Hantavirus nucleocapsid protein is expressed as a membrane-associated protein in the perinuclear region.

Black Creek Canal virus (BCCV) is a New World hantavirus which is associated with hantavirus pulmonary syndrome. We have examined the site of expression of the BCCV nucleocapsid protein (NBCCV) in the absence of BCCV glycoproteins and found that the majority of the protein is localized to the Golgi region. Immunofluorescence analysis of BHK21 cells expressing the NBCCV and La Crosse virus nucleocapsid protein (NLACV) showed different intracellular localization patterns of these proteins within the same cell: NLACV is cytoplasmic, whereas NBCCV is perinuclear. NBCCV was found to be colocalized with alpha-mannosidase II, a marker for the Golgi complex. Also, NBCCV was found to be associated with microsomal membranes following cell fractionation. Sedimentation analysis in density gradients revealed that the membrane association of NBCCV is sensitive to treatments with high-salt and high-pH solutions, which indicates that NBCCV is a peripheral membrane protein. Analysis of NBCCV truncation mutants revealed that the 141-amino-acid C-terminal portion of this protein was capable of targeting green fluorescent protein to the perinuclear region. The difference in the intracellular localization between the NBCCV and NLACV proteins suggests that the mechanisms involved in the morphogenesis of New World hantaviruses are distinct from that documented for other members of the Bunyaviridae family.

Identification of alpha-dystroglycan as a receptor for lymphocytic choriomeningitis virus and Lassa fever virus.

A peripheral membrane protein that is interactive with lymphocytic choriomeningitis virus (LCMV) was purified from cells permissive to infection. Tryptic peptides from this protein were determined to be alpha-dystroglycan (alpha-DG). Several strains of LCMV and other arenaviruses, including Lassa fever virus (LFV), Oliveros, and Mobala, bound to purified alpha-DG protein. Soluble alpha-DG blocked both LCMV and LFV infection. Cells bearing a null mutation of the gene encoding DG were resistant to LCMV infection, and reconstitution of DG expression in null mutant cells restored susceptibility to LCMV infection. Thus, alpha-DG is a cellular receptor for both LCMV and LFV.

Role of actin microfilaments in Black Creek Canal virus morphogenesis.

We have investigated the involvement of cytoskeletal proteins in the morphogenesis of Black Creek Canal virus (BCCV), a New World hantavirus. Immunofluorescent staining of BCCV-infected cells revealed a filamentous pattern of virus antigen, the appearance of which was sensitive to treatment with cytochalasin D, an actin microfilament-depolymerizing drug. Double immunofluorescence staining of BCCV-infected Vero cells with anti-BCCV nucleocapsid (N) monoclonal antibody and phalloidin revealed a colocalization of the BCCV N protein with actin microfilaments. A similar, though less prominent, filamentous pattern was observed in BHK21 cells transiently expressing the BCCV N protein alone but not in cells expressing the BCCV G1 and G2 glycoproteins. Moreover, the association of the N protein with actin microfilaments was confirmed by coimmunoprecipitation with beta-actin-specific antibody. Treatment of the BCCV-infected Vero cells at 3 days postinfection with cytochalasin D decreased the yield of released BCCV by 94% relative to the yield from untreated cells. Pretreatment of Vero cells with cytochalasin D prior to and during BCCV adsorption and entry had no effect on the outcome of virus production. These results indicate that actin filaments may play an important role in hantavirus assembly and/or release.

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.

Polarized entry and release in epithelial cells of Black Creek Canal virus, a New World hantavirus.

Black Creek Canal (BCC) virus is a newly identified hantavirus from Florida which is carried by the cotton rat (Sigmodon hispidus) and is associated with hantavirus pulmonary syndrome (HPS). We have investigated the interaction of BCC virus with polarized epithelial cells to examine whether entry and release of this virus occur at specific plasma membrane domains. The polarized Vero C1008 monkey kidney cell line was grown on permeable filters and infected with BCC virus either through the apical or basolateral surface. As shown by indirect immunofluorescence and radioimmunoprecipitation analysis, cells infected through the apical surface demonstrated a high level of susceptibility to BCC virus infection. In contrast, Vero C1008 cells infected basolaterally exhibited a barely detectable level of BCC virus-synthesized proteins. Titration of virus from apical and basolateral media of infected cells has demonstrated that virus titers released from the apical surface are about 1,200-fold greater than the titer of virus released into the basolateral media. The site of BCC virus release from polarized cells is, therefore, different from that previously described for release of other members of the family Bunyaviridae and may reflect one of the determinants of hantavirus pathogenesis. In addition, we have shown that BCC viral glycoproteins are expressed at the plasma membrane on the apical surface of polarized cells. Electron microscopy studies of the infected cells revealed evidence of BCC virus budding at the plasma membrane. This strongly indicates that, in contrast to most other members of the Bunyaviridae, BCC virus is assembled at the plasma membrane. Since the same site of virus assembly was recently described for Sin Nombre virus, it is likely that all of the new American hantaviruses associated with HPS utilize this same type of virus maturation.

Hantavirus pulmonary syndrome in Florida: association with the newly identified Black Creek Canal virus.

Hantavirus pulmonary syndrome (HPS) is a recently recognized viral zoonosis. The first recognized cases were caused by a newly described hantavirus. Sin Nombre virus (previously known as Muerto Canyon virus), isolated from Peromyscus maniculatus (deer mouse). We describe a 33-year-old Floridian man who resided outside the ecologic range of P maniculatus but was found to have serologic evidence of a hantavirus infection during evaluation of azotemia associated with adult respiratory distress syndrome. Small mammal trapping conducted around this patient's residence demonstrated the presence of antihantaviral antibodies in 13% of Sigmodon hispidus [cotton rat). Serologic testing using antigen derived from the Black Creek Canal hantavirus subsequently isolated from this rodent established that this patient was acutely infected with this new pathogenic American hantavirus. HPS is not confined to the geographical distribution of P maniculatus and should be suspected in individuals with febrile respiratory syndromes, perhaps associated with azotemia, throughout the continental United States.

Genetic and serologic analysis of Black Creek Canal virus and its association with human disease and Sigmodon hispidus infection.

Black Creek Canal (BCC) virus is a newly identified virus associated with hantavirus pulmonary syndrome (HPS) in the southeastern United States. Nucleotide sequences were determined for the complete S and M and partial L genomic segments of a BCC virus isolate. Phylogenetic analysis indicates that each of the virus segments is unique, and there is no evidence of genetic reassortment having occurred between this and other previously characterized hantaviruses. All hantavirus-seropositive, wild-caught Sigmodon hispidus which were tested by polymerase chain reaction for the presence of BCC virus RNA were found to be positive, consistent with a chronic virus infection. This finding, together with serologic evidence, confirms S. hispidus as the primary rodent reservoir of this virus. Nucleotide sequence analysis of these PCR products indicates that BCC virus is genetically diverse and may pose a public health threat throughout much of the extensive range of this rodent species. Immunoprecipitation analysis demonstrated the presence of G1-, G2-, and N-specific antibodies in sera from BCC virus-infected patients with HPS and naturally infected S. hispidus. Comparison of the patterns of protein immunoprecipitation obtained with human acute- and convalescent-phase sera suggests that G1- and G2-specific antibodies increase relative to N-specific antibodies during the course of infection. The ratio of G1 to N protein immunoprecipitation by rodent or human acute-phase sera allowed differentiation of BCC and Sin Nombre virus infections.

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.

Rabies virus glycoprotein gene contains a long 3' noncoding region which lacks pseudogene properties.

Analysis of a limited number of laboratory strains of rabies virus had demonstrated the presence of a genome region bounded by two transcription termination and polyadenylation-like (TTP) signals (approximately 400 to 450 nucleotides apart) which was located between the end of the glycoprotein (G) coding sequence and the beginning of the L polymerase coding sequence. Although this region had been suggested to represent a remnant or pseudogene (psi), no detailed analysis had been carried out to examine this possibility. Here we present the nucleotide sequence analysis of this genome region for several laboratory rabies virus strains and a large number of diverse rabies viruses detected directly in brain tissue of naturally infected animals. Only one distinct lineage of the laboratory strains and none of the wild-type rabies viruses contained the upstream TTP-like signal, indicating that only the downstream TTP motif is the authentic G mRNA transcription termination and polyadenylation and signal. Phylogenetic analysis of sequence differences provided no evidence of laboratory strains containing the two TTP-like signals being ancestral to any of the viruses possessing only the downstream TTP sequence motif. These data indicate that this region of the rabies virus genome encodes a G mRNA with a long 3' noncoding region with no evidence of a pseudogene.