TNF superfamily members promote hepatitis C virus entry via an NF-κB and myosin light chain kinase dependent pathway.

Preventing virally induced liver disease begins with an understanding of the host factors that define susceptibility to infection. Hepatitis C virus (HCV) is a global health issue, with an estimated 170 million infected individuals at risk of developing liver disease including fibrosis and hepatocellular carcinoma. The liver is the major reservoir supporting HCV replication and this hepatocellular tropism is defined by HCV engagement of cellular entry receptors. Hepatocytes are polarized in vivo and this barrier function limits HCV entry. We previously reported that activated macrophages promote HCV entry into polarized hepatocytes via a TNF-α-dependent process; however, the underlying mechanism was not defined. In this study, we show that several TNF superfamily members, including TNF-α, TNF-ß, TWEAK and LIGHT, promote HCV entry via NF-κB-mediated activation of myosin light chain kinase (MLCK) and disruption of tight junctions. These observations support a model where HCV hijacks an inflammatory immune response to stimulate infection and uncovers a role for NF-κB-MLCK signalling in maintaining hepatocellular tight junctions.

Lentiviral hepatitis B pseudotype entry requires sodium taurocholate co-transporting polypeptide and additional hepatocyte-specific factors.

Hepatitis B virus (HBV) is one of the world's major unconquered infections, resulting in progressive liver disease, and current treatments rarely cure infection. A limitation to discovering new therapies is our limited knowledge of HBV entry and dissemination pathways that hinders the development of in vitro culture systems. To address this gap in our understanding we optimized the genesis of infectious lentiviral pseudoparticles (HBVpps). The recent discovery that the bile salt transporter sodium taurocholate co-transporting polypeptide (NTCP) acts as a receptor for HBV enabled us to assess the receptor dependency of HBVpp infection. HBVpps preferentially infect hepatoma cells expressing NTCP, whereas other non-liver cells engineered to express NTCP do not support infection, suggesting that additional hepatocyte-specific factors are required for HBVpp internalization. These results highlight the value of the HBVpp system to dissect the pathways of HBV entry and dissemination.

Hepatoma polarization limits CD81 and hepatitis C virus dynamics.

Many viruses target the polarized epithelial apex during host invasion. In contrast, hepatitis C virus (HCV) engages receptors at the basal surface of hepatocytes in the polarized liver parenchyma. Hepatocyte polarization limits HCV entry by undefined mechanism(s). Given the recent reports highlighting a role for receptor mobility in pathogen entry, we studied the effect(s) of hepatocyte polarization on viral receptor and HCV pseudoparticle (HCVpp) dynamics using real-time fluorescence recovery after photobleaching and single particle tracking. Hepatoma polarization reduced CD81 and HCVpp dynamics at the basal membrane. Since cell polarization is accompanied by changes in the actin cytoskeleton and CD81 links to actin via its C-terminus, we studied the dynamics of a mutant CD81 lacking a C-terminal tail (CD81(ΔC)) and its effect(s) on HCVpp mobility and infection. CD81(ΔC) showed an increased frequency of confined trajectories and a reduction of Brownian diffusing molecules compared to wild-type protein in non-polarized cells. However, these changes were notobserved in polarized cells. HCVpp showed a significant reduction in Brownian diffusion and infection of CD81(ΔC) expressing non-polarized cells. In summary, these data highlight the dynamic nature of CD81 and demonstrate a role for CD81 lateral diffusion to regulate HCV infection in a polarization-dependent manner.

Hepatitis C virus and the brain.

Hepatitis C virus (HCV) is an enveloped, positive-strand RNA virus of the family Flaviviridae that primarily infects hepatocytes, causing acute and chronic liver disease. HCV is also associated with a variety of extrahepatic symptoms including central nervous system (CNS) abnormalities, cognitive dysfunction, fatigue and depression. These symptoms do not correlate with the severity of liver disease and are independent of hepatic encephalopathy. HCV RNA has been associated with CNS tissue, and reports of viral sequence diversity between brain and liver tissue suggest independent viral evolution in the CNS and liver. This review will explore the data supporting HCV infection of the CNS and how this fits into our current understanding of HCV pathogenesis.

Dissociation of gp120 from HIV-1 virions induced by soluble CD4.

The CD4 antigen is the high affinity cellular receptor for the human immunodeficiency virus type-1 (HIV-1). Binding of recombinant soluble CD4 (sCD4) or the purified V1 domain of sCD4 to the surface glycoprotein gp120 on virions resulted in rapid dissociation of gp120 from its complex with the transmembrane glycoprotein gp41. This may represent the initial stage in virus-cell and cell-cell fusion. Shedding of gp120 from virions induced by sCD4 may also contribute to the mechanism by which these soluble receptor molecules neutralize HIV-1.

Primary hepatocytes as targets for hepatitis C virus replication.

Much of our current understanding of hepatitis C virus (HCV) replication has hailed from the use of a small number of cloned viral genomes and transformed hepatoma cell lines. Recent evidence suggests that lipoproteins play a key role in the HCV life cycle and virus particles derived from the sera of infected patients exist in association with host lipoproteins. This report will review the literature on HCV replication in primary hepatocytes and transformed cell lines, focusing largely on host factors defining particle entry.

Characterization of HIV-1 neutralization escape mutants.

Infection by molecularly cloned HIV-1, in the presence of a high-titre neutralizing monoclonal antibody (MAb), resulted in the selection of plaques in MT4 cells releasing HIV resistant to neutralization by the same MAb. The epitope recognized by the MAb was mapped to the V3 neutralization epitope at amino acids 305-321. The HIV-1 variants showed a reduced binding capacity for the selecting MAb as determined by immunofluorescence. Polymerase chain reaction (PCR) amplification of complementary DNA derived from viral RNA, cloning and sequencing identified a base pair (bp) change C----G at position 6663 in variant 110.5/1, predicting a change at amino acid 308 Arg----Gly. No other changes in the epitope were observed by sequencing three other variants. Differential hybridization of PCR amplified viral RNA and DNA, with oligonucleotides specific for the observed bp change or the 'wild type' sequence, indicated that the variants 110.5/1 and 110.5/7 were genotypically mixed for 308Gly/Arg. Subsequent screening of biologically 'recloned' variants 110.5/1 and 110.5/7 identified two subclones homozygous for the 308Gly change. The Arg----Gly change appears to affect the binding of the antibody to the epitope, since the linear peptide substituting 308Gly for 'wild type' 308Arg was 100 times less potent in blocking the neutralization of parental HIV. Amino-acid residue 308 thus appears to be crucial for antibody binding to the epitope. In addition, mutations distant from the monoclonal antibody binding site may also affect neutralization by antibodies recognizing the V3 loop.

An enzyme-linked immunosorbent assay for antibodies to the envelope glycoproteins of divergent strains of HIV-1.

We have developed an enzyme-linked immunosorbent assay (ELISA) specific for antibodies to the envelope glycoproteins gp120 and gp160 of HIV-1. An antibody to a conserved epitope on gp120 is adsorbed to a solid phase and used to capture gp120 and/or gp160 from solution. This may be purified recombinant protein or in simple, non-denaturing detergent extracts of different strains of HIV-1. Human serum antibodies bound to the captured antigen are subsequently detected with an anti-human antibody conjugated to alkaline phosphatase, and the AMPAK ELISA amplification system (Novo BioLabs, Cambridge, UK). With this procedure, antibodies can be detected that recognize gp120 from a wide range of divergent HIV-1 strains. The ELISA is sufficiently sensitive to detect env antibodies in sera from HIV-positive individuals at dilutions of 1:300,000. No repeatable false-positives were detected in a screen of 250 normal serum samples. Env antibodies were detected in all 37 strongly HIV-positive sera tested, and in four sera that were borderline or weakly positive in commercial ELISA. However, 55 sera positive in commercial ELISA but unconfirmable by Western blot ('ambiguously' positive) did not contain detectable env antibodies.

Characterization of recombinant gp120 and gp160 from HIV-1: binding to monoclonal antibodies and soluble CD4.

We compared four preparations of recombinant HIV-1 envelope glycoprotein: mammalian (Chinese hamster ovary cells) gp120 (Celltech); baculovirus gp120 from American Biotechnologies Inc. (ABT) and from MicroGeneSys (MGS); and baculovirus gp160 (Institute of Virology, Oxford, UK). Each envelope glycoprotein binds to a neutralizing monoclonal antibody (MAb) directed against the V3 loop, confirming the integrity of this type-specific neutralization epitope. MGS gp120 binds abnormally well to a MAb which recognizes an epitope preferentially exposed on denatured gp120. Consistent with this finding, MGS gp120 binds to soluble CD4 (sCD4) with an affinity 50-100-fold lower than that of Celltech gp120. The affinity of Celltech gp120 from sCD4 is 2.3 nM, indistinguishable from that of gp120 extracted from HIV-1 virions. Baculovirus gp120 (ABT) and gp160 also have a high affinity for sCD4. A significant proportion of anti-gp120 antibodies in HIV-positive human sera recognize epitopes that are dependent on the mammalian glycosylation pattern, and a human HIV-positive serum inhibits the binding of mammalian gp120 to sCD4 five- to 10-fold more potently than it inhibits baculovirus gp120 binding to sCD4.

Further characterization of an antigenic site of HIV-1 gp120 recognized by virus neutralizing human monoclonal antibodies.

OBJECTIVE: The aim of this study is to characterize antigenic sites on HIV-1 gp120 which may be important for the development of active and passive immunization strategies against HIV-1 infection. DESIGN: Two HIV-1-seropositive individuals were selected from the Amsterdam cohort and Epstein-Barr virus (EBV)-transformed B cells were generated from their peripheral blood mononuclear cells, which produce HIV-1-specific human monoclonal antibodies (HuMAb). METHODS: HuMAb were generated and selected based on their reactivities with native gp120. Reactivity with HIV-1 strains from phylogenetically different subfamilies was determined by immunostaining and virus neutralization assays. Specificity for the CD4-binding site was tested by an inhibition enzyme-linked immunosorbent assay and amino acids (aa) involved in the binding of the HuMAb were identified with a set of gp120 molecules with single aa substitutions. RESULTS: Three HuMAb (GP13, GP44, GP68) were generated, all recognizing a conserved conformation dependent epitope within, or topographically near, the CD4-binding site of gp120. HuMAb GP13 and GP68 neutralized a broad range of HIV-1 strains from phylogenetically different subfamilies, whereas HuMAb GP44 exhibited a more restricted pattern of neutralizing activity. The patterns of gp120 aa involved in their binding were unique for each of these HuMAb. CONCLUSIONS: The pattern of reactivities of these three HIV-1-neutralizing HuMAb developed in these studies is similar to, but distinct from other human and rodent MAb that recognize this antigenic site of HIV-1 gp120.

Human immunodeficiency viruses: neutralization and receptors.

The envelope glycoproteins of HIV, gp120 and gp41, contain epitopes recognized by neutralizing antibodies. Studies of human sera from infected individuals indicate that group-specific neutralization antigens common to most isolates of HIV-1 exist, and that some HIV-2 antisera cross-neutralize HIV-1. Neutralization epitopes for HIV-1 have been identified and mapped, including a group-specific antigen on gp41, and a type-specific antigen on gp120. Neutralization "escape" mutants have been selected in vitro with a neutralizing mab to the type-specific antigenic loop. The CD4 antigen binds HIV-1 gp120 with high affinity and acts as the receptor on human and simian T-lymphocytes and monocytes for all strains of HIV-1, HIV-2, and SIV tested. Following binding to the CD4 receptor, HIV becomes internalized by a pH-independent process. The principle binding domain for gp120 is located in the N-terminal V domain of CD4. Anti-idiotypic sera to CD4 mabs recognizing the same site weakly neutralize HIVs of many strains, and soluble, recombinant forms of CD4 strongly neutralize HIV. Neither anti-CD4 mabs nor sCD4 inhibit the low level of plating of HIV observed on tumour cells in culture of glial (brain) and muscle origin, indicating that CD4 is not essential for infection of these cell types.

Cytomegalovirus and beta 2 microglobulin in urine specimens. Reciprocal interference in their detection is responsible for artifactually high levels of urinary beta 2 microglobulin in infected transplant recipients.

We have previously shown that the binding of host beta 2 microglobulin (beta 2 m) by cytomegalovirus (CMV) in body fluids masks the viral antigenic determinants preventing its detection by CMV-specific monoclonal antibodies. We now report that the recognition of CMV-bound beta 2m by anti-beta 2m-specific antibodies in assays for beta 2m, results in erroneously high readings for beta 2m levels in urine specimens containing CMV. Urinary beta 2m levels have previously been reported to be elevated in patients with CMV infection--however, when virion bound beta 2m was removed by ultracentrifugation of urine specimens, the levels of free beta 2m were not found to be elevated in these patients. Since CMV is frequently excreted by transplant recipients and acquired immunodeficiency syndrome patients, our data suggest that measurements of urinary beta 2m levels in such patients are unreliable unless the urine specimens are confirmed to be free of CMV before analysis.

The role of the viral glycoprotein in HIV-1 persistence.

The study of the immunological defects which arise from HIV infection has led to a deeper understanding both of the normal immune system and of the mechanisms by which it is damaged in disease. The interactions between viral and host factors during the early stages of HIV infection leads to a post-seroconversion steady state or 'set point' of viral RNA load, which has been shown to be a prognostic marker for subsequent progression rates, further underlining the important role of early immunological responses in the disease process. The changing immune response during the course of infection, together with the changing patterns of antigenicity and tropism leads to a complex series of evolutionary interactions which can be monitored as a series of changes in the properties of the virus over time. Furthermore, significant differences may be seen between the antigenicity of viruses adapted to grow in tissue culture and viruses cultured only briefly in primary cells, and also between the antigenicity of monomeric and oligomeric subunit immunogens. The immunodominant, highly polymorphic and rapidly changing envelope glycoproteins of HIV remains the single biggest target for the design of successful candidate vaccines. The recent crystallisation of one HIV envelope, the proven existence of functionally conserved neutralisation targets and our increasing knowledge of the behaviour of the envelope glycoprotein in vivo offers the possibility that the next generation of vaccine candidates will have a far higher chance of success than has currently been achieved.

Immunogenicity of full length and truncated forms of the human immunodeficiency virus type I envelope glycoprotein.

We have monitored the immunogenicity of a V1V2 sub-fragment of gp 120 in contrast to the full length protein and to a truncated form (PR12) where the V1, V2 and V3 regions were removed. In contrast to previously published work [1] these studies show that monomeric forms of envelope are capable of inducing antibodies specific for both linear and discontinuous epitopes. These antibodies are capable of neutralising HIV infectivity. The majority of neutralising antibodies were specific for epitopes within the V2 and V3 regions demonstrating the immunodominance of these regions in monomeric gp 120. Relatively few of the antibodies were specific for the CD4 binding site, suggesting that this region is poorly immunogenic. Immunisation of rats with the PR12 truncated protein did not significantly enhance the immunogenicity of the CD4 binding site. However, the immune response generated included antibodies capable of binding to diverse primary HIV-1 and HIV-2 envelope glycoproteins. We have shown that up to 30% of sera from HIV-1 infected individuals have antibodies that are capable of recognising conformation-dependent epitopes within the V1V2 region of the clone HXB10, suggesting the presence of conserved cross-reactive epitopes. Furthermore we have shown an association between the presence of V1V2 reactive antibodies and the neutralisation titre of the sera tested suggesting that antibodies to this region contribute to the cross-reactive neutralising response.

Soluble CD4 and CD4 immunoglobulin-selected HIV-1 variants: a phenotypic characterization.

The selection of HIV-1 resistance to neutralization by both monovalent and bivalent forms of soluble CD4 was demonstrated under various conditions. Phenotypic traits of the neutralization-resistant variants were systematically explored in order to gain insight into which aspects of the interactions with CD4 are most expendable to HIV-1 replication. The size of the nonneutralized fraction after treatment of preparations of the HIV-1 isolate IIIB and a molecular clone derived from it (HX10), with either monovalent soluble CD4 (sCD4) or bivalent CD4-Ig, was determined. These fractions were greater for the polyclonal IIIB than for the viral clone, and greater after treatment with sCD4 than with CD4-Ig. The virus in the nonneutralized fractions exhibited 2- to 20-fold lower sensitivity to the neutralizing agents than did unselected virus. In addition, clonal HIV-1 (HX10) was cultured in the presence of sCD4 or CD4-Ig for 12 weeks, so as to allow for accumulation of mutations that would confer stronger resistance to the selecting agent. Variants were obtained with up to 100-fold increased resistance to sCD4 or CD4-Ig. Detergent-solubilized gp120 from sCD4- and CD4-Ig-selected virus showed decreases in affinity for sCD4 and CD4-Ig. The monoclonal antibodies 6H10, to the gp120-binding site in domain 1 of CD4, and 5A8, to domain 2 of CD4, inhibited the induction by the viral escape variants of syncytium formation of C8166 cells. In general, the concentration of antibody 6H10 that inhibited the escape variants was lower than the concentration that inhibited the wild type, whereas there was no significant difference for the domain 2 antibody 5A8. We interpret this as a weaker attachment of the escape variants than of the wild-type virus to cellular CD4, but as an intact dependence of the variants on CD4 interactions for gaining entry into cells.

Expression of HIV-1 envelope glycoproteins by Semliki Forest virus vectors.

We have used Semliki Forest virus (SFV) vectors to express both the human immunodeficiency virus type 1 (HIV-1) envelope precursor gp160 and the cleaved external portion gp120. Expression of the foreign gene in this system is by transfection of recombinant SFV RNA, or by infection with a recombinant SFV virus that has a wide host range. pSFV1-gp120 or pSFV1-gp160 were expressed in baby hamster kidney (BHK) cells and two human cell lines: HeLa cervical carcinoma and MOLT-4 CD4+ T cells. After SFV1-gp120 infection of HeLa cells, 3.3 micrograms of gp120 was secreted into the media by 1 million cells in a 24-hr period. The secreted envelope glycoprotein was recognized by anti-gp120 monoclonal antibodies directed against both linear and conformation-dependent epitopes in different regions of the molecule. The recombinant gp120 also bound to a soluble form of the CD4 receptor. Syncytium formation was observed when MOLT-4 cells were infected with SFV1-gp160. The gp160 expressed by BHK cells induced syncytia during cocultivation with C8166 CD4+ T cells. These data indicate that SFV vectors can be used to produce the HIV-1 envelope glycoproteins to high levels, and that these proteins are correctly processed, folded, and transported to the cell surface. Furthermore, they exhibit functional activity as indicated by their ability to bind to soluble receptor and induce cell-to-cell fusion.

Monoclonal antibodies to the C4 region of human immunodeficiency virus type 1 gp120: use in topological analysis of a CD4 binding site.

We have raised antisera and monoclonal antibodies (MAbs) to the C4 region of HIV-1 gp120, using an antigen chimaera of poliovirus as immunogen. These MAbs and sera, together with MAbs to the same region raised by other methods, fall into three groups defined by their abilities to bind to recombinant gp120 and/or the immunogenic peptide. In some cases, the amino acids recognized by the MAbs have been identified by pep-scan and by solution phase peptide inhibition of binding to recombinant gp120. Our results indicate that the amino acids WQEVGKAMYA are exposed on the surface of recombinant gp120. Antibodies to these amino acids on recombinant gp120 compete for soluble CD4 binding in vitro, but only weakly neutralize HIV.

Association between a defective CCR-5 gene and progression to disease in HIV infection.

We measured the effect(s) of CCR-5 genotype on disease progression by studying the frequency of a defective CCR-5 delta32 allele within a cohort of long-term infected individuals. An elevated frequency of CCR-5 delta32 heterozygotes within the cohort compared with a control population of blood donors was observed. An association between progression rate and CCR-5 delta32 heterozygosity was observed. Furthermore, analysis of proviral DNA V3 sequences from a subset of the cohort predicted that the majority of individuals (39 of 44) were infected with viruses predicted to utilize the beta-chemokine receptor CCR-5. The marked association between CCR-5 genotype and disease progression observed in this study may be a consequence of the predicted low frequency of CXCR-4-utilizing viruses present within the selected cohort.

The V3 loops of the HIV-1 and HIV-2 surface glycoproteins contain proteolytic cleavage sites: a possible function in viral fusion?

Located close to the crown of the V3 type-specific neutralization loop of the human immunodeficiency virus type 1 (HIV-1) (IIIB) SU glycoprotein gp120, are several potential sites that should be susceptible to proteolytic cleavage by enzymes of trypsinlike or chymotrypsinlike specificity, or by aspartic proteinases. The linkages potentially sensitive to chymotryptic/aspartic proteinase cleavage are retained also within the equivalent domain of HIV-2 (ROD) gp105. We show that thrombin and tryptase cleave HIV-1 gp120 specifically at the tryptic site (GPGR decreases AFVT), and that cathepsin E, an endosomal aspartic proteinase, cleaves at the chymotrypsinlike site (GPGRAF decreases VT). HIV-2 gp105 is also cut by cathepsin E at a site (QIML decreases MSGH) in its V3 loop. Cleavage of HIV-1 gp120 by thrombin is enhanced by sCD4 binding, but is prevented by transient exposure of gp120 to nonionic detergent. Thrombin treatment of HIV-1 gp120 destroys the binding sites for some neutralizing monoclonal antibodies (MAbs) on the V3 loop, but does not affect the affinity of gp120 for sCD4. Conversely, binding of neutralizing MAbs to the HIV-1 V3 loop prior to addition of thrombin or cathepsin E blocks the cleavage reactions, and the binding of some HIV-positive sera to gp120 blocks thrombin cleavage. Analysis of published sequences suggests that all HIV-1, HIV-2, and simian immunovirus (SIV) isolates contain potential proteolytic cleavage sites at similar positions in their V3 loops or equivalent domains. We suggest that cleavage of the V3 loop by a cell surface or endosomal proteinase occurs during the HIV-cell fusion reaction, and that neutralizing antibodies directed against the V3 loop might act by inhibition of this reaction.

Detection of cytomegalovirus by DNA-DNA hybridization employing probes labelled with 32-phosphorus or biotin.

Various factors influencing the detection of human cytomegalovirus (HCMV) in infected cells by DNA-DNA hybridization have been investigated. Employing the Hind III O fragment of HCMV AD169 labelled with 32P, we found that detection sensitivity was highly influenced by the method employed for extraction of DNA from infected cells. Excision of the Hind III O fragment from the vector by restriction endonuclease digestion prior to 32P-labelling further improved the detection capability of the probe. Similarly, cytomegalovirus (CMV) DNA detection employing biotin-labelled probes and streptavidin/alkaline phosphatase in the hybridot assay was also highly dependent on the method of DNA extraction prior to hybridization. Finally, we describe an in situ assay employing a biotin-labelled probe and fluorescein-conjugated avidin to detect CMV DNA in cultured cells.