Detection and characterization of porcine endogenous retrovirus in porcine plasma and porcine factor VIII.

The pig genome contains porcine endogenous retroviruses (PERVs) capable of infecting human cells. Detection of infectious retrovirus in porcine peripheral blood mononuclear cells and endothelial cells suggested to us that pig plasma is likely to contain PERV. Both PERV env sequences and viral reverse transcriptase (RT) activity were detected in all plasma samples isolated from four NIH minipigs. To detect infectious virus from plasma, we performed a culture assay using three cell lines of feline, swine, and human origin that had previously been shown to be permissive for PERV. Infectious virus was successfully cultured from all four NIH minipig plasmas on the swine cell line ST-IOWA. Using RT-PCR with env-specific primers, we could detect expression of PERV class C envelope in the supernatant of ST-IOWA cells that had been exposed to each pig plasma. We next examined a pig plasma derivative, Hyate:C (porcine factor VIII), and found evidence of PERV particles, since all six lots examined were positive for PERV RNA and RT activity. However, infectious virus could not be detected in clinical lots of Hyate:C, suggesting that the manufacturing process might reduce the load of infectious virus to levels below detectable limits of the assay. Detection of infectious virus in porcine plasma confirms and extends the previous findings that certain porcine cells express PERV when manipulated in vitro and clearly demonstrates that there are porcine cells that express infectious PERV constitutively in vivo.

Immune complexes containing human immunodeficiency virus type 1 primary isolates bind to lymphoid tissue B lymphocytes and are infectious for T lymphocytes.

This study investigated the interaction of tonsil B lymphocytes with immune complexes containing human immunodeficiency virus (HIV IC) primary isolates and the infectivity of the B cell-bound HIV IC. Treatment of virus with a source of antibody and complement increased HIV IC binding to B cells by 5.6-fold. Most of the HIV IC that bound to B cells were not internalized but remained on the cell surface and were gradually released over 72 h. Cell-bound HIV IC were highly infectious for T cells while virus released by cultured B cells was only slightly infectious. Removal of HIV IC from the B-cell surface by protease treatment reduced the infection of T cells to near-background levels, indicating that infectious virus remained on the B-cell surface. These studies show that B lymphocytes can carry and transfer infectious HIV IC to T cells and thus suggest a novel mode of infection of T cells in lymphoid tissue that could be important for pathogenesis during HIV infection.

B lymphocytes in lymph nodes and peripheral blood are important for binding immune complexes containing HIV-1.

We investigated the interaction of HIV immune complexes (HIV IC) with mononuclear cells from lymph nodes and blood. While antibody alone did not affect binding of HIV IC to mononuclear cells, antibody plus complement increased binding by as much as 10-fold and complement alone also increased binding slightly. Most of the increased binding of HIV IC to mononuclear cells was blocked by heat-inactivation of complement and by OKB7 monoclonal antibody, indicating that virus binding was to CR2 on B cells. A similar pattern of antibody and complement dependence for binding of HIV IC was observed with two model systems; Raji and Arent B-cell lines. Most of the HIV IC that bound to lymph node cells were not internalized, but remained on the cell surface and were gradually released. However, even after 48 hr some HIV IC could be detected bound to cells. Under certain conditions, HIV IC were infectious for T cells if bound to B cells but not infectious if added directly to T cells. Additionally, HIV IC bound to B cells led to higher virus replication. These studies show that B lymphocytes from blood and lymph nodes can transfer infectious HIV IC to T cells.

Complement can neutralize HIV-1 plasma virus by a C5-independent mechanism.

A previous study showed a portion of HIV-1 plasma virus was lysed by the addition of exogenous human AB+ seronegative complement. The current study was performed to determine whether infectious plasma virus was inactivated by complement. Incubation of plasma virus with AB+-seronegative serum resulted in substantial decreases in infectious titers, demonstrating that infectious plasma virus is susceptible to complement-mediated inactivation. Although complement also induced some lysis of plasma virus samples, virus was neutralized to a significantly higher degree, suggesting neutralization did not occur solely by lysis. Additionally, C5-deficient complement substantially neutralized virus, indicating coating of virus by early complement components was an important mechanism of neutralization. A portion of some freshly isolated plasma virus samples bound to complement receptor 2 in the absence of exogenous complement, indicating that early complement components bound virus in vivo. Furthermore, plasma virus samples that had less C3 deposited on their surface in vivo had higher infectious titers than samples with a larger fraction with surface C3. These findings suggest that complement can neutralize HIV-1 plasma virus in vivo by coating with complement proteins. This is the first study to provide evidence that coating by complement leads to functional inactivation of a virus in vivo.

Mechanisms of resistance of HIV-1 primary isolates to complement-mediated lysis.

Previous studies suggested that HIV-1 primary isolates (PI) were resistant to complement-mediated lysis (CML), while virus produced in certain T cell lines and virus taken directly from the plasma of HIV+ persons were both susceptible to CML. The purpose of this study was to investigate the mechanism(s) of PI resistance. PI were resistant to CML using pooled seropositive serum as an antibody source. Additionally, PI obtained from two patients at several times over 2 years were resistant to CML using autologous antibody. PI were also resistant to CML induced by monoclonal antibodies which neutralize a broad range of PI. Resistance to CML was associated with low binding of antibody to PI but was not due to low gp120 levels. Cell-line-derived virus and PI were equally sensitive to CML induced by antibody to host-cell proteins, suggesting that PBMC do not contribute properties to virions which make them more physically resistant to CML in general but that PI resistance is restricted to CML induced by antiviral antibody. These studies show that PI are resistant to CML mediated by various antiviral antibodies and indicate that low binding of antibody to virus is an important factor contributing to resistance.

Susceptibility of HIV-1 plasma virus to complement-mediated lysis. Evidence for a role in clearance of virus in vivo.

This study was undertaken to directly assess the susceptibility of HIV-1 plasma virus to C-mediated lysis. Plasma from HIV-infected individuals was collected and ultracentrifuged over 20% sucrose to isolate virions from plasma components including anticoagulants, which inhibit C activity. Treatment with C alone in the absence of exogenously added Ab caused lysis of virus from all patients (n = 18) (range 14 to 86%). This lysis occurred via the classical C pathway and was not due to cross-reactive Abs in the C source. Protein A bound a fraction of isolated plasma virus and this binding was blocked by purified human Ig suggesting that anti-HIV Abs bound to plasma virus could be responsible for inducing C activation. A portion of virus bound to CR2 on cells in the absence of exogenously added C indicating that virus activated C in vivo. C levels from six of six patients were determined to be sufficient to lead to lysis of virus in vivo. Since plasma virus appeared more sensitive to C than primary isolates, isolated virus was evaluated for the presence of C control proteins. While primary isolate virions contained CD46, CD55, and CD59, only CD59 was detected on plasma virus. The results of this study strongly suggest that C is activated by a portion of plasma virus in vivo due to the binding of Ab. The resultant opsonization plus subsequent lysis may be important routes of clearance and destruction of plasma virus in infected persons.

Antibodies to the HIV-1 V3 loop in serum from infected persons contribute a major proportion of immune effector functions including complement activation, antibody binding, and neutralization.

Previous studies have shown that the V3 region of the HIV envelope is both critical to viral functions and immunogenic. However, the relative contribution of anti-V3 antibodies in the sera of infected individuals in mediating immune effector functions directed at whole intact virus and infected cells has not been determined. This study used peptides corresponding to several regions of the HIV envelope as inhibitors of antibody binding and antibody effector functions directed at virions and virus-infected cells in order to assess the relative importance of V3-specific antibodies in sera from infected persons. Approximately 40% of the antibody in serum which could bind to native viral proteins on HIVMN-infected cells was blocked by a peptide corresponding to the central 15 amino acids of the V3 loop. In contrast, little if any blocking of serum antibody binding was observed with peptides corresponding to flanking regions of HIVMN V3 or three regions of gp41. Since antiviral antibody can also activate immune effector functions, we determined whether peptides could block antibody-dependent activation of the complement system by HIV-infected cells or free virus. Surprisingly, the V3 loop peptide blocked 75-95% of complement activation on HIV-infected cells. While the V3 loop peptide also blocked a substantial portion of the neutralizing activity in serum from infected persons for free virus it was again more effective in inhibiting complement-mediated effects on free virus. Accordingly, antibody-dependent, complement-mediated virolysis was inhibited by 61-79%. The results of these experiments indicate that (1) a substantial portion (30-40%) of the antibody in sera from infected persons that is capable of binding to HIV-infected cells and HIV virions is V3-specific, and (2) these V3-specific antibodies are particularly important for complement activation on infected cells and virions. This indicates that the central portion of the V3 loop, while constituting less than 3% of the amino acid sequence of the HIV envelope, apparently provides a major gp160 site for immune effector functions, especially complement activation.

Anti-cellular antibodies in sera from vaccinated macaques can induce complement-mediated virolysis of human immunodeficiency virus and simian immunodeficiency virus.

Previous studies show that immunization of macaques with preparations of either human immunodeficiency virus (HIV) or simian immunodeficiency virus (SIV) that has been produced in human cells can induce antibodies against both viral antigens and human cellular antigens. This is due to the fact that certain host cell antigens are carried along with the virus during the purification process. The current series of experiments were performed to determine whether these anti-cellular antibodies can activate complement and whether the resultant complement activation could lead to virolysis of either HIV or SIV. Sera from macaques immunized with SIV or HIV (produced in the H9 human cell line) contained anti-cellular antibodies as determined by flow cytometry. Antibodies in these sera were capable of activating complement on uninfected human cells. Sera from the HIV-immunized macaques induced complement-mediated virolysis of both HIV and SIV. Similarly, sera from SIV-immunized macaques induced complement-mediated virolysis of both SIV and HIV. These results suggested that anti-cellular antibody in the sera could induce complement-mediated virolysis of either virus. To investigate this further, sera was absorbed with uninfected cells, which removed all of the virolytic activity for the heterologous virus. These in vitro studies indicate that complement activation can be initiated by anti-human cell antibodies, and that this activation can result in the destruction either HIV or SIV. This unusual antiviral mechanism may account for some portion of the resistance of human cell-immunized macaques to human cell-produced SIV that has been recently reported.

Detection of HIV-1 provirus in bronchoalveolar lavage cells by polymerase chain reaction.

This study was undertaken to evaluate whether HIV-seropositive individuals harbor HIV provirus in cells obtained by bronchoalveolar lavage (BAL). BAL cells were obtained from 14 HIV-positive patients undergoing bronchoscopy for evaluation of acute pulmonary symptoms. Cells were fractionated into macrophage-enriched and lymphocyte-enriched populations. The quantity of HIV-1 proviral DNA in the unfractionated BAL cells and in each population of fractionated cells was determined following polymerase chain reaction (PCR) amplification. Detectable quantities (3-90 copies/100,000 cells) of HIV-1 proviral DNA were found in unfractionated BAL cells in 12 of 14 patients. In the other two patients, provirus was detected after a sevenfold enrichment of lymphocytes. Provirus was also detected in BAL macrophages from 8/14 patients although proviral content was significantly higher in the lymphocyte fraction (133 +/- 72 vs. 35 +/- 22 proviral copies, p = 0.03). No correlation was seen with the ability to detect provirus in lymphocyte- or macrophage-enriched fractions and clinical diagnosis (e.g., Pneumocystis carinii pneumonia). The data suggest that lymphocytes are the predominant cells that contain provirus found in the lungs, although macrophages may be infected in some patients.

Complement activation by human monoclonal antibodies to human immunodeficiency virus.

It has been shown that the incubation of human immunodeficiency virus (HIV) with polyclonal antibodies from HIV-infected persons and complement results in complement-mediated neutralization due, at least in part, to virolysis. The current study was performed to determine whether any of a panel of 16 human monoclonal antibodies to HIV could activate complement and, if so, which determinants of the HIV envelope could serve as targets for antibody-dependent complement-mediated effects. Human monoclonal antibodies directed to the third variable region (V3 region) of HIVMN gp120 induced C3 deposition on infected cells and virolysis of free virus. Antibodies to two other sites on HIVMN gp120 and two sites on gp41 induced few or no complement-mediated effects. Similarly, only anti-V3 antibodies efficiently caused complement-mediated effects on the HIVIIIB isolate. In general, the level of C3 deposition on infected cells paralleled the relative level of bound monoclonal antibodies. As expected, pooled polyclonal antibodies from infected persons were much more efficient than monoclonal antibodies inducing C3 deposition per unit of bound immunoglobulin. Treatment of virus or infected cells with soluble CD4 resulted in increases in anti-gp41 antibody-mediated virolysis and C3 deposition but decreases in anti-V3 antibody-mediated virolysis and C3 deposition. In general, virolysis of HIV was more sensitive as an indicator of complement-mediated effects than infected-cell surface C3 deposition, suggesting the absence of or reduced expression of functional complement control proteins on the surface of free virus. Thus, this study shows that human monoclonal antibodies to the V3 region of gp120 are most efficient in causing virolysis of free virus and C3 deposition on infected cells. Elution of gp120 with soluble CD4 exposes epitopes on gp41 that can also bind antibody, resulting in virolysis and C3 deposition. These findings establish a serologically defined model system for the further study of the interaction of complement and HIV.

Selective Medium for Quantitation of Bacillus popilliae in Soil and in Commercial Spore Powders.

A medium consisting of MYPGP agar supplemented with vancomycin was found to be highly selective for Bacillus popilliae, especially for strains originally isolated from Japanese beetle larvae. The medium has proven to be useful for the quantitation of B. popilliae spores in commercial spore powder and in soil.

Human immunodeficiency virus (HIV)-infected cells and free virus directly activate the classical complement pathway in rabbit, mouse and guinea-pig sera; activation results in virus neutralization by virolysis.

Since animal models of human immunodeficiency virus (HIV) infection are being used increasingly in determining various aspects of virus/host interaction and as models for virus expression, it will be important to assess any significant differences in anti-viral immune responses between animals and humans. Previous studies have shown that incubation of HIV with non-immune sera from several animal species results in virus neutralization, and that rabbit serum can lyse HIV-infected cells. The objectives of the current study were to evaluate the animal complement pathway(s) activated by HIV and HIV-infected cells and determine the mechanism by which complement could mediate viral neutralization. Incubation of HIV-infected cells with mouse, guinea-pig or rabbit sera resulted in cell-surface deposition of C3 fragments. Deposition of C3 fragments did not occur either in the presence of C4-deficient guinea-pig serum or in the absence of Ca2+, indicating that activation by infected cells occurred via the classical pathway. Neutralization of free virus was also mediated by the classical pathway since C4-deficient guinea-pig serum and Ca(2+)-chelated sera lacked activity. Serum treatment of virus resulted in release of HIV reverse transcriptase (RT), suggesting that neutralization occurred by C5b-9-mediated virolysis. RT was also released from simian immunodeficiency virus by animal complement. Antibodies in animal sera were not responsible for the classical pathway activation by free virus or HIV-infected cells. These results define several substantial differences between animal and human complement reactivity with HIV which could significantly affect the ability of HIV to replicate in animals, and which need to be considered in the assessment of animal models of HIV infection.