Nucleotide sequence of the M segment of the genomic RNA of Hantaan virus 76-118

Hantavirus Gc induces long-term immune protection via LAMP-targeting DNA vaccine strategy

Hemorrhagic fever with renal syndrome (HFRS) occurs widely throughout Eurasia. Unfortunately, there is no effective treatment, and prophylaxis remains the best option against the major pathogenic agent, hantaan virus (HTNV), which is an Old World hantavirus. However, the absence of cellular immune responses and immunological memory hampers acceptance of the current inactivated HFRS vaccine. Previous studies revealed that a lysosome-associated membrane protein 1 (LAMP1)-targeting strategy involving a DNA vaccine based on the HTNV glycoprotein Gn successfully conferred long-term immunity, and indicated that further research on Gc, another HTNV antigen, was warranted. Plasmids encoding Gc and lysosome-targeted Gc, designated pVAX-Gc and pVAX-LAMP/Gc, respectively, were constructed. Proteins of interest were identified by fluorescence microscopy following cell line transfection. Five groups of 20 female BALB/c mice were subjected to the following inoculations: inactivated HTNV vaccine, pVAX-LAMP/Gc, pVAX-Gc, and, as the negative controls, pVAX-LAMP or the blank vector pVAX1. Humoral and cellular immunity were assessed by enzyme-linked immunosorbent assays (ELISAs) and 15-mer peptide enzyme-linked immunospot (ELISpot) epitope mapping assays. Repeated immunization with pVAX-LAMP/Gc enhanced adaptive immune responses, as demonstrated by the specific and neutralizing antibody titers and increased IFN-γ production. The inactivated vaccine induced a comparable humoral reaction, but the negative controls only elicited insignificant responses. Using a mouse model of HTNV challenge, the in vivo protection conferred by the inactivated vaccine and Gc-based constructs (with/without LAMP recombination) was confirmed. Evidence of pan-epitope reactions highlighted the long-term cellular response to the LAMP-targeting strategy, and histological observations indicated the safety of the LAMP-targeting vaccines. The long-term protective immune responses induced by pVAX-LAMP/Gc may be due to the advantage afforded by lysosomal targeting after exogenous antigen processing initiation and major histocompatibility complex (MHC) class II antigen presentation trafficking. MHC II-restricted antigen recognition effectively primes HTNV-specific CD4+ T-cells, leading to the promotion of significant immune responses and immunological memory. An epitope-spreading phenomenon was observed, which mirrors the previous result from the Gn study, in which the dominant IFN-γ-responsive hot-spot epitopes were shared between HLA-II and H2d. Importantly, the pan-epitope reaction to Gc indicated that Gc should be with potential for use in further hantavirus DNA vaccine investigations.

A recombinant pseudotyped lentivirus expressing the envelope glycoprotein of hantaan virus induced protective immunity in mice

Background

Hantaviruses cause acute hemorrhagic fever with renal syndrome (HFRS). Currently, several types of inactivated HFRS vaccines are widely used, however the limited ability of these immunogen to elicit neutralizing antibodies restricts vaccine efficacy. Development of an effective vaccine to overcome this weakness is must.

Methods

In the present study, a recombinant pseudotyped lentivirus bearing the hantaan virus (HTNV) envelope glycoproteins (GP), rLV-M, was constructed. C57BL/6 mice were immunized with the rLV-M and a series of immunological assays were conducted to determine the immunogenicity of the recombinant pseudotyped lentivirus. The humoral and cell-mediated immune responses induced by rLV-M were compared with those of the inactivated HFRS vaccine.

Results

Indirect immunofluorescence assay (IFA) showed the rLV-M expressed target proteins in HEK-293cells. In mice, the rLV-M efficiently induced GP-specific humoral responses and protection against HTNV infection. Furthermore, the rLV-M induced higher neutralizing antibody titers than the inactivated HFRS vaccine control.

Conclusions

The results indicated the potential of using a pseudotyped lentivirus as a delivery vector for a hantavirus vaccine immunogen.

Complete nucleotide sequence of a Chilean hantavirus

We have determined the genomic sequence of an Andes virus (ANDV) strain isolated from an infected Oligoryzomys longicaudatus rodent trapped in Chile in 1997. This strain, for which we propose the designation Chile R123, reproduces essential attributes of hantavirus pulmonary syndrome (HPS) when injected intramuscularly into laboratory hamsters (Hooper et al., Virology 289 (2001) 6-14). The L, M, and S segment sequences of Chile R123 are 6562, 3671, and 1871 nt long, respectively, with an overall G+C content of 38.5%. These respective genome segments could encode a 247 kd RNA-dependent RNA polymerase (RdRP), 126 kd glycoprotein precursor (GPC), and 48 kd nucleocapsid (N) protein, in line with other Sigmodontine rodent-associated hantaviruses. Among hantaviruses for which complete genomic sequences are available, Chile R123 is most closely related to Sin Nombre virus (SNV) strain NM R11, with greater than 85% amino acid identity between translated L and S segments and 78% amino acid identity between translated M segments. Because Chile R123 shares essentially 100% amino acid identity in regions of overlap with partially sequenced Argentinian and Chilean ANDV strains, Syrian hamster pathogenicity and the potential for interhuman transmission are features likely common to all ANDV strains.

The 5' ends of Hantaan virus (Bunyaviridae) RNAs suggest a prime-and-realign mechanism for the initiation of RNA synthesis

We examined the 5' ends of Hantaan virus (HTN) genomes and mRNAs to gain insight into the manner in which these chains were initiated. Like those of all members of the family Bunyaviridae described so far, the HTN mRNAs contained 5' terminal extensions that were heterogeneous in both length and sequence, presumably because HTN also "cap snatches" host mRNAs to initiate the viral mRNAs. Unexpectedly, however, almost all of the mRNAs contained a G residue at position -1, and a large fraction also lacked precisely one of the three UAG repeats at the termini. The genomes, on the other hand, commenced with a U residue at position +1, but only 5' monophosphates were found here, indicating that these chains may not have initiated with UTP at this position. Taken together, these unusual findings suggest a prime-and-realign mechanism of chain initiation in which mRNAs are initiated with a G-terminated host cell primer and genomes with GTP, not at the 3' end of the genome template but internally (opposite the template C at position +3), and after extension by one or a few nucleotides, the nascent chain realigns backwards by virtue of the terminal sequence repeats, before processive elongation takes place. For genome initiation, an endonuclease, perhaps that involved in cap snatching, is postulated to remove the 5' terminal extension of the genome, leaving the 5' pU at position +1.

Fatal illness associated with a new hantavirus in Louisiana

A fatal case of hantaviral illness occurred in Louisiana, outside of the range of P. maniculatus, the rodent reservoir for Sin Nombre virus. Hantavirus RNA and antigens were detected in patient autopsy tissues, and nucleotide sequence analysis of amplified polymerase chain reaction (PCR) products identified a newly recognized unique hantavirus, provisionally named Bayou virus. Prominent features of the clinical illness are compatible with hantavirus pulmonary syndrome (HPS), but several features such as renal insufficiency and intraalveolar hemorrhage are more compatible with hemorrhagic fever with renal syndrome (HFRS), a disease associated with Eurasian hantaviruses.

Isolation of black creek canal virus, a new hantavirus from Sigmodon hispidus in Florida

Numerous rodents were trapped for serologic and virologic studies following the identification of a hantavirus pulmonary syndrome (HPS) case in Dade County, Florida. Cotton rats (Sigmodon hispidus) were the most frequently capture rodent and displayed the highest seroprevalence to a variety of hantavirus antigens. Hantavirus genome RNA was detected in all the seropositive cotton rats tested, using a reverse transcriptase-polymerase chain reaction (RT-PCR) assay. A virus was isolated from tissues of two seropositive cotton rats by cultivation of lung and spleen homogenates on Vero E6 cells. Nucleotide sequence information obtained by direct RT-PCR and the serologic relationships of this virus with the other hantaviruses indicate that this virus, Black Creek Canal virus, represents a new hantavirus distinct from the previously known serotypes.

Comparison of nucleotide sequences among hantaviruses belonging to the same serotype: an analysis of amplified DNA by thermal cycle sequencing

The hantavirus genus, belonging to the bunyaviridae family, is comprised of at least four serologically distinct types: Hantaan, Seoul, Puumala and Prospect Hill. Previously, we reported the use of the polymerase chain reaction (PCR) for grouping hantavirus isolates by using four sets of primers specific to each serotype. Our PCR typing results agreed with those of serological typing. The present study makes use of thermal cycle sequencing to sequence PCR-amplified DNA products in order to determine the level of similarity among members of the same serotype. We show that members of Hantaan and Seoul serotypes are over 92% homologous, irrespective of their host and geographical origin. Puumala sequences show a degree of homology ranging from 80 to 98%. Despite the variation in sequence at the nucleotide level, amino acids show an even higher level of conservation.

Typing of Hantaviruses from five continents by polymerase chain reaction

Hantavirus, a genus in the family Bunyaviridae, is comprised of at least four serologically distinct types: Hantaan, Seoul, Puumala and Prospect Hill. The present communication reports the use of polymerase chain reaction (PCR) for typing 27 independently isolated Hantaviruses from 5 different continents. Total cellular RNA was extracted from virus-infected Vero E6 cell monolayers by the acid guanidium thiocyanate-phenol-chloroform method. We have utilized 5 different sets of oligonucleotide primers ranging from 18 to 22 nucleotides in length; one set was specific for a conserved region of the S genomic segment and used as genus-specific primers, the other 4 sets of primers were designed from unique sequences of the M genomic segment such that each primer set was specific to only one serological type of Hantavirus. The PCR products were analyzed by restriction endonuclease digestion for further confirmation. We typed 10, 12, 3 and 1 isolates into Hantaan, Seoul, Puumala and Prospect Hill respectively. The results of PCR were 100% agreeable with that of serological typing, and thus, PCR can be used as an adjunct test with serological method(s) or an independent test for diagnosis and for typing of new isolates of Hantaviruses.

Comparison of the deduced gene products of the L, M and S genome segments of hantaviruses

The amino acid sequences deduced from all currently available nucleotide sequences of hantaviruses are compared. Comparisons of three large (L), eight medium (M) and five small (S) genome segments are included. A consensus sequence is provided, allowing easy identification of conserved and unique gene regions. The viruses included in this report represent four serologically distinct hantaviruses which are capable of causing severe, moderate, mild or no human disease.

Coexpression of the membrane glycoproteins G1 and G2 of Hantaan virus is required for targeting to the Golgi complex

To study the intracellular transport and targeting to the Golgi complex of the membrane glycoproteins G1 and G2 of Hantaan virus, we have expressed them together and separately using recombinant vaccinia viruses. When expressed from the same recombinant vaccinia virus, G1 and G2 were localized to the Golgi complex as analyzed by both immunofluorescence and subcellular fractionation. However, when the glycoproteins were expressed from separate recombinant viruses, both proteins remained in the endoplasmic reticulum. Using several monoclonal antibodies, it was found that G1 expressed alone did not acquire its correct conformation. Finally, if cells were coinfected with G1- and G2-expressing recombinant viruses, the proteins were again targeted to the Golgi complex. The N-linked glycans remained in all cases largely endoglycosidase-H sensitive. With none of the recombinant viruses were expression of the glycoproteins observed on the cell surface. Neither did chasing in the presence of cycloheximide result in the surface expression of G1 or G2. Our results indicate that for transport out of the endoplasmic reticulum and proper targeting to the Golgi complex, the two glycoproteins have to be coexpressed. The most likely interpretation is that G1 and G2 have to interact with each other in the endoplasmic reticulum in order to become transport competent.

Identification and characterization of a Hantavirus strain of unknown origin by nucleotide sequence analysis of the cDNA derived from the viral S RNA segment

The genetic characterization of a serologically Hantaan-like virus but of unknown origin (termed DX) was carried out by molecular cloning and nucleotide sequencing of the corresponding cDNA of the viral S RNA segment. The S RNA was found to be 1765 nucleotides long with 3' and 5' termini being complementary for 24 bases. The virus messenger-sense RNA contains one major open reading frame (ORF) encoding 428 amino acids or a 50 kD polypeptide. A comparison of the DX S RNA segment to those of Sapporo rat, Hantaan, Puumala/Hällnäs B1, and Prospect Hill viruses reveals 95.4, 71.3, 55.3, and 60.9% homology at the nucleotide sequence level, and 94.7, 80.1, 58.4, and 59.8% at the deduced amino acid sequence level. Thus Hantavirus strain DX is very closely related to Sapporo rat virus. We also analyzed the S RNA segments of these Hantaviruses for the presence of a second ORF encoding a potential nonstructural NSs protein. All potential second ORFs detected in the different S RNA segments differ substantially in length and position among the viruses, despite the high conservation of the nucleotide sequences and the overall structure of the nucleocapsid proteins. This suggests that the nucleocapsid protein is the only polypeptide encoded by Hantavirus S RNA segments, setting them apart from the other members of the Bunyaviridae family.

Molecular characterization of the M genomic segment of the Seoul 80-39 virus; nucleotide and amino acid sequence comparisons with other hantaviruses reveal the evolutionary pathway

The genomic M segment of Seoul 80-39 virus was characterized by cloning and nucleotide sequence analysis. The virion M RNA segment is 3651 nucleotides long with the 3' and 5' terminal sequences inversely complementary for 20 bases. A single open reading frame was detected in the viral complementary-sense RNA which can encode a polypeptide of 1133 amino acids. The Seoul 80-39 virus M segment was compared with the M segments of related viruses, Hantaan 76-118, Hallnas B1 and Sapporo Rat (SR-11) virus. Our results demonstrate a significant similarity between M RNA segments of the Seoul 80-39, Hantaan 76-118, Hallnas B1 and SR-11 viruses. The degree of conservation of both nucleic acid and protein sequences between these viruses reveals a close evolutionary relationship. Furthermore, it is evident that the serotypic profile of hantaviruses is determined by the rodent host species from which the virus was isolated and not by the geographical area.

Nucleotide sequence and coding capacity of the large (L) genomic RNA segment of Seoul 80-39 virus, a member of the hantavirus genus

The nucleotide sequence of the large (L) genomic RNA segment of Seoul 80-39 virus was determined from overlapping cDNA clones. The virion L RNA segment is 6530 nucleotides long. The 3' and 5' terminal sequences are inversely complementary for 15 bases. The viral complementary-sense RNA contains a single open reading frame from an AUG codon at nucleotide position 37-39 to a UAA stop codon at nucleotide position 6490-6492. This ORF could encode a polypeptide of 2151 amino acids (246,662 kDa) which likely corresponds to the L protein detected in purified viral particles (Elliott et al., 1984) and is assumed to be an RNA-dependent RNA polymerase molecule (Schmaljohn and Dalrymple, 1983). Comparison of the L protein of the Seoul 80-39 virus with the polymerase proteins encoded by other negative-stranded RNA viruses revealed 44% similarity only with the part of the Bunyamwera virus L protein (Elliott, 1989) and a very weak homology with the PB1 protein of influenza virus.

Rapid detection of genomic variations in different strains of hantaviruses by polymerase chain reaction techniques and nucleotide sequence analysis

The polymerase chain reaction (PCR) with subsequent nucleotide sequence analysis was employed to rapidly detect genomic variations among different Hantavirus strains. Using synthetic oligonucleotide primers derived from the M and S segment RNAs of nephropathia epidemica virus strain Hällnäs B1 (NEV) we succeeded in amplifying the corresponding sequences of Hantaan and Puumala viruses. The nucleotide sequences of the cDNAs derived from the Puumala M and S RNA segments were analyzed. It was found that the particular nucleotide sequences of Puumala M and S segments were 81% and 82% homologous to the corresponding genomic segments of NEV, respectively. The amino acid homology was 94% for both segments. In contrast, the degree of homology to the corresponding Hantaan M and S genomic RNA segments was 63% at the nucleotide level for both segments and 53 and 55% at the deduced amino acid level, respectively. This demonstrates that Puumala virus is very similar to NEV and significantly different from Hantaan virus at both the nucleotide and protein level.

Coding properties of the S and the M genome segments of Sapporo rat virus: comparison to other causative agents of hemorrhagic fever with renal syndrome

Three serologically distinct groups of hantaviruses have been associated with severe, moderate, and mild forms of hemorrhagic fever with renal syndrome (HFRS). To gain a better understanding of the genetic variation among these viruses, we cloned and sequenced the M and the S genome segments of Sapporo rat virus, an etiologic agent of moderate HFRS, and compared the predicted gene products to those of Hantaan virus, and the Hällnäs strain of Puumala virus, which are etiologic agents of severe and mild HFRS, respectively. The SR-11 S segment consisted of 1769 nucleotides and had an open reading frame (ORF) in the virus-complementary sense RNA with a coding capacity of 429 amino acids. Deduced amino acids from the SR-11 S segment ORF displayed 83% homology with those of Hantaan nucleocapsid (N) protein. Comparison of the S segment ORFs of all three viruses revealed 58% homology. No evidence for additional nonstructural protein(s) encoded by the SR-11 S segment was obtained. The SR-11 M segment consisted of 3651 nucleotides and had an ORF in the virus-complementary sense RNA with a coding capacity of 1134 amino acids. Amino acid sequences predicted from the SR-11 M segment ORF were 75% homologous with those encoding Hantaan G1 and G2 envelope glycoproteins. Comparison of the deduced amino acid sequences of the M segment ORFs of SR-11, Hantaan, and Hällnäs viruses revealed a 43% homology for amino acids constituting the G1 proteins and a 55% homology for amino acids constituting the G2 proteins of the three viruses. The envelope proteins of SR-11 virus were localized within the M segment ORF by amino-terminal sequence analysis of purified G1 and G2. G1 initiated at amino acid 17 and G2 at amino acid 647 within the ORF. Five potential asparagine-linked glycosylation sites were identified in the SR-11 G1 coding sequences, four of which were conserved between Hantaan and SR-11 viruses and three of which were conserved among all three viruses. One potential glycosylation site was identified in the SR-11 G2 coding sequences and was conserved among Hantaan, SR-11 and Hällnäs viruses. Cysteine residues were highly conserved within the M segment ORFs of all three viruses, suggesting a similar structure and function of the G1 and G2 proteins.

Molecular characterization of the RNA S segment of nephropathia epidemica virus strain Hällnäs B1

The S segment RNA of nephropathia epidemica virus (NEV) strain Hällnäs B1 was isolated by molecular cloning of the corresponding cDNA. The RNA is 1785 nucleotides long with the 3' and 5' termini being complementary for 23 bases. The viral messenger-sense RNA contains one major open reading frame (ORF) with a coding capacity of 433 amino acids encoding a 49-kDa polypeptide. Compared to the Hantaan S segment cDNA sequence there is a nucleotide homology of 60 and 61% at the amino acid level. Many of the amino acid differences are conservative exchanges. The C-termini of the NEV and Hantaan nucleocapsid proteins are nearly identical and the hydrophilicity profiles are very similar. In contrast, the following differences are significant: The calculated isoelectric points of the NEV and Hantaan nucleocapsid proteins are 5.6 and 6.7, respectively. The most prominent antigenic determinants predicted by the hydrophilicity profiles are located close to the C-terminus of NEV and close to the N-terminus of Hantaan virus nucleocapsid polypeptides.

Determination of the coding capacity of the M genome segment of nephropathia epidemica virus strain Hällnäs B1 by molecular cloning and nucleotide sequence analysis

The M genome RNA segment of nephropathia epidemica virus (NEV) strain Hällnäs B1 was characterized by molecular cloning and DNA nucleotide sequencing of the corresponding cDNA clones. The size of the M RNA segment is 3682 nucleotides. The 3' and 5' terminal sequences are complementary for 21 bases and their predicted secondary structure is very stable. The viral complementary messenger RNA possesses a single long open reading frame with a coding capacity of 1148 amino acids (polypeptide of 126 kDa). A comparison of the NEV M segment to that of Hantaan virus strain 76-118 reveals 61% sequence homology at the nucleotide level and 53% at the deduced amino acid level. Four out of five potential asparagine-linked glycosylation sites of the encoded glycoproteins have been conserved between NEV and Hantaan M. The isoelectric points (IEP) are nearly identical. Furthermore it was found that 90% of all cysteine residues have been conserved. Putative NEV G1 and G2 are preceded by a short hydrophobic sequence as shown for G1 and G2 of Hantaan virus. Hydrophilicity profiles of the two segments are of striking similarity. These data indicate that NEV- and Hantaan virus M-encoded polypeptides seem to be very similar in structure and function despite the relatively low amino acid sequence homology.