Identification of a competitive translation determinant in the 3' untranslated region of alfalfa mosaic virus coat protein mRNA

trans regulation of cap-independent translation by a viral subgenomic RNA

Many positive-strand RNA viruses generate 3'-coterminal subgenomic mRNAs to allow translation of 5'-distal open reading frames. It is unclear how viral genomic and subgenomic mRNAs compete with each other for the cellular translation machinery. Translation of the uncapped Barley yellow dwarf virus genomic RNA (gRNA) and subgenomic RNA1 (sgRNA1) is driven by the powerful cap-independent translation element (BTE) in their 3' untranslated regions (UTRs). The BTE forms a kissing stem-loop interaction with the 5' UTR to mediate translation initiation at the 5' end. Here, using reporter mRNAs that mimic gRNA and sgRNA1, we show that the abundant sgRNA2 inhibits translation of gRNA, but not sgRNA1, in vitro and in vivo. This trans inhibition requires the functional BTE in the 5' UTR of sgRNA2, but no translation of sgRNA2 itself is detectable. The efficiency of translation of the viral mRNAs in the presence of sgRNA2 is determined by proximity to the mRNA 5' end of the stem-loop that kisses the 3' BTE. Thus, the gRNA and sgRNA1 have "tuned" their expression efficiencies via the site in the 5' UTR to which the 3' BTE base pairs. We conclude that sgRNA2 is a riboregulator that switches off translation of replication genes from gRNA while permitting translation of structural genes from sgRNA1. These results reveal (i) a new level of control of subgenomic-RNA gene expression, (ii) a new role for a viral subgenomic RNA, and (iii) a new mechanism for RNA-mediated regulation of translation.

In vitro selection of translational regulatory elements

Untranslated regions (UTRs) of mRNAs carry various kinds of translational regulatory elements; however, our knowledge of them is still limited. We created an in vitro selection system that allows us to make a systematic enrichment of the sequences that alter translation efficiency (SESTRE) in any given mRNA and translation system. This method consists of the introduction of random nucleotide sequences into the UTRs of given mRNAs, followed by translation, size fractionation of the polyribosomes, and reverse transcription and PCR amplification (RT-PCR), with repeated cycles of these steps to enrich highly or poorly translatable mRNAs. With this experimental method, we examined how and where translational enhancer motifs emerge on mRNAs using the in vitro translation systems of wheat germ extract. The results indicate that the translational enhancers differentially emerge in response to the presence or absence of the 5' cap. Interestingly, the translational enhancers that activate cap-independent translation evolved more readily in the 3' UTR than in the 5' UTR in wheat germ extract. This SESTRE method should be a powerful tool with which to improve the translational efficiency of given mRNAs in given translation systems and to investigate the structure-function relationship of eukaryotic mRNAs underlying translational control.

Translation reinitiation and leaky scanning in plant viruses

While translation of mRNAs in eukaryotic cells in general follows strict rules, viruses infecting these cells break those rules in various ways. Viruses are under high selection pressure to compete with the host, to economize genome size, and to accommodate signals for replication, virus assembly, etc., on their RNAs as well as using them for translation. The cornucopia of extraordinary translation strategies, such as leaky scanning, internal initiation of translation, ribosome shunt, and virus-controlled reinitiation of translation, evolved by viruses continues to surprise and inform our understanding of general translation mechanisms. While internal initiation is treated in another section of this issue, we concentrate on leaky scanning, shunt and reinitiation, with emphasis on plant pararetroviruses.

The tRNA-like structure of Turnip yellow mosaic virus RNA is a 3'-translational enhancer

Many positive stand RNA viral genomes lack the poly(A) tail that is characteristic of cellular mRNAs and that promotes translation in cis. The 3' untranslated regions (UTRs) of such genomes are expected to provide similar translation-enhancing properties as a poly(A) tail, yet the great variety of 3' sequences suggests that this is accomplished in a range of ways. We have identified a translational enhancer present in the 3' UTR of Turnip yellow mosaic virus (TYMV) RNA using luciferase reporter RNAs with generic 5' sequences transfected into plant cells. The 3' terminal 109 nucleotides comprising the tRNA-like structure (TLS) and an upstream pseudoknot (UPSK) act in synergy with a 5'-cap to enhance translation, with a minor contribution in stabilizing the RNA. Maximum enhancement requires that the RNA be capable of aminoacylation, but either the native valine or engineered methionine is acceptable. Mutations that decrease the affinity for translation elongation factor eEF1A (but also diminish aminoacylation efficiency) strongly decrease translational enhancement, suggesting that eEF1A is mechanistically involved. The UPSK seems to act as an important, though nonspecific, spacer element ensuring proper presentation of a functional TLS. Our studies have uncovered a novel type of translational enhancer and a new role for a plant viral TLS.

Efficient translation of alfamovirus RNAs requires the binding of coat protein dimers to the 3' termini of the viral RNAs

The coat protein (CP) of Alfalfa mosaic virus (AMV) is required to initiate infection by the viral tripartite RNA genome whereas infection by the tripartite Brome mosaic virus (BMV) genome is independent of CP. AMV CP stimulates translation of AMV RNA in vivo 50- to 100-fold. The 3' untranslated region (UTR) of the AMV subgenomic CP messenger RNA 4 contains at least two CP binding sites. A CP binding site in the 3'-terminal 112 nucleotides of RNA 4 was found to be required for efficient translation of the RNA whereas an upstream binding site was not. Binding of CP to the AMV 3' UTR induces a conformational change of the RNA but this change alone was not sufficient to stimulate translation. CP mutant R17A is unable to bind to the 3' UTR and translation in vivo of RNA 4 encoding this mutant occurs at undetectable levels. Replacement of the 3' UTR of this mutant RNA 4 by the 3' UTR of BMV RNA 4 restored translation of R17A-CP to wild-type levels. Apparently, the BMV 3' UTR stimulates translation independently of CP. AMV CP mutant N199 is defective in the formation of CP dimers and did not stimulate translation of RNA 4 in vivo although the mutant CP did bind to the 3' UTR. The finding that N199-CP does not promote AMV infection corroborates the notion that the requirement of CP in the inoculum reflects its role in translation of the viral RNAs.

Cis-acting regulatory elements in the potato virus X 3' non-translated region differentially affect minus-strand and plus-strand RNA accumulation

The 72nt 3' non-translated region (NTR) of potato virus X (PVX) RNA is identical in all sequenced PVX strains and contains sequences that are conserved among all potexviruses. Computer folding of the 3' NTR sequence predicted three stem-loop structures (SL1, SL2, and SL3 in the 3' to 5' direction), which generally were supported by solution structure analyses. The importance of these sequence and/or structural elements to PVX RNA accumulation was further analyzed by inoculation of Nicotiana tabacum (NT-1) protoplasts with PVX transcripts containing mutations in the 3' NTR. Analyses of RNA accumulation by S(1) nuclease protection indicated that multiple sequence elements throughout the 3' NTR were important for minus-strand RNA accumulation. Formation of SL3 was required for accumulation of minus-strand RNA, whereas SL1 and SL2 formation were less important. However, sequences within all of these predicted structures were required for minus-strand RNA accumulation, including a conserved hexanucleotide sequence element in the loop of SL3, and the CU nucleotide in a U-rich sequence within SL2. In contrast, 13 nucleotides that were predicted to reside in SL1 could be deleted without any significant reduction in minus or plus-strand RNA levels. Potential polyadenylation signals (near upstream elements; NUEs) in the 3' NTR of PVX RNA were more important for plus-strand RNA accumulation than for minus-strand RNA accumulation. In addition, one of these NUEs overlapped with other sequence required for optimal minus-strand RNA levels. These data indicate that the PVX 3' NTR contains multiple, overlapping elements that influence accumulation of both minus and plus-strand RNA.

Translational regulation of rotavirus gene expression

Rotavirus mRNAs are transcribed from 11 genomic dsRNA segments within a subviral particle. The mRNAs are extruded into the cytoplasm where they serve as mRNA for protein synthesis and as templates for packaging and replication into dsRNA. The molecular steps in the replication pathway that regulate the levels of viral gene expression are not well defined. We have investigated potential mechanisms of regulation of rotavirus gene expression by functional evaluation of two differentially expressed viral mRNAs. NSP1 (gene 5) and VP6 (gene 6) are expressed early in infection, and VP6 is expressed in excess over NSP1. We formulated the hypothesis that the amounts of NSP1 and VP6 were regulated by the translational efficiencies of the respective mRNAs. We measured the levels of gene 5 and gene 6 mRNA and showed that they were not significantly different, and protein analysis indicated no difference in stability of NSP1 compared with VP6. Polyribosome analysis showed that the majority of gene 6 mRNA was present on large polysomes. In contrast, sedimentation of more than half of the gene 5 mRNA was subpolysomal. The change in distribution of gene 5 mRNA in polyribosome gradients in response to treatment with low concentrations of cycloheximide suggested that gene 5 is a poor translation initiation template compared with gene 6 mRNA. These data define a regulatory mechanism for the difference in amounts of VP6 and NSP1 and provide evidence for post-transcriptional control of rotavirus gene expression mediated by the translational efficiency of individual viral mRNAs.

Assembly of the ribonucleoprotein complex containing the mRNA of the beta-subunit of the mitochondrial H+-ATP synthase requires the participation of two distal cis-acting elements and a complex set of cellular trans-acting proteins

The mRNA encoding the beta-subunit of the mitochondrial H(+)-ATP synthase (beta-F1-ATPase) is localized in an approx. 150 nm structure of the hepatocyte of mammals. In the present study, we have investigated the cis- and trans-acting factors involved in the generation of the ribonucleoprotein complex containing beta-F1-ATPase mRNA. Two cis-acting elements (beta1.2 and 3'beta) have been identified. The beta1.2 element is placed in the open reading frame, downstream of the region encoding the mitochondrial pre-sequence of the protein. The 3'beta element is the 3' non-translated region of the mRNA. Complex sets of proteins from the soluble and non-soluble fractions of the liver interact with the beta1.2 and 3'beta elements. A soluble p88, present also in reticulocyte lysate, displays binding specificity for both the cis-acting elements. Sedimentation and high-resolution in situ hybridization experiments showed that the structure containing the rat liver beta-F1-ATPase mRNA is found in fractions of high sucrose concentration, where large polysomes sediment. Treatment of liver extracts with EDTA promoted the mobilization of beta-F1-ATPase mRNA to fractions of lower sucrose concentration, suggesting that the structure containing beta-F1-ATPase mRNA is a large polysome. Finally, in vitro reconstitution experiments with reticulocyte lysate, using either the full-length, mutant or chimaeric versions of beta-F1-ATPase mRNA, reveal that the assembly of the beta-F1-ATPase mRNA polysome requires the co-operation of both the cis-acting mRNA determinants. The present study illustrates the existence of an intramolecular RNA cross-talking required for the association of the mRNA with the translational machinery.

Translation of a nonpolyadenylated viral RNA is enhanced by binding of viral coat protein or polyadenylation of the RNA

On entering a host cell, positive-strand RNA virus genomes have to serve as messenger for the translation of viral proteins. Efficient translation of cellular messengers requires interactions between initiation factors bound to the 5'-cap structure and the poly(A) binding protein bound to the 3'-poly(A) tail. Initiation of infection with the tripartite RNA genomes of alfalfa mosaic virus (AMV) and viruses from the genus Ilarvirus requires binding of a few molecules of coat protein (CP) to the 3' end of the nonpolyadenylated viral RNAs. Moreover, infection with the genomic RNAs can be initiated by addition of the subgenomic messenger for CP, RNA 4. We report here that extension of the AMV RNAs with a poly(A) tail of 40 to 80 A-residues permitted initiation of infection independently of CP or RNA 4 in the inoculum. Specifically, polyadenylation of RNA 1 relieved an apparent bottleneck in the translation of the viral RNAs. Translation of RNA 4 in plant protoplasts was autocatalytically stimulated by its encoded CP. Mutations that interfered with CP binding to the 3' end of viral RNAs reduced translation of RNA 4 to undetectable levels. Possibly, CP of AMV and ilarviruses stimulates translation of viral RNAs by acting as a functional analogue of poly(A) binding protein or other cellular proteins.

The reovirus S4 gene 3' nontranslated region contains a translational operator sequence

Reovirus mRNAs are efficiently translated within host cells despite the absence of 3' polyadenylated tails. The 3' nontranslated regions (3'NTRs) of reovirus mRNAs contain sequences that exhibit a high degree of gene-segment-specific conservation. To determine whether the 3'NTRs of reovirus mRNAs serve to facilitate efficient translation of viral transcripts, we used T7 RNA polymerase to express constructs engineered with full-length S4 gene cDNA or truncation mutants lacking sequences in the 3'NTR. Full-length and truncated s4 mRNAs were translated using rabbit reticulocyte lysates, and translation product sigma3 was quantitated by phosphorimager analysis. In comparison to full-length s4 mRNA, translation of the s4 mRNA lacking the 3'NTR resulted in a 20 to 50% decrease in sigma3 produced. Addition to translation reactions of an RNA oligonucleotide corresponding to the S4 3'NTR significantly enhanced translation of full-length s4 mRNA but had no effect on s4 mRNA lacking 3'NTR sequences. Translation of s4 mRNAs with smaller deletions within the 3'NTR identified a discrete region capable of translational enhancement and a second region capable of translational repression. Differences in translational efficiency of full-length and deletion-mutant mRNAs were independent of RNA stability. Protein complexes in reticulocyte lysates that specifically interact with the S4 3'NTR were identified by RNA mobility shift assays. RNA oligonucleotides lacking either enhancer or repressor sequences did not efficiently compete the binding of these complexes to full-length 3'NTR. These results indicate that the reovirus S4 gene 3'NTR contains a translational operator sequence that serves to regulate translational efficiency of the s4 mRNA. Moreover, these findings suggest that cellular proteins interact with reovirus 3'NTR sequences to regulate translation of the nonpolyadenylated reovirus mRNAs.

Efficient GFP mutations profoundly affect mRNA transcription and translation rates

Green fluorescent protein (GFP) variants with higher expression efficiencies have been generated by mutagenesis. Favorable mutations often improve the folding of GFP. However, an effect on protein folding fails to explain the efficiency of several other GFP mutations. In this work, we demonstrate that mutations of the GFP open reading frame and untranslated regions profoundly affect mRNA transcription and translation efficiencies. The removal of the GFP 5' untranslated region halves the transcription rate of the GFP gene, but hugely improves its translation rate. Mutations of the GFP open reading frame or the addition of peptide sequences differentially reduce the GFP mRNA transcription rate, translation efficiency and protein stability. These previously unrecognized effects are demonstrated to be critical to the efficiency of GFP mutants. These findings indicate the feasibility of generating more efficient GFP variants, with optimized mRNA transcription and translation in eukaryotic cells.

A four-nucleotide translation enhancer in the 3'-terminal consensus sequence of the nonpolyadenylated mRNAs of rotavirus

The 5' cap and poly(A) tail of eukaryotic mRNAs work synergistically to enhance translation through a process that requires interaction of the cap-associated eukaryotic initiation factor, eIF-4G, and the poly(A)-binding protein, PABP. Because the mRNAs of rotavirus, and other members of the Reoviridae, contain caps but lack poly(A) tails, their translation may be enhanced through a unique mechanism. To identify translation-enhancement elements in the viral mRNAs that stimulate translation in vivo, chimeric RNAs were prepared that contained an open reading frame for luciferase and the 5' and 3' untranslated regions (UTRs) of a rotavirus mRNA or of a nonviral mRNA. Transfection of the chimeric RNAs into rotavirus-infected cells showed that the viral 3' UTR contained a translation-enhancement element that promoted gene expression. The element did not enhance gene expression in uninfected cells and did not affect the stability of the RNAs. Mutagenesis showed that the conserved sequence GACC located at the 3' end of rotavirus mRNAs operated as an enhancement element. The 3'-GACC element stimulated protein expression independently of the sequence of the 5' UTR, although efficient expression required the RNA to contain a cap. The results indicate that the expression of viral proteins in rotavirus-infected cells is specifically up-regulated by the activity of a novel 4-nt 3' translation enhancer (TE) common to the 11 nonpolyadenylated mRNAs of the virus. The 4-nt sequence of the rotavirus 3' TE represents by far the shortest of any of the sequence enhancers known to stimulate translation.

Translational control of viral gene expression in eukaryotes

As obligate intracellular parasites, viruses rely exclusively on the translational machinery of the host cell for the synthesis of viral proteins. This relationship has imposed numerous challenges on both the infecting virus and the host cell. Importantly, viruses must compete with the endogenous transcripts of the host cell for the translation of viral mRNA. Eukaryotic viruses have thus evolved diverse mechanisms to ensure translational efficiency of viral mRNA above and beyond that of cellular mRNA. Mechanisms that facilitate the efficient and selective translation of viral mRNA may be inherent in the structure of the viral nucleic acid itself and can involve the recruitment and/or modification of specific host factors. These processes serve to redirect the translation apparatus to favor viral transcripts, and they often come at the expense of the host cell. Accordingly, eukaryotic cells have developed antiviral countermeasures to target the translational machinery and disrupt protein synthesis during the course of virus infection. Not to be outdone, many viruses have answered these countermeasures with their own mechanisms to disrupt cellular antiviral pathways, thereby ensuring the uncompromised translation of virion proteins. Here we review the varied and complex translational programs employed by eukaryotic viruses. We discuss how these translational strategies have been incorporated into the virus life cycle and examine how such programming contributes to the pathogenesis of the host cell.

Internal-ribosome-entry-site functional activity of the 3'-untranslated region of the mRNA for the beta subunit of mitochondrial H+-ATP synthase

Translation in vitro of the mammalian nucleus-encoded mRNA for the beta subunit of mitochondrial H(+)-ATP synthase (beta-mRNA) of oxidative phosphorylation is promoted by a 150 nt translational enhancer sequence in the 3'-untranslated region (3' UTR). Titration of the eukaryotic initiation factor eIF4E with cap analogue revealed that translation of capped beta-mRNA was pseudo-cap independent. The 3' UTR of beta-mRNA stimulates the translation of heterologous uncapped mRNA species, both when the 3' UTR is placed at the 3' end and at the 5' end of the transcripts. The 3' UTRs of the alpha subunit of mitochondrial H(+)-ATP synthase (alpha-F1-ATPase) and subunit IV of cytochrome c oxidase (COX IV) mRNA species, other nucleus-encoded transcripts of oxidative phosphorylation, do not have the same activity in translation as the 3' UTR of beta-mRNA. On dicistronic RNA species, the 3' UTR of beta-mRNA, and to a smaller extent that of COX IV mRNA, is able to promote the translation of the second cistron to a level comparable to the activity of internal ribosome entry sites (IRESs) described in picornavirus mRNA species. These results indicate that the 3' UTRs of certain mRNA species of oxidative phosphorylation have IRES-like functional activity. Riboprobes of the active 3' UTRs on dicistronic assays formed specific RNA-protein complexes when cross-linked by UV to proteins of the lysate, suggesting that cytoplasmic translation of the mRNA species bearing an active 3' UTR is assisted by specific RNA-protein interactions.

Differential roles of the 5' untranslated regions of cucumber mosaic virus RNAs 1, 2, 3 and 4 in translational competition

RNA species of plant tripartite RNA viruses show distinct translational activities in vitro when the viral RNA concentration is high. However, it is not known what causes the differential translation of virion RNAs. Using an in vitro wheat germ translation system, we investigated the translation efficiencies and competitive activities of chimeric cucumber mosaic virus (CMV) RNAs that contained viral untranslated regions (UTRs) and a luciferase-coding sequence. The chimeric RNAs exhibited distinct translation efficiencies and competitive activities. For example, the translation of chimeric CMV RNA 4 was about 40-fold higher than that of chimeric CMV RNA 3 in a competitive environment. The distinct translation resulted mainly from differences in competitive activities rather than translation efficiencies of the chimeric RNAs. The differential competitive activities were specified by viral 5 UTRs, but not by 3 UTRs or viral proteins. The competitive translational activities of the 5 UTRs were as follows: RNA 4 (coat protein)>RNAs 2 and 1 (2a and 1a protein, or replicase )> RNA 3 (3a protein).

A single-stranded loop in the 5' untranslated region of cucumber mosaic virus RNA 4 contributes to competitive translational activity

The 5' untranslated region (UTR) of cucumber mosaic virus (CMV) RNA 4 confers a highly competitive translational advantage on a heterologous luciferase open reading frame. Here we investigated whether secondary structure in the 5' UTR contributes to this translational advantage. Stabilization of the 5' UTR RNA secondary structure inhibited competitive translational activity. Alteration of a potential single-stranded loop to a stem by substitution mutations greatly inhibited the competitive translational activity. Tobacco plants infected with wild type virus showed a 2.5-fold higher accumulation of maximal coat protein than did plants infected with a loop-mutant virus. Amplification of viral RNA in these plants could not explain the difference in accumulation of coat protein. Phylogenetic comparison showed that potential single-stranded loops of 12-23 nucleotides in length exist widely in subgroups of CMV.

A primary determinant of cap-independent translation is located in the 3'-proximal region of the tomato bushy stunt virus genome

Tomato bushy stunt virus (TBSV) is a positive-strand RNA virus and is the prototype member of the genus Tombusvirus. The genomes of members of this genus are not polyadenylated, and prevailing evidence supports the absence of a 5' cap structure. Previously, a 167-nucleotide-long segment (region 3.5) located near the 3' terminus of the TBSV genome was implicated as a determinant of translational efficiency (S.K. Oster, B. Wu and K. A. White, J. Virol. 72:5845-5851, 1998). In the present report, we provide evidence that a 3'-proximal segment of the genome, which includes region 3.5, is involved in facilitating cap-independent translation. Our results indicate that (i) a 5' cap structure can substitute functionally for the absence of region 3.5 in viral and chimeric reporter mRNAs in vivo; (ii) deletion of region 3.5 from viral and chimeric mRNAs has no appreciable effect on message stability; (iii) region 3.5 represents part of a larger 3' proximal element, designated as the 3' cap-independent translational enhancer (3'CITE), that is required for proficient cap-independent translation; (iv) the 3'CITE also facilitates cap-dependent translation; (v) none of the major viral proteins are required for 3'CITE activity; and (vi) no significant 3'CITE-dependent stimulation of translation was observed when mRNAs were tested in vitro in wheat germ extract under various assay conditions. This latter property distinguishes the 3'CITE from other characterized plant viral 3'-proximal cap-independent translational enhancers. Additionally, because the 3'CITE overlaps with cis-acting replication signals, it could potentially participate in regulating the initiation of genome replication.

A potential mechanism for selective control of cap-independent translation by a viral RNA sequence in cis and in trans

Highly efficient cap-independent translation initiation at the 5'-proximal AUG is facilitated by the 3' translation enhancer sequence (3'TE) located near the 3' end of barley yellow dwarf virus (BYDV) genomic RNA. The role of the 3'TE in regulating viral translation was examined. The 3'TE is required for translation and thus replication of the genomic RNA that lacks a 5' cap (Allen et al., 1999, Virology253:139-144). Here we show that the 3'TE also mediates translation of uncapped viral subgenomic mRNAs (sgRNA1 and sgRNA2). A 109-nt viral sequence is sufficient for 3'TE activity in vitro, but additional viral sequence is necessary for cap-independent translation in vivo. The 5' extremity of the sequence required in the 3' untranslated region (UTR) for cap-independent translation in vivo coincides with the 5' end of sgRNA2. Thus, sgRNA2 has the 3'TE in its 5' UTR. Competition studies using physiological ratios of viral RNAs showed that, in trans, the 109-nt 3'TE alone, or in the context of 869-nt sgRNA2, inhibited translation of genomic RNA much more than it inhibited translation of sgRNA1. The divergent 5' UTRs of genomic RNA and sgRNA1 contribute to this differential susceptibility to inhibition. We propose that sgRNA2 serves as a novel regulatory RNA to carry out the switch from early to late gene expression. Thus, this new mechanism for temporal control of translation control involves a sequence that stimulates translation in cis and acts in trans to selectively inhibit translation of viral mRNA.

Selective translation of cytoplasmic mRNAs in plants

Translation of mRNA is emerging as an important mode of gene regulation in plants. It is frequently controlled at initiation and appears to be regulated by competition for limiting translational components, different requirements for specific factors and cis-acting mRNA elements. Recent studies indicate that interactions between the 5' and 3' ends of the message enhance translation, perhaps by facilitating recruitment of initiation factors or enhancing ribosome recycling. Normal development and environmental stimuli modulate the phosphorylation of components of the mRNA 5'-cap-binding complex, ribosomes and mRNA-binding proteins. These modifications might be responsible for changes in the hierarchy of mRNAs that are in competition for translation.

Control of translation initiation in animals

Regulation of translation initiation is a central control point in animal cells. We review our current understanding of the mechanisms of regulation, drawing particularly on examples in which the biological consequences of the regulation are clear. Specific mRNAs can be controlled via sequences in their 5' and 3' untranslated regions (UTRs) and by alterations in the translation machinery. The 5'UTR sequence can determine which initiation pathway is used to bring the ribosome to the initiation codon, how efficiently initiation occurs, and which initiation site is selected. 5'UTR-mediated control can also be accomplished via sequence-specific mRNA-binding proteins. Sequences in the 3' untranslated region and the poly(A) tail can have dramatic effects on initiation frequency, with particularly profound effects in oogenesis and early development. The mechanism by which 3'UTRs and poly(A) regulate initiation may involve contacts between proteins bound to these regions and the basal translation apparatus. mRNA localization signals in the 3'UTR can also dramatically influence translational activation and repression. Modulations of the initiation machinery, including phosphorylation of initiation factors and their regulated association with other proteins, can regulate both specific mRNAs and overall translation rates and thereby affect cell growth and phenotype.

The role of herpes simplex virus ICP27 in the regulation of UL24 gene expression by differential polyadenylation

Herpes simplex virus specifies two sets of transcripts from the UL24 gene, short transcripts (e.g., 1.4 kb), processed at the UL24 poly(A) site, and long transcripts (e.g., 5.6 kb), processed at the UL26 poly(A) site. The 1.4- and 5.6-kb transcripts initiate from the same promoter but are expressed with early and late kinetics, respectively. Measurements of transcript levels following actinomycin D treatment of infected cells revealed that the 1.4- and 5.6-kb UL24 transcripts have similar stabilities, consistent with UL24 transcript kinetics being regulated by differential polyadenylation rather than by differential stabilities. Although the UL24 poly(A) site, which gives rise to short transcripts, is encountered first during processing, long transcripts processed at the UL26 site are equally or more abundant; thus, operationally, the UL24 site is weak. Using a series of viral ICP27 mutants, we investigated whether ICP27, which has been suggested to stimulate the usage of weak poly(A) sites, stimulates 1.4-kb transcript accumulation. We found that accumulation of 1.4-kb transcripts did not require ICP27 during viral infection. Rather, ICP27 was required for full expression of 5.6-kb transcripts, and the decrease in 5. 6-kb transcripts relative to 1.4-kb transcripts was not due solely to reduced DNA synthesis. Our results indicate that temporal expression of UL24 transcripts can be regulated by differential polyadenylation and that although ICP27 is not required for processing at the operationally weak UL24 poly(A) site, it does modulate 5.6-kb transcript levels at a step subsequent to transcriptional initiation.

The 5' untranslated region of cucumber mosaic virus RNA4 confers highly competitive activity on heterologous luciferase mRNA in cell-free translation

The cell-free translation of virion RNAs of several tripartite RNA viruses has shown that RNA4, a subgenomic RNA, is more competitive than other virion RNAs. Recently, the 3' untranslated region (UTR) of alfalfa mosaic virus (AMV) RNA4 was identified to be a competitive determinant. In this study, we observed that the RNA4 of cucumber mosaic virus (CMV), another tripartite RNA virus, was also found to be a strong competitor in translational competition among CMV virion RNAs. To identify the competitive determinant of CMV RNA4, we constructed various chimeric luciferase mRNAs containing RNA4 and/or vector-derived UTRs. The relative translations of luciferase-containing mRNA in the presence of a competitor mRNA showed that the 5' UTR, not the 3' UTR, substantially contributed to the highly competitive activity of CMV RNA4.

The enigma of pX: A host-dependent cis-acting element with variable effects on tombusvirus RNA accumulation

Tomato bushy stunt virus (TBSV) is a small isometric virus that contains a single-stranded RNA genome with five major genes. In this study, we have analyzed the importance of an additional small sixth open reading frame (ORF) of 207 nucleotides, designated pX, which resides at the 3' end of the genome. Bioassays showed that deletions or additions of nucleotides at the 5' end of the pX gene that were designed to disrupt the ORF, or site-specific inactivation of its start codon, all gave rise to TBSV mutants which were unable to accumulate to detectable levels in cucumber or Nicotiana benthamiana protoplasts. Although these results suggested a role for the putative pX protein, introduction of a premature stop codon in the pX gene had no strong negative effect. However, a comparable mutation that affected the same nucleotides without changing the predicted amino acid sequence greatly reduced RNA accumulation. Therefore, we hypothesize that cis-acting RNA sequences within the pX gene, rather than the predicted protein influence genome accumulation. The requirement of the cis-acting pX ORF sequences appears to be host-dependent because comparisons revealed that subtle pX gene mutations that prohibited accumulation of TBSV RNA in cucumber or N. benthamiana, failed to interfere substantially with replication in Chenopodium quinoa protoplasts or plants. Irrespective of the host, the cis-acting pX gene sequences were dispensable on replicase-deficient RNAs that require helper TBSV for replication in trans. In addition, the pX gene was not essential for in vitro translation of replicase proteins from genomic RNA. These results suggest that neither translation nor polymerase activity of the replicase proteins require pX gene sequences. However, it is possible that very early in the replication cycle of genomic RNA in vivo, the pX gene cis-acting element is essential for some other unidentified function which involves interaction with one or more host components whose composition varies slightly between different plants.

Control of the translational efficiency of beta-F1-ATPase mRNA depends on the regulation of a protein that binds the 3' untranslated region of the mRNA

The expression of the nucleus-encoded beta-F1-ATPase gene of oxidative phosphorylation is developmentally regulated in the liver at both the transcriptional and posttranscriptional levels. In this study we have analyzed the potential mechanisms that control the cytoplasmic expression of beta-F1-ATPase mRNA during liver development. Remarkably, a full-length 3' untranslated region (UTR) of the transcript is required for its efficient in vitro translation. When the 3' UTR of beta-F1-ATPase mRNA is placed downstream of a reporter construct, it functions as a translational enhancer. In vitro translation experiments with full-length beta-F1-ATPase mRNA and with a chimeric reporter construct containing the 3' UTR of beta-F1-ATPase mRNA suggested the existence of an inhibitor of beta-F1-ATPase mRNA translation in the fetal liver. Electrophoretic mobility shift assays and UV cross-linking experiments allowed the identification of an acutely regulated protein (3'betaFBP) of the liver that binds at the 3' UTR of beta-F1-ATPase mRNA. The developmental profile of 3'betaFBP parallels the reported changes in the translational efficiency of beta-F1-ATPase mRNA during development. Fractionation of fetal liver extracts revealed that the inhibitory activity of beta-F1-ATPase mRNA translation cofractionates with 3'-UTR band-shifting activity. Compared to other tissues of the adult rat, kidney and spleen extracts showed very high expression levels of 3'betaFBP. Translation of beta-F1-ATPase mRNA in the presence of kidney and spleen extracts further supported a translational inhibitory role for 3'betaFBP. Mapping experiments and a deletion mutant of the 3' UTR revealed that the cis-acting element for binding 3'betaFBP is located within a highly conserved region of the 3' UTR of mammalian beta-F1-ATPase mRNAs. Overall, we have identified a mechanism of translational control that regulates the rapid postnatal differentiation of liver mitochondria.