one set of upstream sequences with two different types of N-terminal coding sequence, it was possible to distinguish between the respective influences of primary and secondary structure upon initiation. The data indicate that in the presence of a given Shine-Dalgarno (SD)/start codon combination, the decisive factor for translational initiation efficiency is the stability of base pairing involving, or in the vicinity of, this region. The sequences contributing to this secondary structure can be many bases upstream of the SD region and/or downstream of the start codon. There was no indication that the specific base sequence upstream of the SD region could, other than to the extent that it contributed to the local secondary structure, significantly influence the efficiency of translational initiation.     

Evidence that the GCN2 protein kinase regulates reinitiation by yeast ribosomes.

The yeast gene GCN4 produces an mRNA that has a long 5' 'untranslated' region containing four small open reading frames (ORFs) preceding the protein coding frame. This configuration suppresses the rate by which GCN4 protein is synthesized. However, translational derepression of the GCN4 mRNA occurs when yeast cells are grown under conditions of amino acid limitation. Such translational derepression requires the GCN2 protein kinase and the presence of the 5' most proximal ORF. In this study we show that a functional coupling between the translation of the first ORF and the amount of the GCN2 protein is responsible for the translational derepression of the GCN4 mRNA. Our evidence suggests that this coupling involves an increase in the ability of 40S ribosomal subunits that have translated the first frame to resume scanning and reinitiate translation at a downstream AUG independently of the base sequence in the intervening region.