Location of the initiation site for protein synthesis on foot-and-mouth disease virus RNA by in vitro translation of defined fragments of the RNA

Modification of the second translation initiation site restricts the replication of foot-and-mouth disease virus in PK-15 cells

Abstract

The translation initiation of foot-and-mouth disease virus (FMDV) occurs at two alternative initiation sites (Lab AUG and Lb AUG). Usually, the Lb AUG is more favorably used to initiate protein synthesis than the Lab AUG. To explore the effect of Lb AUG on FMDV replication and obtain FMDV with restricted replication, this initiation codon was mutated to a variety of non-AUG codons (UGG, AUC, CUG, and AAA). Fortunately, the modifications did not prevent viral viability but influenced replication characteristics of some FMDV mutants in a cell-specific manner, as was shown by the similar replication in BHK-21 cells and delayed growth kinetics in PK-15 cells. This attenuated phenotype of FMDV mutants in PK-15 cells was found to be correlated with reduced abilities to cleave eIF4GI and suppress interference (IFN) expression. As leader (L) protein was reported to be responsible for eIF4GI cleavage and inhibition of IFN expression, the in vivo L protein synthesis was examined during the infection of FMDV mutants. Our results showed that not only the total yield of L proteins was severely influenced but also the individual yield of L protein was seen to be affected, which implied that both the relative usage of the two initiation sites and overall translation efficiency were changed by Lb AUG modifications. In addition, the in vitro translation activity was also negatively regulated by Lb AUG mutations. Collectively, these findings suggested that the restricted replications of Lb AUG-modified FMDVs were related to the delayed eIF4GI cleavage and decreased ability to block IFN expression but were mainly determined by the inefficient translation initiation. FMDVs precisely with modifications of Lb AUG initiation codon may represent safer seed viruses for vaccine production.

Key points

• The polyprotein translation of FMDV initiates at two alternative initiation sites (Lab AUG and Lb AUG). In order to explore the effect of Lb AUG on FMDV replication and obtain FMDV with restricted replication, the Lb initiation AUG was mutated to a variety of non-AUG codons (UGG, AUC, CUG, and AAA), and four FMDV mutants with Lb AUG modification were generated.

• We found that partial FMDV mutants grew almost as well as WT virus in BHK-21 cells, a typical cell line used for FMD vaccine production, but displayed impaired replication in IFN-competent PK-15 cells.

• The attenuation of mutant FMDVs in PK-15 cells was found to be correlated with delayed eIF4GI cleavage and decreased ability to block IFN expression.

• We proved that the attenuated phenotype of Lb AUG-modified FMDVs was mainly determined by the inefficient translation initiation, as demonstrated by the decrease of total yield of L proteins and individual production of L protein.

• We successfully generated genetically engineered FMDV with attenuated phenotype. The approach of precise engineering of FMDV with the modification of initiation codon provides a safe platform to produce inactivated antigen vaccines.

Foot-and-mouth disease

Foot-and-mouth disease (FMD) is a highly contagious disease of cloven-hoofed animals. The disease was initially described in the 16th century and was the first animal pathogen identified as a virus. Recent FMD outbreaks in developed countries and their significant economic impact have increased the concern of governments worldwide. This review describes the reemergence of FMD in developed countries that had been disease free for many years and the effect that this has had on disease control strategies. The etiologic agent, FMD virus (FMDV), a member of the Picornaviridae family, is examined in detail at the genetic, structural, and biochemical levels and in terms of its antigenic diversity. The virus replication cycle, including virus-receptor interactions as well as unique aspects of virus translation and shutoff of host macromolecular synthesis, is discussed. This information has been the basis for the development of improved protocols to rapidly identify disease outbreaks, to differentiate vaccinated from infected animals, and to begin to identify and test novel vaccine candidates. Furthermore, this knowledge, coupled with the ability to manipulate FMDV genomes at the molecular level, has provided the framework for examination of disease pathogenesis and the development of a more complete understanding of the virus and host factors involved.

Foot-and-mouth disease virus Lb proteinase can stimulate rhinovirus and enterovirus IRES-driven translation and cleave several proteins of cellular and viral origin

Rhinovirus and enterovirus 2A proteinases stimulate translation initiation driven from the cognate internal ribosome entry segment (IRES) (S. J. Hambidge and P. Sarnow, Proc. Natl. Acad. Sci. USA 89:10272-10276, 1992; H.-D. Liebig, E. Ziegler, R. Yan, K. Hartmuth, H. Klump, H. Kowalski, D. Blaas, W. Sommergruber, L. Frasel, B. Lamphear, R. Rhoads, E. Kuechler, and T. Skern, Biochemistry 32:7581-7588, 1993). Given the functional similarities between the foot-and-mouth disease virus (FMDV) L proteinase and these 2A proteinases (autocatalytic excision from the nascent viral polyprotein and cleavage of eIF-4 gamma), we investigated whether the FMDV L proteinase would also be able to stimulate translation initiation. We found that purified recombinant FMDV Lb proteinase could stimulate in vitro translation driven from a rhinovirus or enterovirus IRES by 5- to 10-fold. In contrast, stimulation of translation initiation on a cardiovirus IRES by this proteinase was minimal, and stimulation of translation driven from the cognate FMDV IRES could not be evidenced. Studies using an inhibitor or a mutant Lb proteinase indicated that stimulation of IRES-driven translation is mediated via proteolysis of some cellular component(s). Our studies also demonstrated that the Lb proteinase is capable of stimulating initiation of translation on an uncapped cellular message. Unexpectedly, and in contrast to the 2A proteinases, the Lb proteinase specifically cleaved the products of the two reporter genes used in this study: Xenopus laevis cyclin B2 and influenza virus NS. Therefore, we also set out to investigate the requirements for substrate recognition by the Lb proteinase. Purified recombinant Lb proteinase recognized at least one mengovirus polypeptide and specifically cleaved human cyclin A and poliovirus replicase-related polypeptides. In the latter case, the site(s) of cleavage was located within the N-terminal part of polypeptide 3D. Sequence comparisons revealed no significant primary sequence similarities between the target proteins and the two sites already known to be recognized by the FMDV L proteinase.

Translation of encephalomyocarditis virus RNA by internal ribosomal entry

Picornavirus 5' NCRs contain IRES elements that have been divided into two groups, exemplified by PV (type 1) and EMCV (type 2). These elements are functionally related and have an intriguing level of structural and sequence similarity. Some conserved RNA sequences and/or structures may correspond to cis-acting elements involved in IRES function, so that there may also be similarities in the mechanism by which the two types or IRES promote initiation. The function of both types of IRES element appears to depend on a cellular 57 kDa polypeptide, which has been identified as the predominantly nuclear hnRNP protein PTB. However, a specific function for p57/PTB in translation has not yet been established. These two groups can be differentiated on the basis of their requirements for trans-acting factors. The EMCV IRES functions efficiently in a broader range of eukaryotic cell types than type 1 IRES elements, probably because the latter require additional factor(s). A second distinction between these IRES element is that initiation occurs directly at the 3' border of type 2 IRES elements, whereas a nonessential spacer of between 30 nt and 154 nt separates type 1 IRES elements from the downstream initiation codon.

Functional analysis of the internal translation initiation site of foot-and-mouth disease virus

Mutagenesis of the large untranslated sequence at the 5' end of the genome of foot-and-mouth disease virus revealed that a region of approximately 450 nucleotides preceding the open reading frame of the viral polyprotein is involved in the regulation of translation initiation at two internal start sites. Variations in two domains of this region reduced the translation efficiency up to 10-fold, whereas an intermediate segment seemed to be less essential. A pyrimidine-rich sequence preceding the start codon was most sensitive in that conversion of single pyrimidine residues to purines decreased the translation efficiency strongly. The data are in agreement with a recently proposed general structural model for the internal ribosome entry site of the cardiovirusaphthovirus subgroup of picornaviruses (E. V. Pilipenko, V. M. Blinov, B. K. Chernov, T. M. Dmitrieva, and V. I. Agol, Nucleic Acids Res. 17:5701-5711, 1989). They suggest, however, that this model represents only a core structure for the internal entry of ribosomes and that foot-and-mouth disease virus and other members of the picornaviruses need additional regulatory RNA elements for efficient translation initiation.

Cap-independent translation of encephalomyocarditis virus RNA: structural elements of the internal ribosomal entry site and involvement of a cellular 57-kD RNA-binding protein

Translation of encephalomyocarditis virus (EMCV) mRNA occurs by ribosomal internal entry into the 5'-nontranslated region (5' NTR) rather than by ribosomal scanning. The internal ribosomal entry site (IRES) in the EMCV 5' NTR was determined by in vitro translation with RNAs that were generated by in vitro transcription of EMCV cDNAs containing serial deletions from either the 5' or 3' end of the EMCV 5' NTR. Regions downstream of nucleotide 403 and upstream of nucleotide 811 of EMCV were required for efficient translation. Site-directed mutagenesis revealed that a stem-loop structure (400 nucleotides upstream of the initiation codon) was essential for IRES function. We discovered a 57-kD cellular protein whose specific interaction with this stem-loop appears to be prerequisite for IRES function. A A pyrimidine-rich stretch proximal to the initiation codon was also crucial for efficient translation of EMCV mRNA. We propose that ribosomes bind directly to the initiating AUG without scanning.

The nucleotide sequence of the structural-protein-coding region of foot-and-mouth disease virus serotype SAT3

The nucleotide sequence coding for the structural proteins and nonstructural protein P2A has been determined for a foot-and-mouth disease virus (FMDV) isolated in Africa. This virus, serotypically designated SAT3 (South African Territories type 3), shows about 60% homology at the nucleotide level to prototype viruses from the O, A and C serotypes of FMDV. The highest region of variability was shown in structural protein VP1, presumably a consequence of its position on the surface of the virus and its exposure to selection pressure by neutralising antibody. Within this region amino acids (aa) 141-160, which have been shown to represent an immunodominant region in other FMDV serotypes, showed hypervariability as well as the insertion of 5 or 9 additional aa relative to the O1 and C1 serotypes, respectively. In contrast, the sequence of nonstructural protein P2A was completely conserved indicating a probable important role in virus replication.

A segment of the 5' nontranslated region of encephalomyocarditis virus RNA directs internal entry of ribosomes during in vitro translation

Picornavirus RNAs are uncapped messengers and have unusually long 5' nontranslated regions (5'NTRs) which contain many noninitiating AUG triplets. The translational efficiency of different picornavirus RNAs varies between different cell-free extracts and even in the same extract, such as micrococcal nuclease-treated rabbit reticulocyte lysates. The effect of the poliovirus 5'NTR on in vitro translation was compared with that of the 5'NTR of encephalomyocarditis virus by the use of synthetic mRNAs, micrococcal nuclease-treated HeLa cell extracts, and rabbit reticulocyte lysates. Artificial mono- and dicistronic mRNAs synthesized with T7 RNA polymerase were used to investigate whether the 5'NTR of encephalomyocarditis virus RNA contains a potential internal ribosomal entry site. The sequence between nucleotides 260 and 484 in the 5'NTR of encephalomyocarditis RNA was found to play a critical role in the efficient translation in both mono- and dicistronic mRNAs. Our data suggest that an internal ribosomal entry site resides in this region.

Insights into Theiler's virus neurovirulence based on a genomic comparison of the neurovirulent GDVII and less virulent BeAn strains

Theiler's murine encephalomyelitis viruses (TMEV) are naturally occurring enteric pathogens of mice which can be divided into two subgroups based primarily on their neurovirulence after intracerebral inoculation: the highly virulent GDVII group and the less virulent TO strains. To begin to elucidate the molecular basis of neurovirulence of the two TMEV subgroups, we have cloned and sequenced the entire 8105 nucleotide RNA genome of the highly virulent GDVII virus and compared it to the less virulent BeAn 8386 virus (D. C. Pevear, M. Calenoff, E. Rozhon, and H. L. Lipton (1987) J. Virol. 61, 1507-1516). The viruses are 90.4% identical at the nucleotide level. The highest level of nucleotide identity is in the 5' and 3' noncoding regions of the RNAs (95.5 and 99.2%, respectively): regions believed to be important for control of viral RNA synthesis, initiation of translation, encapsidation, and virion uncoating. The 2303 amino acid polyproteins of BeAn and GDVII viruses are 95.7% identical at the amino acid level (99 of 2303 residues differed). Thirty-nine of these amino acid differences occur in the three surface coat proteins, VP1 (20 differences), VP2 (10 differences), and VP3 (9 differences), while the remainder of the changes are distributed throughout the polyprotein. Although these levels of identity are too low to determine where neurovirulence maps based solely on nucleotide sequence analysis, having the complete sequence will facilitate construction of recombinant BeAn-GDVII viruses to be used for this purpose.

Potential secondary and tertiary structure in the genomic RNA of foot and mouth disease virus

The nucleotide sequence of the 5' untranslated region of foot and mouth disease virus (FMDV), serotype A10 has been determined. This completes the first total genomic sequence for any one serotype of FMDV. Analysis of the sequence to the 3' side of the poly (C) tract reveals the presence of a 24 nucleotide repeated motif which has homologies with a sequence located upstream of the transcriptional initiation site from several mammalian fibrinogen genes. The function of this element in FMDV is unclear. However, computer analysis of this region predicts the presence of a high degree of secondary and tertiary structure in which these repeats form an important part. The implications of these predictions are discussed.

Safety and efficacy of foot-and-mouth disease vaccines containing endonuclease-inactivated virions

Inactivation of foot-and-mouth disease virus (FMDV) by means of virion-associated endonuclease was found to be suited to the production of safe and potent vaccines, which proved to be equal or better than those containing formaldehyde or ethyleneimine in guinea-pig potency tests. First order inactivation kinetics were regularly shown, with half life values which varied according to the different temperatures used. Inactivation brought about extensive degradation of FMDV RNA, while it did not adversely influence the integrity of critical viral epitopes on FMDV VP1.

Effects of cDNA hybridization on translation of encephalomyocarditis virus RNA

Cell-free translation of the RNA of encephalomyocarditis virus was examined after hybridization of chemically synthesized cDNA fragments to different sites of the 5' noncoding region of the viral RNA. The following results were obtained. The binding of cDNA fragments to the first 41 nucleotides, to the poly(C) tract (between nucleotides 149 and 263), and to the sequence between nucleotides 309 and 338 did not affect translation of the viral RNA; the binding of cDNA fragments to the sequence between nucleotides 420 and 449 caused a slight inhibition; and the binding of fragments to eight different sites between nucleotides 450 and the initiator AUG codon (nucleotide 834) caused high degrees of inhibition. The results suggest that the first part of the 5' untranslated region, at least to nucleotide 338, may not be required for encephalomyocarditis viral RNA translation; however, the region near nucleotide 450 is important for translation of the viral RNA. The possibility that initiation occurs at an internal site is discussed.

All foot and mouth disease virus serotypes initiate protein synthesis at two separate AUGs

Translation of the foot and mouth disease virus genome in vitro and in vivo indicated that all seven serotypes initiate protein synthesis at two separate AUGs. Sequence analysis of the region surrounding these AUGs has shown that the efficiency with which the initiating AUG is recognized is dependent on the flanking nucleotides. However, in vitro, the major factor determining which AUG is used is the concentration of Mg2+.

Encephalomyocarditis virus 3C protease: efficient cell-free expression from clones which link viral 5' noncoding sequences to the P3 region

All picornaviral peptides are derived by progressive posttranslational cleavage of a giant precursor polyprotein. Translation of encephalomyocarditis virus (EMC) RNA in rabbit reticulocyte extracts produces active viral peptides, including protease 3C, which is responsible for many cleavage reactions within the processing cascade. DNA plasmids containing 5' noncoding sequences of EMC linked to other portions of the viral genome were constructed and transcribed into RNA. Like virion RNA, the clone-derived transcripts directed efficient protein translation in vitro. The 5'-linked constructions may represent examples of a general method for cell-free expression of any cloned gene segment. One construction produced a self-cleaving P3 region precursor, which contained active 3C protease. A genetically engineered insertion within the 3C sequences eliminated endogenous self-cleavage activity without altering the ability of the P3 peptide to serve as substrate in bimolecular reactions with added 3C. Another plasmid encoding the L-VP0 portion of the capsid region was used to demonstrate that scission between the leader peptide (L) and capsid protein VP0 can be catalyzed by 3C. The enzyme responsible for this step was previously unidentified. A rapid purification scheme for isolation of 3C from EMC-infected HeLa cells is also presented.

Characterization of foot-and-mouth disease virus gene products with antisera against bacterially synthesized fusion proteins

Defined segments of the cloned foot-and-mouth disease virus genome corresponding to all parts of the coding region were expressed in Escherichia coli as fusions to the N-terminal part of the MS2-polymerase gene under the control of the inducible lambda PL promoter. All constructs yielded large amounts of proteins, which were purified and used to raise sequence-specific antisera in rabbits. These antisera were used to identify the corresponding viral gene products in 35S-labeled extracts from foot-and-mouth disease virus gene products in the nucleotide sequence, to identify precursor-product relationships, and to detect several foot-and-mouth disease virus gene products not previously identified in vivo or in vitro.

Nucleotide and amino acid sequence coding for polypeptides of foot-and-mouth disease virus type A12

The coding region for the structural and nonstructural polypeptides of the type A12 foot-and-mouth disease virus genome has been identified by nucleotide sequencing of cloned DNA derived from the viral RNA. In addition, 704 nucleotides in the 5' untranslated region between the polycytidylic acid tract and the probable initiation codon of the first translated gene, P16-L, have been sequenced. This region has several potential initiation codons, one of which appears to be a low-frequency alternate initiation site. The coding region encompasses 6,912 nucleotides and ends in a single termination codon, UAA, located 96 nucleotides upstream from a 3'-terminal polyadenylic acid tract. Microsequencing of radiolabeled in vivo and in vitro translation products identified the genome position of the major foot-and-mouth disease virus proteins and the cleavage sites recognized by the putative viral protease and an additional protease(s), probably of cellular origin, to generate primary and functional foot-and-mouth disease virus polypeptides.

The sequence of foot-and-mouth disease virus RNA to the 5' side of the poly(C) tract

The nucleotide sequence of foot-and-mouth disease virus (FMDV) RNA to the 5' side of the poly(C) tract (S fragment) has been determined for representatives of the A and O serotypes of the virus. The two S fragments differ in length by five nucleotides (nt), with 367 nt for O1 compared with 362 nt for A10, due to a number of insertions/deletions. However, the two sequences show 86% homology. There are no conserved open reading frames (ORFs). Secondary structure predictions reveal a high degree of potential base-pairing, such that the entire S fragment sequence can be folded into a hairpin structure.

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.

Multiple proteases in foot-and-mouth disease virus replication

Translation of foot-and-mouth disease virus RNA in a rabbit reticulocyte lysate for short time intervals resulted in the production of the peptides P20a , P16, and P88 (Lab, Lb, and P1) (R. R. Rueckert , Recommendations of the 3rd European Study Group on Molecular Biology of Picornavirus, Urbino , Italy, 1983). If further translation was prevented, the structural protein precursor P88 was not cleaved, even after prolonged incubation. This result indicates that the mechanism of the cleavage between P20a -P16 and P88 and of that between P88 and P52 (P2) differs from the mechanism of the secondary cleavages which produce the structural proteins. Furthermore, treatment of foot-and-mouth disease virus-infected cells with the protease inhibitor D-valyl phenylalanyl lysyl chloromethyl ketone prevented the in vivo cleavage between P20a -P16 and P88 but had no effect on any of the other cleavage events. These results suggest that the cleavage of the foot-and-mouth disease virus polyprotein utilizes two different host proteases.

Biochemical map of polypeptides specified by foot-and-mouth disease virus

Pulse-chase labeling of foot-and-mouth disease virus-infected bovine kidney cells revealed stable and unstable viral-specific polypeptides. To identify precursor-product relationships among these polypeptides, antisera against a number of structural and nonstructural viral-specific polypeptides were used. Cell-free translations programmed with foot-and-mouth disease virion RNA or foot-and-mouth disease virus-infected bovine kidney cell lysates, which were shown to contain almost identical polypeptides, were immunoprecipitated with the various antisera. To further establish identity, some proteins were compared by partial protease digestion. Evidence for a membrane association of the polypeptides coded for by the middle genome region is also presented. A biochemical map of the foot-and-mouth disease virus genome was established from the above information.

The complete nucleotide sequence of the RNA coding for the primary translation product of foot and mouth disease virus

The complete nucleotide sequence of the coding region of foot and mouth disease virus RNA (strain A1061) is presented. The sequence extends from the primary initiation site, approximately 1200 nucleotide from the 5' end of the genome, in an open translational reading frame of 6,999 nucleotides to a termination codon 93 nucleotides from the 3' terminal poly (A). Available amino acid sequence data correlates with that predicted from the nucleotide sequence. The amino acid sequence around cleavage sites in the polyprotein shows no consistency, although a number of the virus-coded protease cleavage sites are between glutamate and glycine residues.

Biotechnological approach to a new foot-and-mouth disease virus vaccine

Major contributions towards the development of an absolutely safe FMDV vaccine are evident. With the identification of VP1 as the immunogenic protein, it is possible to manufacture a subunit vaccine via biotechnology. DNA sequences encoding the VP1 protein can be introduced into a bacterium with ease; under the appropriate conditions, large amounts of VP1 can be produced in a short time. The accumulation of amino acid sequences generated by recombinant DNA techniques allows identification of antigenic domains, which are the basis of variability among serotype and subtype viruses. As a result, vaccine production by chemical synthesis of short peptides corresponding to the antigenic determinants is greatly facilitated. At present, results from experimental vaccines employing genetically engineered or chemically synthesized VP1 antigens against homologous virus infection are encouraging. The current approach of preparing vaccine is to utilize the antigenic specificity of the virus. Since FMDV undergoes antigenic drift, variants not neutralized by type-specific serum will arise. An alternative approach is to prepare vaccines based on antigenic sites shared among all serotype and subtype viruses.

The gene organisation of a small RNA-containing insect virus: comparison with that of mammalian picornaviruses

The coding regions of an insect virus, cricket paralysis virus, have been mapped using pactamycin. The results suggest that the genome of this virus functions as a polycistronic mRNA, the structural proteins being encoded by the 5' end of the RNA in an order similar to those of mammalian picornaviruses. High-molecular-weight proteins of unknown function map at the 3' end of the genome.

Structure of the FMDV translation initiation site and of the structural proteins

A cDNA clone of Foot and Mouth Diseases Virus (FMDV), strain C1, has been sequenced. The limits of the structural genes were defined by comparison with the available protein data. We identified two potential translation initiation sites for the viral polyprotein separated by 84 nucleotides. We suggest that these two initiation sites could be used to express two proteins differing only at the N-terminal, P16 and P20a. This model is supported by the fact that antiserum against a bacterially synthesized polypeptide corresponding to the anterior region of the polyprotein precipitates specifically both P16 and P20a. Comparison of the C1 sequence with two other serotypes, O1K and A10 revealed variability in the major immunogenic structural protein, VP1, and also in two other capsid proteins, VP2 and VP3. P16/P20a, VP4, and the N-terminal part of the precursor of the nonstructural genes, P52, are rather conserved between the different FMDV strains.

Orientation of the Cleavage Map of the 200-Kilodalton Polypeptide Encoded by the Bottom-Component RNA of Cowpea Mosaic Virus

The genomic organization of the bottom-component RNA of cowpea mosaic virus was studied. In vivo, this RNA encodes at least eight different polypeptides of 170, 110, 87, 84, 60, 58, 32, and 4 kilodaltons (K), the last polypeptide representing the genome-bound protein VPg. In rabbit reticulocyte lysates, bottom-component RNA is translated into a 200K polypeptide which is then processed to give the 32 and 170K polypeptides also found in vivo. By pulse-labeling the 200K primary translation product, we now show that the 32 and 170K polypeptides are derived from the NH 2 -terminal and COOH-terminal parts of this polypeptide, respectively. Comparison of the proteolytic peptide patterns of 170K polypeptides synthesized in vitro and pulse-labeled at either the NH 2 -terminal or the COOH-terminal end with the patterns of the 170 and 110K polypeptides found in vivo demonstrates that the order within the 200K primary translation product of cowpea mosaic virus bottom-component RNA is as follows: NH 2 -32K polypeptide-58K polypeptide-VPg-24K polypeptide-87K polypeptide-COOH.

The position of polypeptide G on the encephalomyocarditis virus polyprotein cleavage map

The two-dimensional mapping of tryptic peptides of encephalomyocarditis virus-specific proteins has demonstrated that the amino acid sequence of non-structural polypeptide G constitutes a portion of the molecule of a precursor of capsid proteins, polypeptide A. The results of pulse-chase in vitro translation experiments strongly suggest that polypeptide G corresponds to a C-terminal moiety of polypeptide A. Variations in the polyprotein cleavage maps of different picornaviruses are briefly discussed.

Recombination in RNA

The aphthovirus genome consists of a single molecule of single-stranded RNA that encodes all the virus-induced proteins. We isolated recombinant aphthoviruses from cells simultaneously infected with temperature-sensitive mutants of two different subtype strains. Analysis of the proteins induced by 16 independently generated recombinants revealed two types of protein pattern, which were consistent with single genetic crossovers on the 5' side and 3' side, respectively, of the central P34-coding region. Recombinants invariably inherited all four coat proteins from the same parent, and novel recombinant proteins were not observed. RNAase T1 fingerprints of virus RNA, prepared from representatives of each recombinant type, confirmed the approximate crossover sites that had been deduced from the inheritance of proteins. These fingerprints provide molecular evidence of recombination at the level of RNA and demonstrate the potential of RNA recombination for producing genetic diversity among picornaviruses.

Identification of the initiation site of poliovirus polyprotein synthesis

The complete nucleotide sequence of poliovirus RNA has a long open reading frame capable of encoding the precursor polyprotein NCVP00. The first AUG codon in this reading frame is located 743 nucleotides from the 5' end of the RNA and is preceded by eight AUG codons in all three reading frames. Because all proteins that map at the amino terminus of the polyprotein (P1-1a, VP0, and VP4) are blocked at their amino termini and previous studies of ribosome binding have been inconclusive, direct identification of the initiation site of protein synthesis was difficult. We separated and identified all of the tryptic peptides of capsid protein VP4 and correlated these peptides with the amino acid sequence predicted to follow the AUG codon at nucleotide 743. Our data indicate that VP4 begins with a blocked glycine that is encoded immediately after the AUG codon at nucleotide 743. An S1 nuclease analysis of poliovirus mRNA failed to reveal a splice in the 5' region. We concluded that synthesis of the poliovirus polyprotein is initiated at nucleotide 743, the first AUG codon in the long open reading frame.

The nucleotide sequence of cDNA coding for the structural proteins of foot-and-mouth disease virus

The complete nucleotide sequence of cDNA coding for the structural capsid polypeptides of foot-and-mouth disease virus (FMDV) (strain A(10)61) has been determined. Portions of the flanking sequence coding for the nonstructural proteins p20a and p52 are also provided. The three larger structural polypeptides VP1, VP2 and VP3 have unmodified Mrs of 23248, 24649 and 24213, respectively. The size of the smaller polypeptide, VP4, can only be estimated at 7360 because the 5'-limit of its coding region is not yet known with certainty. The sequence data for VP1 (the major immunising antigen) and the amino-terminal quarter of p52 are compared with the data of Kurz et al. (Nucl. Acids Res. 9 (1981) 1919-1931) for a different serotype (O1K). This shows that variation is much greater in the region coding for VP1 than in that coding for p52. This is reflected in the level of amino acid sequence variation predicted for the two proteins. Analysis of relative codon usage reveals a strong bias in favour of C and G over U and A in the third base position. The dinucleotide frequencies show a bias against A-U and U-A, and for A-C and C-A.

Genomic RNA of mengovirus V. Recognition of common features by ribosomes and eucaryotic initiation factor 2

Binding of ribosomes to the 32P-labeled genomic RNA of mengovirus was studied in lysates of mouse L929 and Krebs ascites cells under conditions for initiation of translation. Upon total digestion with RNase T1, the 32P-labeled RNA protected in either 40S or 80S initiation complexes yielded four unique, large oligonucleotides. Each of these oligonucleotides occurred once in the viral RNA molecule. The same four oligonucleotides were recovered from 80S initiation complexes formed in lysates in which unlabeled mengovirus RNA had been translated extensively, indicating that recognition by ribosomes was not modulated detectably by a viral translation product. The recognition of intact, 32P-labeled mengovirus RNA by eucaryotic initiation factor 2 (eIF-2) was examined by direct complex formation. Fingerprint analysis of the RNA protected by eIF-2 against RNase T1 digestion yielded three T1 oligonucleotides that were identical to three of the four oligonucleotides protected in either 40S or 80S initiation complexes. A physical map of the large T1 oligonucleotides of the mengovirus RNA molecule was constructed, and the four protected oligonucleotides were found to map internally, within the region between the polycytidylate tract and the 3' end. For either ribosomes or eIF-2, the protected oligonucleotides could not be arranged in a continuous sequence, suggesting that they constitute at least two widely separated domains. These results show that ribosomes recognize and blind to more than a single sequence in mengovirus RNA, located internally in regions that are far removed from the 5' end of the molecule. eIF-2 itself binds with high specificity to mengovirus RNA, recognizing apparently three of the four sequences recognized by ribosomes.

Removal of the genome-linked protein of foot-and-mouth disease virus by rabbit reticulocyte lysate

Rabbit reticulocyte lysate cleaves the genome-linked protein VPg from foot-and-mouth disease virus (FMDV) RNA. This activity could be reliably monitored since removal of the protein resulted in a change in migration in polyacrylamide gels of the small specific 5' and fragment of the RNA (S fragment). The unlinking activity cleaved the bond between the tyrosine residue of VPg and the RNA to leave a 5' phosphate on the RNA. The 5' sequence of the RNA from which VPg had been removed by rabbit reticulocyte lysate was the same as that of FMDV mRNA isolated from infected cells. VPg released from the RNA was rapidly degraded by the rabbit reticulocyte lysate to material which eluted with the inclusion volume of a Sepharose 6B column and partitioned to the aqueous phase during phenol extraction. The unlinking activity was inhibited by heating the lysate to 56 degrees C, by sodium dodecyl sulfate (SDS), EDTA, and Zn2+ ions but was unaffected by reducing agents, a translation inhibitor, and a number of protease and RNase inhibitors.

Primary structure, gene organization and polypeptide expression of poliovirus RNA

The primary structure of the poliovirus genome has been determined. The RNA molecule is 7,433 nucleotides long, polyadenylated at the 3' terminus, and covalently linked to a small protein (VPg) at the 5' terminus. An open reading frame of 2,207 consecutive triplets spans over 89% of the nucleotide sequence and codes for the viral polyprotein NCVPOO. Twelve viral polypeptides have been mapped by amino acid sequence analysis and were found to be proteolytic cleavage products of the polyprotein, cleavages occurring predominantly at Gln-Gly pairs.

In vitro translation of cricket paralysis virus RNA

Cricket paralysis virus RNA acted as a messenger in a translation system and directed incorporation of 35S-methionine into protein. Polyacrylamide gel analysis of the proteins demonstrated the presence of proteins of comparable molecular weight to the viral structural proteins and also potential high molecular weight precursors.

Molecular cloning of foot and mouth disease virus genome and nucleotide sequences in the structural protein genes

Foot and mouth disease virus (FMDV), of the family Picornaviridae, consists of a single-stranded RNA (approximately 8,000 nucleotides), the translation of which is initiated on the 3' side of a 150-nucleotide poly(C) tract and yields a single polyprotein which is processed by host cell proteases into four primary products (Fig. 1). One or more virus-specified proteases further cleave these into the final products, the capsid proteins (VP1-4) being derived from the precursor p88 (for review see ref. 5). There are seven serotypes of the virus and as it has been shown that the immunizing activity of FMDV particles is associated primarily with VP1 (refs 6, 7), it seems likely that antigenic variation in FMDV is a result of changes in the structure of this protein. To further our understanding of this variation and as a first step in the possible development of FMDV vaccines from genetically manipulated microorganisms, we report here the construction and analysis of recombinant plasmids containing cDNA copies of the RNA. Comparison of the deduced amino acid sequence with the known polypeptide sequences shows that the NH2-termini of VP2 and VP3 are conserved between the A and O serotypes whereas that of VP1 (the immunizing antigen) varies by as much as 42% between serotypes.

Binding of ribosomes to the 5' leader sequence (N = 258) of RNA 3 from alfalfa mosaic virus

RNA 3 of alfalfa mosaic virus (AlMV) contains information for two genes: near the 5' end an active gene coding for a 35 Kd protein and, near the 3' end, a silent gene coding for viral coat protein. We have determined a sequence of 318 nucleotides which contains the potential initiation codon for the 35 Kd protein at 258 nucleotides from the 5' end. This long leader sequence can form initiation complexes containing three 80 S ribosomes. A shorter species of RNA, corresponding to a molecule of RNA 3 lacking the cap and the first 154 nucleotides (RNA 3') has been isolated. The remaining leader sequence of 104 nucleotides in RNA 3' forms a single 80 S initiation complex with wheat germ ribosomes. The location of the regions of the leader sequence of RNA 3 involved in initiation complex formation with 80 S ribosomes is reported.

Comparison of the nucleotide sequence at the 5' end of RNAs from nine aphthoviruses, including representatives of the Seven serotypes

The sequence of about 70 nucleotides at the 5' end of the RNAs of nine different aphthoviruses (foot-and-mouth disease viruses), including representatives of the seven serotypes of the virus, has been determined by partial enzyme digestion of (32)P-end-labeled S fragment-that part of the RNA lying to the 5' side of the poly(C) tract and including the 5' end of the molecule. The S fragments were prepared from polyadenylated virus-specific RNA extracted from infected cells by digestion with RNase H in the presence of oligo(dG)(12-18). The first 27 nucleotides from the 5' end were highly conserved in all the RNAs. This region was followed by a more variable region of about 15 nucleotides, showing some length and sequence heterogeneity and including potential but probably nonutilized initiation codons. In agreement with previous homology studies, the sequencing results showed that the European serotypes A, O, and C form a group distinct from the SAT serotypes and that the Asia 1 serotype is closely related to the European group. The lengths of the S fragments of two different RNAs were confirmed as containing 360 to 400 nucleotides by gel electrophoresis with reference to nucleotide markers of known size.

Binding of wheat germ ribosomes to fragmented viral mRNA

The specificity of binding of wheat germ ribosomes to mRNA was greatly altered by cleavage of the message. Fragmentation of reovirus mRNA allowed wheat germ ribosomes to bind and protect a variety of internal sequences which were not accessible to ribosomes in the intact message. In experiments using the polycistronic mRNA from bacteriophage R17, wheat germ ribosomes bound preferentially at the beginning of the lysis peptide and synthetase cistrons, and at a third site which may be derived from the C-terminal region of the A protein cistron. This result is similar to that reported previously in a mammalian translational system (J.F. Atkins et al., Cell 18:246-256, 1979) except that, in the present study, limited cleavage of the phage RNA was necessary to activate these sites. More extensive fragmentation of R17 RNA permitted wheat germ ribosomes to bind and protect a great many additional sites. Thus, presence of an (exposed) 5'-terminus on an RNA molecule appears to be necessary and sufficient for attachment of eucaryotic ribosomes.