Emanuela Balestra

Evidence for antiviral activity of glutathione: in vitro inhibition of herpes simplex virus type 1 replication

The role of glutathione (GSH) in the in vitro infection and replication of human herpes simplex virus type 1 (HSV-1) was investigated. Intracellular endogenous GSH levels dramatically decreased in the first 24 h after virus adsorption, starting immediately after virus challenge. The addition of exogenous GSH was not only able to restore its intracellular levels almost up to those found in uninfected cells, but also to inhibit > 99% the replication of HSV-1. This inhibition was concentration-dependent, not related to toxic effects on host cells and also maintained if the exogenous GSH was added as late as 24 h after virus challenge, i.e. when virus infection was fully established. Electron microscopic examination of HSV-1-infected cells showed that GSH dramatically reduced the number of extracellular and intracytoplasmic virus particles, whereas some complete nucleocapsids were still detected within the nuclei of GSH-treated cells. Consistent with this observation, immunoblot analysis showed that the expression of HSV-1-glycoprotein B, crucial for the release and the infectivity of virus particles, was significantly decreased. Data suggest that exogenous GSH inhibits the replication of HSV-1 by interfering with very late stages of the virus life cycle, without affecting cellular metabolism.

TOPICAL TENOFOVIR, A MICROBICIDE EFFECTIVE AGAINST HIV, INHIBITS HERPES SIMPLEX VIRUS-2 REPLICATION

The HIV reverse-transcriptase inhibitor, tenofovir, was recently formulated into a vaginal gel for use as a microbicide. In human trials, a 1% tenofovir gel inhibited HIV sexual transmission by 39% and, surprisingly, herpes simplex virus-2 (HSV-2) transmission by 51%. We demonstrate that the concentration achieved intravaginally with a 1% tenofovir topical gel has direct antiherpetic activity. Tenofovir inhibits the replication of HSV clinical isolates in human embryonic fibroblasts, keratinocytes, and organotypic epithelial 3D rafts, decreases HSV replication in human lymphoid and cervicovaginal tissues ex vivo, and delays HSV-induced lesions and death in topically treated HSV-infected mice. The active tenofovir metabolite inhibits HSV DNA-polymerase and HIV reverse-transcriptase. To exert dual antiviral effects, tenofovir requires topical administration to achieve a drug concentration higher than systemic levels achieved by oral treatment. These findings indicate that a single topical treatment, like tenofovir, can inhibit the transmission of HIV and its copathogens.

Inhibition of replication of HIV in primary monocyte/macrophages by different antiviral drugs and comparative efficacy in lymphocytes

Several anti‐HIV drugs acting on different steps of virus replication were tested in our experimental model of primary monocyte/macrophages; the results were compared with the activity found in lymphocytes. Nucleoside analogues (AZT, ddl, ddC, d4T, PMEA, 3TC etc.) show greater activity in macrophages (M/M) than in lymphocytes. In particular, the EC50 of AZT, ddC, and ddI in M/M is 2‐ to 100‐fold lower than that found in lymphocytes. This greater efficacy of nucleoside analogues in M/M depends on the enhancement of their chain‐terminating activity by the low levels of endogenous deoxynucleoside‐triphosphates (dNTP) usually found in resting cells such as M/M. Non‐nucleoside reverse transcriptase inhibitors (NNRTI) do not act as chain terminators (thus their antiviral effect is not related to the intracellular concentrations of dNTP); as a consequence the activity of TSAO, HEPT, TIBO, and other NNRTI tested in M/M is similar to that found in lymphocytes. Regarding inhibitors of binding and fusion of HIV, we found that their anti‐HIV activity is markedly decreased (or even nullified) when M/M are treated with cytokine activators of M/M function and enhancers of HIV replication. More relevant from a clinical standpoint, protease inhibitors are able to inhibit HIV replication in chronically infected macrophages cells carrying the proviral genome already integrated in the host genome). All other inhibitors of late stage of virus life cycle tested (antisense‐rev, anti‐tat, interferon‐α and ‐γ, phosphorothioate analogues, GLQ‐223, etc.) were totally inactive in chronically infected macrophages. The different effects of various classes of HIV inhibitors in lymphocytes and macrophages suggests that AIDS therapy should consider all aspects of the pathogenesis of HIV infection and must be restricted to drugs, or combinations of drugs, active against both lymphocytes and M/M in all body compartments where the virus hides and replicates. J. Leukoc. Biol. 62: 138–143; 1997.

Enhancement of natural killer activity and interferon induction by different acyclic nucleoside phosphonates

Acyclic nucleoside phosphonate (ANP) analogues are a class of compounds with potent activity against herpesviruses and/or retroviruses. Our preliminary experiments have shown that 9-(2-phosphonylmethoxyethyl)adenine (PMEA), a prototype of the ANP family, enhances some parameters of natural immunity. In this paper we have evaluated the effect of different schedules of administration of PMEA and other ANP analogues of clinical interest upon natural killer (NK) activity and interferon (IFN) production in a mouse model. The results show that PMEA significantly enhances NK activity and interferon production. Other ANP analogues tested in our system, i.e., 9-(2-phosphonylmethoxyethyl)-2,6-diaminopurine (PMEDAP), and 9-(3-fluoro-2-phosphonylmethoxypropyl)adenine (FPMPA), similarly induced enhancement of natural immunity. The immunomodulating effect of PMEA was even more pronounced with a single administration compared to repeated administrations of the drug. Dose-dependent enhancement of NK activity and IFN production could also be demonstrated during chronic administration of PMEA (more resembling to what will be the schedule of administration of this drug in patients). Overall, the data here presented suggest that the enhancement of some natural immune functions induced by ANP analogues may add to the direct antiviral activity of these drugs against retroviruses and herpesviruses, and thus may be able to increase the host resistance against viral infections.

Primary macrophages infected by human immunodeficiency virus trigger CD95-mediated apoptosis of uninfected astrocytes

Infection of macrophages (M/M) by human immunodeficiency virus (HIV) is a main pathogenetic event leading to neuronal dysfunction and death in patients with AIDS dementia complex. Alteration of viability of neurons and astrocytes occurs in vivo even without their infection, thus it is conceivable that HIV‐infected M/M may affect viability of such cells even without direct infection. To assess this hypothesis, we studied the effects of HIV‐infected M/M on an astrocytic cell‐line lacking CD4‐receptor expression. Exposure to supernatants of HIV‐infected M/M triggers complete disruption and apoptotic death of astrocytic cells. This effect is not related to HIV transmission from infected M/M, because HIV‐DNA and p24 production in astrocytic cells remained negative. Apoptotic death of astrocytes is mainly mediated by Fas ligand released in supernatants of HIV‐infected M/M (as demonstrated by complete reversal of such phenomenon by adding neutralizing antibodies against CD95 receptor). Treatment of astrocytic cells with recombinant (biologically active) Tat induces <10% apoptosis, and gp120 was totally ineffective. Treatment of HIV‐infected M/M with AZT completely reverses the proapoptotic effect of their supernatants on astrocytes, thus demonstrating that productive virus replication within M/M is required for the induction of astrocytic cell death.

Drug-loaded red blood cell-mediated clearance of HIV-1 macrophage reservoir by selective inhibition of STAT1 expression

Current highly active antiretroviral therapy (HAART) cannot eliminate HIV‐1 from infected persons, mainly because of the existence of refractory viral reservoir(s). Beyond latently‐infected CD4+‐T lymphocytes, macrophages (M/M) are important persistent reservoirs for HIV in vivo, that represent a major obstacle to HIV‐1 eradication. Therefore, a rational therapeutic approach directed to the selective elimination of long‐living HIV‐infected M/M may be relevant in the therapy of HIV infection. Here we report that HIV‐1 chronic infection of human macrophages results in the marked increase of expression and phosphorylation of STAT1, a protein involved in the regulation of many functions such as cell growth, differentiation, and maintenance of cellular homeostasis, thereby providing a new molecular target for drug development. A single and brief exposure to 9‐(β‐D‐arabinofuranosyl)‐2‐fluoroadenine 5′‐monophosphate (FaraAMP, Fludarabine), a potent antileukemic nucleoside analog active against STAT1 expressing cells, selectively kills macrophage cultures infected by HIV‐1 without affecting uninfected macrophages. Furthermore, encapsulation of Fludarabine into autologous erythrocytes (RBC) and targeting to macrophages through a single‐18 h treatment with drug‐loaded RBC, not only abolishes the Fludarabine‐mediated toxic effect on non‐phagocytic cells, but also enhances the selective killing of HIV‐infected macrophages. As a final result, a potent (>98%) and long‐lasting (at least 4 weeks without rebound) inhibition of virus release from drug‐loaded RBC‐treated chronically‐infected macrophages was achieved. Taken together, the evidence of HIV‐1‐induced increase of STAT1, and the availability of a selective drug targeting system, may prove useful in the design of new pharmacological treatments to clear the HIV‐1 macrophage reservoir.

Macrophage depletion induced by clodronate-loaded erythrocytes.

Given the important role of macrophages in various disorders, the transient and organ specific suppression of their functions may benefit some patients. Until now, liposome-encapsulated bisphosphonate clodronate has been extensively proposed to this end. In this paper, we demonstrate that erythrocytes loaded with clodronate can also be effective in macrophage depletion. Here, clodronate was encapsulated in erythrocytes through hypotonic dialysis, isotonic resealing and reannealing to final concentrations of 4.1±0.4 and 10.1±0.8 μmol/ml of human and murine erythrocytes, respectively. The ability of clodronate-loaded erythrocytes to deplete macrophages was evaluated both in vitro and in vivo. In vitro studies on human macrophages showed that a single administration of engineered erythrocytes was able to reduce cell adherence capacity in a time-dependent manner, reaching 50±4% reduction, 13 days post treatment. The administration of loaded erythrocytes to cultures of murine peritoneal macrophages was able to reduce macrophage adhesion 67±3%, 48 h post treatment. In vivo, the ability of clodronate-loaded erythrocytes to deplete macrophages was evaluated both in Swiss and C57BL/6 mice. Swiss mice received 125 μg of clodronate through eryhtrocytes and 6 days post treatment 69±7% reduction in the number of adherent peritoneal macrophages and 75±5% reduction in number of spleen macrophages were observed. C57BL/6 mice received 220 μg clodronate by RBC and 3 and 8 days post treatment 65±7% reduction in the number of spleen macrophages and the complete depletion of liver macrophages were obtained. In summary, our results indicate that clodronate selectively targeted to the phagocytic cells by a single administration of engineered erythrocytes is able to deplete macrophages, even if not completely. The transient suppression of macrophage functions through clodronate-loaded erythrocytes can be used in many biomedical phenomena and research applications.

HIV-1 dual/mixed tropic isolates show different genetic and phenotypic characteristics and response to maraviroc in vitro

Dual/mixed-tropic HIV-1 strains are predominant in a significative proportion of patients, though few information is available regarding the genetic characteristics, quasispecies composition, and susceptibility against CCR5-antagonists of the primary-isolates. For this reason, we investigated in deep details, both phenotypically and genotypically, the characteristics of 54 HIV-1 primary-isolates obtained from HIV-infected patients. Tropism was assessed by multiple-cycles phenotypic-assay on U87MG-CD4(+)-CCR5(+)-/CXCR4(+)-expressing cells. In vitro selection in PBMCs of X4-tropic viral strains following maraviroc-treatment was also performed. Phenotypic-assay reported pure R5-tropic viruses in 31 (57.4%) isolates, dual/mixed-tropic viruses in 22 (40.7%), and pure X4-tropic virus in only 1 (1.8%). Among dual/mixed-tropic isolates, 12 showed a remarkably higher replication-efficacy in CCR5-expressing cells (R5(+)/X4), and 2 in CXCR4-expressing cells (R5/X4(+)). Genotypic-tropism testing showed a correlation between PSSM-scores, geno2pheno false-positive-rate, and V3-net-charge with both CCR5-usage and syncytium-inducing ability. Moreover, specific gp120- and gp41-mutations were significantly associated with tropism and/or syncytium-inducing ability. Ultra-deep V3-pyrosequencing showed the presence of a swarm of genetically distinct species with a preference for CCR5-coreceptor not only in all pure R5-isolates, but also in 6/7 R5(+)/X4-tropic isolates. In both pure-X4 and R5/X4(+)-isolates, we observed extensive prevalence of X4-using species. In vitro selection-experiments with CCR5-inhibitor maraviroc (up to 2 months) showed no-emergence of X4-tropic variants for all R5- and R5(+)/X4-isolates tested (while X4-virus remained fully-resistant). In conclusion, our study shows that dual/mixed-tropic viruses are constituted by different species, whereby those with characteristics R5(+)/X4 are genotypically and phenotypically similar to the pure-R5 isolates; thus the use of CCR5-antagonists in patients with R5(+)/X4-tropic viruses may be a therapeutic-option that deserves further investigations.

The lowest X4 Geno2Pheno false-positive rate is associated with greater CD4 depletion in HIV-1 infected patients

Through this study we evaluated whether the HIV-1 tropism determined by genotypic analysis correlates with HIV-1 markers, such as CD4 cell count and plasma HIV-RNA. The analysis was performed on 1221 HIV-1 B-subtype infected patients with an available V3 sequence (all maraviroc naive). Of them, 532 were antiretroviral therapy (ART) naive and 689 ART experienced. Tropism determination was performed by using the geno2pheno (co-receptor) algorithm set at a false-positive rate (FPR) of 10% and 2%. Potential associations of FPR with CD4 cell count and viraemia were evaluated. Association of V3 mutations with genotypic-determined tropism was also evaluated according to different FPR ranges. About 26% of patients (either ART naive or ART experienced) were infected by X4-tropic viruses (using the classical 10% FPR cut-off). However, a significantly lower proportion of ART-naive patients had FPR ≤ 2% in comparison with ART-experienced patients (4.9% vs. 12.6%, respectively, p <0.001). The risk of advanced HIV-1 infection (with CD4 cell count ≤ 200 cells/mm(3)) was significantly greater in X4-infected patients, either ART-naive (OR (95% CI)), 4.2 (1.8-9.2); p 0.0006) or ART-experienced (2.3 (1.4-3.6); p 0.0003), with FPR set at 2% (but not at 10%). This finding was confirmed by multivariable logistic analysis. No relationship was found between viraemia and FPR ≤2%. Some X4-related mutations were significantly associated with FPR ≤2% (ART-naive patients, S11R, Y21V, G24K and G24R, p ≤0.001; ART-experienced patients, Y7K, S11R, H13Y, p ≤0.002). In conclusion, these findings show that within the context of genotypically-assessed CXCR4 tropism, FPR ≤2% defines (far better than 10%-FPR) a viral population associated with low CD4 rank, with potentially greater cytopathic effect, and with more advanced disease.

A killer mimotope with therapeutic activity against AIDS-related opportunistic micro-organisms inhibits ex-vivo HIV-1 replication.

Objective:To verify whether a synthetic therapeutic killer decapeptide (KP), a functional mimotope of a yeast killer toxin with wide-spectrum microbicidal activity, inclusive of AIDS-related opportunistic micro-organisms, through interaction with β-glucan receptors, which has been found to possess sequence homology with critical segments in gp160 V1/V2 and V3 loops, may also be inhibiting HIV-1 replication. Methods:Primary peripheral blood mononuclear cells (PBMCs) cultures established from HIV-1-infected patients were treated with KP in comparison with zidovudine and supernatants and cells were harvested for analysis of HIV RNA and proviral contents, respectively. Virus production in exogenous in-vitro PBMCs infection with lymphocytotropic and monocytotropic HIV-1 strains was also assessed in presence of KP by enzyme-linked immunosorbent assay HIV p24 gag antigen detection. The binding affinity of KP to CD4, CCR5 and CXCR4 was evaluated on CD4-CCR5 or CD4-CXCR4 transfected astroglioma cell lines. Results:KP was shown to be devoid of cytotoxicity on PBMCs and to inhibit HIV-1 replication in PBMCs of a patient in the acute phase of infection. The antiretroviral activity of KP, which proved to be more potent than zidovudine at micromolar concentrations, is abolished by β 1,3-glucan but not by β 1,6-glucan. Down-regulation of CCR5 co-receptor, and/or physical block of the gp120-receptor interaction are possible mechanisms of KP activity. Conclusion:KP appears to be the first antibody-derived short peptide displaying an inhibitory activity against HIV-1 and related opportunistic micro-organisms by different mechanisms of action.