Exploitation of Langerhans cells for in vivo DNA vaccine delivery into the lymph nodes.

There is no clinically available cancer immunotherapy that exploits Langerhans cells (LCs), the epidermal precursors of dendritic cells (DCs) that are the natural agent of antigen delivery. We developed a DNA formulation with a polymer and obtained synthetic 'pathogen-like' nanoparticles that preferentially targeted LCs in epidermal cultures. These nanoparticles applied topically under a patch-elicited robust immune responses in human subjects. To demonstrate the mechanism of action of this novel vaccination strategy in live animals, we assembled a high-resolution two-photon laser scanning-microscope. Nanoparticles applied on the native skin poorly penetrated and poorly induced LC motility. The combination of nanoparticle administration and skin treatment was essential both for efficient loading the vaccine into the epidermis and for potent activation of the LCs to migrate into the lymph nodes. LCs in the epidermis picked up nanoparticles and accumulated them in the nuclear region demonstrating an effective nuclear DNA delivery in vivo. Tissue distribution studies revealed that the majority of the DNA was targeted to the lymph nodes. Preclinical toxicity of the LC-targeting DNA vaccine was limited to mild and transient local erythema caused by the skin treatment. This novel, clinically proven LC-targeting DNA vaccine platform technology broadens the options on DC-targeting vaccines to generate therapeutic immunity against cancer.

Latent infection of CD4+ T cells provides a mechanism for lifelong persistence of HIV-1, even in patients on effective combination therapy.

Combination therapy for HIV-1 infection can reduce plasma virus to undetectable levels, indicating that prolonged treatment might eradicate the infection. However, HIV-1 can persist in a latent form in resting CD4+ T cells. We measured the decay rate of this latent reservoir in 34 treated adults whose plasma virus levels were undetectable. The mean half-life of the latent reservoir was very long (43.9 months). If the latent reservoir consists of only 1 x 10(5) cells, eradication could take as long as 60 years. Thus, latent infection of resting CD4+ T cells provides a mechanism for lifelong persistence of HIV-1, even in patients on effective anti-retroviral therapy.

Hydroxyurea as an inhibitor of human immunodeficiency virus-type 1 replication.

Hydroxyurea, a drug widely used in therapy of several human diseases, inhibits deoxynucleotide synthesis--and, consequently, DNA synthesis--by blocking the cellular enzyme ribonucleotide reductase. Hydroxyurea inhibits human immunodeficiency virus-type 1 (HIV-1) DNA synthesis in activated peripheral blood lymphocytes by decreasing the amount of intracellular deoxynucleotides, thus suggesting that this drug has an antiviral effect. Hydroxyurea has now been shown to block HIV-1 replication in acutely infected primary human lymphocytes (quiescent and activated) and macrophages, as well as in blood cells infected in vivo obtained from individuals with acquired immunodeficiency syndrome (AIDS). The antiviral effect was achieved at nontoxic doses of hydroxyurea, lower than those currently used in human therapy. Combination of hydroxyurea with the nucleoside analog didanosine (2',3'-dideoxyinosine, or ddl) generated a synergistic inhibitory effect without increasing toxicity. In some instances, inhibition of HIV-1 by hydroxyurea was irreversible, even several weeks after suspension of drug treatment. The indirect inhibition of HIV-1 by hydroxyurea is not expected to generate high rates of escape mutants. Hydroxyurea therefore appears to be a possible candidate for AIDS therapy.

Control of SIV rebound through structured treatment interruptions during early infection.

In a randomized controlled trial with acute simian immunodeficiency virus (SIV)-infected macaques, both highly active antiretroviral therapy (HAART) and HAART with fixed-schedule structured treatment interruption (STI-HAART; alternating 3 weeks on and 3 weeks off therapy) suppressed viral load. In the STI-HAART group, T cell virus-specific immune response (VIR) and control of viral rebound increased concurrently during subsequent interruptions. In contrast, VIR did not increase and SIV rebounded after permanent treatment withdrawal in all animals on continuous HAART. Fixed-schedule STI-HAART appears to be an effective alternative to continuous HAART for the early treatment of retroviral infection.

Nanochemistry-based immunotherapy for HIV-1.

Highly active antiretroviral treatment (HAART), i.e. the combination of three or more drugs against human immunodeficiency virus type 1 (HIV-1), has greatly improved the clinical outcome of HIV-1-infected individuals. However, HAART is unable to reconstitute HIV-specific immunity and eradicate the virus. Several observations in primate models and in humans support the notion that cell-mediated immunity can control viral replication and slow disease progression. Thus, besides drugs, an immunotherapy that induces long-lasting HIV-specific T-cell responses could play a role in the treatment of HIV/AIDS. To induce such immune responses, DermaVir Patch has been developed. DermaVir consists of an HIV-1 antigen-encoding plasmid DNA that is chemically formulated in a nanoparticle. DermaVir is administered under a patch after a skin preparation that supports the delivery of the nanoparticle to Langerhans cells (LC). Epidermal LC trap and transport the nanomedicine to draining lymph nodes. While in transit, LC mature into dendritic cells (DC), which can efficiently present the DNA-encoded antigens to naïve T-cells for the induction of cellular immunity. Pre-clinical studies and Phase I clinical testing of DermaVir in HIV-1-infected individuals have demonstrated the safety and tolerability of DermaVir Patch. To further modulate cellular immunity, molecular adjuvants might be added into the nanoparticle. DermaVir Patch represents a new nanomedicine platform for immunotherapy of HIV/AIDS. In this review, the antiviral activity of DermaVir-induced cellular immunity is discussed. Furthermore, the action of some cytokines currently being tested as adjuvants are highlighted and the adjuvant effect of cytokine plasmid DNA included in the DermaVir nanoparticle is reviewed.

Virostatics: a new class of anti-HIV drugs.

In this review we discuss the features of a new class of antiretroviral combinations, namely "Virostatics". Virostatics are characterized by the combination of a drug directly inhibiting virus production (viro), and another drug indirectly inhibiting the virus by reducing cellular proliferation (static). In particular, we will focus on the combination of hydroxyurea and didanosine against HIV-1. Hydroxyurea and didanosine synergize to control viral replication and present with a favorable resistance profile, suppressing several resistant quasi-species. Because virostatics target essential cellular proteins, they exert an immune modulating activity and reduce viral targets (CD4 T cells), possibly with limited immunosuppressive effects. Importantly, a dose-finding clinical study has shown that decreasing the dose of hydroxyurea not only diminishes toxicity but also increases antiviral potency. Therefore, the combination of hydroxyurea and didanosine strikes a balance between viral suppression, drug-related toxicity and viral escape, and could have a role both in induction and maintenance therapy. In this review we would like to appraise what is known about hydroxyurea and didanosine and specifically address the major advantages, i.e. novel mechanism of action leading to a new class of drugs and resistance profile providing durability, as well as the major criticisms of this combination, i.e. toxicity and reasons for prescribing a perceived immune suppressant to immune compromised patients.

Analysis of amino insertion mutations in the fingers subdomain of HIV-1 reverse transcriptase.

In response to dideoxy inosine/hydroxyurea dual therapy, HIV-1 (human immunodeficiency virus type-1) variants were isolated that had a small amino acid insertion and flanking amino acid substitutions in the fingers subdomain of HIV-1. We have analyzed the reverse transcriptase variants for their effects on HIV-1 reverse transcriptase activity. The data suggests that the inserted amino acid residues are responsible for low-level resistance to the nucleoside analog ddITP, while the role of the flanking amino acid substitutions is to compensate for the deleterious effects of the insertion.

Lowering the dose of hydroxyurea minimizes toxicity and maximizes anti-HIV potency.

The goal of this study was to optimize the hydroxyurea dosage in HIV-infected patients, and to minimize the toxicity and maximize the antiviral efficacy of the hydroxyurea-didanosine combination. In a randomized, open-label study (RIGHT 702, a multicenter trial performed in private and institutional practices), three daily doses (600 microg, 800-900 microg, and 1200 microg) of hydroxyurea were administered in combination with didanosine and stavudine to 115 chronically HIV-infected patients, one-third antiretroviral drug naive, with viremia between 5000 and 200,000 copies/ml regardless of CD4+ cell count. The primary efficacy end point was the proportion of patients with plasma HIV-1 RNA levels below 400 copies/ml after 24 weeks of therapy. In the RIGHT 702 intent-to-treat population the lowest (600 mg) dose of hydroxyurea was better tolerated, associated with fewer adverse events, and more potent by all efficacy parameters, including the primary end point (76 versus 60% patients with viremia<400 copies/ml at week 24 for the 600-mg and 800- to 900-mg dose groups, respectively; p=0.027), the mean area under the curve (60.3 versus 65.8; p=0.016), and the mean log10 decrease (-1.95 versus -0.77; p=0.001). Patients receiving 600 mg of hydroxyurea daily also had the highest CD4+ cell count, CD4+/CD8+ cell ratio, and lowest CD8+ cell count and percentage (p=0.035). The RIGHT 702 trial provides an explanation for the increased toxicity and decreased efficacy of hydroxyurea when it was used at high dosage (1200 mg daily). At the optimal dosage of 600 mg daily, hydroxyurea, in combination with didanosine, deserves reevaluation for the long-term management of HIV/AIDS worldwide, because of its excellent resistance profile, durability, and affordability.

Expansion of CD57 and CD62L-CD45RA+ CD8 T lymphocytes correlates with reduced viral plasma RNA after primary HIV infection.

OBJECTIVE: CD8 T cells, expressing cell surface molecules distinct from those on resting and naive T cells, are increased in HIV infection. The association of increased CD38 and human leukocyte antigen DR (HLA-DR) CD8 T cells with poor prognosis has suggested that activated CD8 T cells may aggravate HIV infection. We examined whether other immunological parameters might influence the viral setpoint. DESIGN: Peripheral T cells from nine untreated patients, obtained after primary HIV infection when plasma HIV had stabilized, were examined for proteins expressed in activated versus resting, memory versus naive, and cytolytic versus non-cytolytic T cells. METHODS: The proportion of CD8 T cells that stain for CD38 and HLA-DR, CD28 and CD57 was compared with plasma viraemia and CD4 cell count. These parameters were also compared with the proportion of CD4 and CD8 T cells that express CD62L and CD45RA, present on naive cells and down-modulated in memory cells. Internal staining for the cytotoxic protein granzyme A was also examined. RESULTS: An increase in CD38 and CD38 HLA-DR CD8 T cells correlated with increased plasma viral RNA (P < 0.00002, P < 0.03, respectively). An increase in CD8 T cells expressing granzyme A was associated with lower CD4 cell counts (P < 0.04). However, the expansion of CD57 and CD62L CD45RA+ CD8 T cells was associated with a lower viral setpoint (P < 0.01, P < 0.02, respectively). CONCLUSION: Phenotypically defined activated CD8 T cells may have different functions in HIV infection. Activated CD8 T cells that are CD57 or CD62L(-)CD45RA+ may be beneficial, because their expansion in untreated patients correlates with a reduced viral setpoint after primary infection.

Direct analysis of mitochondrial toxicity of antiretroviral drugs.

OBJECTIVES: Mitochondrial toxicity is a serious side-effect of antiretroviral drugs, especially nucleoside reverse transcriptase inhibitors (NRTI). An in vitro assay to predict mitochondrial toxicity of in-use and developmental NRTI would be invaluable. To test the ability of a cytofluorimetric technique to predict the mitochondrial-dependent pancreatic and hepatic toxicity we used didanosine (ddI) alone or in combination with hydroxyurea (HU). METHODS: The technique is based on the ability of the lipophilic cation JC-1 to enter selectively into mitochondria and change its colour as the membrane potential changes due to toxicity. Mitochondrial toxicity by HU and ddI was evaluated in pancreatic and hepatic human cell lines. The results were expressed as mitochondrial toxicity index (MTI), ranging from 0 to 100: the negative control was 0, and 100 indicating maximal toxicity. RESULTS: Dose-dependent pancreatic toxicity of ddI was evident after 14 days of culture (MTI 34 +/- 4 at 100 microM, 10 +/- 4 at 10 microM, 2 +/- 3 at 1 microM ddI). HU alone was not toxic (MTI 7 +/- 10 at 100 microM, 2 +/- 2 at 50 microM and 2 +/- 4 at 10 microM HU); however, HU increased the toxicity of high, but not low, concentrations of ddI. For example, the MTI of 10 microM ddI plus 50 microM HU was 54 +/- 9. Negligible mitochondrial toxicity was observed in the hepatic cell line exposed to ddI alone or in combination with HU. CONCLUSIONS: This in vitro assay might have in vivo relevance. First, ddI-related pancreatitis is dose dependent, and is reported more frequently than hepatic failure, consistent with our in vitro results. Second, patients who developed pancreatitis during randomized, controlled trials were treated with HU in combination with 400 mg ddI once daily (high peak concentration of ddI in the blood). In contrast, no pancreatitis was observed when HU was combined with 200 mg ddI twice daily (low peak concentration of ddI). These in vivo results are consistent with our in vitro observation that HU increases pancreatic cell toxicity in the presence of high concentrations of ddI. The in vitro assay described here might be used to predict the mitochondrial toxicity of other NRTI, alone or in combination.

Efficacy of antitat gene therapy in the presence of high multiplicity infection and inflammatory cytokines.

Because human immunodeficiency virus type 1 (HIV-1) infection is characterized by a large number of viral replication cycles and rapid cell turnover in vivo, successful gene therapy requires an approach effective under these conditions. The antitat gene has been proposed for gene therapy because it effectively blocks Tat function and the replication of HIV-1. However, neither antitat nor any other antiviral gene has been shown to inhibit HIV in the presence of high viral load and inflammatory cytokines, a condition closer to the in vivo situation. We show that cells transduced with antitat retrovirus vector are resistant to high multiplicity of HIV infection. In the presence of inflammatory cytokines, including interleukin-1 and tumor necrosis factor, both known to activate viral gene expression independently of Tat, antitat suppressed virus replication. HIV-1 inhibition was observed when cell were treated with a mixture of inflammatory cytokines able to induce acquired immunodeficiency syndrome (AIDS) Kaposi's sarcoma cell growth. These molecules have been shown to be increased in HIV-1-infected individuals, and it is suggested they play a role in the pathogenesis of AIDS. Our results suggest that antitat is effective under conditions present in vivo and therefore a primary candidate for HIV-1 gene therapy.

Combination gene therapy: synergistic inhibition of human immunodeficiency virus Tat and Rev functions by a single RNA molecule.

Current drug combinations can achieve long-term suppression of HIV replication in infected individuals. Unfortunately, complicated dosing schedules and high toxicity make long-term compliance with drug regimens difficult for most patients. Gene therapy may provide a permanent solution for HIV disease by generating cells genetically resistant to virus replication. As with the highly active antiretroviral therapies, genetic drugs must have strong antiviral potency and the ability to prevent the emergence of escape mutants. We have constructed antiviral genes containing unique combinations of Tat- and Rev-binding decoys. The new antiviral molecules are chimeric TAR-RRE RNAs that are expressed only in HIV infected cells in a Tat-regulated manner. One RNA molecule competes for both Tat and Rev binding, and thus blocks the activation and the expression of all viral genes. The two functional Tat- and Rev-binding domains exhibit the highest synergy at the lowest concentration. Conservative quantitative estimates of this synergistic effect were I = 0.24 at 50% inhibition, in terms of the Berenbaum "interaction index," indicating that the combined construct was approximately fourfold more potent than would be predicted on the basis of additive effects. The possibility of HIV escape from this inhibition is unlikely, because it requires simultaneous mutation of TAR and RRE in a manner in which both Tat and Rev preserve their respective functions. TAR-RRE combination decoys represent the first example of mathematically proven synergistic antiviral activity between two domains of the same molecule.

Hydroxyurea: mechanisms of HIV-1 inhibition.

Hydroxyurea inhibits cellular ribonucleotide reductase, resulting in decreased pools of dNTPs and thus inhibition of DNA synthesis. Studies in vitro have shown that hydroxyurea reduces dNTP pools in cells infected with human immunodeficiency virus type 1 (HIV-1), inhibiting HIV-1 DNA synthesis in infected quiescent and activated primary human lymphocytes and macrophages. Hydroxyurea also potentiates the activity of nucleoside reverse transcriptase inhibitors (NRTIs): the activated triphosphate forms of NRTIs compete with naturally occurring dNTPs for incorporation into nascent viral DNA during reverse transcription. A synergistic effect is observed between hydroxyurea and didanosine (2',3'-dideoxyinosine; DDI). This combination exerts persistent suppression of HIV-1 replication without evidence of viral rebound for over 1 year in HIV-1-infected patients. Didanosine-resistant HIV-1 mutants retain sensitivity to didanosine in the presence of hydroxyurea. The incorporation of didanosine triphosphate by resistant reverse transcriptase is increased in the context of the hydroxyurea-induced depletion of dATP. Although hydroxyurea has a reduced effect on dNTPs competing with the triphosphate forms of pyrimidine NRTIs, it appears to augment the anti-HIV-1 activity of these agents by increasing their intracellular phosphorylation; this may be of particular interest for salvage strategies given recent data indicating disruption of NRTI phosphorylation with specific NRTI treatment regimens. Finally, by exerting a cytostatic effect on CD4 and CD8 T lymphocytes, hydroxyurea may (i) reduce HIV-1 replication by decreasing CD4 T cell proliferation; and (ii) prevent the exhaustion of CD8 T cell populations that may occur as a result of excessive activation in the context of HIV-1 infection.

Cellular factors: targets for the treatment of HIV infection.

On 19-20 April 1998, researchers and clinical investigators from around the world gathered in Pavia, Italy, for Cellular Factors: Targets for the Treatment of HIV Infection, a comprehensive 2 day meeting designed to share the most recent findings in human immunodeficiency virus (HIV) and AIDS treatment research. Because viral replication is dependent on the host cell machinery, many researchers are seeking new treatment strategies that control HIV by limiting the availability of cellular proteins and metabolic functions. Other approaches, such as gene therapy, seek to confer cellular resistance to the effects of viral gene products. Conference participants discussed a range of new therapeutic approaches, as well as new research into the workings of the cells that are targets of HIV infection. The meeting was sponsored by the Research Institute for Genetic and Human Therapy (RIGHT), with the support of Bristol-Myers Squibb Immunology and Policlinico San Matteo. Established in 1994 and codirected by Drs Julianna Lisziewicz and Franco Lori, RIGHT is a non-profit organization dedicated to translating basic research into clinical trials. With laboratories at Georgetown University in Washington, DC, and at the Policlinico San Matteo in Pavia, Italy, RIGHT works with an international research network of molecular biologists, virologists and immunologists to understand how diseases might be attacked at the molecular level. Current research focuses on prevention and treatment of HIV infection. Several clinical studies are now underway. Hydroxyurea, which targets a cellular enzyme, is being tested in combination with antiretroviral drugs to inhibit HIV-1 replication and control the onset of resistance. In gene therapy pilot studies, a novel antiviral gene is being tested for its ability to confer cellular resistance to HIV.

Hydroxyurea: overview of clinical data and antiretroviral and immunomodulatory effects.

Data from comparative trials involving more than 500 patients indicate that hydroxyurea is safe and augments suppression of HIV-1 replication when used in combination with didanosine or didanosine/stavudine as initial therapy or in patients without extensive antiretroviral experience. Additional studies will determine the optimum dosage and schedule for hydroxyurea and its effects when used with other agents and in patients with advanced disease or extensive pretreatment. Activities of hydroxyurea include inhibition of HIV-1 in active and resting CD4 lymphocytes and macrophages, potentiation of the activity of nucleoside reverse transcriptase inhibitors (NRTIs), compensation for resistance to adenosine analogue NRTIs, and potential increased phosphorylation of pyrimidine NRTIs. Recent attention, however, has focused on the potential immunomodulatory effects of hydroxyurea. The cytostatic effect of this agent on both CD4 and CD8 T cells may provide immunological benefits by reducing immune system overactivation, thus preventing both CD8 T cell exhaustion and CD4 T cell depletion. Accumulating evidence indicates that hydroxyurea-containing regimens may be associated with decreased levels of activated CD8 T cells, increased levels of naive CD4 and CD8 T cells, and preservation of the HIV-1-specific immune response. Further study of the potential for beneficial immunomodulation with hydroxyurea-containing regimens is needed to ascertain the clinical implications of these initial findings.

Hydroxyurea and didanosine is a more potent combination than hydroxyurea and zidovudine.

The in vitro and in vivo antiviral activity of hydroxyurea in combination with either zidovudine or didanosine was evaluated in primary human peripheral mononuclear cells and in a cohort of 29 asymptomatic patients infected with HIV. In vitro, hydroxyurea alone did not significantly affect HIV replication, whereas the combination of hydroxyurea with didanosine was more effective than the combination of hydroxyurea with zidovudine. Our clinical results confirmed these studies. Patients were randomly assigned to five arms (zidovudine, hydroxyurea or didanosine monotherapy, or hydroxyurea in combination with either zidovudine or didanosine) to evaluate preliminary safety and efficacy. Bone-marrow toxicity occurred in two patients treated with zidovudine plus hydroxyurea, alopecia was reported in one patient treated with hydroxyurea monotherapy, and there were no toxic effects recorded in the remaining three groups. Plasma viraemia was not influenced by hydroxyurea monotherapy, and the hydroxyurea-zidovudine combination did not give any advantage over either zidovudine or didanosine monotherapy (0.3-0.5 log decrease in plasma viraemia). In contrast, a 1.1 log drop in plasma viraemia was observed in patients treated with hydroxyurea plus didanosine, this reduction was sustained throughout the 24-week course of the treatment. Combination therapy with hydroxyurea and didanosine exhibited statistically significant improvements compared with the other therapeutic approaches. Although further clinical trials are required, these results suggest that hydroxyurea in combination with didanosine might be an effective and well-tolerated, simple and affordable, treatment for HIV infection.

"Virostatics" as a potential new class of HIV drugs.

The combination of three or more antiretroviral drugs is referred to as highly active antiretroviral therapy (HAART) and constitutes the standard of care for HIV-1 patients in industrialized nations. Although HAART is usually effective in reducing viral load and re-constituting CD4 counts, latent virus reservoirs persist, and as many as 60 years therapy [1, 2] may be required to eradicate the virus. Meanwhile, patients are likely to experience drug related toxicity and may have to change therapy due to the emergence of drug resistant strains. For these reasons, the search for different therapeutic approaches continues. A new concept of antiviral/cytostatic ("virostatics") drugs has been proposed within the context of HAART to restrict virus target populations (CD4(+) T lymphocytes), target viral reservoirs, and possibly restore immune functions, by reducing excess immune activation, a fundamental component of HIV/AIDS pathogenesis. These virostatics include drugs such as hydroxyurea, mycophenolic acid, leflunomide and rapamycin, which are currently used for other therapeutic indications; and other experimental drugs, which are not for human use. They utilize multiple novel mechanisms of action to impede HIV by targeting host cellular proteins that are not susceptible to mutation. Therefore, their resistance profile appears to be quite favorable. Since many of these drugs act by inhibiting the synthesis of deoxynucleotides, essential for HIV reverse transcription, they favor the incorporation of nucleoside analogues into viral DNA, thus synergizing with the antiviral activity of currently used nucleoside reverse transcriptase inhibitors (NRTI). The rationale for the use of virostatics in HIV/AIDS, their mechanism of action, and ongoing preclinical and clinical research will be reviewed.

Immune restoration by combination of a cytostatic drug (hydroxyurea) and anti-HIV drugs (didanosine and indinavir).

Cell activation is essential for HIV infection. CD4+ T lymphocyte activation allows virus replication and CD8+ T lymphocyte activation may contribute to pathogenesis. We combined hydroxyurea, a cytostatic drug that inhibits cell activation and proliferation, with two drugs that inhibit HIV (didanosine and indinavir), to block the "cell activation-virus production-pathogenesis" cycle. HIV was strongly suppressed in treated patients, and the average CD4 count increased to 224/mm3. Compared with a matched group of patients who had declined antiretroviral treatment, treated patients had a significantly lower proportion of activated CD8+ T lymphocytes and a significantly higher number of naive CD8+ and CD4+ T lymphocytes. The proliferative responses to allogeneic and influenza virus antigens were increased in treated patients, and a defect in CD3-zeta expression, the signaling chain of the T cell receptor complex, was reversed. The use of a cytostatic drug was not detrimental to the immune system; on the contrary, the combination of antiviral and cytostatic treatment improved all of the immune parameters tested.

Antisense phosphorothioate oligodeoxynucleotides alter HIV type 1 replication in cultured human macrophages and peripheral blood mononuclear cells.

The use of antisense oligodeoxynucleotides as antiviral drugs to combat HIV-1 infection may offer an alternative to traditional pharmacological therapies. We compared the effects of two 28-mer antisense phosphorothioate oligodeoxynucleotides [PS-oligo(dN)] with non-sequence-specific controls on HIV-1 replication in long-term human monocyte/macrophage and PBMC cultures. The anti-rev PS-oligo(dN) was complementary to the messenger RNA (mRNA) sequences derived from the overlapping region of the HIV-1 regulatory genes tat and rev, while anti-gag targeted the translational initiation site of the gag mRNA. In vitro cytotoxicity of the PS-oligo(dN) was evaluated at concentrations ranging from 0.1 to 10.0 microM for a period of 20 days. Cell survival was 100% at 0.1 microM, but decreased to 5% at 10.0 microM in relation to the untreated control cultures. Our data demonstrate that replication of both the T cell-tropic and macrophage-tropic HIV-1 strains in primary cells can be inhibited by PS-oligo(dN) in a sequence-specific and dose-dependent manner at concentrations achievable in vivo. However, the sequence-dependent antiviral activity of the utilized PS-oligo(dN) was limited to a window of specificity at concentrations between 0.25 and 1.0 microM.

Hydroxyurea and didanosine long-term treatment prevents HIV breakthrough and normalizes immune parameters.

Hydroxyurea and didanosine treatment suppressed HIV replication for more than 2 years, in the absence of viral breakthrough, in chronically infected patients. The profile of viral load reduction was unusual for a two-drug combination, since a continuous gradual decrease in viremia persisted despite residual viral replication. The increase in CD4+ T cell counts was not robust. However, unlike those of patients treated by other therapies, CD4+ T lymphocytes were functionally competent against HIV, mediating a vigorous HIV-specific helper T cell response in half of these patients. In addition, the percentages of naive CD4+ and CD8+ T lymphocytes were not different from those in uninfected individuals. These results demonstrate that prolonged antiretroviral therapy with a simple, well-tolerated combination of two affordable drugs can lead to sustained control of HIV, normalization of immune parameters, and specific anti-HIV immune response.