Functional analysis of the two alternative translation initiation sites of foot-and-mouth disease virus

The antiviral response triggered by the cGAS/STING pathway is subverted by the foot-and-mouth disease virus proteases

Propagation of viruses requires interaction with host factors in infected cells and repression of innate immune responses triggered by the host viral sensors. Cytosolic DNA sensing pathway of cyclic GMP-AMP synthase (cGAS) and stimulator of interferon genes (STING) is a major component of the antiviral response to DNA viruses, also known to play a relevant role in response to infection by RNA viruses, including foot-and-mouth disease virus (FMDV). Here, we provide supporting evidence of cGAS degradation in swine cells during FMDV infection and show that the two virally encoded proteases, Leader (Lpro) and 3Cpro, target cGAS for cleavage to dampen the cGAS/STING-dependent antiviral response. The specific target sequence sites on swine cGAS were identified as Q140/T141 for the FMDV 3Cpro and the KVKNNLKRQ motif at residues 322-330 for Lpro. Treatment of swine cells with inhibitors of the cGAS/STING pathway or depletion of cGAS promoted viral infection, while overexpression of a mutant cGAS defective for cGAMP synthesis, unlike wild type cGAS, failed to reduce FMDV replication. Our findings reveal a new mechanism of RNA viral antagonism of the cGAS-STING innate immune sensing pathway, based on the redundant degradation of cGAS through the concomitant proteolytic activities of two proteases encoded by an RNA virus, further proving the key role of cGAS in restricting FMDV infection.

Uncovering targets of the Leader protease: Linking RNA-mediated pathways and antiviral defense

RNA viruses have developed specialized mechanisms to subvert host RNA‐binding proteins (RBPs) favoring their own gene expression. The Leader (L) protein of foot‐and‐mouth disease virus, a member of the Picornaviridae family, is a papain‐like cysteine protease that self‐cleaves from the polyprotein. Early in infection, the L protease cleaves the translation initiation factors eIF4GI and eIF4GII, inducing the shutdown of cap‐dependent translation. However, the cleavage sites on the viral polyprotein, eIF4GI, and eIF4GII differ in sequence, challenging the definition of a consensus site for L targets. Identification of Gemin5 and Daxx proteolytic products in infected cells unveiled a motif centered on the RKAR sequence. The RBP Gemin5 is a member of the survival of motor neurons complex, a ribosome interacting protein, and a translation downregulator. Likewise, the Fas‐ligand Daxx is a multifunctional adaptor that plays key roles in transcription control, apoptosis, and innate immune antiviral response. Remarkably, the cleavage site on the RNA helicases MDA5 and LGP2, two relevant immune sensors of the retinoic acid‐inducible gene‐I (RIG‐I)‐like receptors family, resembles the L target site of Gemin5 and Daxx, and similar cleavage sites have been reported in ISG15 and TBK1, two proteins involved in type I interferon response and signaling pathway, respectively. In this review we dissect the features of the L cleavage sites in essential RBPs, eventually helping in the discovery of novel L targets.

This article is categorized under:

RNA in Disease and Development > RNA in Disease

Translation > Translation Regulation

Foot-and-Mouth Disease Virus Evades Innate Immune Response by 3C-Targeting of MDA5

Foot-and-mouth disease (FMD) is a highly contagious disease caused by FMD virus (FMDV) in cloven-hoofed animals. Retinoic acid-inducible gene I (RIG-I) and melanoma differentiation-associated gene 5 (MDA5) are representative receptors in the cytoplasm for the detection of viral RNA and trigger antiviral responses, leading to the production of type I interferon. Although MDA5 is a crucial receptor for sensing picornavirus RNA, the interplay between MDA5 and FMDV is relatively unknown compared to the interplay between RIG-I and FMDV. Here, we observed that the FMDV infection inhibits MDA5 protein expression. Of the non-structural proteins, the Lb and 3C proteinases (Lbpro and 3Cpro) were identified to be primarily responsible for this inhibition. However, the inhibition by 3Cpro was independent of proteasome, lysosome and caspase-dependent pathway and was by 3C protease activity. A direct interaction between 3Cpro and MDA5 protein was observed. In conclusion, this is the first report that 3Cpro inhibits MDA5 protein expression as a mechanism to evade the innate immune response during FMDV infection. These results elucidate the pathogenesis of FMDV and provide fundamental insights for the development of a novel vaccine or therapeutic agent.

MDA5 cleavage by the Leader protease of foot-and-mouth disease virus reveals its pleiotropic effect against the host antiviral response

The RIG-I-like receptor (RLR) melanoma differentiation-associated gene 5 (MDA5) plays a key role in triggering innate antiviral response during infection by RNA viruses. MDA5 activation leads to transcription induction of type-I interferon (IFN) and proinflammatory cytokines. MDA5 has also been associated with autoimmune and autoinflammatory diseases by dysfunctional activation of innate immune response in the absence of infection. Here, we show how foot-and-mouth disease virus (FMDV) counteracts the specific antiviral effect exerted by MDA5 targeting the protein for cleavage by the viral Leader protease (Lpro). MDA5 overexpression had an inhibitory effect on FMDV infection in IFN-competent cells. Remarkably, immunostimulatory viral RNA co-immunoprecipitated with MDA5 in infected cells. Moreover, specific cleavage of MDA5 by Lpro was detected in co-transfected cells, as well as during the course of FMDV infection. A significant reduction in IFN induction associated with MDA5 cleavage was detected by comparison with a non-cleavable MDA5 mutant protein with preserved antiviral activity. The Lpro cleavage site in MDA5 was identified as the RGRAR sequence in the conserved helicase motif VI, coinciding with that recently reported for Lpro in LGP2, another member of the RLRs family involved in antiviral defenses. Interestingly, specific mutations within the MDA5 Lpro target sequence have been associated with immune disease in mice and humans. Our results reveal a pleiotropic strategy for immune evasion based on a viral protease targeting phylogenetically conserved domains of immune sensors. Identification of viral strategies aimed to disrupt MDA5 functionality may also contribute to develop new treatment tools for MDA5-related disorders.

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 virus: Prospects for using knowledge of virus biology to improve control of this continuing global threat

Understanding of the biology of foot-and-mouth disease virus (FMDV) has grown considerably since the nucleotide sequence of the viral RNA was determined. The ability to manipulate the intact genome and also to express specific parts of the genome individually has enabled detailed analyses of viral components, both RNA and protein. Such studies have identified the requirements for specific functional elements for virus replication and pathogenicity. Furthermore, information about the functions of individual virus proteins has enabled the rational design of cDNA cassettes to express non-infectious empty capsid particles that can induce protective immunity in the natural host animals and thus represent new vaccine candidates. Similarly, attempts to block specific virus activities using antiviral agents have also been performed. However, currently, only the well-established, chemically inactivated FMDV vaccines are commercially available and suitable for use to combat this important disease of livestock animals. These vaccines, despite certain shortcomings, have been used very successfully (e.g. in Europe) to control the disease but it still remains endemic in much of Africa, southern Asia and the Middle East. Hence there remains a significant risk of reintroduction of the disease into highly susceptible animal populations with enormous economic consequences.

The Different Tactics of Foot-and-Mouth Disease Virus to Evade Innate Immunity

Like all pathogens, foot-and-mouth disease virus (FMDV) is recognized by the immune system inducing a heightened immune response mainly mediated by type I and type III IFNs. To overcome the strong antiviral response induced by these cytokines, FMDV has evolved many strategies exploiting each region of its small RNA genome. These include: (a) inhibition of IFN induction at the transcriptional and translational level, (b) inhibition of protein trafficking; (c) blockage of specific post-translational modifications in proteins that regulate innate immune signaling; (d) modulation of autophagy; (e) inhibition of stress granule formation; and (f) in vivo modulation of immune cell function. Here, we summarize and discuss FMDV virulence factors and the host immune footprint that characterize infection in cell culture and in the natural hosts.

Innate immune sensor LGP2 is cleaved by the Leader protease of foot-and-mouth disease virus

The RNA helicase LGP2 (Laboratory of Genetics and Physiology 2) is a non-signaling member of the retinoic acid-inducible gene-I (RIG-I)-like receptors (RLRs), whose pivotal role on innate immune responses against RNA viruses is being increasingly uncovered. LGP2 is known to work in synergy with melanoma differentiation-associated gene 5 (MDA5) to promote the antiviral response induced by picornavirus infection. Here, we describe the activity of the foot-and-mouth disease virus (FMDV) Leader protease (Lpro) targeting LGP2 for cleavage. When LGP2 and Lpro were co-expressed, cleavage products were observed in an Lpro dose-dependent manner while co-expression with a catalytically inactive Lpro mutant had no effect on LGP2 levels or pattern. We further show that Lpro localizes and immunoprecipitates with LGP2 in transfected cells supporting their interaction within the cytoplasm. Evidence of LGP2 proteolysis was also detected during FMDV infection. Moreover, the inhibitory effect of LGP2 overexpression on FMDV growth observed was reverted when Lpro was co-expressed, concomitant with lower levels of IFN-β mRNA and antiviral activity in those cells. The Lpro target site in LGP2 was identified as an RGRAR sequence in a conserved helicase motif whose replacement to EGEAE abrogated LGP2 cleavage by Lpro. Taken together, these data suggest that LGP2 cleavage by the Leader protease of aphthoviruses may represent a novel antagonistic mechanism for immune evasion.

Interaction between FMDV Lpro and transcription factor ADNP is required for optimal viral replication

The foot-and-mouth disease virus (FMDV) leader protease (L^pro) inhibits host translation and transcription affecting the expression of several factors involved in innate immunity. In this study, we have identified the host transcription factor ADNP (activity dependent neuroprotective protein) as an L^pro interacting protein by mass spectrometry. We show that L^pro can bind to ADNP in vitro and in cell culture. RNAi of ADNP negatively affected virus replication and higher levels of interferon (IFN) and IFN-stimulated gene expression were detected. Importantly, infection with FMDV wild type but not with a virus lacking Lpro (leaderless), induced recruitment of ADNP to IFN-α promoter sites early during infection. Furthermore, we found that L^pro and ADNP are in a protein complex with the ubiquitous chromatin remodeling factor Brg-1. Our results uncover a novel role of FMDV L^pro in targeting ADNP and modulation of its transcription repressive function to decrease the expression of IFN and ISGs.

Natural mitochondrial proteolysis confirms transcription systematically exchanging/deleting nucleotides, peptides coded by expanded codons

Protein sequences have higher linguistic complexities than human languages. This indicates undeciphered multilayered, overprinted information/genetic codes. Some superimposed genetic information is revealed by detections of transcripts systematically (a) exchanging nucleotides (nine symmetric, e.g. A<->C, fourteen asymmetric, e.g. A->C->G->A, swinger RNAs) translated according to tri-, tetra- and pentacodons, and (b) deleting mono-, dinucleotides after each trinucleotide (delRNAs). Here analyses of two independent proteomic datasets considering natural proteolysis confirm independently translation of these non-canonical RNAs, also along tetra- and pentacodons, increasing coverage of putative, cryptically encoded proteins. Analyses assuming endoproteinase GluC and elastase digestions (cleavages after residues D, E, and A, L, I, V, respectively) detect additional peptides colocalizing with detected non-canonical RNAs. Analyses detect fewer peptides matching GluC-, elastase- than trypsin-digestions: artificial trypsin-digestion outweighs natural proteolysis. Results suggest occurrences of complete proteins entirely matching non-canonical, superimposed encoding(s). Protein-coding after bijective transformations could explain genetic code symmetries, such as along Rumer's transformation.

Biological function of Foot-and-mouth disease virus non-structural proteins and non-coding elements

Foot-and-mouth disease virus (FMDV) represses host translation machinery, blocks protein secretion, and cleaves cellular proteins associated with signal transduction and the innate immune response to infection. Non-structural proteins (NSPs) and non-coding elements (NCEs) of FMDV play a critical role in these biological processes. The FMDV virion consists of capsid and nucleic acid. The virus genome is a positive single stranded RNA and encodes a single long open reading frame (ORF) flanked by a long structured 5ʹ-untranslated region (5ʹ-UTR) and a short 3ʹ-UTR. The ORF is translated into a polypeptide chain and processed into four structural proteins (VP1, VP2, VP3, and VP4), 10 NSPs (L^pro, 2A, 2B, 2C, 3A, 3B_1–3, 3C^pro, and 3D^pol), and some cleavage intermediates. In the past decade, an increasing number of studies have begun to focus on the molecular pathogenesis of FMDV NSPs and NCEs. This review collected recent research progress on the biological functions of these NSPs and NCEs on the replication and host cellular regulation of FMDV to understand the molecular mechanism of host–FMDV interactions and provide perspectives for antiviral strategy and development of novel vaccines.

Distance effects during polyprotein processing in the complementation between defective FMDV RNAs

Passage of foot-and-mouth disease virus (FMDV) in BHK-21 cells resulted in the segmentation of the viral genome into two defective RNAs lacking part of either the L- or the capsid-coding region. The two RNAs are infectious by complementation. Electroporation of L-defective RNA in BHK-21 cells resulted in the accumulation of the precursor P3 located away from the deleted sequence. Expression of L in trans led to the processing of P3, indicating that there is a connection between L protease activity and the secondary cleavages carried out by 3C protease within P3. These results suggest that the complementation mechanism between defective RNAs is not restricted to supplying the L and capsid proteins but that distance effects on polyprotein processing events are also implicated.

The leader proteinase of foot-and-mouth disease virus: structure-function relationships in a proteolytic virulence factor

The leader proteinase (Lpro) of the foot-and-mouth disease virus inhibits the host innate immune response by at least three different mechanisms. The most well-characterised of these is the prevention of the synthesis of cytokines such as interferons immediately after infection, brought about by specific proteolytic cleavage of the eukaryotic initiation factor 4G. This prevents the recruitment of capped cellular mRNA; however, the viral RNA can be translated under these conditions. The two other mechanisms are the induction of NF-κB cleavage and the deubiquitination of immune signalling molecules. This review focuses on the structure-function relationships in Lpro responsible for these widely divergent activities.

Multifunctional roles of leader protein of foot-and-mouth disease viruses in suppressing host antiviral responses

Foot-and-mouth disease virus (FMDV) leader protein (L^pro) is a papain-like proteinase, which plays an important role in FMDV pathogenesis. L^pro exists as two forms, Lab and Lb, due to translation being initiated from two different start codons separated by 84 nucleotides. L^pro self-cleaves from the nascent viral polyprotein precursor as the first mature viral protein. In addition to its role as a viral proteinase, L^pro also has the ability to antagonize host antiviral effects. To promote FMDV replication, L^pro can suppress host antiviral responses by three different mechanisms: (1) cleavage of eukaryotic translation initiation factor 4 γ (eIF4G) to shut off host protein synthesis; (2) inhibition of host innate immune responses through restriction of interferon-α/β production; and (3) L^pro can also act as a deubiquitinase and catalyze deubiquitination of innate immune signaling molecules. In the light of recent functional and biochemical findings regarding L^pro, this review introduces the basic properties of L^pro and the mechanisms by which it antagonizes host antiviral responses.

Influence of Foot-and-Mouth Disease Virus O/CHN/Mya98/33-P Strain Leader Protein on Viral Replication and Host Innate Immunity

Foot-and-mouth disease virus (FMDV) O/CHN/Mya98/33-P strain was isolated from the esophageal-pharyngeal fluid sample of cattle, and was shown to cause persistent infection. Its leader protein contains 200 amino acids with one amino acid deletion, which is upstream and next to the second initiation codon compared with the majority of FMDV Mya98 strains. The FMDV genome includes two initiation codons that can produce two different leader proteins, Lab (from the first AUG) and Lb (from the second AUG). For convenience, the inter-AUG region was named as La. Previously, it was found that a recombinant virus with Lab of FMDV O/CHN/Mya98/33-P strain had higher proliferation efficiency, and better ability to inhibit the host innate immune response. Three full-length infectious cDNA clones-rHN33-Lb, rHN33-La, and rHNGSLX-Lb-containing the FMDV O/CHN/Mya98/33-P strain leader proteins Lb, La, or the FMDV O/GSLX/2010 strain leader protein Lb, respectively, were constructed based on an established infectious clone r-HN rescued from FMDV O/HN/CHN/93 strain. After infecting pig kidney primary cells, rHN33-La showed higher replication efficiency than r-HN, and rHN33-Lb displayed better ability to resist host innate immunity than rHNGSLX-Lb. These results demonstrated that the inter-AUG region of FMDV strain O/CHN/Mya98/33-P leader protein must be involved in increasing viral replication efficiency. Additionally, the Lb of FMDV O/CHN/Mya98/33-P must be involve in increasing its ability to inhibit host innate immune response, and the distinctive amino acids G56 and/or R118 of FMDV leader protein may play essential roles in it.

Picornavirus IRES elements: RNA structure and host protein interactions

Internal ribosome entry site (IRES) elements were discovered in picornaviruses. These elements are cis-acting RNA sequences that adopt diverse three-dimensional structures and recruit the translation machinery using a 5' end-independent mechanism assisted by a subset of translation initiation factors and various RNA binding proteins termed IRES transacting factors (ITAFs). Many of these factors suffer important modifications during infection including cleavage by picornavirus proteases, changes in the phosphorylation level and/or redistribution of the protein from the nuclear to the cytoplasm compartment. Picornavirus IRES are amongst the most potent elements described so far. However, given their large diversity and complexity, the mechanistic basis of its mode of action is not yet fully understood. This review is focused to describe recent advances on the studies of RNA structure and RNA-protein interactions modulating picornavirus IRES activity.

Foot-and-mouth disease virus leader proteinase: structural insights into the mechanism of intermolecular cleavage

Translation of foot-and-mouth disease virus RNA initiates at one of two start codons leading to the synthesis of two forms of leader proteinase L^pro (Lab^pro and Lb^pro). These forms free themselves from the viral polyprotein by intra- and intermolecular self-processing and subsequently cleave the cellular eukaryotic initiation factor (eIF) 4G. During infection, Lb^pro removes six residues from its own C-terminus, generating sLb^pro. We present the structure of sLb^pro bound to the inhibitor E64-R-P-NH₂, illustrating how sLb^pro can cleave between Lys/Gly and Gly/Arg pairs. In intermolecular cleavage on polyprotein substrates, Lb^pro was unaffected by P1 or P1′ substitutions and processed a substrate containing nine eIF4GI cleavage site residues whereas sLb^pro failed to cleave the eIF4GI containing substrate and cleaved appreciably more slowly on mutated substrates. Introduction of 70 eIF4GI residues bearing the Lb^pro binding site restored cleavage. These data imply that Lb^pro and sLb^pro may have different functions in infected cells.

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The leader proteinase (L^pro) of foot-and-mouth disease virus is a virulence factor.

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L^pro can exist in three different forms in the infected cell.

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Structural analysis reveals how L^pro can accept basic residues at P1 and P1′.

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Isoform lacking six C-terminal residues is impaired in intermolecular cleavage.

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Properties of the isoforms may modulate enzymatic activity during viral replication.

Characterization of a chimeric foot-and-mouth disease virus bearing a bovine rhinitis B virus leader proteinase

Bovine rhinitis B virus (BRBV) shares many motifs and sequence similarities with foot-and-mouth disease virus (FMDV). This study examined if the BRBV leader proteinase (L(pro) ) could functionally replace that of FMDV. A mutant A24LBRV3DYR FMDV engineered with the BRBV L(pro) and an antigenic marker in the 3D polymerase exhibited growth properties and eIF4G cleavage similar to parental A24WT virus. The A24LBRV3DYR type I interferon activity in infected bovine cells resembled that of A24LL virus that lacks L(pro), but this effect was less pronounced for A24LBRV3DYR infected porcine cells. In vivo studies showed that the A24LBRV3DYR virus was attenuated in cattle, and exhibited low virulence in pigs exposed by direct contact. The mutant virus induced protective immunity in cattle against challenge with parental A24WT. These results provide evidence that L(pro) of different Aphthoviruses are not fully functionally interchangeable and have roles that may depend on the nature of the infected host.

Influence of the Leader protein coding region of foot-and-mouth disease virus on virus replication

The foot-and-mouth disease virus (FMDV) Leader (L) protein is produced in two forms, Lab and Lb, differing only at their amino-termini, due to the use of separate initiation codons, usually 84 nt apart. It has been shown previously, and confirmed here, that precise deletion of the Lab coding sequence is lethal for the virus, whereas loss of the Lb coding sequence results in a virus that is viable in BHK cells. In addition, it is now shown that deletion of the ‘spacer’ region between these two initiation codons can be tolerated. Growth of the virus precisely lacking just the Lb coding sequence resulted in a previously undetected accumulation of frameshift mutations within the ‘spacer’ region. These mutations block the inappropriate fusion of amino acid sequences to the amino-terminus of the capsid protein precursor. Modification, by site-directed mutagenesis, of the Lab initiation codon, in the context of the virus lacking the Lb coding region, was also tolerated by the virus within BHK cells. However, precise loss of the Lb coding sequence alone blocked FMDV replication in primary bovine thyroid cells. Thus, the requirement for the Leader protein coding sequences is highly dependent on the nature and extent of the residual Leader protein sequences and on the host cell system used. FMDVs precisely lacking Lb and with the Lab initiation codon modified may represent safer seed viruses for vaccine production.

A safe foot-and-mouth disease vaccine platform with two negative markers for differentiating infected from vaccinated animals

Vaccination of domestic animals with chemically inactivated foot-and-mouth disease virus (FMDV) is widely practiced to control FMD. Currently, FMD vaccine manufacturing requires the growth of large volumes of virulent FMDV in biocontainment-level facilities. Here, two marker FMDV vaccine candidates (A(24)LL3D(YR) and A(24)LL3B(PVKV)3D(YR)) featuring the deletion of the leader coding region (L(pro)) and one of the 3B proteins were constructed and evaluated. These vaccine candidates also contain either one or two sets of mutations to create negative antigenic markers in the 3D polymerase (3D(pol)) and 3B nonstructural proteins. Two mutations in 3D(pol), H(27)Y and N(31)R, as well as RQKP(9-12)→PVKV substitutions, in 3B(2) abolish reactivity with monoclonal antibodies targeting the respective sequences in 3D(pol) and 3B. Infectious cDNA clones encoding the marker viruses also contain unique restriction endonuclease sites flanking the capsid-coding region that allow for easy derivation of custom designed vaccine candidates. In contrast to the parental A(24)WT virus, single A(24)LL3D(YR) and double A(24)LL3B(PVKV)3D(YR) mutant viruses were markedly attenuated upon inoculation of cattle using the natural aerosol or direct tongue inoculation. Likewise, pigs inoculated with live A(24)LL3D(YR) virus in the heel bulbs showed no clinical signs of disease, no fever, and no FMD transmission to in-contact animals. Immunization of cattle with chemically inactivated A(24)LL3D(YR) and A(24)LL3B(PVKV)3D(YR) vaccines provided 100% protection from challenge with parental wild-type virus. These attenuated, antigenically marked viruses provide a safe alternative to virulent strains for FMD vaccine manufacturing. In addition, a competitive enzyme-linked immunosorbent assay targeted to the negative markers provides a suitable companion test for differentiating infected from vaccinated animals.

Exploring IRES region accessibility by interference of foot-and-mouth disease virus infectivity

Translation initiation of picornavirus RNA is driven by an internal ribosome entry site (IRES) element located upstream of the initiator codon. RNA structure organization as well as RNA-protein interaction plays a fundamental role in internal initiation. IRES activity has been mainly analyzed in the context of reporter genes, lacking regions of the viral genome potentially affecting translation efficiency. With the aim to understand the vulnerability of the IRES and translation start region to small molecules in the context of the viral genome, we designed a set of customized RNase-resistant 2'O-methyl antisense oligoribonucleotides (2'OMe AONs) based on RNA structure data. These AONs were then used to monitor their capacity to interfere viral RNA translation, and thus, to inhibit virus yield. Foot-and-mouth disease virus (FMDV) RNA translation can be initiated at two in-frame AUG codons. We show here that a 2'OMe AON complementary to AUG2 inhibited viral multiplication more efficiently than the one that targeted AUG1. Furthermore, the response of the viral RNA to AONs targeting the IRES region denoted important differences between tissue culture cells and cell-free systems, reinforcing the need to analyze viral RNA response in living cells. Importantly, we have identified four specific motifs within the IRES element that are targets for viral inhibitors both in tissue culture cells and in cell-free systems. The identified targets define accessible regions to small molecules, which disturb either the RNA structural organization or the RNA-protein interactions needed to initiate translation in FMDV RNA.

Mechanisms governing the selection of translation initiation sites on foot-and-mouth disease virus RNA

Translation initiation dependent on the foot-and-mouth disease virus (FMDV) internal ribosome entry site (IRES) occurs at two sites (Lab and Lb), 84 nucleotides (nt) apart. In vitro translation of an mRNA comprising the IRES and Lab-Lb intervening segment fused to a chloramphenicol acetyltransferase (CAT) reporter has been used to study the parameters influencing the ratio of the two products and the combined product yield as measures of relative initiation site usage and productive ribosome recruitment, respectively. With wild-type mRNA, ∼40% of initiation occurred at the Lab site, which was increased to 90% by optimization of its context, but decreased to 20% by mutations that reduced downstream secondary structure, with no change in recruitment in either case. Inserting 5 nt into the pyrimidine-rich tract located just upstream of the Lab site increased initiation at this site by 75% and ribosome recruitment by 50%. Mutating the Lab site to RCG or RUN codons decreased recruitment by 20 to 30% but stimulated Lb initiation by 20 to 40%. An antisense oligodeoxynucleotide annealing across the Lab site inhibited initiation at both sites. These and related results lead to the following conclusions. Recruitment by the wild-type IRES is limited by its short oligopyrimidine tract. At least 90% of internal ribosome entry occurs at the Lab AUG, but initiation at this site is restricted by its poor context, despite a counteracting effect of downstream secondary structure. Initiation at the Lb site is by ribosomes that access it by linear scanning from the original entry site, and not by an independent entry process.

[Current situation and future preventive measures of foot-and-mouth disease in Japan]

Foot-and-mouth disease caused by Foot-and-mouth disease virus (FMDV) is a severe and acute vesicular disease of cloven-hoofed animals including cattle, pigs, sheep and goats. As FMDV is highly contagious and causes productivity losses among infected animals, outbreaks of the disease are a primary animal health concern worldwide. In April, 2010, the disease reoccurred in Miyazaki prefecture in 10 years. Compared to the outbreak in 2000 in which no infection among pigs was observed, a total of 292 infected farms have been involved in this outbreak, and infected animals (37,412 cattle, 42 water buffalos, 174,132 pigs, 14 goats, and 8 sheep) were culled and buried. Vaccination was decided to reduce the speed of virus spreading. Finally a total of 76,756 heads of vaccinated animals were also slaughtered. The outbreak has continued for 2.5 months, and the ban on animal movements have been eased 3 months after the first occurrence. As several factors for disease spreading have been rumored, I would like to note this point and discuss future preventive measures.

Introduction of tag epitopes in the inter-AUG region of foot and mouth disease virus: effect on the L protein

Foot-and-mouth disease virus (FMDV) initiates translation from two in-frame AUG codons producing two forms of the leader (L) proteinase, Lab (starting at the first AUG) and Lb (starting at second AUG). In a previous study, we have demonstrated that a cDNA-derived mutant FMDV (A24-L1123) containing a 57-nucleotide transposon (tn) insertion between the two AUG initiation codons (inter-AUG region) was completely attenuated in cattle, suggesting that this region is involved in viral pathogenesis. To investigate the potential role of the Lab protein in attenuation, we have introduced two epitope tags (Flag: DYKDDDK and HA: YPYDVPDYA) or a small tetracysteine motif (tc: CCGPCC) into the pA24-L1123 infectious DNA clone. Mutant viruses with a small plaque phenotype similar to the parental A24-L1123 were recovered after transfection of constructs encoding the Flag tag and the tc motif. However, expression of the Flag- or tc-tagged Lab protein was abolished or greatly diminished in these viruses. Interestingly, the A24-L1123/Flag virus acquired an extra base in the inter-AUG region that resulted in new AUG codons in-frame with the second AUG, and produced a larger Lb protein. This N terminal extension of the Lb protein in mutant A24-L1123/Flag did not affect virus viability or L functions in cell culture.

A conserved domain in the leader proteinase of foot-and-mouth disease virus is required for proper subcellular localization and function

The leader proteinase (L(pro)) of foot-and-mouth disease virus (FMDV) is involved in antagonizing the innate immune response by blocking the expression of interferon (IFN) and by reducing the immediate-early induction of IFN-beta mRNA and IFN-stimulated genes. In addition to its role in shutting off cap-dependent host mRNA translation, L(pro) is associated with the degradation of the p65/RelA subunit of nuclear factor kappaB (NF-kappaB). Bioinformatics analysis suggests that L(pro) contains a SAP (for SAF-A/B, Acinus, and PIAS) domain, a protein structure associated in some cases with the nuclear retention of molecules involved in transcriptional control. We have introduced a single or a double mutation in conserved amino acid residues contained within this domain of L(pro). Although three stable mutant viruses were obtained, only the double mutant displayed an attenuated phenotype in cell culture. Indirect immunofluorescence analysis showed that L(pro) subcellular distribution is altered in cells infected with the double mutant virus. Interestingly, nuclear p65/RelA staining disappeared from wild-type (WT) FMDV-infected cells but not from double mutant virus-infected cells. Consistent with these results, NF-kappaB-dependent transcription was not inhibited in cells infected with double mutant virus in contrast to cells infected with WT virus. However, degradation of the translation initiation factor eIF-4G was very similar for both the WT and the double mutant viruses. Since L(pro) catalytic activity was demonstrated to be a requirement for p65/RelA degradation, our results indicate that mutation of the SAP domain reveals a novel separation-of-function activity for FMDV L(pro).

Relevance of RNA structure for the activity of picornavirus IRES elements

The RNA of all members of the Picornaviridae family initiates translation internally, via an internal ribosome entry site (IRES) element present in their 5' untranslated region. IRES elements consist of cis-acting RNA structures that often operate in association with specific RNA-binding proteins to recruit the translational machinery. This specialized mechanism of translation initiation is shared with other viral RNAs, and represents an alternative to the general cap-dependent initiation mechanism. In this review we discuss recent evidences concerning the relationship between RNA structure and IRES function in the genome of picornaviruses. The biological implications of conserved RNA structural elements for the mechanism of internal translation initiation driven by representative members of enterovirus and rhinovirus (type I IRES) and cardiovirus and aphthovirus (type II IRES) will be discussed.

Residue L143 of the foot-and-mouth disease virus leader proteinase is a determinant of cleavage specificity

The foot-and-mouth disease virus (FMDV) leader proteinase (L(pro)) self-processes inefficiently at the L(pro)/VP4 cleavage site LysLeuLys*GlyAlaGly (* indicates cleaved peptide bond) when the leucine at position P2 is replaced by phenylalanine. Molecular modeling and energy minimization identified the L(pro) residue L143 as being responsible for this discrimination. The variant L(pro) L143A self-processed efficiently at the L(pro)/VP4 cleavage site containing P2 phenylalanine, whereas the L143M variant did not. L(pro) L143A self-processing at the eIF4GII sequence AspPheGly*ArgGlnThr was improved but showed more-extensive aberrant processing. Residue 143 in L(pro) is occupied only by leucine and methionine in all sequenced FMDV serotypes, implying that these bulky side chains are one determinant of the restricted specificity of L(pro).

Degradation of nuclear factor kappa B during foot-and-mouth disease virus infection

We have previously shown that the leader proteinase (L(pro)) of foot-and-mouth disease virus (FMDV) interferes with the innate immune response by blocking the translation of interferon (IFN) protein and by reducing the immediate-early induction of beta IFN mRNA and IFN-stimulated genes. Here, we report that L(pro) regulates the activity of nuclear factor kappaB (NF-kappaB). Analysis of NF-kappaB-dependent reporter gene expression in BHK-21 cells demonstrated that infection with wild-type (WT) virus has an inhibitory effect compared to infection with a genetically engineered mutant lacking the leader coding region. The expression of endogenous NF-kappaB-dependent genes tumor necrosis factor alpha and RANTES is also reduced in WT virus-infected primary porcine cells. This inhibitory effect is neither the result of a decrease in the level of the mRNA of p65/RelA, a subunit of NF-kappaB, nor a block on the nuclear translocation of p65/RelA, but instead appears to be a consequence of the degradation of accumulated p65/RelA. Viral L(pro) is localized to the nucleus of infected cells, and there is a correlation between the translocation of L(pro) and the decrease in the amount of nuclear p65/RelA. By using a recombinant cardiovirus expressing L(pro), we demonstrate that the disappearance of p65/RelA takes place in the absence of any other FMDV product. The observation that L(pro) disrupts the integrity of NF-kappaB suggests a global mechanism by which FMDV antagonizes the cellular innate immune and inflammatory responses to viral infection.

Investigating the substrate specificity and oligomerisation of the leader protease of foot and mouth disease virus using NMR

The leader protease (Lbpro) of foot-and-mouth disease virus frees itself during translation from the viral polyprotein by cleavage between its own C terminus and the N terminus of the subsequent protein, VP4. Lbpro also specifically cleaves the host proteins eukaryotic initiation factor (eIF) 4GI and 4GII, thus disabling host cell protein synthesis. We used NMR to study full-length Lbpro as well as a shortened species lacking six C-terminal amino acid residues (sLbpro) to examine the mechanism of self-processing, the quaternary structure and the substrate specificity. Both Lbpro forms have the same structure in solution as in the crystal. In the solution structure of sLbpro, the 12 residue C-terminal extension was flexible and disordered. In contrast, the 18 residue C-terminal extension of full-length Lbpro was bound by the substrate-binding site of a neighbouring molecule, resulting in the formation of a stable dimer in solution. The Lbpro dimer could not be dissociated by increasing the ionic strength or by dilution. Furthermore, titration with model peptides mimicking the substrates destabilised the dimer interface without dissociating the dimer. The peptides were, however, bound by sLbpro in the canonical substrate binding site. Peptide binding gave rise to chemical shifts of residues around the sLbpro substrate binding site. Shifts of Asn146 and Glu147 indicated that these residues might form the enzyme's S1' site and interact with the P1' arginine residue of the eIF4GI cleavage site. Furthermore, differences in substrate specificity between sLbpro and Lbpro observed with an in vitro translated protein indicate some involvement of the C terminus in substrate recognition.

Inhibition of foot-and-mouth disease virus infections in cell cultures with antisense morpholino oligomers

Foot-and-mouth disease (FMD) is a highly contagious viral disease of cloven-hoofed ungulates that can lead to severe losses in the livestock production and export industries. Although vaccines have been extensively used to control FMD, there is no antiviral therapy available to treat ongoing infections with FMD virus (FMDV). Six peptide-conjugated morpholino oligomers (PPMOs) with sequences complementary to various 21-nucleotide segments of the 5' and 3' untranslated regions (UTRs) of the FMDV genome (strain A(24) Cruzeiro/Brazil/1955 [A(24)Cru]) were evaluated in cell cultures. Three of the PPMOs, targeting domain 5 of the internal ribosome entry site (5D PPMO), and the two translation start codon regions (AUG1 and AUG2 PPMOs), showed high levels of anti-FMDV activity. A dose-dependent and sequence-specific reduction in viral titers of greater than 5 log(10), with a concomitant reduction of viral protein and RNA expression, was achieved at low micromolar concentrations. Under identical conditions, three other PPMOs targeting the 5'-terminal region of the genome, the cis-acting replication element in the 5' UTR, and the 3' "ab" stem-loop showed less dramatic titer reductions of 1.5 log(10) to 2 log(10). Treatment with 5D PPMO reduced the titers of FMDV strains representing five different serotypes by 2 log(10) to 4 log(10) compared to those of the controls. A(24)Cru-infected BHK-21 cells treated repeatedly with 5D or AUG2 PPMO generated resistant viruses for which phenotypic and genotypic properties were defined. Notably, three passages with low concentrations of the AUG1 PPMO extinguished all traces of detectable virus. The results indicate that PPMOs have potential for treating FMDV infections and that they also represent useful tools for studying picornaviral translation and evolution.

Translation and replication of FMDV RNA

Foot-and-mouth disease virus (FMDV) RNA is infectious. After delivery of the RNA (about 8.3 kb) into the cytoplasm of a cell, the RNA must initially be translated to produce the viral proteins required for RNA replication and for the packaging of the RNA into new virions. Subsequently there has to be a switch in the function of the RNA; translation has to be stopped to permit RNA replication. The signals required for the control of the different roles of viral RNA must be included within the viral RNA sequence. Many cellular proteins interact with the viral RNA and probably also with the virus-encoded proteins. The functions of different RNA elements within the viral RNA and the various virus-encoded proteins in determining the efficiency of virus replication are discussed. Unique aspects of FMDV RNA translation and replication are emphasised.

The binding of foot-and-mouth disease virus leader proteinase to eIF4GI involves conserved ionic interactions

The leader proteinase (L(pro)) of foot-and-mouth disease virus (FMDV) initially cleaves itself from the polyprotein. Subsequently, L(pro) cleaves the host proteins eukaryotic initiation factor (eIF) 4GI and 4GII. This prevents protein synthesis from capped cellular mRNAs; the viral RNA is still translated, initiating from an internal ribosome entry site. L(pro) cleaves eIF4GI between residues G674 and R675. We showed previously, however, that L(pro) binds to residues 640-669 of eIF4GI. Binding was substantially improved when the eIF4GI fragment contained the eIF4E binding site and eIF4E was present in the binding assay. L(pro) interacts with eIF4GI via residue C133 and residues 183-195 of the C-terminal extension. This binding domain lies about 25 A from the active site. Here, we examined the binding of L(pro) to eIF4GI fragments generated by in vitro translation to narrow the binding site down to residues 645-657 of human eIF4GI. Comparison of these amino acids with those in human eIF4GII as well as with sequences of eIF4GI from other organisms allowed us to identify two conserved basic residues (K646 and R650). Mutation of these residues was severely detrimental to L(pro) binding. Similarly, comparison of the sequence between residues 183 and 195 of L(pro) with those of other FMDV serotypes and equine rhinitis A virus showed that acidic residues D184 and E186 were highly conserved. Substitution of these residues in L(pro) significantly reduced eIF4GI binding and cleavage without affecting self-processing. Thus, FMDV L(pro) has evolved a domain that specifically recognizes a host cell protein.

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.

Effects of potassium and chloride on ribosome association with the RNA of foot-and-mouth disease virus

Foot-and-mouth disease virus (FMDV) and other picornaviruses initiate translation of their polyprotein cap-independently at an internal site of the positive-strand viral RNA. This process is mediated by the internal ribosome entry site (IRES), a highly structured cis-acting RNA element that binds translation initiation factors and ribosomal subunits. During their life cycle, picornaviruses induce proliferation of membrane structures involved in viral replication and an increase in membrane permeability probably facilitating virus progeny release. Here, I analyze the efficiency of association of the ribosomal subunits with the FMDV IRES RNA at elevated salt concentrations. Potassium stimulates FMDV translation, whereas sodium chloride concentrations up to 150 mM neither stimulate nor interfere with FMDV translation. Even high potassium concentrations allow binding of the viral RNA to ribosomes. Chloride stimulates binding of ribosomes to the viral RNA at the stage of 48S initiation complex formation and FMDV translation at concentrations up to 150 mM. Only at elevated concentrations, binding of ribosomal subunits and translation are inhibited by chloride. However, FMDV start site selection is not influenced by potassium salts. These results indicate that the association of the viral RNA with ribosomal subunits is well adapted to high salt conditions that are induced during picornavirus infection.

Stable expression of antisense RNAs targeted to the 5' non-coding region confers heterotypic inhibition to foot-and-mouth disease virus infection

The antiviral potential of transcripts targeted to the non-coding regions (NCRs) of foot-and-mouth disease virus (FMDV) RNA have been studied during transient and constitutive expression in susceptible BHK-21 cells. Transient expression of antisense transcripts corresponding to the 5' and 3'NCRs, alone or in combination, confers specific inhibition of homologous (serotype C) virus infection in BHK-21 cells. Constitutive expression of antisense 5'NCR transcripts (5'AS) exerted higher levels of inhibition to homologous and heterologous (serotypes O, A, Asia, SAT 1, SAT 2 and SAT 3) FMDV infection, as estimated by a 10-fold reduction in virus titre in the supernatants from infected clones and by a plaque reduction assay. These inhibitions were also observed, albeit to a lesser extent, in clones stably expressing antisense 3'NCR transcripts. The antiviral response was specific for FMDV, as the picornavirus encephalomyocarditis virus was not inhibited in any of the transformed cell lines. In all cases, a correlation was found between the level of transcript expression and the extent of virus inhibition. The potential to efficiently inhibit FMDV, including isolates representing the seven serotypes, by expressing interfering 5'AS transcripts opens the possibility of developing transgenic animals with a reduced susceptibility to FMDV.

Molecular basis of pathogenesis of FMDV

Current understanding of the molecular basis of pathogenesis of foot-and-mouth disease (FMD) has been achieved through over 100 years of study into the biology of the etiologic agent, FMDV. Over the last 40 years, classical biochemical and physical analyses of FMDV grown in cell culture have helped to reveal the structure and function of the viral proteins, while knowledge gained by the study of the virus' genetic diversity has helped define structures that are essential for replication and production of disease. More recently, the availability of genetic engineering methodology has permitted the direct testing of hypotheses formulated concerning the role of individual RNA structures, coding regions and polypeptides in viral replication and disease. All of these approaches have been aided by the simultaneous study of other picornavirus pathogens of animals and man, most notably poliovirus. Although many questions of how FMDV causes its devastating disease remain, the following review provides a summary of the current state of knowledge into the molecular basis of the virus' interaction with its host that produces one of the most contagious and frightening diseases of animals or man.

Eukaryotic initiation factor 4GI is a poor substrate for HIV-1 proteinase

Eukaryotic initiation factor (eIF) 4GI is efficiently cleaved during picornaviral replication. eIF4GI processing has also recently been observed during HIV-1 replication. We have compared the efficiency of eIF4GI proteolysis in rabbit reticulocyte lysates during translation of mRNAs encoding the foot-and-mouth disease virus leader proteinase (L(pro)) or the HIV-1 proteinase (HIV-1(pro)). L(pro) cleaved 50% eIF4GI within 12 min whereas HIV-1(pro) required 4 h; the concentrations were 2 pg/microl (0.1 nM) for L(pro) and 60 pg/microl (2.66 nM) for HIV-1(pro). HIV-1(pro) processing of eIF4GI is therefore not quantitatively analogous to that of L(pro), suggesting that the primary function of eIF4GI cleavage in HIV-1 replication may not be protein synthesis inhibition.

Construction of regulatable picornavirus IRESes as a test of current models of the mechanism of internal translation initiation

Picornavirus internal ribosome entry sites (IRESs) are approximately 450 nt. RNA elements that direct internal initiation of translation, such that when placed between the two cistrons of a dicistronic construct, they drive independent translation of the downstream cistron. Consequently they have been widely used for coordinated expression of two or more proteins. All picornavirus IRESs have an AUG triplet at the very 3' end, which is thought to be the actual site of internal ribosome entry. However with some IRESs, such as foot-and-mouth disease virus, and especially poliovirus, the majority of ribosomes do not initiate translation at this putative entry site AUG, but at the next AUG further downstream, which is thought to be accessed by a process of linear ribosome scanning from the entry site. If this is so, then it should be possible to regulate IRES-dependent translation by inserting an iron responsive element (IRE) between the putative entry site AUG and the main functional initiation site. This should make IRES-dependent translation sensitive to the concentration of iron regulatory protein (IRP), the protein that specifically binds to the IRE. This has been attempted with both the foot-and-mouth disease virus and poliovirus IRESs, and was successful in so far as an inhibition specifically of IRES-dependent translation was observed that was strictly dependent on both the presence of IRP and of a functional IRE motif inserted in the sense orientation. However, the range over which expression could be varied was rather limited (three- to fourfold maximum), because some IRES-dependent translation remained completely refractory to inhibition by even very high IRP concentrations. In contrast, with a cap-proximal IRE in the 5' untranslated region of an mRNA translated by the scanning mechanism, addition of sufficient IRP results in complete inhibition. These results support the model of IRES-promoted ribosome entry at an upstream site followed by strictly linear scanning to the main functional initiation site for the majority of internal initiation events, but imply that some ribosomes must access the functional initiation site by another route, possibly a nonlinear shunting-like mechanism.

Extremely efficient cleavage of eIF4G by picornaviral proteinases L and 2A in vitro

Certain picornaviruses encode proteinases which cleave the translation initiation factor eIF4G, a member of the eIF4F complex which recruits mRNA to the 40S ribosomal subunit during initiation of protein synthesis in eukaryotes. We have compared the efficiency of eIF4G cleavage in rabbit reticulocyte lysates during translation of mRNAs encoding the foot-and-mouth disease virus leader proteinase (Lpro) or the human rhinovirus 2Apro. Under standard translation conditions, Lpro cleaved 50% of eIF4G within 4 min after initiation of protein synthesis, whereas 2Apro required 15 min. At these times, the molar ratios of proteinase to eIF4G were 1:130 for Lpro and 1:12 for 2Apro, indicating a much more efficient in vitro cleavage than previously observed. The molar ratios are similar to those observed during viral infection in vivo.

Translation initiation factor eIF4B interacts with a picornavirus internal ribosome entry site in both 48S and 80S initiation complexes independently of initiator AUG location

Most eukaryotic initiation factors (eIFs) are required for internal translation initiation at the internal ribosome entry site (IRES) of picornaviruses. eIF4B is incorporated into ribosomal 48S initiation complexes with the IRES RNA of foot-and-mouth disease virus (FMDV). In contrast to the weak interaction of eIF4B with capped cellular mRNAs and its release upon entry of the ribosomal 60S subunit, eIF4B remains tightly associated with the FMDV IRES during formation of complete 80S ribosomes. Binding of eIF4B to the IRES is energy dependent, and binding of the small ribosomal subunit to the IRES requires the previous energy-dependent association of initiation factors with the IRES. The interaction of eIF4B with the IRES in 48S and 80S complexes is independent of the location of the initiator AUG and thus independent of the mechanism by which the small ribosomal subunit is placed at the actual start codon, either by direct internal ribosomal entry or by scanning. eIF4B does not greatly rearrange its binding to the IRES upon entry of the ribosomal subunits, and the interaction of eIF4B with the IRES is independent of the polypyrimidine tract-binding protein, which enhances FMDV translation.

The properties of chimeric picornavirus IRESes show that discrimination between internal translation initiation sites is influenced by the identity of the IRES and not just the context of the AUG codon

The internal ribosome entry segment (IRES) of picornaviruses consists of approximately 450 nt of 5'-untranslated region, terminating at the 3' end with an approximately 25 nt element consisting of an absolutely conserved UUUC motif followed by a more variable pyrimidine-rich tract and G-poor spacer, and finally an AUG triplet, which is considered to be the actual ribosome entry site. Events following entry at this site differ among picornaviruses: in encephalomyocarditis virus (EMCV) virtually all ribosomes initiate translation at this site (AUG-11); in foot-and-mouth-disease virus (FMDV), one-third of the ribosomes initiate at this AUG (the Lab site), and the rest at the next AUG 84 nt downstream (Lb site); and in poliovirus (PV), the AUG at the 3' end of the IRES (at nt 586 in PV type 1) is considered to be a silent entry site, with all ribosomes initiating translation at the next AUG downstream (nt 743). To investigate what determines this different behavior, chimeras were constructed with a crossover at the conserved UUUC motif: the body of the IRES, the sequences upstream of this UUUC motif, was derived from one species, and the downstream sequences from another. When the body of the FMDV or PV IRESes was replaced by that of EMCV, there was a marked increase in the absolute and relative frequency of initiation at the upstream AUG, the Lab site of FMDV and 586AUG of PV, respectively. In contrast, when the body of the EMCV IRES was replaced by that of PV, initiation occurred with no preference at three AUGs: the normal site (AUG-11), AUG-10 situated 8 nt upstream, and AUG-12, which is 12 nt downstream. Thus although the context of the AUG at the 3' end of the IRES may influence initiation frequency at this site, as was shown by improving the context of 586AUG of PV, the behavior of the ribosome is also highly dependent on the nature of the upstream IRES. Delivery of the ribosome to this AUG in an initiation-competent manner is particularly efficient and accurate with the EMCV IRES.

Involvement of the aphthovirus RNA region located between the two functional AUGs in start codon selection

Initiation of translation in picornavirus RNAs occurs internally, mediated by an element termed internal ribosome entry site (IRES). In the aphthovirus RNA, the IRES element directs translation initiation at two in-frame AUGs separated by 84 nucleotides. We have found that bicistronic constructs that contained the IRES element followed by the fragment including the aphthovirus start codons in front of the second gene mimicked the translation initiation pattern of viral RNA observed in infected cells. In those constructs, the frequency of initiation at the first AUG was increased by a sequence context that resembled the favorable consensus for cap-dependent translation, although initiation at the second site was always preferred. In addition, we have found that initiation at the second start codon was not diminished under conditions in which the first initiation codon was blocked by antisense oligonucleotide interference. Interestingly, mutations that positioned the second AUG out-of-frame with the first AUG did not interfere with the frequency of initiation at the second one. On the contrary, IRES-dependent translation initiation in bicistronic constructs lacking the sequences present between functional AUGs in the viral RNA was sensitive to the presence of out-of-frame initiator codons and hairpins in the spacer region. This remarkable difference in start codon recognition was due to the nucleotide composition of the RNA that separated the IRES from the initiator codon. Thus our results indicate that the region located in the aphthovirus RNA between functional AUGs is involved in start codon recognition, strongly favoring selection of the second start AUG as the main initiator codon.

Proteolytic Enzymes of the Viruses of the Family Picornaviridae

This chapter deals with proteolytic enzymes of the viruses of the family picornaviridae. The picornaviral 3C proteinases constitute an ideal target for the rational design of antiviral drugs. The chapter discusses the chymotrypsin-like cysteine proteinases, which constitute a unique class of enzymes with a distinct substrate specificity, and are so far only found in +RNA viruses. Within these viruses the 3C proteinases perform a central and indispensable role during the viral life cycle and 3C proteinase inhibitors have the potential to limit the spread of viral infections. The chapter concludes that there is a wealth of experimental information available for the best-studied examples of the viruses of the Picornaviridae. This information provides an opportunity to design inhibitors against the viral 3C proteinase. Effective inhibitors of the picornaviral 3C proteinase have the potential to become effective antiviral drugs against human diseases such as the common cold, HAV, enteroviral infections, and diseases caused by related + RNA viruses.

Parameters influencing translational efficiency in aphthovirus IRES-based bicistronic expression vectors

Initiation of translation in picornavirus RNAs occurs internally, mediated by an internal ribosome entry site (IRES) element. This property has been exploited to coexpress proteins from a single bicistronic transcription unit in eukaryotic cells. The region that separates the IRES element from the authentic initiator codon of the second gene plays an important role in the translation efficiency of this cistron. In the present report, we have analyzed the effect of sequence modifications in this region on the translation efficiency directed by the foot-and-mouth disease (FMDV) IRES in bicistronic expression vectors. Insertion of various sequences, which contained additional start codons and/or the capacity to form hairpins immediately downstream of the 3' border of the IRES, strongly reduced the translation efficiency of the second gene in bicistronic RNAs. Interestingly, an increase of distance per se did not have a deleterious effect on translation efficiency. The bicistronic vector studied here tolerated 95 nucleotides between the 3' border of the IRES and the authentic start codon, provided that out-of-frame AUG codons or hairpins were not present in this RNA segment. These results indicate that FMDV-derived bicistronic constructs are extremely well suited for use in eukaryotic expression vectors.