Tacaribe virus L gene encodes a protein of 2210 amino acid residues

Peptide based vaccine designing against endemic causing mammarenavirus using reverse vaccinology approach

The rodent-borne Arenavirus in humans has led to the emergence of regional endemic situations and has deeply emerged into pandemic-causing viruses. Arenavirus have a bisegmented ambisense RNA that produces four proteins: glycoprotein, nucleocapsid, RdRp and Z protein. The peptide-based vaccine targets the glycoprotein of the virus encountered by the immune system. Screening of B-Cell and T-Cell epitopes was done based on their immunological properties like antigenicity, allergenicity, toxicity and anti-inflammatory properties were performed. Selected epitopes were then clustered and epitopes were stitched using linker sequences. The immunological and physico-chemical properties of the vaccine construct was checked and modelled structure was validated by a 2-step MD simulation. The thermostability of the vaccine was checked followed by the immune simulation to test the immunogenicity of the vaccine upon introduction into the body over the course of the next 100 days and codon optimization was performed. Finally a 443 amino acid long peptide vaccine was designed which could provide protection against several members of the mammarenavirus family in a variety of population worldwide as denoted by the epitope conservancy and population coverage analysis. This study of designing a peptide vaccine targeting the glycoprotein of mammarenavirues may help develop novel therapeutics in near future.

Development of a Reverse Genetic System to Generate Recombinant Chimeric Tacaribe Virus that Expresses Junín Virus Glycoproteins

Mammarenaviruses are enveloped and segmented negative-stranded RNA viruses that comprise several pathogenic members associated with severe human hemorrhagic fevers. Tacaribe virus (TCRV) is the prototype for the New World group of mammarenaviruses and is not only naturally attenuated but also phylogenetically and antigenically related to all South American pathogenic mammarenaviruses, particularly the Junín virus (JUNV), which is the etiological agent of Argentinian hemorrhagic fever (AHF). Moreover, since TCRV protects guinea pigs and non-human primates from lethal challenges with pathogenic strains of JUNV, it has already been considered as a potential live-attenuated virus vaccine candidate against AHF. Here, we report the development of a reverse genetic system that relies on T7 polymerase-driven intracellular expression of the complementary copy (antigenome) of both viral S and L RNA segments. Using this approach, we successfully recovered recombinant TCRV (rTCRV) that displayed growth properties resembling those of authentic TCRV. We also generated a chimeric recombinant TCRV expressing the JUNV glycoproteins, which propagated similarly to wild-type rTCRV. Moreover, a controlled modification within the S RNA 5′ non-coding terminal sequence diminished rTCRV propagation in a cell-type dependent manner, giving rise to new perspectives where the incorporation of additional attenuation markers could contribute to develop safe rTCRV-based vaccines against pathogenic mammarenaviruses.

Complete genome sequence of Tacaribe virus

Tacaribe virus (TCRV) is the prototype of the New World arenaviruses (also known as TCRV serocomplex viruses). While TCRV is not itself a human pathogen, many closely related members of this group cause hemorrhagic fever, and thus TCRV has long served as an important BSL2 system for research into diverse areas of arenavirus biology. Due to its widespread use, a coding-complete sequence for both the S and L segments of the bipartite genome has been publically available for almost 30 years. However, more recently, this sequence has been found to contain significant discrepancies compared to other samples of the same original strain (i.e., TRVL-11573). Further, it is incomplete with respect to the genome ends, which contain critical regulatory elements for RNA synthesis. In order to rectify these issues we now present the first complete genome sequence for this important prototype arenavirus. In addition to completing the S segment 5’ end, we identified an apparent error in the L segment 3’ end as well as substantial discrepancies in the S segment intergenic region likely to affect folding. Comparison of this sequence with existing partial sequences confirmed a 12-amino-acid deletion in GP, including putative glycosylation sites, and a 4-amino-acid exchange flanking the exonuclease domain of NP. Accounting for these corrections, the TRVL-11573 strain appears to be nearly identical to that isolated in Florida in 2012. The availability of this information provides a solid basis for future molecular and genetic work on this important prototype arenavirus.

Hemorrhagic Fever-Causing Arenaviruses: Lethal Pathogens and Potent Immune Suppressors

Hemorrhagic fevers (HF) resulting from pathogenic arenaviral infections have traditionally been neglected as tropical diseases primarily affecting African and South American regions. There are currently no FDA-approved vaccines for arenaviruses, and treatments have been limited to supportive therapy and use of non-specific nucleoside analogs, such as Ribavirin. Outbreaks of arenaviral infections have been limited to certain geographic areas that are endemic but known cases of exportation of arenaviruses from endemic regions and socioeconomic challenges for local control of rodent reservoirs raise serious concerns about the potential for larger outbreaks in the future. This review synthesizes current knowledge about arenaviral evolution, ecology, transmission patterns, life cycle, modulation of host immunity, disease pathogenesis, as well as discusses recent development of preventative and therapeutic pursuits against this group of deadly viral pathogens.

Mapping of the tacaribe arenavirus Z-protein binding sites on the L protein identified both amino acids within the putative polymerase domain and a region at the N terminus of L that are critically involved in binding

Tacaribe virus (TacV) is the prototype of the New World group of arenaviruses. The TacV genome encodes four proteins: the nucleoprotein (N), the glycoprotein precursor, the polymerase (L), and a RING finger protein (Z). Using a reverse genetics system, we demonstrated that TacV N and L are sufficient to drive transcription and replication mediated by TacV-like RNAs and that Z is a powerful inhibitor of these processes (Lopez et al., J. Virol. 65:12241-12251, 2001). More recently, we provided the first evidence of an interaction between Z and L and showed that Z's inhibitory activity was dependent on its ability to bind to L (Jácamo et al., J. Virol. 77:10383-10393, 2003). In the present study, we mapped the TacV Z-binding sites on the 2,210-amino-acid L polymerase. To that end, we performed deletion analysis and point mutations of L and studied the Z-L interaction by coimmunoprecipitation with specific sera. We found that the C-terminal region of L was not essential for the interaction and identified two noncontiguous regions that were critical for binding: one at the N-terminus of L between residues 156 and 292 and a second one in the polymerase domain (domain III). The importance of domain III in binding was revealed by substitutions in D1188 and H1189 within motif A and in each residue of the conserved SDD sequence (residues 1328, 1329, and 1330) within motif C. Our results showed that of the substituted residues, only H1189 and D1329 appeared to be critically involved in binding Z.

A single stem-loop structure in Tacaribe arenavirus intergenic region is essential for transcription termination but is not required for a correct initiation of transcription and replication

The genome of Tacaribe virus (TV), prototype of the New World arenaviruses, comprises two RNA segments each encoding two proteins in an ambisense orientation separated by an intergenic region (IGR). We used a TV minireplicon system to investigate the nature of the IGR structures required for transcription termination. We show that efficient generation of subgenomic (SG) RNAs is related to a single hairpin structure comprising a stem with variable numbers of uninterrupted base pairs and stabilized by high DeltaG values. The low ability of highly stable hairpin structures comprising bulged stems to support SG RNA synthesis suggested the importance of hairpin configuration for transcription termination. Neither the sequences downstream nor those upstream from the hairpin played a role in SG RNA accumulation. We also show that independently of the IGR structure the unencapsidated mRNAs contained short stretches of nontemplated bases at their 5' ends which are capped, whereas the 5' ends of the nucleocapsid-associated antiminigenomes contained an uncapped extra residue. The results support the conclusions that: (i) transcription termination in TV is related to a structural element that is independent of sequence and (ii) the transcription termination signal is not required for a correct initiation of transcription and replication.

Phylogeny of the Venezuelan arenaviruses

Guanarito virus (the etiologic agent of Venezuelan hemorrhagic fever, VHF) and Pirital virus coexist in the region of Venezuela in which Venezuelan hemorrhagic fever is endemic. The purpose of this study was to extend our knowledge of the evolutionary relationship between these two arenaviruses. We determined that the large genomic segments of Guanarito virus and Pirital virus are similar in size and identical in structural organization to the large genomic segments of other South American arenaviruses. For example, the Z proteins and RNA-dependent RNA polymerases of Guanarito virus and Pirital virus are encoded in nonoverlapping open reading frames of opposite polarities. Phylogenetic analyses of Z protein gene nucleotide sequences and RNA-dependent RNA polymerase gene nucleotide sequences grouped Pirital virus with Pichindé virus (a South American arenavirus which, like Pirital virus, does not appear to be pathogenic for humans) and placed the Pirital-Pichindé lineage in a sister relationship to a lineage represented by Guanarito virus and the three other arenaviruses known to cause hemorrhagic fever in South America. These results are concordant with the results of studies on the phylogeny of the arenavirus small genomic segment. Thus, the exchange of genomic elements between Guanarito virus and Pirital virus via recombination or reassortment likely did not contribute to the emergence of Venezuelan hemorrhagic fever.

Sequence analysis of L RNA of Lassa virus

The L RNA of three Lassa virus strains originating from Nigeria, Ghana/Ivory Coast, and Sierra Leone was sequenced and the data subjected to structure predictions and phylogenetic analyses. The L gene products had 2218-2221 residues, diverged by 18% at the amino acid level, and contained several conserved regions. Only one region of 504 residues (positions 1043-1546) could be assigned a function, namely that of an RNA polymerase. Secondary structure predictions suggest that this domain is very similar to RNA-dependent RNA polymerases of known structure encoded by plus-strand RNA viruses, permitting a model to be built. Outside the polymerase region, there is little structural data, except for regions of strong alpha-helical content and probably a coiled-coil domain at the N terminus. No evidence for reassortment or recombination during Lassa virus evolution was found. The secondary structure-assisted alignment of the RNA polymerase region permitted a reliable reconstruction of the phylogeny of all negative-strand RNA viruses, indicating that Arenaviridae are most closely related to Nairoviruses. In conclusion, the data provide a basis for structural and functional characterization of the Lassa virus L protein and reveal new insights into the phylogeny of negative-strand RNA viruses.

Tacaribe virus Z protein interacts with the L polymerase protein to inhibit viral RNA synthesis

Tacaribe virus (TV) is the prototype of the New World group of arenaviruses. The TV genome encodes four proteins, the nucleoprotein (N), the glycoprotein precursor, the polymerase (L), and a small RING finger protein (Z). Using a reverse genetic system, we recently demonstrated that TV N and L are sufficient to drive transcription and full-cycle RNA replication mediated by TV-like RNAs and that Z is a powerful inhibitor of these processes (N. López, R. Jácamo, and M. T. Franze-Fernández, J. Virol. 65:12241-12251, 2001). In the present study we investigated whether Z might interact with either of the proteins, N and L, required for RNA synthesis. To that end, we used coimmunoprecipitation with monospecific antibodies against the viral proteins and coimmunoprecipitation with serum against glutathione S-transferase (GST) and binding to glutathione-Sepharose beads when Z was expressed as a fusion protein with GST. We demonstrated that Z interacted with L but not with N and that Z inhibitory activity was dependent on its ability to bind to L. We also evaluated the contribution of different Z regions to its binding ability and functional activity. We found that integrity of the RING structure is essential for Z binding to L and for Z inhibitory activity. Mutants with deletions at the N and C termini of Z showed that amino acids within the C-terminal region and immediately adjacent to the RING domain N terminus contribute to efficient Z-L interaction and are required for inhibitory activity. The data presented here provide the first evidence of an interaction between Z and L, suggesting that Z interferes with viral RNA synthesis by direct interaction with L. In addition, coimmunoprecipitation studies revealed a previously unreported interaction between N and L.

Transcription and RNA replication of tacaribe virus genome and antigenome analogs require N and L proteins: Z protein is an inhibitor of these processes

Tacaribe virus (TV), the prototype of the New World group of arenaviruses, comprises a single phylogenetic lineage together with four South American pathogenic producers of hemorrhagic disease. The TV genome consists of two single-stranded RNA segments called S and L. A reconstituted transcription-replication system based on plasmid-supplied TV-like RNAs and TV proteins was established. Plasmid expression was driven by T7 RNA polymerase supplied by a recombinant vaccinia virus. Plasmids were constructed to produce TV S segment analogs containing the negative-sense copy of chloramphenicol acetyltransferase (CAT) flanked at the 5' and 3' termini by sequences corresponding to those of the 5' and 3' noncoding regions of the S genome (minigenome) or the S antigenome (miniantigenome). In cells expressing N and L proteins, input minigenome or miniantigenome produced, respectively, encapsidated miniantigenome or minigenome which in turn produced progeny minigenome or progeny miniantigenome. Both minigenome and miniantigenome in the presence of N and L mediated transcription, which was analyzed as CAT expression. Coexpression of the small RING finger Z (p11) protein was highly inhibitory to both transcription and replication mediated by the minigenome or the miniantigenome. The effect depended on synthesis of Z protein rather than on plasmid or the RNA and was not ascribed to decreased amounts of plasmid-supplied template or proteins (N or L). N and L proteins were sufficient to support full-cycle RNA replication of a plasmid-supplied S genome analog in which CAT replaced the N gene. Replication of this RNA was also inhibited by Z expression.

Allpahuayo virus: a newly recognized arenavirus (arenaviridae) from arboreal rice rats (oecomys bicolor and oecomys paricola) in northeastern peru

Allpahuayo virus was initially isolated from arboreal rice rats (Oecomys bicolor and Oecomys paricola) collected during 1997 at the Allpahuayo Biological Station in northeastern Peru. Serological and genetic studies identified the virus as a new member of the Tacaribe complex of the genus Arenavirus. The small (S) segment of the Allpahuayo virus prototype strain CLHP-2098 (Accession No. AY012686) was sequenced, as well as that of sympatric isolate CLHP-2472 (Accession No. AY012687), from the same rodent species. The S segment was 3382 bases in length and phylogenetic analysis indicated that Allpahuayo is a sister virus to Pichinde in clade A. Two ambisense, nonoverlapping reading frames were identified, which result in two predicted gene products, a glycoprotein precursor (GPC) and a nucleocapsid protein (NP). A predicted stable single hairpin secondary structure was identified in the intergenic region between GPC and NP. Details of the genetic organization of Allpahuayo virus are discussed.

Arenavirus nucleocapsid protein displays a transcriptional antitermination activity in vivo

RNA polymerase pausing and transcriptional antitermination regulates gene activity in several systems. In arenavirus infected cells the switch from transcription to replication is subjected to a hairpin-dependent termination and requires protein synthesis to bypass this signal. The transcriptional antitermination control by Junín virus nucleocapsid protein N, has been demonstrated in vivo by infecting BHK-21 cells expressing this viral protein in the presence of translation inhibitors. This is the first demonstration in vivo of a transcriptional antitermination control in arenavirus-infected cells.

Arenavirus phylogeny: a new insight

Arenaviridae is a worldwide distributed family, of enveloped, single stranded, RNA viruses. The arenaviruses were divided in two major groups (Old World and New World), based on serological properties and genetic data, as well as the geographic distribution. In this study the phylogenetic relationship among the members of the Arenaviridae was examined, using the reported genomic sequences. The comparison of the aligned nucleotide sequences of the S RNA and the predicted amino acid sequences of the GPC and N proteins, together with the phylogenetic analysis, strongly suggest a possible kinship of Pichindé and Oliveros viruses, with the Old World arenavirus group. This analysis points at the evolutive relationships between the arenaviruses of the Americas and can be used to evaluate the different hypotheses about their origin.

Completion of the Lassa fever virus sequence and identification of a RING finger open reading frame at the L RNA 5' End

Lassa (LAS) fever virus is a highly pathogenic arenavirus with large (L) and small (S) RNA genomic segments. The 5' end of the LAS L segment is described here, thereby completing the sequence of the most virulent arenavirus analyzed to date. In keeping with the ambisense gene structure of the arenaviruses, the LAS L RNA encodes a 250-kDa protein and an 11-kDa protein in opposite senses with respect to each other. The 11-kDa protein, defined previously in arenaviruses lymphocytic choriomeningitis (LCM), Tacaribe (TAC), and Pichinde (PIC), contains a RING type of zinc-binding structure. Expression of the 11-kDa protein in LAS virus-infected cells has been confirmed by binding to peptide-specific antibody.

Characterization of arenaviruses using a family-specific primer set for RT-PCR amplification and RFLP analysis. Its potential use for detection of uncharacterized arenaviruses

Arenaviruses are enveloped viruses with a genome composed of two ssRNA species, designated L and S. The arenaviruses were divided in two major groups (Old World and New World), based on serological properties and genetic data, as well as geographic distribution. A sequence alignment analysis of all reported arenavirus S RNAs yielded 17 conserved regions in addition to a reported conserved region at the end of both RNAs. The consensus sequences of these regions were used to design generalized primers suitable for RT-PCR amplification of a set of overlapping nucleotide sequence fragments comprising the complete S RNA of any arenavirus. A restriction analysis (RFLP) was designed to rapidly typify the amplified fragments. This RT-PCR-RFLP approach was tested with Old World (LCM) and New World (Junin and Tacaribe) arenaviruses. Furthermore, using this procedure the whole S RNA of a novel arenavirus isolate obtained from a rodent trapped in central Argentina, was amplified and characterized. Partial nucleotide sequence data were used for phylogenetic analyses that showed the relationships between this arenavirus and the rest of the members of the family. This relatively simple methodology will be useful both in basic studies and epidemiological survey programs.

Roles of the influenza virus polymerase and nucleoprotein in forming a functional RNP structure

Influenza virus transcription and replication is performed by ribonucleoprotein particles (RNPs). They consist of an RNA molecule covered with many copies of nucleoprotein (NP) and carry a trimeric RNA polymerase complex. RNA modification analysis and electron microscopy performed on native RNPs suggest that the polymerase forms a complex with both conserved viral RNA (vRNA) ends, whereas NP binding exposes the RNA bases to the solvent. After chemical removal of the polymerase, the bases at the vRNA extremities become reactive to modification and the vRNPs behave as structures with free ends, as judged from the observation of salt-induced conformational changes by electron microscopy. The vRNA appears to be completely single-stranded in polymerase-free RNPs despite a partial, inverted complementarity of the vRNA ends. The absence of a stable double-stranded panhandle structure in polymerase-free RNPs has important implications for the mechanism of viral transcription and the switch from transcription to replication.

The Lassa fever virus L gene: nucleotide sequence, comparison, and precipitation of a predicted 250 kDa protein with monospecific antiserum

The large (L) RNA segment of Lassa fever virus (LAS) encodes a putative RNA-dependent RNA polymerase (RdRp or L protein). Similar to other arenaviruses, the LAS L protein is encoded on the genome-complementary strand and is predicted to be 2218 amino acids in length (253 kDa). It has an unusually large non-coding region adjacent to its translation start site. The LAS L protein contains six motifs of conserved amino acids that have been found among arenavirus L proteins and core RdRp of other segmented negative-stranded (SNS) viruses (Arena-, Bunya- and Orthomyxoviridae). Phylogenetic analyses of the RdRp of 20 SNS viruses reveals that arenavirus L proteins represent a distinct cluster divided into LAS-lymphocytic choriomeningitis and Tacaribe-Pichinde virus lineages. Monospecific serum against a synthetic peptide corresponding to the most conserved central domain precipitates a 250 kDa product from LAS and lymphocytic choriomeningitis virus-infected cells.

Immunological identification of Tacaribe virus proteins

Tacaribe virus (TV), an arenavirus, is an enveloped virus with genetic information encoded in two segments of single-stranded RNA. The completed sequence of TV led to the identification of four open reading frames (ORF). In order to establish a direct link between ORFs in the sequence of TV and proteins present in virus particles and virus-infected cells, segments of the molecularly cloned TV genome were engineered so as to be expressed in Escherichia coli to produce fusion proteins that were used to raise antisera. The antisera were in turn employed to identify the TV gene products. Serum to the putative nucleocapsid (N) protein reacted with a 68-kDa protein, both in TV particles and in the infected cells. Sera raised to the glycoprotein precursor (GPC) immunoprecipitated two proteins of 68 and 70 kDa from infected cell lysates. Analysis of GPC synthesis in the presence of tunicamycin revealed that the unglycosylated GPC appeared as two polypeptides of 43 and 46 kDa. The putative RNA polymerase gene product (L) was detected as a approximately 240-kDa protein. Serum to the small zinc-binding domain protein (p11-Z) recognized a protein of approximately 11kDa. Immunological evidence is presented that in addition to N and L, two glycoproteins (GP1 and GP2) and p11-Z are structural components of Tacaribe virions.

5' termini of Pichinde arenavirus S RNAs and mRNAs contain nontemplated nucleotides

Primer extension of Pichinde arenavirus purified virion RNA suggests that genomes have at least a single nontemplated base at the 5' end which is a G in all cDNA clones having one such single base. On the other hand, the predominant products of primer extension on total virus-infected-cell RNA are at positions -1 and -2. The primer extension product at position -2 is not represented in virion RNA, and neither of these products is proportionally represented in mRNA. mRNA is predominantly 3 or 4 bases longer than genomes and antigenomes, but primer extension products as long as 7 bases were observed. The sequence of nontemplated bases reported here is unambiguous with respect to the 5'-terminal base and supports the view that there is a sequence preference for a G at the 5' termini of mRNAs. Assessment of our sequence data in the context of the sequences of Tacaribe and lymphocytic choriomeningitis viruses suggests that the mechanism of initiation of arenavirus transcription is fundamentally different from that of members of the families Orthomyxoviridae and Bunyaviridae.

Analysis of Pichinde arenavirus transcription and replication in human THP-1 monocytic cells

Human promonocytic THP-1 cells were previously shown to be nonpermissive for Pichinde virus (PV) replication unless the cells were induced to differentiate to macrophages by stimulation with phorbol ester (PMA) (J. Virol. 65, 3575, 1991). The restriction did not involve receptor modulation, virus binding, nor internalization of virus but a requirement for a host cell function in PV replication was observed in that the phorbol ester effect required protein kinase C activation and was inhibited by actinomycin D. In this report we demonstrate that PV S RNA genomes, antigenomes, GPC mRNA and NP mRNA are expressed at high levels in PMA treated THP-1 cells but at significantly lower levels or not at all in untreated cells. We have also determined that degradation of input viral S RNA does not account for decreased PV RNA synthesis in the undifferentiated cells. This suggests that the restriction of PV replication in THP-1 cells is a post-penetration event which precedes transcription of viral mRNAs and replication of viral genomes and supports a role for differentiation-specific host cell factors early in PV replication.

Sequence heterogeneity in the termini of lymphocytic choriomeningitis virus genomic and antigenomic RNAs

Sequence analysis of lymphocytic choriomeningitis virus L and S RNAs has revealed evidence of heterogeneity within the termini of the genomic and antigenomic RNAs. The RNAs are missing from 0 to 38 bases, show characteristic patterns of deleted nucleotides at both 5' and 3' termini, and often have a nontemplated base at the terminus. The same deletions, at either the 5' or the 3' terminus of the genomic L and S RNAs, are frequently found in the complementary strand of antigenomic RNA, suggesting that RNAs with deleted termini may be recognized as functional templates for replication. RNAs extracted from virions, or viral nucleocapsids isolated from acutely infected cells, are similar in the nature and extent of terminal heterogeneity that have been observed. This finding brings into question the function of the conserved sequences located at the termini of arenavirus genomic RNAs. Our data suggest that, while replication and packaging of the genomic and antigenomic RNA molecules can occur with terminally deleted molecules, mature transcripts may be derived only from full-length templates containing the conserved terminal sequence.

Toscana virus genomic L segment: molecular cloning, coding strategy and amino acid sequence in comparison with other negative strand RNA viruses

The complete nucleotide sequence of Toscana (TOS) virus (Bunyaviridae, Phlebovirus) L segment was determined. The L segment is 6404 nucleotides long, containing a single open reading frame (ORF) in the viral complementary sense coding for a protein of 2095 amino acids that, as in the case of negative strand RNA viruses, could be part of the RNA polymerase of TOS virus. This ORF is expressed by a messenger RNA (mRNA) as long as the genomic segment. Like the mRNAs expressed by the genomic segments of the other Bunyaviruses, the L mRNA has non-templated sequences at the 5' end. The comparison of TOS L protein sequence with the corresponding sequences of other negative strand RNA viruses showed a very high homology only with the Rift Valley Fever (RVF) virus. The residues conserved between the two proteins are mainly concentrated in the central region and contain three DD motifs proposed by Argos (1988) to be functional domains of DNA and RNA polymerases. The complete sequence of the Toscana virus L genomic segment has been deposited in the EMBL library with the accession number X68414.

The Tacaribe arenavirus small zinc finger protein is required for both mRNA synthesis and genome replication

An antiserum to a peptide of the Tacaribe virus Z protein was used to determine whether this small Zn(2+)-binding protein was required for viral RNA synthesis in infected cell extracts. Specific immunodepletion of the extracts invariably reduced genome synthesis to near background levels, but strong effects on mRNA synthesis occurred only early in the infection or when mRNA synthesis was relatively weak. Our results suggest that the Z protein is required for both mRNA and genome synthesis, but in somewhat different manners.

Sequence of the nucleocapsid protein gene of Machupo virus: close relationship with another South American pathogenic arenavirus, Junín

The sequence of the nucleocapsid (N) protein of Machupo virus (causative agent of Bolivian haemorrhagic fever) has been determined, and used to infer a phylogenetic relationship to other arenaviruses. The relationship of the virus to Junín and Tacaribe viruses, together with previous demonstrations of antigenic similarity and cross-protection by heterologous viruses, suggest that vaccines developed against Argentine haemorrhagic fever might also be effective against the Bolivian disease.

Conservation analysis and structure prediction of the SH2 family of phosphotyrosine binding domains

Src homology 2 (SH2) regions are short (approximately 100 amino acids), non-catalytic domains conserved among a wide variety of proteins involved in cytoplasmic signaling induced by growth factors. It is thought that SH2 domains play an important role in the intracellular response to growth factor stimulation by binding to phosphotyrosine containing proteins. In this paper we apply the techniques of multiple sequence alignment, secondary structure prediction and conservation analysis to 67 SH2 domain amino acid sequences. This combined approach predicts seven core secondary structure regions with the pattern beta-alpha-beta-beta-beta-beta-alpha, identifies those residues most likely to be buried in the hydrophobic core of the native SH2 domain, and highlights patterns of conservation indicative of secondary structural elements. Residues likely to be involved in phosphotyrosine binding are shown and orientations of the predicted secondary structures suggested which could enable such residues to cooperate in phosphate binding. We propose a consensus pattern that encapsulates the principal conserved features of the SH2 domains. Comparison of the proposed SH2 domain of akt to this pattern shows only 12/40 matches, suggesting that this domain may not exhibit SH2-like properties.

Current progress towards vaccines for arenavirus-caused diseases

The arenaviruses are primarily viruses of rodents, but some members of the group cause severe disease (Argentine and Bolivian haemorrhagic fevers and Lassa fever) when transmitted to humans in the specific areas of the world where they are enzootic. Current research of relevance to the provision of vaccines against these diseases, which highlights many of the problems encountered generally in the development of vaccines, is reviewed here. Although one of the classical approaches to vaccine production, the use of inactivated preparations of virus of varying degrees of purity, has produced no results of promise, attenuation of a virulent strain of Junin virus by passage in cultured cells has yielded a vaccine strain currently being tested for efficacy in protecting against Argentine haemorrhagic fever in the human population at risk. The experimental evidence for protection in animal model systems by related, apparently non-pathogenic, viruses and by recombinant vaccinia viruses expressing arenavirus proteins is discussed, together with some of the potential difficulties of these approaches.

Sequence analysis of the polymerase L gene of human respiratory syncytial virus and predicted phylogeny of nonsegmented negative-strand viruses

The complete nucleotide sequence of the large (L) polymerase gene of human respiratory syncytial virus (RSV) strain A2 was determined by analysis of cloned-cDNAs representing the entire gene and confirmed in part by dideoxy sequencing of genomic RNA. The RSV L gene is 6578 nucleotides in length and contains a single major open reading frame that encodes a protein of 2165 amino acids. The molecular weight (250,226) and amino acid composition of the deduced RSV L protein are similar to those of other negative-strand RNA viruses. Regions of statistically significant amino acid sequence similarity were identified in pairwise global alignments of the RSV L protein with its counterparts in four paramyxoviruses (parainfluenza virus type 3, Sendai virus, measles virus, Newcastle disease virus) and two rhabdoviruses (rabies virus, vesicular stomatitis virus). In addition, amino acid sequence alignments showed that the RSV L protein has a 70-amino acid amino-terminal extension relative to the others. This is suggested to be due to the acquisition of gene overlap of the RSV L gene with its upstream neighbor, the 22K (M2) gene and the use of a new translational start site. The most highly related region among these seven proteins is located within the amino-terminal half, representing approximately 20% of each protein sequences. This region contains six discrete segments that are colinear and highly conserved in each paramyxovirus and rhabdovirus L protein, and three of these overlapped with sequence motifs found previously in other RNA-dependent RNA and DNA polymerases. A phylogenetic tree was constructed from the paramyxovirus and rhabdovirus L protein sequences to further define their relationships. The branching order indicates that RSV represents a lineage within the paramyxovirus family which is relatively distinct from the others, which in turn are more closely interrelated. Among these other members of the family Paramyxoviridae, the branching order does not entirely conform to their current taxonomic organization, providing support for its reevaluation.

The 3' end termini of the Tacaribe arenavirus subgenomic RNAs

Tacaribe virus (TV), a member of the Arenaviridae family, contains two single-stranded RNA genome segments called S and L. Two proteins, in an ambisense coding strategy, are encoded in both the S RNA and the L RNA. The 3' ends of the TV four putative mRNAs have been characterized using S1 nuclease mapping. The experiments revealed that the transcripts terminate within the intergenic region in each RNA segment. No special sequences that might function as termination signals were evident. The 3' end sequences of the four putative mRNAs can be predicted to adopt GC-rich stable hairpin configurations (delta G greater than or equal to -25 kcal). These observations suggest that the transcript structure rather than particular sequences might be the signal involved in the termination of arenavirus transcription.

Sequence analysis of the S RNA of the African arenavirus Mopeia: an unusual secondary structure feature in the intergenic region

Mopeia virus is an apparently nonpathogenic African arenavirus which can protect animals from subsequent challenge by the closely related Lassa virus. As a step toward understanding these differences in pathogenicity and the means by which Mopeia virus infection can protect against subsequent Lassa virus infection, cDNA clones corresponding to 3419 nucleotides of Mopeia virus S RNA were isolated and sequenced. Two open reading frames, encoding the glycoprotein precursor (GPC) and nucleocapsid (N) proteins, were located in the ambisense arrangement characteristic of the arenaviruses. Comparison of the amino acid sequences of the translation products with those of two Lassa virus strains showed considerable conservation, with 74 and 80% identity for the two glycoproteins G1 and G2, and 74% identity for the N protein. The putative dibasic site of GPC cleavage (R-R) was conserved, as were the potential N-linked glycosylation sites. A striking difference between Mopeia virus and Lassa virus was identified in the noncoding intergenic region. Instead of the single hairpin structure formed by base-pairing of complementary sequences which is usually found, the Mopeia virus S RNA has the potential to form two hairpins. These hairpins were similar in sequence and may have been formed in a duplication event during RNA replication. The possible contribution of this secondary structure feature to differences in pathogenicity between Mopeia and Lassa viruses is discussed.

Nucleotide sequence analysis of the L gene of vesicular stomatitis virus (New Jersey serotype): identification of conserved domains in L proteins of nonsegmented negative-strand RNA viruses

We have determined the nucleotide sequence of the L gene of vesicular stomatitis virus (VSV), New Jersey serotype (Ogden strain) by primer extension dideoxy sequencing of the genomic RNA with reverse transcriptase. This analysis completes the entire genomic sequence of the VSVNJ (Ogden). Comparison of the deduced amino acid sequence of this L protein with those reported for L proteins of Indiana serotype and Hazelhurst strain of New Jersey serotype revealed an extensive sequence similarity among all three proteins. The comparison was further extended to the L proteins of other nonsegmented negative-strand RNA viruses, namely the rabies virus and four members of the paramyxovirus family: measles, Newcastle disease, human parainfluenza 3, and Sendai viruses. Our findings confirmed the existence of conserved as well as unique domains in the L proteins, suggesting an evolutionary relationship among these viruses.

Identification of four conserved motifs among the RNA-dependent polymerase encoding elements

Four consensus sequences are conserved with the same linear arrangement in RNA-dependent DNA polymerases encoded by retroid elements and in RNA-dependent RNA polymerases encoded by plus-, minus- and double-strand RNA viruses. One of these motifs corresponds to the YGDD span previously described by Kamer and Argos (1984). These consensus sequences altogether lead to 4 strictly and 18 conservatively maintained amino acids embedded in a large domain of 120 to 210 amino acids. As judged from secondary structure predictions, each of the 4 motifs, which may cooperate to form a well-ordered domain, places one invariant amino acid in or proximal to turn structures that may be crucial for their correct positioning in a catalytic process. We suggest that this domain may constitute a prerequisite 'polymerase module' implicated in template seating and polymerase activity. At the evolutionary level, the sequence similarities, gap distribution and distances between each motif strongly suggest that the ancestral polymerase module was encoded by an individual genetic element which was most closely related to the plus-strand RNA viruses and the non-viral retroposons. This polymerase module gene may have subsequently propagated in the viral kingdom by distinct gene set recombination events leading to the wide viral variety observed today.

The 5' region of Tacaribe virus L RNA encodes a protein with a potential metal binding domain

We have just completed the Tacaribe arenavirus (TV) genome structure by sequencing the 5' region of the L RNA. Analysis of the sequence has indicated the existence of an open reading frame (ORF) in the viral sense RNA encoding a 95 amino acid polypeptide. The first in phase AUG codon is in positions 70-72 from the 5' end of the viral RNA surrounded by a sequence favorable for the initiation of protein synthesis. The ORF ends at positions 355-357. The predicted polypeptide (P11) contains a cysteine-rich sequence bearing a remarkable similarity to the "zinc finger" sequences found in a number of proteins. We have recently reported that the 3' region of the TV L RNA encodes a polypeptide comprising 2210 amino acids in the viral-complementary sequence. This latter gene, i.e., the L gene, terminates at positions 442-440 from the 5' end of the viral RNA. The two genes encoded by the L RNA (L and P11) are in opposite strands of the RNA in sequences that do not overlap, but are separated by a noncoding intergenic region of 82 nucleotides. The nucleotide sequence of the intergenic region leads to the prediction of a strong secondary structure.