Critical factors influencing prion inactivation by sodium hydroxide.

BACKGROUND AND OBJECTIVES: Transmissible spongiform encephalopathies (TSEs) are fatal neurodegenerative diseases caused by aberrantly folded cellular proteins (PrP(Sc); prions) that are generally resistant to conventional pathogen-inactivation techniques. To ensure effective decontamination and inactivation of prions that could be present in source material, we investigated critical factors that influence prion inactivation by NaOH. MATERIALS AND METHODS: A decrease in prion infectivity correlates with the disappearance of the protease-resistant core of PrPSc (PrPRES) observed in biochemical assays. To model prion inactivation, hamster scrapie (strain 263K) brain homogenate (SBH) was incubated for specific periods of time in 0.1 m NaOH at 4 or 18 degrees C, with or without detergent. Neutralized samples were subjected to limited digestion with proteinase K (PK) and then analysed using an endpoint dilution western blot assay and antibody 3F4. Structural changes in prions exposed to NaOH were examined using differential immunoprecipitation. RESULTS: Treatment of SBH with 0.1 m NaOH for 15 min, in the absence of detergent, at 4 and 18 degrees C caused a reduction in the PrP(RES) signal of 3.5 and 4.0 log10 units, respectively, with some residual signal remaining. The presence of the detergent sarkosyl during a 60-min incubation in NaOH further enhanced PrPRES reduction to > or = 4.5 log10 units (i.e. below the limit of detection). NaOH treatment induced conformational changes in PrP that resulted in the exposure of a hidden epitope and enabled prion immunoprecipitation by antibody 3F4. CONCLUSIONS: The use of NaOH can effectively reduce prion levels in an in vitro inactivation assay. After pretreatment of SBH with detergent, NaOH completely eliminates the PrPRES signal. Detergent may liberate lipid membrane-protected PrPSc to improve access to NaOH, which can then inactivate PrPSc by altering its structure. In cases of unidentified exposure to PrPSc during manufacturing, sanitizing procedures combining the use of detergent and NaOH may help to ensure minimal levels of contamination carryover in products.

Enveloped virus inactivation by caprylate: a robust alternative to solvent-detergent treatment in plasma derived intermediates.

Solvent-detergent treatment, although used routinely in plasma product processing to inactivate enveloped viruses, substantially reduces product yield from the human plasma resource. To improve yields in plasma product manufacturing, a new viral reduction process has been developed using the fatty acid caprylate. As licensure of plasma products warrants thorough evaluation of pathogen reduction capabilities, the present study examined susceptibility of enveloped viruses to inactivation by caprylate in protein solutions with varied pH and temperature. In the immunoglobin-rich solutions from Cohn Fraction II+III, human immunodeficiency virus, Type-1, bovine viral diarrhea virus (BVDV), and pseudorabies virus were inactivated by caprylate concentrations of >/=9 mM, >/=12 mM, and >/=9 mM, respectively. Compared to solvent-detergent treatment, BVDV inactivation in Fraction II+III solution was significantly faster (20-60 fold) using 16 mM caprylate. Caprylate-mediated inactivation of BVDV was not noticeably affected by temperature within the range chosen manufacturing the immunoglobulin product. In Fraction II+III solutions, IgG solubility was unaffected by

Pathogen safety of manufacturing processes for biological products: special emphasis on KOGENATE Bayer.

Manufacturers of human therapeutic proteins derived from biological sources continuously strive to improve the pathogen safety profiles of these products. Efforts to improve pathogen safety margins for these biological products are directed towards several areas within the manufacturing processes including: (a) sourcing and screening of raw materials (b) determining the potential for manufacturing processes to reduce pathogen titres, and (c) incorporating methods designed specifically to remove or inactivate contaminating pathogens. Methods that could potentially reduce pathogen titres are a major focus for many manufacturers. In general, these methods are grouped into two categories, pathogen clearance and pathogen inactivation. Assessments are performed on small-scale, laboratory simulations of the manufacturing process of interest that are spiked with a known amount of a selected pathogen. These studies provide estimates of the potential for a process step to remove or inactivate a particular pathogen. There are several pathogen clearance/inactivation methods that are inherent in manufacturing processes, however, some methods are intentionally incorporated into manufacturing for the sole purpose of reducing putative pathogen titres. Not only are well-known pathogens such as viruses targeted, but also suspected pathogens such as those associated with the transmissible spongiform encephalopathies (TSEs). The production processes for the isolation of several biological products, including recombinant KOGENATE Bayer (Kogenate FS), have been evaluated for the ability to reduce pathogen titres and/or have been designed to incorporate methods for reducing potential pathogen safety risks. Several processing steps with the potential to reduce pathogen titres have been identified.

Ensuring the pathogen safety of intravenous immunoglobulin and other human plasma-derived therapeutic proteins.

Countless patients and clinicians rely on therapeutic proteins, such as intravenous immunoglobulins (IVIGs), isolated from human blood plasma. Since plasma is predisposed to contamination by a variety of blood-borne pathogens, ascertaining and ensuring the pathogen safety of plasma-derived therapeutics is a priority among manufacturers. Even though the pathogen safety records for IVIG and other plasma proteins are excellent, the industry remains active in research programs aimed at improving the margin of safety. Industry initiatives designed to increase the safety of plasma-derived products range from donor screening and testing to implementing methods into the manufacturing processes that can inactivate or remove pathogens from product streams. In general, the industry's comprehensive strategy is designed to provide patients and caregivers with the safest plasma products possible.

A direct relationship between the partitioning of the pathogenic prion protein and transmissible spongiform encephalopathy infectivity during the purification of plasma proteins.

BACKGROUND: Experimental evidence from rodent models indicates that blood can contain transmissible spongiform encephalopathy (TSE) infectivity, which suggests a potential risk for TSE transmission via proteins isolated from human plasma. Because methods that can reduce TSE infectivity typically are detrimental to protein function, infectivity must be removed to ensure the safety of these therapeutic proteins. Animal bioassays are conventionally used to detect infectivity, but the pathogenic form of the prion protein (PrP(Sc)) can serve as a marker for TSE infectivity. STUDY DESIGN AND METHODS: Seven plasma protein-purification steps were performed after the plasma intermediates were spiked with TSE-infected material. Resulting fractions were analyzed for PrP(Sc) by using a Western blot assay and for TSE infectivity by using an animal bioassay. Western blots were quantitated by an endpoint dilution analysis, and infectivity titers were calculated by the Spearman-Kärber method. RESULTS: PrP(Sc) partitioning paralleled TSE infectivity partitioning, regardless of the nature of the protein-purification step. The detection ranges for PrP(Sc) and infectivity were 0 to 5.3 log and 1.1 to 8.9 log median infectious dose per unit, respectively. Clearance of PrP(Sc) and infectivity ranged from 1.0 to 6.0 log. CONCLUSION: Purification steps for isolating therapeutic proteins from human plasma showed the removal of both PrP(Sc) and TSE infectivity. PrP(Sc) partitioning coincided with infectivity partitioning, which showed a close relationship between PrP(Sc) and TSE infectivity. By exploiting this association, the in vitro Western blot assay for PrP(Sc) was valuable for estimating the partitioning of TSE infectivity during plasma protein purification.

Monitoring plasma processing steps with a sensitive Western blot assay for the detection of the prion protein.

Determining the risk of transmissible spongiform encephalopathy (TSE) transmission by blood or plasma-derived products requires sensitive and specific assays for the detection of either infectivity or a reliable marker for infectivity. To this end, a Western blot assay that is both sensitive and reproducible for the detection of PrP(RES), a marker for TSE infectivity, was developed. Using the 263K strain of TSE as a model system, the Western blot assay proved to be sensitive, specific and quantitative over a 3-4 log dynamic range. Compared to the rodent bioassay, the assay was shown to detect PrP(RES) down to approximately 10(3.4) IU/ml which is approximately 5-10 pg of PrP or approximately 10-20 ng brain equivalents. The Western blot was applied to monitor the partitioning of spiked PrP(Sc) through three plasma fractionation steps, cryoprecipitation, fraction I and fraction III, that are common to the purification of several human plasma-derived therapeutic products including albumin and immunoglobulins. The results from these studies demonstrated 1 log, 1 log and 4 logs of PrP(Sc) partitioning away from the effluent fraction for the cryoprecipitation, fraction I and fraction III steps, respectively.

HIV-1 membrane fusion mechanism: structural studies of the interactions between biologically-active peptides from gp41.

Two synthetic peptides corresponding to sequences in HIV-1LAI gp41, (aa558-595) and T20 (aa 643-678), are strong inhibitors of HIV-1 viral fusion, having EC50 values of 1 microgram/mL and 1 ng/mL, respectively. Previous work suggested that T21 forms a coiled-coil structure in PBS solution, while T20 is primarily nonhelical, and that the inhibitory action of these peptides occurs after the interaction between the viral gp120 protein and the cellular CD4 receptor [Wild, C.T., Shugars, D. C., Greenwell, T. K., McDanal, C. B., Matthews, T. J. (1994) Proc. Natl. Acad. Sci. U.S.A. 91, 9770 and references therein]. The current study uses sedimentation equilibrium (SE), circular dichroism (CD), and viral-fusion assays to quantitatively investigate peptide structure and peptide-peptide interactions. SE analyses of T21 (1-100 microM) indicate that the peptide self associates via a monomer/dimer/tetramer equilibrium; in addition, T20 is monomeric in the range of 1-10 microM and exhibits a complicated monomer/tetramer equilibrium between 20 and 100 microM. Singular value decomposition analyses of the CD spectra of T21 and T20 indicate that the helical content of these peptides in PBS solution is 90% and 20%, respectively. A structural interaction between the two peptides is detected by CD at several concentration ratios of T20:T21. These experiments emphasize that T20 interacts specifically with the tetrameric form of T21. Truncated forms of T20 also exhibit structural interactions with T21 at varying concentration ratios. The ability of T20 and the truncated peptides to interact structurally with tetrameric T21 correlates with antiviral activity. Implications of these findings are discussed in terms of proposed mechanisms of membrane fusion inhibition and the structural changes which occur in gp41 during membrane fusion.

Potent inhibition of HIV type 1 infection of mononuclear phagocytes by synthetic peptide analogs of HIV type 1 protease substrates.

The HIV-1 genome encodes a protease that is required for viral processing of the precursor polyproteins Pr55gag and Pr160gag-pol. Interference with this process in human lymphocytes inhibits production of infectious virus. We tested the ability of several protease inhibitors to decrease replication of HIV-1BaL in human monocytes and peritoneal macrophages. The compounds tested are oligopeptide analogs of HIV-1 protease substrates in which the scissile dipeptide has been replaced by a hydroxyethylene isostere. The protease inhibitors were added only once, 1 hr prior to inoculation with virus. Every 3-5 days, half the medium was replaced with fresh medium. Inhibition of virus production was assessed by measuring reverse transcriptase (RT) activity in supernatant medium 14 days after infection. The concentration of drug required to inhibit infection by 50% (IC50) in monocytes ranged from 0.17 to 2.99 microM; IC50 values for peritoneal macrophages ranged from 0.21 to 1.9 microM. The IC50 values for these compounds were 1.1- to 10-fold higher when tested in monocytes compared to their inhibitory effect in lymphocytes, although still potently effective in the dosage range that appeared nontoxic to cells. Cell toxicity was seen only at concentrations greater than 10 microM, and varied among the drugs tested. Immunoblot analysis of two of the drugs (SB205700 and SB108922) confirmed inhibition of polyprotein processing. In control cells, 22% of viral protein pr55 was processed to p24 by 24 hr, and 51% was processed by 48 hr. In cells treated with the protease inhibitors (2 microM), Pr55 processing was inhibited 77% at 24 hr and 89% at 48 hr. Thus, these synthetic peptide analogs potently inhibit productive infection of mononuclear phagocytes by HIV-1. Drugs of this class may be useful for the treatment of HIV-1 infection in humans.

Effects of SKF 108922, an HIV-1 protease inhibitor, on retrovirus replication in mice.

Rationally designed synthetic inhibitors of retroviral proteases inhibit the processing of viral polypeptides in cultures of human T lymphocytes infected with human immunodeficiency virus type 1 (HIV-1) and therefore suppress the infectivity of HIV-1 in vitro. We have previously reported the antiviral activity in vitro of HIV-1 protease inhibitors against the C-type retrovirus Rauscher murine leukemia virus (RMuLV) and the lentivirus simian immunodeficiency virus (SIV). The same compounds which blocked the infectivity of HIV-1 also inhibited the infectivity of RMuLV and SIV in vitro. This report extends these findings by testing the antiviral activity of HIV-1 protease inhibitors in vivo in the RMuLV model. RMuLV-infected mice were treated twice a day (bid) with either an active (SKF 108922) or inactive (SKF 109273) compound for fourteen days by the intraperitoneal (i.p.) route. Compared with excipient control, SKF 108922, formulated with hydroxypropyl-beta-cyclodextrin (HPB), reduced virus-induced splenomegaly, viremia, and serum reverse transcriptase (RT) levels, while SKF 109273 was inactive. The HPB vehicle by itself enhanced replication of RMuLV. The effects of changing the formulation and the route of administration were examined. SKF 108922, formulated in HPB, had similar antiviral activity when administered by the i.p. or subcutaneous (SC) routes. However, SKF 108922 administered as a colloidal suspension in cholesterol sulfate (CS) had no detectable antiviral effect. Measurements of the circulating levels of the protease inhibitor in plasma explained this result. Plasma concentrations of SKF 108922 exceeded 1000 nM within 10 min after SC administration of the compound solubilized in HPB, but SKF 108922 was not detected in plasma after SC administration of the same dose formulated with CS. Information on optimal conditions for administering these agents should prove useful in guiding their clinical application Therefore, RMuLV should provide a good model for the preclinical evaluation and development of this class of agents for the treatment of HIV.

Peptides from conserved regions of paramyxovirus fusion (F) proteins are potent inhibitors of viral fusion.

The synthetic peptides DP-107 and DP-178 (T-20), derived from separate domains within the human immunodeficiency virus type 1 (HIV-1) transmembrane (TM) protein, gp4l, are stable and potent inhibitors of HIV-1 infection and fusion. Using a computer searching strategy (computerized antiviral searching technology, C.A.S.T.) based on the predicted secondary structure of DP-107 and DP-178 (T-20), we have identified conserved heptad repeat domains analogous to the DP-107 and DP-178 regions of HIV-1 gp41 within the glycoproteins of other fusogenic viruses. Here we report on antiviral peptides derived from three representative paramyxoviruses, respiratory syncytial virus (RSV), human parainfluenza virus type 3 (HPIV-3), and measles virus (MV). We screened crude preparations of synthetic 35-residue peptides, scanning the DP-178-like domains, in antiviral assays. Peptide preparations demonstrating antiviral activity were purified and tested for their ability to block syncytium formation. Representative DP-178-like peptides from each paramyxovirus blocked homologous virus-mediated syncytium formation and exhibited EC50 values in the range 0.015-0.250 microM. Moreover, these peptides were highly selective for the virus of origin. Identification of biologically active peptides derived from domains within paramyxovirus F1 proteins analogous to the DP-178 domain of HIV-1 gp4l is compelling evidence for equivalent structural and functional features between retroviral and paramyxoviral fusion proteins. These antiviral peptides provide a novel approach to the development of targeted therapies for paramyxovirus infections.

Effect of a single amino acid substitution in the V3 domain of the human immunodeficiency virus type 1: generation of revertant viruses to overcome defects in infectivity in specific cell types.

Proviral clones of human immunodeficiency virus type 1 which contained single amino acid changes in the envelope V3 region were constructed. PCR amplification of Sup-T1 T cells transfected with one such mutant, G312T, revealed low levels of virus that resulted in the generation of a revertant virus, in which an alanine replaced the threonine residue at amino acid 312. The revertant virus (rA312) was fully infectious in Sup-T1 cells but lacked the ability to infect AA5 cells. The presence of a second mutation in a subsequent revertant virus (rR306), in which arginine was substituted for serine at amino acid 306 within the V3 loop, restored the ability of the mutated virus to infect AA5 cells. Our data highlight the importance of the V3 loop in defining virus tropism for specific cell types in culture and further suggest that a degree of interplay exists among V3 loop residues that helps maintain or control its biological function of the virus.

Efficacy of the hematoregulatory peptide SK&F 107647 in experimental systemic Candida albicans infections in normal and immunosuppressed mice.

SK&F 107647, a novel synthetic dimeric pentapeptide, has been shown to be a potent hematoregulatory agent. The potential for the hematoregulatory factors elicited by SK&F 107647 to confer protection in experimental models of systemic Candida albicans infection was evaluated in immunosuppressed and immunocompetent mice. Prophylactic treatment with recombinant human interleukin-1 (rhIL-1), recombinant human granulocyte colony stimulating factor (rhG-CSF), or the hematoregulatory peptide SK&F 107647 significantly increased survival times in gamma irradiated immunosuppressed as well as non-irradiated immunocompetent mice challenged with a lethal dose of C. albicans. Protection was also observed in athymic nu/nu "nude" mice. Additionally, significant increases in survival in non-irradiated immunocompetent mice dosed by oral gavage were observed. These results indicate that SK&F 107647 can significantly enhance natural host resistance to experimental C. albicans infections both in immunosuppressed and immunocompetent mice.

In vivo modulation of hematopoiesis by a novel hematoregulatory peptide.

The hematoregulatory peptide dimer, HP5B, enhances myelopoiesis by stimulating stromal cell cytokine production. However, the disulfide bridge of this peptide is susceptible to reduction, leading to the formation of monomeric pentapeptide, HP5, a direct-acting inhibitor of myelopoiesis. We have replaced the disulfide (S-S) bond of HP5B dimer with an isosteric ethylene (CH2-CH2) group, creating a new, nonreducible, metabolically more stable peptide (SK&F 107647). This novel peptide was tested in vitro and in vivo for hematopoietic effects. In vitro, SK&F 107647 has no direct colony-stimulating activity (CSA). Stimulation of murine stromal cells with SK&F 107647 results in production and release of CSA at concentrations as low as 0.01 ng/mL, at least 10-fold lower than observed with HP5B dimer. Injection of SK&F 107647 in normal mice results in a two- to six-fold increase in serum CSA, which becomes maximal at 6 hours postinjection. Administration of peptide daily over 4 days (q.d. x 4) by both parenteral and oral routes results in significant increases in absolute numbers of granulocyte-macrophage (CFU-GM), erythroid (BFU-E), and multipotential (CFU-GEMM) progenitor cells, as well as stimulating their cell cycle rates. A doubling in day 8 CFU-S was also observed in SK&F 107647-treated mice. Continuous subcutaneous (s.c.) infusion of SK&F 107647 in femorally cannulated rats demonstrated modest but significant elevation of peripheral blood neutrophil and monocyte counts within 7 days. SK&F 107647 represents a novel synthetic hematoregulatory peptide that shares biological and/or modulatory activities with natural hematopoietic cytokines.

Synergistic drug interactions of an HIV-1 protease inhibitor with AZT in different in vitro models of HIV-1 infection.

Synthetic peptide mimetic inhibitors of HIV-1 protease effectively block spread of infectious virus in acutely infected T-cells. These compounds also inhibit production of infectious virions from chronically infected T-cell lines. In order to determine the potential for drug interaction effects on antiviral activity, an HIV-1 protease inhibitor (SK&F 108922) and AZT were studied in three different in vitro models of HIV-1 infection of T-cell lines, specifically, (1) acutely infected cells infected at low multiplicity, (2) HIV-1 chronically-infected cells and (3) co-cultivations of chronically infected with non-infected cells. Upon co-treatment, these compounds demonstrated synergy in Molt4 or H9 cells acutely infected with HIV-1 strain IIIB. Either compound alone was a potent inhibitor of HIV-1 in co-cultivations of uninfected and chronically infected cells. In combination treatments of co-cultures, SK&F 108922 demonstrated strong synergy with AZT. Treatment of H9/IIIB chronically infected cells demonstrated no inhibitory effect by AZT treatment (EC50 = > 100 microM) whereas SK&F 108922 was inhibitory (EC50 = 3 microM). Upon co-treatment of H9/IIIB chronically infected cultures with both compounds, the antiviral activity was similar to that of the protease inhibitor alone suggesting no drug interaction. In the co-cultivation experiments, AZT's antiviral effect was most likely due to blocking spread of acute infection to uninfected cells in the culture. No antagonistic effects were observed with AZT and SK&F 108922 co-treatments. These results clearly demonstrate that an HIV-1 protease inhibitor can exert a potent antiviral effect on chronically infected T-cells in contrast to AZT and is capable of potent synergy with AZT in acute and co-culture in vitro infection models.

Antiretroviral activities of protease inhibitors against murine leukemia virus and simian immunodeficiency virus in tissue culture.

Rationally designed synthetic inhibitors of retroviral proteases inhibit the processing of viral polyproteins in cultures of human immunodeficiency virus type 1 (HIV-1)-infected T lymphocytes and, as a result, inhibit the infectivity of HIV-1 for such cultures. The ability of HIV-1 protease inhibitors to suppress replication of the C-type retrovirus Rauscher murine leukemia virus (R-MuLV) and the HIV-related lentivirus simian immunodeficiency virus (SIV) was examined in plaque reduction assays and syncytium reduction assays, respectively. Three of seven compounds examined blocked production of infectious R-MuLV, with 50% inhibitory concentrations of < or = 1 microM. Little or no cellular cytotoxicity was detectable at concentrations up to 100 microM. The same compounds which inhibited the infectivity of HIV-1 also produced activity against SIV and R-MuLV. Electron microscopic examination revealed the presence of many virions with atypical morphologies in cultures treated with the active compounds. Morphometric analysis demonstrated that the active compounds reduced the number of membrane-associated virus particles. These results demonstrate that synthetic peptide analog inhibitors of retroviral proteases significantly inhibit proteolytic processing of the gag polyproteins of R-MuLV and SIV and inhibit the replication of these retroviruses. These results are similar to those for inhibition of HIV-1 infectivity by these compounds, and thus, R-MuLV and SIV might be suitable models for the in vivo evaluation of the antiretroviral activities of these protease inhibitors.

Effect of retroviral proteinase inhibitors on Mason-Pfizer monkey virus maturation and transmembrane glycoprotein cleavage.

Mason-Pfizer monkey virus (M-PMV) is the prototype type D retrovirus which preassembles immature intracytoplasmic type A particles within the infected cell cytoplasm. Intracytoplasmic type A particles are composed of uncleaved polyprotein precursors which upon release are cleaved by the viral proteinase to their constituent mature proteins. This results in a morphological change in the virion described as maturation. We have investigated the role of the viral proteinase in virus maturation and infectivity by inhibiting the function of the enzyme through mutagenesis of the proteinase gene and by using peptide inhibitors originally designed to block human immunodeficiency virus type 1 proteinase activity. Mutation of the active-site aspartic acid, Asp-26, to asparagine abrogated the activity of the M-PMV proteinase but did not affect the assembly of noninfectious, immature virus particles. In mutant virions, the transmembrane glycoprotein (TM) of M-PMV, initially synthesized as a cell-associated gp22, is not cleaved to gp20, as is observed with wild-type virions. This demonstrates that the viral proteinase is responsible for this cleavage event. Hydroxyethylene isostere human immunodeficiency virus type 1 proteinase inhibitors were shown to block M-PMV proteinase cleavage of the TM glycoprotein and Gag-containing precursors in a dose-dependent manner. The TM cleavage event was more sensitive than cleavage of the Gag precursors to inhibition. The infectivity of treated particles was reduced significantly, but experiments showed that inhibition of precursor and TM cleavage may be at least partially reversible. These results demonstrate that the M-PMV aspartyl proteinase is activated in released virions and that the hydroxyethylene isostere proteinase inhibitors used in this study exhibit a broad spectrum of antiretroviral activity.

Human immunodeficiency virus type 1 protease inhibitors irreversibly block infectivity of purified virions from chronically infected cells.

Synthetic peptide analog inhibitors of human immunodeficiency virus type 1 (HIV-1) protease were used to study the effects of inhibition of polyprotein processing on the assembly, structure, and infectivity of virions released from a T-cell line chronically infected with HIV-1. Inhibition of proteolytic processing of both Pr55gag and Pr160gag-pol was observed in purified virions from infected T cells after treatment. Protease inhibition was evident by the accumulation of precursors and processing intermediates of Pr55gag and by corresponding decreases in mature protein products. Electron microscopy revealed that the majority of the virion particles released from inhibitor-treated cells after a 24-h treatment had an immature or aberrant capsid morphology. This morphological change correlated with the inhibition of polyprotein processing and a loss of infectivity. The infectivity of virion particles purified from these chronically infected cell cultures was assessed following treatment with the inhibitor for 1 to 3 days. Virions purified from cultures treated with inhibitor for 1 or 2 days demonstrated a 95- to 100-fold reduction in virus titers, and treatment for 3 days resulted in complete loss of detectable infectivity. The fact that virions from treated cultures were unable to establish infection over the 7- to 10-day incubation period in the titration experiments strongly suggests that particles produced by inhibitor-treated cells were unable to reactivate to an infectious form when they were purified away from exogenous protease inhibitor. Thus, a block of HIV-1 protease processing of viral polyproteins by specific inhibitors results in a potent antiviral effect characterized by the production of noninfectious virions with altered protein structures and immature morphologies.

V3 loop region of the HIV-1 gp120 envelope protein is essential for virus infectivity.

The mechanism by which HIV-1 mediates cell fusion and penetrates target cells, subsequent to receptor (CD4) binding, is not well understood. However, neutralizing antibodies, which recognize the principal neutralizing determinants of the gp120 envelope protein (the V3 loop region, residues 296 to 331), have been shown to effectively block cell fusion and virus infectivity independent of the initial gp120-CD4 binding. To investigate the role of the V3 loop in an HIV infection, a series of site-specific mutations were introduced into the HIV-1 envelope gene. Specifically, each residue (312 to 315) in the strongly conserved tetrapeptide sequence, GPGR, which is positioned in the center of the V3 loop domain was individually altered. The processing, transport, and CD4 binding properties of the mutant envelope proteins were comparable to those of the wild-type protein, however, none of the mutants were able to form syncytia in the HeLa-T4 assay. Molecular HIV-1 clones containing mutations altering the G312, G314, or R315 residues produced noninfectious virions, whereas a clone with a P313A mutation was found to be infectious. These results demonstrate that certain V3 loop mutations can be lethal and clearly indicate that this region of the HIV-1 gp120 protein is essential for virus infectivity.

Human chromosome-dependent and -independent pathways for HIV-2 trans-activation.

Human immunodeficiency virus (HIV types 1 and 2) replication is controlled by the interaction of viral-encoded regulatory proteins and host cellular proteins with the viral long terminal repeat (LTR). The presence of HIV-1 and HIV-2 trans-activator proteins, tat1 and tat2, respectively, greatly increases viral gene expression from their homologous LTRs. It is unclear if the cellular factors that support tat1-directed trans-activation of the HIV-1 LTR are the same for tat2 trans-activation of the HIV-2 LTR. Human-Chinese hamster ovary hybrid cell clones were used to probe for human chromosomes involved in regulating HIV-1 and HIV-2 tat-directed transactivation. DNA transfection experiments showed that the presence of human chromosome 12 in human-hamster hybrid clones was necessary for high-level tat-directed trans-activation of the HIV-1 and -2 LTR. Cross-trans-activation of the HIV-2 LTR by tat1 was found to be chromosome 12 independent. In addition, chromosome 12 did not support trans-activation of another human retrovirus (human T-cell leukemia virus type I). Our results suggest that HIV-1 and -2 have evolved to employ a cellular pathway(s) encoded on human chromosome 12 for supporting homologous tat-directed trans-activation. Trans-activation of the HIV-2 LTR by tat1 in chromosome 12-minus cells suggests that multiple cellular pathways can be recruited to trans-activate the HIV-2 LTR and that these pathways may have been important in an HIV-like progenitor virus.

Alteration of HIV-1 infectivity and neutralization by a single amino acid replacement in the V3 loop domain.

The V3 loop (residues 303-338) of the human immunodeficiency virus type 1 (HIV-1) gp120 envelope protein represents a principal neutralizing determinant for the virus. An HIV-1 proviral clone containing a mutation in the V3 loop was constructed in which the proline residue at position 313 was changed to an alanine (P313-A). This mutation alters the conserved GPGR sequence that is found in the V3 loop sequences of different HIV-1 isolates. The P313-A clone produced virus particles, which were infectious for a number of T-cell lines including MOLT-4, CEM, and SupT1, but demonstrated a relatively low infectivity on the AA5 B-cell line when compared with wild-type viruses, HTLV-IIIB, HXB2/10 (a chimeric molecular clone), and another mutant virus (Q290-T). V3 loop-specific neutralizing polyclonal sera and the 9284 monoclonal antibody, which recognizes the amino side of the V3 loop sequence, effectively blocked infectivity and syncytia formation of all viruses tested. In contrast, the 0.5 beta monoclonal antibody, which is biologically more potent than 9284 and recognizes a different V3 loop determinant, failed to neutralize the P313-A virus. These results suggest that the proline residue in the relatively conserved GPGR "turn" region of the V3 loop is crucial for recognition by the 0.5 beta antibody. The observed variation in sensitivity of the B-cell line to the P313-A virus may reflect the presence of cell-specific factors which could be important in establishing an HIV-1 infection.