Characterization of a neuraminidase-deficient influenza a virus as a potential gene delivery vector and a live vaccine

We recently identified a packaging signal in the neuraminidase (NA) viral RNA (vRNA) segment of an influenza A virus, allowing us to produce a mutant virus [GFP(NA)-Flu] that lacks most of the NA open reading frame but contains instead the gene encoding green fluorescent protein (GFP). To exploit the expanding knowledge of vRNA packaging signals to establish influenza virus vectors for the expression of foreign genes, we studied the replicative properties of this virus in cell culture and mice. Compared to wild-type virus, GFP(NA)-Flu was highly attenuated in normal cultured cells but was able to grow to a titer of >10(6) PFU/ml in a mutant cell line expressing reduced levels of sialic acid on the cell surface. GFP expression from this virus was stable even after five passages in the latter cells. In intranasally infected mice, GFP was detected in the epithelial cells of nasal mucosa, bronchioles, and alveoli for up to 4 days postinfection. We attribute the attenuated growth of GFP(NA)-Flu to virion aggregation at the surface of bronchiolar epithelia. In studies to test the potential of this mutant as a live attenuated influenza vaccine, all mice vaccinated with >/==" BORDER="0">10(5) PFU of GFP(NA)-Flu survived when challenged with lethal doses of the parent virus. These results suggest that influenza virus could be a useful vector for expressing foreign genes and that a sialidase-deficient virus may offer an alternative to the live influenza vaccines recently approved for human use.     

Evolution of a defective virus from a cellular defense mechanism

Adeno-associated virus is a defective DNA virus, requiring the presence of a helper virus in order to replicate. In this paper we consider its origin in light of several observations, most notably the following: its own replication inhibits that of the helper virus; its DNA structure resembles that of transposable (moveable) elements; and extrachromosomal circles of DNA, about the size of adeno-associated virus DNA, have been found recently in eukaryotic cells. We have arrived at a hypothesis consisting of two main ideas: (1) that cells may use transposable DNA as a mechanism of defense against viral attack, and (2) that adeno-associated virus may have evolved directly from this cellular defense mechanism.     

Characterization of a virion protein kinase as a virus-specified enzyme.

Antibodies which completely inhibited the enzymatic activity of the protein kinase associated with virions of frog virus were obtained by immunization of rabbits with the purified enzyme. This inhibition provided a specific probe for the frog virus protein kinase, since this antiserum had no inhibitory effect on a variety of other protein kinases, including the activity of uninfected cells, or the protein kinase associated with vesicular stomatitis virus or vaccinia virus cultivated in the same cell line as frog virus. The frog virus protein kinase was characterized as a virus-specified protein on the basis of the following observations: (a) the virion protein kinase was antigenically distinct from essentially all of the protein kinase expressed in uninfected cells; (b) following infection by frog virus more than a 15-fold increase was detected in the specific activity of intracellular protein kinase and most of this activity was antigenically related to the virion enzyme; (c) when frog virus was grown in cells derived from widely different species, the antigenic and biochemical specificities of the virion protein kinase remained identical; and (d) screening of cells infected with different temperature-sensitive mutants of frog virus indicated that certain viral mutants failed to synthesize this protein kinase when cultivated at the nonpermissive temperature.     

Generation of a recombinant cytomegalovirus for expression of a hantavirus glycoprotein

A cytomegalovirus (CMV) was isolated from its natural host, Peromyscus maniculatus, and was designated Peromyscus CMV (PCMV). A recombinant PCMV was constructed that contained Sin Nombre virus glycoprotein G1 (SNV-G1) fused in frame to the enhanced green fluorescent protein (EGFP) gene inserted into a site homologous to the human CMV UL33 (P33) gene. The recombinant CMV was used for expression and immunization of deer mice against SNV-G1. The results of the study indicate that P. maniculatus could be infected with as few as 10 virus particles of recombinant virus. Challenge of P. maniculatus with either recombinant or wild-type PCMV produced no overt pathology in infected animals. P. maniculatus immunized with recombinant virus developed an antibody response to SNV and EGFP. When rechallenged with recombinant virus, animals exhibited an anamnestic response against SNV. Interestingly, a preexisting immune response against PCMV did not prevent reinfection with recombinant PCMV.     

Use of a mammalian internal ribosomal entry site element for expression of a foreign protein by a transfectant influenza virus.

The ribonucleoprotein transfection system for influenza virus allowed us to construct two influenza A viruses, GP2/BIP-NA and HGP2/BIP-NA, which contained bicistronic neuraminidase (NA) genes. The mRNAs derived from the bicistronic NA genes have two different open reading frames (ORFs). The first ORF encodes a foreign polypeptide (GP2 or HGP2) containing amino acid sequences derived from the gp41 protein of human immunodeficiency virus type 1. The second ORF encodes the NA protein; its translation is achieved via an internal ribosomal entry site which is derived from the 5' noncoding region of the human immunoglobulin heavy-chain-binding protein mRNA. The GP2 (79 amino acids) and HGP2 (91 amino acids) polypeptides are expressed in cells infected with the corresponding transfectant virus. The HGP2 polypeptide, which contains transmembrane and cytoplasmic domains identical to those of the hemagglutinin (HA) protein of influenza A/WSN/33 virus, is packaged into virus particles. This novel influenza virus system involving an internal ribosomal entry site element may afford a way to express a variety of foreign genes in mammalian cells.     

Characterization of a siberian virus isolated from a patient with progressive chronic tick-borne encephalitis

A strain of Tick-borne encephalitis virus designated Zausaev (Za) was isolated in Siberia from a patient who died of a progressive (2-year) form of tick-borne encephalitis 10 years after being bitten by a tick. The complete genomic sequence of this virus was determined, and an attempt was made to correlate the sequence with the biological characteristics of the virus. Phylogenetic analysis demonstrated that this virus belongs to the Siberian subtype of Tick-borne encephalitis virus. Comparison of Za virus with two related viruses, a Far Eastern isolate, Sofjin, and a Siberian isolate, Vasilchenko, revealed differences among the three viruses in pathogenicity for Syrian hamsters, cytopathogenicity for PS cells, plaque morphology, and the electrophoretic profiles of virus-specific nonstructural proteins. Comparative amino acid alignments revealed 10 individual amino acid substitutions in the Za virus polyprotein sequence that were different from those of other tick-borne flaviviruses. Notably, the dimeric form of the Za virus NS1 protein migrated in polyacrylamide gels as a heterogeneous group of molecules with a significantly higher electrophoretic mobility than those of the Sofjin and Vasilchenko viruses. Two amino acid substitutions, T(277)-->V and E(279)-->G, within the NS1 dimerization domain are probably responsible for the altered oligomerization of Za virus NS1. These studies suggest that the patient from whom Za virus was isolated died due to increased pathogenicity of the latent virus following spontaneous mutagenesis.     

Isolation and Characterization of a Neuropathogenic Simian Immunodeficiency Virus Derived from a Sooty Mangabey

Transfusion of blood from a simian immunodeficiency virus (SIV)- and simian T-cell lymphotropic virus-infected sooty mangabey (designated FGb) to rhesus and pig-tailed macaques resulted in the development of neurologic disease in addition to AIDS. To investigate the role of SIV in neurologic disease, virus was isolated from a lymph node of a pig-tailed macaque (designated PGm) and the cerebrospinal fluid of a rhesus macaque (designated ROn2) and passaged to additional macaques. SIV-related neuropathogenic effects were observed in 100% of the pig-tailed macaques inoculated with either virus. Lesions in these animals included extensive formation of SIV RNA-positive giant cells in the brain parenchyma and meninges. Based upon morphology, the majority of infected cells in both lymphoid and brain tissue appeared to be of macrophage lineage. The virus isolates replicated very well in pig-tailed and rhesus macaque peripheral blood mononuclear cells (PBMC) with rapid kinetics. Differential replicative abilities were observed in both PBMC and macrophage populations, with viruses growing to higher titers in pig-tailed macaque cells than in rhesus macaque cells. An infectious molecular clone of virus derived from the isolate from macaque PGm (PGm5.3) was generated and was shown to have in vitro replication characteristics similar to those of the uncloned virus stock. While molecular analyses of this virus revealed its similarity to SIV isolates from sooty mangabeys, significant amino acid differences in Env and Nef were observed. This virus should provide an excellent system for investigating the mechanism of lentivirus-induced neurologic disease.     

Superinfection of a chimpanzee with a second strain of human immunodeficiency virus.

Two chimpanzees, one (C-499) infected with the acquired immunodeficiency syndrome-associated retrovirus type 2 (ARV-2) strain of human immunodeficiency virus (HIV) and one (C-560) infected with the lymphadenopathy-associated virus type 1 (LAV-1) strain of HIV, were inoculated with approximately 10(4) tissue culture infective doses of the reciprocal strain. At the time of the second inoculation, both chimpanzees had high titers of HIV-specific antibodies, including antibodies that neutralized both virus strains. After inoculation of the second strain of HIV, the antibody titers in both chimpanzees increased 4- to 10-fold, and in one chimpanzee (C-499), the numbers of infectious peripheral blood mononuclear cells (PBMC) increased 1,000-fold to levels that are comparable with those observed after primary HIV infections. By restriction enzyme analysis of virus recovered from PBMC, both ARV-2 and LAV-1 were identified in C-499, thus demonstrating that superinfection had occurred.     

High-throughput analysis of mumps virus and the virus-specific monoclonal antibody on the arrays of a cationic polyelectrolyte with a spectral SPR biosensor

We investigated the potential use of a spectral surface plasmon resonance (SPR) biosensor in a high-throughput analysis of mumps virus and a mumps virus-specific mAb on the arrays of a cationic polyelectrolyte, poly(diallyldimethylammonium chloride) (PDDA). The PDDA surface was constructed by electrostatic adsorption of the polyelectrolyte onto a monolayer of 11-mercaptoundecanoic acid (MUA). Poly-L-lysine was also adsorbed onto the MUA monolayer and compared with the PDDA surface in the capacity of mumps virus immobilization. The PDDA surface showed a higher adsorption of mumps virus than the poly-L-lysine surface. The SPR signal caused by the virus binding onto the PDDA surface was proportional to the concentration of mumps virus from 0.5 x 10(5) to 14 x 10(5) pfu/mL. The surface structure of the virus arrays was visualized by atomic force microscopy. Then, a dose-dependent increase in the SPR signal was observed when various concentrations of the antimumps virus antibody in buffer or human serum were applied to the virus arrays, and their interaction was specific. Thus, it is likely that the spectral SPR biosensor based on the cationic polyelectrolyte surface may provide an efficient system for a high-throughput analysis of intact virus and serodiagnosis of infectious diseases.     

Complementation of a binding-defective retrovirus by a host cell receptor mutant

The entry of ecotropic murine leukemia virus (MLV) into cells requires the interaction of the envelope protein (Env) with its receptor, mouse cationic amino acid transporter 1 (mATRC1). An aspartic acid-to-lysine change at position 84 (D84K) of ecotropic Moloney MLV Env abolishes virus binding and infection. We recently identified lysine 234 (rK234) in mATRC1 as a residue that influences virus binding and infection. Here we show that D84K virus infection increased 3,000-fold on cells expressing receptor with an rK234A change and 100,000-fold on cells expressing an rK234D change. The stronger complementation of D84K virus infection by rK234D than by the rK234A receptor suggests that although the major reason for loss of infection of D84K and D84R virus is due to steric hindrance and charge repulsion, the loss of an interaction of D84 with receptor appears to contribute as well. Taken together, these results indicate that D84 is very close to rK234 of mATRC1 in the bound complex and there is likely an interaction between them. The definitive localization of the receptor binding site on SU should facilitate the design of chimeric envelope proteins that target infection to new receptors by replacing the receptor binding site with an exogenous ligand sequence.     

Comparison of the Neurovirulence of a Vaccine and a Wild-Type Mumps Virus Strain in the Developing Rat Brain

Prior to the adoption of widespread vaccination programs, mumps virus was the leading cause of virus-induced central nervous system (CNS) disease. Mumps virus-associated CNS complications in vaccinees continue to be reported; outside the United States, some of these complications have been attributed to vaccination with insufficiently attenuated neurovirulent vaccine strains. The development of potentially neurovirulent, live, attenuated mumps virus vaccines stems largely from the lack of an animal model that can reliably predict the neurovirulence of mumps virus vaccine candidates in humans. The lack of an effective safety test with which to measure mumps virus neurovirulence has also hindered analysis of the neuropathogenesis of mumps virus infection and the identification of molecular determinants of neurovirulence. In this report we show, for the first time, that mumps virus infection of the neonatal rat leads to developmental abnormalities in the cerebellum due to cerebellar granule cell migration defects. The incidence of the cerebellar abnormalities and other neuropathological and clinical outcomes of mumps virus infection of the neonatal rat brain demonstrated the ability of this model to distinguish neurovirulent (Kilham) from nonneurovirulent (Jeryl Lynn) mumps virus strains. Thus, this neonatal rat model may prove useful in evaluating the neurovirulence potential of new live, attenuated vaccine strains and may also be of value in elucidating the molecular basis of mumps virus neurovirulence.     

Building a virus from scratch: assembly of an infectious virus using purified components in a rigorously defined biochemical assay system

The assembly of double-stranded DNA (dsDNA) viruses such as poxvirus, the herpesviruses and many bacteriophages is a complex process that requires the coordinated activities of numerous proteins of both viral and host origin. Here, we report the assembly of an infectious wild-type lambda virus using purified proteins and commercially available DNA, and optimization of the assembly reaction in a rigorously defined biochemical system. Seven proteins, purified procapsids and tails, and mature lambda DNA are necessary and sufficient for efficient virus assembly in vitro. Analysis of the reaction suggests that (i) virus assembly in vitro is optimal under conditions that faithfully mimic the intracellular environment within an Escherichia coli cell, (ii) concatemeric DNA is required for the successful completion of virus assembly, (iii) several of the protein components oligomerize concomitant with their step-wise addition to the nascent virus particle and (iv) tail addition is the rate-limiting step in virus assembly. Importantly, the assembled virus may enter either of the developmental pathways (lytic or lysogenic) expected of a lambda virion. Thus, we demonstrate for the first time that a wild-type, complex DNA virus may be assembled from purified components under defined biochemical conditions. This system provides a powerful tool to characterize, at the molecular level, the step-by-step processes required to assemble an infectious virus particle. Given the remarkable similarities between dsDNA bacteriophage and eukaryotic dsDNA viruses, characterization of the lambda system has broad biological implications in our understanding of virus development at a global level.     

Characterization of a recombinant herpes simplex virus which expresses a glycoprotein D lacking asparagine-linked oligosaccharides.

Glycoprotein D (gD) is an envelope component of herpes simplex virus essential for virus penetration. gD contains three sites for addition of asparagine-linked carbohydrates (N-CHO), all of which are utilized. Previously, we characterized mutant forms of herpes simplex virus type 1 gD (gD-1) lacking one or all three N-CHO addition sites. All of the mutants complemented the infectivity of a gD-minus virus, F-gD beta, to the same extent as wild-type gD. Here, we show that recombinant viruses containing mutations in the gD-1 gene which eliminate the three N-CHO signals are viable. Two such viruses, called F-gD(QAA)-1 and F-gD(QAA)-2, were independently isolated, and the three mutations in the gD gene in one of these viruses were verified by DNA sequencing. We also verified that the gD produced in cells infected by these viruses is devoid of N-CHO. Plaques formed by both mutants developed more slowly than those of the wild-type control virus, F-gD(WT), and were approximately one-half the size of the wild-type. One mutant, F-gD(QAA)-2, was selected for further study. The QAA mutant and wild-type gD proteins extracted from infected cells differed in structure, as determined by the binding of monoclonal antibodies to discontinuous epitopes. However, flow cytometry analysis showed that the amount and structure of gD found on infected cell surfaces was unaffected by the presence or absence of N-CHO. Other properties of F-gD(QAA)-2 were quite similar to those of F-gD(WT). These included (i) the kinetics of virus production as well as the intracellular and extracellular virus titers; (ii) the rate of virus entry into uninfected cells; (iii) the levels of gB, gC, gE, gH, and gI expressed by infected cells; and (iv) the turnover time of gD. Thus, the absence of N-CHO from gD-1 has some effect on its structure but very little effect on its function in virus infection in cell culture.     

Replication of Herpes-Type Virus in a Burkitt Lymphoma Cell Line

Replication of the herpes-type virus in the P3HR-1 Burkitt lymphoma cell line was studied. The cell cultures with 10(6) viable cells/ml were incubated at 33 C for 15 days. The amount of virus in both the cell and fluid portions of the cultures was determined by the loop-drop particle-counting procedure with electron microscopy. An apparent growth curve of the virus was constructed. The maximal cell-associated virus, 10(10) virus particles in an 80-ml culture, was observed after 9 days of incubation. The maximal extracellular virus, 2.5 x 10(9) particles per culture, was observed at the 12th day. About 10% of the released virus particles were enveloped. Under these conditions, there was little or no cell multiplication, but the percentage of immunofluorescent cells reactive to a selected human serum (probably indicating the presence of virus in the cells) increased to a maximum of 50% at the 9th day.     

Cellular Origin of a Mouse Leukemia Viral Ribonucleic Acid

Mouse erythroblastosis virus, a member of the mouse leukemia virus group, was obtained from chronically infected C(3)H mouse embryo cells and purified on sucrose gradients. The ribonucleic acid (RNA) extracted from ribonuclease-treated virus consisted of a rapidly sedimenting (72S) species and a more slowly sedimenting component (4 to 30S). The 72S RNA did not contain base sequences homologous to deoxyribonucleic acid (DNA) from infected cells as determined by hybridization studies. In contrast, the slowly sedimenting RNA enclosed within the virus had base sequences homologous to DNA from infected and uninfected C(3)H mouse embryo cells.     

Chemoenzymatic synthesis and application of a sialoglycopolymer with a chitosan backbone as a potent inhibitor of human influenza virus hemagglutination

Sialoglycopeptide (SGP) is referred as the glycopeptide in hen's egg yolk, which has an N-linked, complex-type, disialyl biantennary oligosaccharide with an alpha-(2-->6)-sialyl N-acetyllactosamine residue. The residue is known as a binding ligand of type-A human influenza virus hemagglutinin. We describe herein a simple synthesis of a sialoglycopolymer with a chitosan backbone as a potent inhibitor of human influenza virus hemagglutination that makes use of the natural source ingredient, SGP, and the transglycosylation activity of endo-beta-N-acetylglucosaminidase from Mucor hiemalis (Endo-M). Its inhibitiory activity for influenza virus hemagglutination is 40 times higher than that of SGP, and its competitive inhibition is determined to be over 300 times higher than that of fetuin. These results indicate that a sialoglycopolymer having a multivalent sialo-oligosaccharide could potentially be used for the prevention of influenza virus infection.     

Phloem Unloading in Sink Leaves of Nicotiana benthamiana: Comparison of a Fluorescent Solute with a Fluorescent Virus

Using noninvasive imaging techniques, we compared phloem unloading of the membrane-impermeant, fluorescent solute carboxyfluorescein (CF) with that of potato virus X expressing the gene for the green fluorescent protein. Although systemic virus transport took considerably longer to occur than did CF transport, unloading of both solute and virus occurred predominantly from the class III vein network, a highly branched veinal system found between class II veins. The minor veins (classes IV and V) played no role in solute or virus import but were shown to be functional in xylem transport at the time of import by labeling with Texas Red dextran. After virus exit from the class III phloem, the minor veins eventually became infected by cell-to-cell virus movement from the mesophyll. During the sink/source transition, phloem unloading of CF was inhibited from class III veins before the cessation of phloem import through them, suggesting a symplastic isolation of the phloem in class III veins before its involvement in export. The progression of the sink/source transition for carbon was unaffected by the presence of the virus in the sink leaf. However, the virus was unable to cross the sink/source boundary for carbon that was present at the time of viral entry, suggesting a limited capacity for cell-to-cell virus movement into the apical (source) region of the leaf. A functional model of the sink/source transition in Nicotiana benthamiana is presented. This model provides a framework for the analysis of solute and virus movement in leaves.     

Characterisation of a variant of zucchini yellow fleck virus (ZYFV), a potyvirus causing a wilt disease of melons in Israel*

A flexuous filamentous virus 750 nm in length was isolated from field-grown melons (Cucumis melo L.) and squirting cucumber (Ecballium elaterium L.). Infection of melon seedlings of most commercial varieties resulted in a lethal wilting, but late infections gave dieback. The virus infected systemically all economically important cucurbit crops. Its coat protein consists of a single polypeptide, 34 500 D in size, encapsidating a single stranded RNA genome of 10.1 kb. Antiserum against the Italian zucchini yellow fleck virus (ZYFV) reacted specifically with the Israeli isolate in both ISEM and Western blot. The virus was aphid transmissible in a non-persistent manner. Based on host range, host reaction and serological data, it is suggested that the virus described is an Israeli variant of ZYFV.