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.

A novel circulating tamiami mammarenavirus shows potential for zoonotic spillover.

A detailed understanding of the mechanisms underlying the capacity of a virus to break the species barrier is crucial for pathogen surveillance and control. New World (NW) mammarenaviruses constitute a diverse group of rodent-borne pathogens that includes several causative agents of severe viral hemorrhagic fever in humans. The ability of the NW mammarenaviral attachment glycoprotein (GP) to utilize human transferrin receptor 1 (hTfR1) as a primary entry receptor plays a key role in dictating zoonotic potential. The recent isolation of Tacaribe and lymphocytic choriominingitis mammarenaviruses from host-seeking ticks provided evidence for the presence of mammarenaviruses in arthropods, which are established vectors for numerous other viral pathogens. Here, using next generation sequencing to search for other mammarenaviruses in ticks, we identified a novel replication-competent strain of the NW mammarenavirus Tamiami (TAMV-FL), which we found capable of utilizing hTfR1 to enter mammalian cells. During isolation through serial passaging in mammalian immunocompetent cells, the quasispecies of TAMV-FL acquired and enriched mutations leading to the amino acid changes N151K and D156N, within GP. Cell entry studies revealed that both substitutions, N151K and D156N, increased dependence of the virus on hTfR1 and binding to heparan sulfate proteoglycans. Moreover, we show that the substituted residues likely map to the sterically constrained trimeric axis of GP, and facilitate viral fusion at a lower pH, resulting in viral egress from later endosomal compartments. In summary, we identify and characterize a naturally occurring TAMV strain (TAMV-FL) within ticks that is able to utilize hTfR1. The TAMV-FL significantly diverged from previous TAMV isolates, demonstrating that TAMV quasispecies exhibit striking genetic plasticity that may facilitate zoonotic spillover and rapid adaptation to new hosts.

MicroRNAs and Mammarenaviruses: Modulating Cellular Metabolism.

Mammarenaviruses are a diverse genus of emerging viruses that include several causative agents of severe viral hemorrhagic fevers with high mortality in humans. Although these viruses share many similarities, important differences with regard to pathogenicity, type of immune response, and molecular mechanisms during virus infection are different between and within New World and Old World viral infections. Viruses rely exclusively on the host cellular machinery to translate their genome, and therefore to replicate and propagate. miRNAs are the crucial factor in diverse biological processes such as antiviral defense, oncogenesis, and cell development. The viral infection can exert a profound impact on the cellular miRNA expression profile, and numerous RNA viruses have been reported to interact directly with cellular miRNAs and/or to use these miRNAs to augment their replication potential. Our present study indicates that mammarenavirus infection induces metabolic reprogramming of host cells, probably manipulating cellular microRNAs. A number of metabolic pathways, including valine, leucine, and isoleucine biosynthesis, d-Glutamine and d-glutamate metabolism, thiamine metabolism, and pools of several amino acids were impacted by the predicted miRNAs that would no longer regulate these pathways. A deeper understanding of mechanisms by which mammarenaviruses handle these signaling pathways is critical for understanding the virus/host interactions and potential diagnostic and therapeutic targets, through the inhibition of specific pathologic metabolic pathways.

Differences in Tissue and Species Tropism of Reptarenavirus Species Studied by Vesicular Stomatitis Virus Pseudotypes.

Reptarenaviruses cause Boid Inclusion Body Disease (BIBD), and co-infections by several reptarenaviruses are common in affected snakes. Reptarenaviruses have only been found in captive snakes, and their reservoir hosts remain unknown. In affected animals, reptarenaviruses appear to replicate in most cell types, but their complete host range, as well as tissue and cell tropism are unknown. As with other enveloped viruses, the glycoproteins (GPs) present on the virion's surface mediate reptarenavirus cell entry, and therefore, the GPs play a critical role in the virus cell and tissue tropism. Herein, we employed single cycle replication, GP deficient, recombinant vesicular stomatitis virus (VSV) expressing the enhanced green fluorescent protein (scrVSV∆G-eGFP) pseudotyped with different reptarenavirus GPs to study the virus cell tropism. We found that scrVSV∆G-eGFPs pseudotyped with reptarenavirus GPs readily entered mammalian cell lines, and some mammalian cell lines exhibited higher, compared to snake cell lines, susceptibility to reptarenavirus GP-mediated infection. Mammarenavirus GPs used as controls also mediated efficient entry into several snake cell lines. Our results confirm an important role of the virus surface GP in reptarenavirus cell tropism and that mamma-and reptarenaviruses exhibit high cross-species transmission potential.

Proteomics Computational Analyses Suggest that the Antennavirus Glycoprotein Complex Includes a Class I Viral Fusion Protein (α-Penetrene) with an Internal Zinc-Binding Domain and a Stable Signal Peptide.

A metatranscriptomic study of RNA viruses in cold-blooded vertebrates identified two related viruses from frogfish (Antennarius striatus) that represent a new genus Antennavirus in the family Arenaviridae (Order: Bunyavirales). Computational analyses were used to identify features common to class I viral fusion proteins (VFPs) in antennavirus glycoproteins, including an N-terminal fusion peptide, two extended alpha-helices, an intrahelical loop, and a carboxyl terminal transmembrane domain. Like mammarenavirus and hartmanivirus glycoproteins, the antennavirus glycoproteins have an intracellular zinc-binding domain and a long virion-associated stable signal peptide (SSP). The glycoproteins of reptarenaviruses are also class I VFPs, but do not contain zinc-binding domains nor do they encode SSPs. Divergent evolution from a common progenitor potentially explains similarities of antennavirus, mammarenavirus, and hartmanivirus glycoproteins, with an ancient recombination event resulting in a divergent reptarenavirus glycoprotein.

Structure-function relationship of the mammarenavirus envelope glycoprotein.

Mammarenaviruses, including lethal pathogens such as Lassa virus and Junín virus, can cause severe hemorrhagic fever in humans. Entry is a key step for virus infection, which starts with binding of the envelope glycoprotein (GP) to receptors on target cells and subsequent fusion of the virus with target cell membranes. The GP precursor is synthesized as a polypeptide, and maturation occurs by two cleavage events, yielding a tripartite GP complex (GPC) formed by a stable signal peptide (SSP), GP1 and GP2. The unique retained SSP interacts with GP2 and plays essential roles in virion maturation and infectivity. GP1 is responsible for binding to the cell receptor, and GP2 is a class I fusion protein. The native structure of the tripartite GPC is unknown. GPC is critical for the receptor binding, membrane fusion and neutralization antibody recognition. Elucidating the molecular mechanisms underlining the structure-function relationship of the three subunits is the key for understanding their function and can facilitate novel avenues for combating virus infections. This review summarizes the basic aspects and recent research of the structure-function relationship of the three subunits. We discuss the structural basis of the receptor-binding domain in GP1, the interaction between SSP and GP2 and its role in virion maturation and membrane fusion, as well as the mechanism by which glycosylation stabilizes the GPC structure and facilitates immune evasion. Understanding the molecular mechanisms involved in these aspects will contribute to the development of novel vaccines and treatment strategies against mammarenaviruses infection.

Genetic diversity among Lassa virus strains.

The arenavirus Lassa virus causes Lassa fever, a viral hemorrhagic fever that is endemic in the countries of Nigeria, Sierra Leone, Liberia, and Guinea and perhaps elsewhere in West Africa. To determine the degree of genetic diversity among Lassa virus strains, partial nucleoprotein (NP) gene sequences were obtained from 54 strains and analyzed. Phylogenetic analyses showed that Lassa viruses comprise four lineages, three of which are found in Nigeria and the fourth in Guinea, Liberia, and Sierra Leone. Overall strain variation in the partial NP gene sequence was found to be as high as 27% at the nucleotide level and 15% at the amino acid level. Genetic distance among Lassa strains was found to correlate with geographic distance rather than time, and no evidence of a "molecular clock" was found. A method for amplifying and cloning full-length arenavirus S RNAs was developed and used to obtain the complete NP and glycoprotein gene (GP1 and GP2) sequences for two representative Nigerian strains of Lassa virus. Comparison of full-length gene sequences for four Lassa virus strains representing the four lineages showed that the NP gene (up to 23.8% nucleotide difference and 12.0% amino acid difference) is more variable than the glycoprotein genes. Although the evolutionary order of descent within Lassa virus strains was not completely resolved, the phylogenetic analyses of full-length NP, GP1, and GP2 gene sequences suggested that Nigerian strains of Lassa virus were ancestral to strains from Guinea, Liberia, and Sierra Leone. Compared to the New World arenaviruses, Lassa and the other Old World arenaviruses have either undergone a shorter period of diverisification or are evolving at a slower rate. This study represents the first large-scale examination of Lassa virus genetic variation.

[The localization and preliminary characteristics of antigenic sites (B epitopes) in the nucleocapsid protein of the Lassa virus]. / Lokalizatsiia i predvaritel'naia kharakteristika antigennykh saitov (B-épitopov) v belke nukleokapsida virusa Lassa.

Nucleocapsid protein of Lassa virus contains 4 epitope sites. Three of them were localized in amino acid position 123-1 27, 337-346, and 518-527. Monoclonal antibody 1108 specific to Lassa virus NP-protein reacted with 123-127 synthetic peptide in solid-phase ELISA and precipitated nucleocapsid proteins of Machupo, Tacaribe, and Mopeia arenaviruses in RIP.

Generation of reassortants between African arenaviruses.

Lassa (LAS) and Mopeia (MOP) viruses are African arenaviruses which are carried by wild rodents and occasionally transferred to humans. In humans and nonhuman primates, Lassa causes mortality in 60% of untreated cases, whereas Mopeia does not cause mortality and has been known to protect monkeys from lethal challenge with Lassa. These two African arenaviruses also differ in their lethality for suckling outbred mice and in their plaque sizes under agar overlay. MOP virus induces small plaques and lethal infection after intracerebral (ic) inoculation. In contrast, LAS inoculation does not kill mice and the virus induces large plaques. After coinfection of Vero cells with LAS and MOP viruses some phenotypic reassortants which produced small plaques and were not lethal for outbred mice were isolated and plaque-purified. Dot-blot hybridization using LAS and MOP cDNA probes specific for L and S RNA segments revealed a genotype consisting of the L RNA of MOP and the S RNA of LAS (MOP/LAS reassortant). Adoptive transfer experiments demonstrated an ability of immune splenocytes from CBA mice intraperitoneally infected with the MOP/LAS reassortants to protect recipient mice against lethal disease after ic inoculation with LAS virus.

Molecular organization of Junin virus S RNA: complete nucleotide sequence, relationship with other members of the Arenaviridae and unusual secondary structures.

In this study, overlapping cDNA clones covering the entire S RNA molecule of Junin virus, an arenavirus that causes Argentine haemorrhagic fever, were generated. The complete sequence of this 3400 nucleotide RNA was determined using the dideoxynucleotide chain termination method. The nucleocapsid protein (N) and the glycoprotein precursor (GPC) genes were identified as two non-overlapping open reading frames of opposite polarity, encoding primary translation products of 564 and 481 amino acids, respectively. Intracellular processing of the latter yields the glycoproteins found in the viral envelope. Comparison of the Junin virus N protein with the homologous proteins of other arenaviruses indicated that amino acid sequences are conserved, the identity ranging from 46 to 76%. The N-terminal half of GPC exhibits an even higher degree of conservation (54 to 82%), whereas the C-terminal half is less conserved (21 to 50%). In all comparisons the highest level of amino acid sequence identity was seen when Junin virus and Tacaribe virus sequences were aligned. The nucleotide sequence at the 5' end of Junin virus S RNA is not identical to that determined of the other sequenced arenaviruses. However, it is complementary to the 3'-terminal sequences and may form a very stable panhandle structure (delta G-242.7 kJ/mol) involving the complete non-coding regions upstream from both the N and GPC genes. In addition, a distinct secondary structure was identified in the intergenic region, downstream from the coding sequences; Junin virus S RNA shows a potential secondary structure consisting of two hairpin loops (delta G -163.2 and -239.3 kJ/mol) instead of the single hairpin loop that is usually found in other arenaviruses. The analysis of the arenavirus S RNA nucleotide sequences and their encoded products is discussed in relation to structure and function.

Analysis of the glycoprotein gene of Tacaribe virus and neutralization-resistant variants.

We have previously generated neutralization-resistant variants of Tacaribe virus in the presence of a monoclonal antibody (MAb) specific for the envelope glycoprotein. The envelope glycoprotein precursor (GPC) genes of two variant viruses were sequenced following polymerase chain reaction amplification of a specific region of the Tacaribe virus S RNA, and compared with the GPC gene of the parental virus. Multiple nucleotide changes in the 3' half of the GPC gene were identified in the variants, suggesting that this part of the gene codes for the envelope glycoprotein of Tacaribe virus recognized by the MAb. Both variants showed unique amino acid substitutions up to 166 residues apart, suggesting that the most likely basis for neutralization resistance was a change in an epitope in which the critical residues are juxtaposed by conformation rather than by proximity in coding.

Nucleotide sequence of the S RNA of Lassa virus (Nigerian strain) and comparative analysis of arenavirus gene products.

The nucleotide sequence of the small (S) genomic RNA of Lassa virus (strain GA391, of Nigerian origin) has been determined. The RNA has features which conform to those seen in most other arenavirus S RNAs which have been characterised, including conserved terminal sequences, an ambisense arrangement of the coding regions for the precursor glycoprotein (GPC) and nucleocapsid (N) proteins and an intergenic region capable of forming a base-paired "hairpin" structure. Comparison of the nucleotide sequence with that of the Josiah strain of Lassa virus (from Sierra Leone) reveals considerable nucleotide divergence in the third base of codons in the reading frames of all three proteins, although the resulting protein sequences are highly conserved, with 92, 94 and 91% identical residues for the mature glycoproteins G1 and G2 and the N protein, respectively. Sequence alignments of the available arenavirus structural proteins and dendrograms summarising the relationships between the viral proteins are presented.

A mouse attenuated mutant of Junin virus with an altered envelope glycoprotein.

The XJC13 strain of Junin virus (JV) and the mouse-attenuated mutant C167 showed different GP38 peptide mapping after limited proteolysis with ficin and papain; viral infectivity of both viruses also exhibited a different susceptibility to protease treatment. A correlation between envelope glycoprotein alteration and JV virulence in neonatal mice is proposed.

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.

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

The nucleotide sequence of Tacaribe virus (TV) L gene was obtained from two sets of overlapping cDNA clones constructed by walking along the virus L RNA using two successive synthetic DNA primers. Analysis of the sequence indicated the existence of a unique long open reading frame in the viral complementary strand. The first in-phase AUG codon is in positions 31-33 from the 5' end of the viral complementary L RNA surrounded by a sequence favorable for initiation of protein synthesis. The open reading frame ends at positions 6661-6663. The predicted TV L protein is a 2210 amino acid long polypeptide with an estimated molecular weight of 251,942. Comparison of the amino acid sequence of TV L protein with peptide sequences predicted from L-derived cDNA clones of lymphocytic choriomeningitis virus shows an overall 42% of homology.

Nucleotide sequence of the Lassa virus (Josiah strain) S genome RNA and amino acid sequence comparison of the N and GPC proteins to other arenaviruses.

The complete nucleotide sequence of the S genome RNA of the Josiah strain of Lassa virus was determined from cloned cDNA. The S RNA is 3402 nucleotides long with a calculated molecular weight of 1.09 x 10(6) Da. The nucleotide base composition is 26.84% adenine, 21.40% guanine, 22.75% cytosine, and 29.01% uridine. The 5' and 3' terminal nucleotide sequences are conserved and complimentary for 19 nucleotides, the nucleoprotein and glycoprotein genes are arranged in ambisense coding strategy, and the intergenic region contains an inverted complimentary sequence, as do all other arenavirus S RNAs characterized to date. Amino acid sequence comparisons between the nucleoproteins and glycoproteins of the Josiah and Nigerian (N sequences only) strains of Lassa virus, the WE and ARM strains of lymphocytic choriomeningitis virus (LCMV), Tacaribe, and Pichinde viruses are presented. These findings reveal that the G2 envelope glycoprotein is more conserved among different arenaviruses than the internal nucleoprotein.

Characterization of temperature-sensitive mutants of Pichinde virus.

The synthesis of viral proteins and S RNAs in cells infected with 12 temperature-sensitive (ts) mutants of Pichinde virus was characterized. The mutants could be divided into five groups on the basis of the patterns of radiolabeled proteins immunoprecipitated from infected-cell lysates. Markedly reduced nucleoprotein levels and undetectable amounts of glycoprotein precursor and L protein were synthesized at the nonpermissive temperature in cells infected with five of the mutants. Reduced but detectable amounts of the viral proteins were synthesized at the nonpermissive temperature in cells infected with a single mutant. Two mutants were associated with the intracellular accumulation of glycoprotein precursor, which was apparently not transported across the cell membrane in cells incubated at the nonpermissive temperature. The synthesis of viral proteins in cells infected with two mutants was indistinguishable from those produced by wild-type virus. Two additional mutants were associated with markedly reduced amounts of immunoprecipitable proteins in infected cells incubated at both the permissive and nonpermissive temperatures. Analysis of viral RNA with radiolabeled single-stranded cDNA probes representing complementary and genomic-sense sequences corresponding to the 3' region of S RNA revealed two basic patterns of viral RNA synthesis. At the nonpermissive temperature, the synthesis of complementary- and genomic-sense sequences and mRNA of the S RNA segment was markedly reduced in cells infected with representative members of these mutant groups, suggesting the presence of mutations altering transcriptase activity. Viral-complementary- and genomic-sense sequence and RNA synthesis, as well as nucleoprotein mRNA in cells, was detected in reduced amounts for mutants associated with reduced levels of proteins at both temperatures. Interestingly, RNA species larger than the S RNA segment were detected in cells infected with some of the mutants, especially those with putative transcriptase lesions. These molecules suggest a possible oligomeric intermediate in the synthesis of S RNA of Pichinde virus.

Identification of messenger RNA for nucleocapsid protein of Lassa virus in infected cells.

Single-stranded RNAs from Lassa virus-infected cells were fractionated by affinity chromatography on an oligo(dT)-cellulose column as well as by sucrose gradient centrifugation. Fractionated RNAs were translated in rabbit reticulocyte lysates, and translation products were precipitated with monoclonal antibodies to the nucleocapsid protein of Lassa virus. It has been shown that mRNA for the nucleocapsid protein is 15-16S and the RNA does not contain long if any poly(A) sequences.