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

The Emergence and Epidemiology of Resistance in the Nucleoside-Experienced HIV-Infected Population

HIV drug resistance remains one of the most important influences on long-term therapeutic prospects. Resistance and therapeutic failure arises out of the selection and preservation of randomly generated genomic mutations that confer a replicative advantage in the presence of one or more antiretrovirals. The primary correlate to the time to emergence of a drug-resistant HIV variant is the extent of residual replication under selecting drug pressure, emphasizing the importance of full virological suppression to long-term therapy. Further contributions to the time to emergence are the degree of selective pressure exerted by a given drug, whereby greater potency forces earlier selection of mutant strains in balance with the extent of residual replication, and the degree of reduced drug susceptibility afforded by a particular mutation. Once evolved, drug-resistant strains can persist indefinitely as minority viral populations or archived genomes in latently infected CD4 cells, despite long-term withdrawal of the selecting drugs, to re-emerge rapidly on rechallenge with those or any cross-resistant drug. Variable adherence to medication in the routine clinical setting has given rise to resistance mutations being observed in some 50–60% of those with detectable viral loads on therapy in countries where anti-retroviral therapy has been widely available. Nucleoside reverse transcriptase inhibitor-associated mutations form the majority of these, and the long and almost universal use of zidovudine and stavudine has led to mutations selected by these drugs being the most common observed, along with the primary lamivudine resistance mutation M184V. Transmission of drug-resistant HIV in cases of new infection has also been widely studied, and although the extent is considerably lower than that in the treated population (typically 4–10% outside certain geographic areas), early data suggest that it is rising over time as the infected source population becomes more therapy-experienced. Once again, mutations from zidovudine or, to a lesser extent, stavudine exposure form the majority of mutations observed in cases of primary transmission. These data are a cause for concern, and imply that, as things stand, the use of a drug resistance test may become as important to the design of an effective first-line highly active antiretroviral therapy regimen as they have become for selecting new drugs on therapeutic failure.

Anti-human immunodeficiency virus activity of YK-FH312 (a betulinic acid derivative), a novel compound blocking viral maturation

Betulinic acid, a triterpenoid isolated from the methyl alcohol extract of the leaves of Syzigium claviflorum, was found to have a potent inhibitory activity against human immunodeficiency virus type 1 (HIV-1). Betulinic acid derivatives were synthesized to enhance the anti-HIV activity. Among the derivatives, 3-O-(3',3'-dimethylsuccinyl) betulinic acid, designated YK-FH312, showed the highest activity against HIV-induced cytopathic effects in HIV-1-infected MT-4 cells. To determine the step(s) of HIV replication affected by YK-FH312, a syncytium formation inhibition assay in MOLT-4/HIV-1(IIIB) and MOLT-4 coculture, a multinuclear-activation-of-galactosidase-indicator (MAGI) assay in MAGI-CCR5 cells, electron microscopic observation, and a time-of-addition assay were performed. In the syncytium formation inhibition assay or in the MAGI assay for de novo infection, the compound did not show inhibitory effects against HIV replication. Conversely, no virions were detected in HIV-1-infected cell cultures treated with YK-FH312 either by electron microscopic observation or by viral yield in the supernatant. In accordance with a p24 enzyme-linked immunosorbent assay of culture supernatant in the time-of-addition assay, YK-FH312 inhibited virus expression in the supernatant when it was added 18 h postinfection. However, Western blot analysis of the cells in the time-of-addition assay revealed that the production of viral proteins in the cells was not inhibited completely by YK-FH312. These results suggest that YK-FH312 might affect the step(s) of virion assembly and/or budding of virions, and this is a novel mechanism of action of an anti-HIV compound.

Generation of HIV latency during thymopoiesis

The use of combination antiretroviral therapy results in a substantial reduction in viremia, a rebound of CD4+ T cells and increased survival for HIV-infected individuals. However, this treatment does not result in the total eradication of HIV. Rather, the virus is thought to remain latent in a subset of cells, where it avoids elimination by the immune system. In this state the virus is capable of reactivation of productive infection following cessation of therapy. These latently infected cells are very few in number and it has thus been difficult to determine their origin and to study the molecular nature of the latent viral genome. HIV replication is linked to cellular gene transcription and requires target cell activation. Therefore, should an activated, infected cell become transcriptionally inactive prior to cytopathic effects, the viral genome might be maintained in a latent state. We used the SCID-hu (Thy/Liv) mouse model to establish that activation-inducible HIV can be generated at high frequency during thymopoiesis, a process where previously activated cells mature towards quiescence. Moreover, we showed that these cells can be exported into the periphery where the virus remains latent until T-cell receptor stimulation, indicating that the thymus might be a source of latent HIV in humans.

A Rational Approach to the Selection and Sequencing of Nucleoside/Nucleotide Analogues: A New Paradigm

While the value of highly active antiretroviral therapy (HAART) is unquestionable, its use as a life-long therapy will require a more structured and strategic approach to the sequential use of antiretroviral agents than has previously been the case. A complex cocktail of factors influences the durability of a given regimen, but the durability of HAART requires a carefully planned approach to the selection of agents across multiple regimens from first-line onwards, based on considerations of drug cross-resistance and sequenceability at regimen failure. Despite considerable ongoing interest in sequencing protease inhibitors and even non-nucleoside reverse transcriptase inhibitors, there has been little study into the optimal sequence of nucleoside reverse transcriptase inhibitor (NRTI) drugs in consecutive regimens. Historical practice, clinical experience and force of habit have all emphasized the use of thymidine analogue-based first-line combinations and the frequent retention of a thymdine analogue at all subsequent stages until a salvage situation is reached. Emerging data clearly associates thymidine analogue-derived reverse transcriptase mutations with loss of drug susceptibility and clinical response to other members of the NRTI class, particularly when present alongside other NRTI-associated mutations. Any approach to strategic therapy across multiple treatment lines will require, as a basic tenet, that agents with the greatest potential for cross-resistance be used later in therapy rather than earlier. To this end, a move away from the universal use of the thymidine analogues in first-line therapy is likely as strategic thinking becomes more integrated into clinical management in HIV disease. However, more clinical investigation is required into both the performance of alternative first-line NRTI combinations and the individual sequenceability of NRTI drugs, in the absence of the class reductions in susceptibility conferred by accumulations of thymidine analogue mutations that are the corollary to most current definitions of ‘treatment-experienced’. Another basic tenet of strategic therapy is that while drugs with high potency in treatment-experienced individuals, and favourable cross-resistance profiles, are urgently required for the salvage of patients with limited options, constraining such agents to this niche merely cements the bad habits which led to an early salvage situation in the first place. Potent drugs with low cross-resistance should be investigated at all stages of therapy, including first-line, for their potential to provide not only individual regimen durability but also to extend the number of effective, successive treatment lines. Just as highly cross-resistant agents are best used later in therapy, poorly cross-resistant agents may provide an even greater strategic advantage in first- or second-line regimens than they do when used where little else is likely to work.

Quantification of human immunodeficiency virus type 1 proviral load by a TaqMan real-time PCR assay

Proviral human immunodeficiency virus type 1 (HIV-1) DNA could be a useful marker for exploring viral reservoirs and monitoring antiretroviral treatment, particularly when HIV-1 RNA is undetectable in plasma. A new technique was developed to quantify proviral HIV-1 using a TaqMan real-time PCR assay. One copy of proviral HIV-1 DNA could be detected with 100% sensitivity for five copies and the assay had a range of 6 log(10). Reproducibility was evaluated in intra- and interassays using independent extractions of the 8E5 cell line harboring the HIV-1 proviral genome (coefficients of variation [CV], 13 and 27%, respectively) and peripheral blood mononuclear cells (PBMC) from a patient with a mean proviral load of 26 copies per 10(6) PBMC (CV, 46 and 56%, respectively). The median PBMC proviral load of 21 patients, measured in a cross-sectional study, was determined to be 215 copies per 10(6) PBMC (range, <10 to 8,381). In a longitudinal study, the proviral load of 15 out of 16 patients with primary infection fell significantly during 1 year of antiretroviral therapy (P = 0.004). In the remaining patient, proviral HIV-1 DNA was detectable but not quantifiable due to a point mutation at the 5' end of the TaqMan probe. No correlation was observed between proviral load and levels of CD4(+) cells or HIV-1 RNA in plasma. TaqMan PCR is sensitive and adaptable to a large series of samples. The full interest of monitoring proviral HIV-1 DNA can now be ascertained by its application to the routine monitoring of patients.

Timing of antiretroviral therapy. Use of Markov modeling and decision analysis to evaluate the long-term implications of therapy

BACKGROUND

The timing of initiation of antiretroviral therapy is controversial. Current guidelines are heavily based on the principle of 'hit early, hit hard', although the long-term implications of this approach are unknown.

METHODS

Using Markov modeling and decision analysis we modeled the virologic outcomes over 10 years in a hypothetical population of 10 000 HIV-infected patients in which therapy (with the possibility of three sequential regimens before the development of multidrug-resistant virus) is started immediately versus starting progressively at rates of 5, 10, 15, 20 or 30% of the original population each year. The model used inputs from available clinical trial data: virologic success rate and durability of the response of the first and subsequent regimens. We performed one-way and two-way sensitivity analysis to evaluate changes in the input variables.

RESULTS

If therapy is started immediately in all patients, by 10 years 57% would be undetectable, but 38% would have detectable multidrug-resistant virus. In contrast, the population as a whole would have had better virologic outcomes if one waited before starting treatment at any progression rate; for example, initiating therapy in 10% of the subjects per year results in 64% of patients being undetectable and 24% with multidrug-resistant virus. Two-way sensitivity analysis demonstrates that immediate initiation should be at least 15 to 20% better than delayed antiretroviral therapy to justify immediate initiation of therapy over a wide range of success rates of the delayed start.

CONCLUSION

Our analysis, utilizing optimistic outcomes based on short-term clinical trials, provides a theoretical basis for questioning the current aggressive early use of therapy and should help prompt studies that look at when and how to start antiretroviral therapy.

Absence of genetic diversity reduction in the HIV-1 integrated proviral LTR sequence population during successful combination therapy

We report the integrated proviral LTR sequence variation in four patients on highly active antiretroviral therapy (HAART). Integrated proviral fragments of LTR taken from four time points were PCR amplified from PBMCs and 10 to 12 individual clones were sequenced for each time point. Intrasample genetic distances and phylogenetic reconstruction of all LTR sequences demonstrated that 1-2 years of successful HAART did not significantly reduce the genetic repertoire of the integrated reservoir of HIV-1.

Initiation of therapy during primary HIV type 1 infection results in a continuous decay of proviral DNA and a highly restricted viral evolution

A latent pool of HIV-1 is established early in memory CD4+ T lymphocytes and persists during antiretroviral therapy. Also, viral replication may continue in subjects despite undetectable viremia. However, it remains unclear whether this residual replication results in any significant sequence evolution. We were therefore interested in studying the viral evolution and HIV-1 DNA dynamics in subjects with primary infection receiving or not receiving early potent antiretroviral therapy. In 16 subjects, HIV-1 DNA load was monitored from 1 to 23 days, up to 1253 days, after onset of symptoms. Extensive sequential cloning and sequence analysis of the V3 region was performed in four subjects. In the treated subjects a continuous decline in the proviral load was found, corresponding to a half-life of about 6 months. As expected in newly infected individuals the founder virus populations showed high intrasubject sequence similarity. Also, a limited increase in the viral divergence was detected during the first 6 months in three treated subjects. Thereafter, no significant sequence changes were found despite analysis of a large number of clones. Our data thus suggest that early and successful therapy in compliant subjects with primary HIV-1 infection results in a highly restricted viral evolution and a decline in the proviral load close to the decay rate of human memory T lymphocytes.

Multivalent anti-CCR ribozymes for stem cell-based HIV type 1 gene therapy

HIV-1 infection of susceptible cells is mediated by the specific interaction of viral envelope glycoproteins with the cell surface CD4 receptor and a chemokine coreceptor, CCR5 or CXCR4. Individuals with a CCR5 genetic defect show resistance to HIV-1 infection, indicating that downregulation of CCR5 expression on target cells can prevent viral infection. In previous studies we demonstrated the utility of an anti-CCR5 ribozyme targeted to a single cleavage site in downregulating CCR5 expression and consequently providing resistance to viral infection. To improve on the level of downregulation we designed a construct containing an anti-CCR5 ribozyme heterotrimer (R5RbzTM) targeted to three different cleavage sites in CCR5 mRNA. In vitro tests showed that the anti-CCR5 ribozyme heterotrimer could effectively cleave the CCR5 RNA substrates to yield products of the expected sizes. This construct was introduced into various retroviral vectors for stable gene transduction. HOS.CD4/R5 cells stably transduced with this anti-CCR5 heterotrimer showed a marked reduction in the surface expression of CCR5 and a concomitant 70% reduction in macrophage-tropic viral infection. In addition, a retroviral vector containing the anti-CCR5 ribozyme heterotrimer and an anti-HIV-1 tat-rev ribozyme heterodimer was constructed. This construct also showed a similar inhibition of CCR5 surface expression and reduced infectability by the macrophage-tropic HIV-1 vector in HOS.CD4/R5 cells. The trimeric and multimeric ribozyme constructs were transduced into CD34+ hematopoietic progenitor cells to determine their effects on lineage-specific differentiation. We show that multivalent ribozyme gene-transduced hematopoietic progenitors differentiated normally into mature macrophages that bear CD14 and CD4 surface markers. Macrophages containing the transgenes expressed ribozymes, and showed resistance to M-tropic HIV-1 infection. These results provide strong support for the use of the trimeric anti-CCR5 ribozyme approach in a gene therapy setting for the treatment of HIV infection.

Membrane-anchored peptide inhibits human immunodeficiency virus entry

Peptides derived from the heptad repeats of human immunodeficiency virus (HIV) gp41 envelope glycoprotein, such as T20, can efficiently inhibit HIV type 1 (HIV-1) entry. In this study, replication of HIV-1 was inhibited more than 100-fold in a T-helper cell line transduced with a retrovirus vector expressing membrane-anchored T20 on the cell surface. Inhibition was independent of coreceptor usage.

New drug combinations for the treatment of murine AIDS and macrophage protection

The failure of highly active antiretroviral therapies (HAART) is mainly due to the existence of latent infected reservoirs, such as macrophages and resting CD4+ T cells. In this paper, we report the results that we obtained in a murine model of AIDS by alternating the administration of the lympholitic drug 2-Fluoro-ara-AMP (Fludarabine) to eliminate the infected cells, with that of Azidothymidine (AZT) plus reduced glutathione (GSH) encapsulated in erythrocytes, to protect lymphocytes and macrophages not yet infected, respectively. Two groups of infected mice were treated as follows: one group was treated by alternating the administration of Fludarabine and AZT (treatment A), while the other group received the same treatment plus GSH-loaded erythrocytes given with AZT (treatment A + L-RBC). Fludarabine was administered intraperitoneally, AZT in the drinking water and GSH was encapsulated in erythrocytes by a procedure of hypotonic dialysis and isotonic resealing. The results obtained show that GSH-loaded erythrocytes provide additive effects in all the parameters examined. Alternation of a lympholitic drug and antiretroviral drug is effective in reducing the progression of murine AIDS. Addition of a system to protect macrophages provides additive effects in almost all the parameters considered, confirming that combination therapies aimed at protecting different infectable cell compartments are better than treatments protecting mainly lymphocytes.

Mature dendritic cells infected with canarypox virus elicit strong anti-human immunodeficiency virus CD8+ and CD4+ T-cell responses from chronically infected individuals

Recombinant canarypox virus vectors containing human immunodeficiency virus type 1 (HIV-1) sequences are promising vaccine candidates, as they replicate poorly in human cells. However, when delivered intramuscularly the vaccines have induced inconsistent and in some cases transient antigen-specific cytotoxic T-cell (CTL) responses in seronegative volunteers. An attractive way to enhance these responses would be to target canarypox virus to professional antigen-presenting cells such as dendritic cells (DCs). We studied (i) the interaction between canarypox virus and DCs and (ii) the T-cell responses induced by DCs infected with canarypox virus vectors containing HIV-1 genes. Mature and not immature DCs resisted the cytopathic effects of canarypox virus and elicited strong effector CD8+ T-cell responses from chronically infected HIV+ individuals, e.g., cytolysis, and secretion of gamma interferon (IFN-gamma) and beta-chemokines. Furthermore, canarypox virus-infected DCs were >30-fold more efficient than monocytes and induced responses that were comparable to those induced by vaccinia virus vectors or peptides. Addition of exogenous cytokines was not necessary to elicit CD8+ effector cells, although the presence of CD4+ T cells was required for their expansion and maintenance. Most strikingly, canarypox virus-infected DCs were directly able to stimulate HIV-specific, IFN-gamma-secreting CD4 helper responses from bulk as well as purified CD4+ T cells. Therefore, these results suggest that targeting canarypox virus vectors to mature DCs could potentially elicit both anti-HIV CD8+ and CD4+ helper responses in vivo.

Simian immunodeficiency virus infection of monkeys as a model system for the study of AIDS pathogenesis, treatment, and prevention

As presented in this review, there are a number of different models of both natural and experimental infection of monkeys with primate lentiviruses. There are numerous different viruses and multiple different monkey species, making for a potentially large number of different combinations. The fact that each different combination of virus isolate and host macaque species may show different behavior underscores the need to understand the different models and their key features. On the one hand, this diversity of systems underscores the need to provide some standardization of the systems used for certain kinds of studies, such as vaccine evaluations, in order to facilitate the comparison of results obtained in different experiments, but in essentially the same experimental system. On the other hand, the rich diversity of different systems, with different features and behaviors, represents a tremendous resource, among other things allowing the investigator to select the system that best recapitulates particular aspects of human HIV infection for study in a relevant nonhuman primate model. Such studies have provided, and may be expected to continue to provide, important insights to guide HIV treatment and vaccine development in the future.

Virologic and immunologic consequences of discontinuing combination antiretroviral-drug therapy in HIV-infected patients with detectable viremia

BACKGROUND

In many patients with human immunodeficiency virus (HIV) infection, therapy with potent antiretroviral drugs does not result in complete suppression of HIV replication. The effect of cessation of therapy in these patients is unknown.

METHODS

Sixteen patients who had a plasma HIV RNA level of more than 2500 copies per milliliter during combination antiretroviral-drug therapy were randomly assigned, in a 2:1 ratio, to discontinue or continue therapy. Plasma HIV RNA levels, CD4 cell counts, and drug susceptibility were measured weekly. Viral replicative capacity was measured at base line and at week 12.

RESULTS

Discontinuation of therapy for 12 weeks was associated with a median decrease in the CD4 cell count of 128 cells per cubic millimeter and an increase in the plasma HIV RNA level of 0.84 log copies per milliliter. Virus from all patients with detectable resistance at entry became susceptible to HIV-protease inhibitors within 16 weeks after the discontinuation of therapy. Drug susceptibility began to increase a median of six weeks after the discontinuation of therapy and was temporally associated with increases in plasma HIV RNA levels and decreases in CD4 cell counts. Viral replicative capacity, measured by means of a recombinant-virus assay, was low at entry into the study and increased after therapy was discontinued. Despite the loss of detectable resistance in plasma, resistant virus was cultured from peripheral-blood mononuclear cells in five of nine patients who could be evaluated. Plasma HIV RNA levels, CD4 cell counts, and drug susceptibility remained stable in the patients who continued therapy.

CONCLUSIONS

Despite the presence of reduced drug susceptibility, antiretroviral-drug therapy can provide immunologic and virologic benefit. This benefit reflects continued antiviral-drug activity and the maintenance of a viral population with a reduced replicative capacity.

Preferential suppression of CXCR4-specific strains of HIV-1 by antiviral therapy

To initiate infection, HIV-1 requires a primary receptor, CD4, and a secondary receptor, principally the chemokine receptor CCR5 or CXCR4. Coreceptor usage plays a critical role in HIV-1 disease progression. HIV-1 transmitted in vivo generally uses CCR5 (R5), but later CXCR4 (X4) strains may emerge; this shift heralds CD4+ cell depletion and clinical deterioration. We asked whether antiretroviral therapy can shift HIV-1 populations back to R5 viruses after X4 strains have emerged, in part because treatment has been successful in slowing disease progression without uniformly suppressing plasma viremia. We analyzed the coreceptor usage of serial primary isolates from 15 women with advanced disease who demonstrated X4 viruses. Coreceptor usage was determined by using a HOS-CD4+ cell system, biological and molecular cloning, and sequencing the envelope gene V3 region. By constructing a mathematical model to measure the proportion of virus in a specimen using each coreceptor, we demonstrated that the predominant viral population shifted from X4 at baseline to R5 strains after treatment. Multivariate analyses showed that the shift was independent of changes in plasma HIV-1 RNA level and CD4+ cell count. Hence, combination therapy may lead to a change in phenotypic character as well as in the quantity of HIV-1. Shifts in coreceptor usage may thereby contribute to the clinical efficacy of anti-HIV drugs.

Follow-up study of intrahost HIV type 2 variability reveals discontinuous evolution of C2V3 sequences

Sequence change dynamics in the highly polymorphic C2V3 region of the envelope glycoprotein gp105 coding sequence of HIV-2 was studied for two HIV-2 seropositive Guinean individuals over a 5-year period. Proviral DNA was amplified by PCR from uncultured peripheral blood mononuclear cells (PBMC), cloned, and sequenced. Amino acid sequence alignment and phylogenetic analysis showed distinct viral populations for the three collected samples (1992, 1995, and 1997) for both individuals. A discontinuous replacement of sequences suggests activation of latent viruses present in reservoirs, a process that has been documented for the HIV-1 infection but unreported so far for HIV-2. The nucleotide sequences presented in this work have been assigned accession numbers AJ400276 to AJ400319.

Two long terminal repeat circles and persistent HIV-1 replication

Building on the success of combination antiretroviral drug therapy will require a better understanding of the underlying basis for viral persistence. Characterization of the therapeutic, viral, and immunological factors that influence the size and stability of viral reservoirs will foster the development of strategies to control or eliminate HIV-1 from infected individuals. Here we review recent work aimed at delineating the complex interplay between viral replication, the immune system, and viral reservoirs. Finally, we address the implications and clinical significance of the residual replication that persists in infected individuals on potent antiretroviral therapy to evaluate both the possible risks and benefits of ongoing HIV-1 replication.

Residual HIV-1 RNA in blood plasma of patients taking suppressive highly active antiretroviral therapy

Residual HIV-1 disease remains in the vast majority of patients treated with even the most intensive highly active antiretroviral therapy (HAART). There are at least two well-described molecular mechanisms for HIV-1 persistence in these patients. These include proviral latency in resting CD4+ T-cells, as well as 'cryptic' residual viral replication. As well, potential sanctuary sites, including the brain and testes, may be important areas which will hinder HIV-1 eradication attempts. It is not clear whether other sites of HIV-1 persistence, including tissue-bound infected monocytes/macrophages, may also be involved in residual HIV-1 disease during virally-suppressive HAART.

Cellular immune response to human immunodeficiency virus

Despite recent success with the use of highly active antiretroviral therapy, eradication of HIV type 1 appears beyond the capabilities of presently available therapy. Therefore, greater emphasis has been given to finding mechanisms that promote immunologic control of viral replication rather than eradication. Although the correlates of immune protection in HIV-1 infection remain undefined, increasing evidence indicates that HIV-1-specific cellular immune responses may play a critical role in antiviral control. Vigorous HIV-1-specific CD4+ T-helper cell and CD8+ cytotoxic T-lymphocyte responses may play a critical role in control of viral replication in the absence of antiretroviral therapy, which has been demonstrated in individuals with long-term nonprogressive infection. However, in chronic, progressive HIV-1 infection, virus-specific T-helper cell responses are typically weak or absent in all stages of disease, and HIV-1-specific cytotoxic T-lymphocyte responses wane over time, presumably due to the lack of HIV-1-specific T helper cells. Effective treatment of individuals during acute HIV-1 seroconversion syndrome appears to restore HIV-1-specific T-helper cell responses, which are otherwise only observed in persons with long-term nonprogressive infection. This observation, along with anecdotal reports of individuals successfully controlling viral replication after treating acute HIV-1 infection, provides immunologic rationale for structured treatment interruption and other immunotherapeutic approaches designed to augment HIV-1-specific immune responses.

The impact of highly active antiretroviral therapy on HIV-specific immune function

Highly active antiretroviral therapy (HAART) can suppress HIV type 1 plasma viremia to undetectable levels for up to 3 years or more. When the therapy is discontinued, viral rebound occurs in a majority of patients, indicating that HAART is unable to completely eradicate the virus. Initial calculations of the half-lives of the infected cells (estimated to be 14-21 days) suggested that only 3 years continuous HAART therapy would be necessary to achieve complete eradication; however, several studies have determined that the half-lives of chronically infected cells are in the order of 6-44 months. New estimates indicate that it may take as long as 60 years to eradicate the virus. Thus, there has been movement toward combining HAART with various means of augmenting and/or reconstituting the host's immune system, especially HIV-1-specific immune responses. The long-term goal is to discontinue HAART and permit the reconstituted immune system to contain whatever small amounts of the virus remain.

Structured treatment interruptions to control HIV-1 and limit drug exposure

Although therapy-mediated suppression of HIV-1 is effective and results in a degree of immune reconstitution, the complications resulting from life-long treatment emphasize the need for alternatives. This review discusses the use of structured interruptions in antiviral therapy to induce drug-free periods of immune-mediated control of HIV-1. Such an approach has the ultimate objective of harnessing anti-viral immune responses, reducing drug exposure (toxicity and cost) and potentially extending the clinical benefits of a suppressive treatment regimen.

Monocytes harbour replication-competent, non-latent HIV-1 in patients on highly active antiretroviral therapy

OBJECTIVE

To determine whether HIV-1 can be recovered from blood monocytes as well as resting, memory CD4 T lymphocytes of patients on highly active antiretroviral therapy (HAART) with undetectable plasma viraemia and whether infection is active or latent.

DESIGN

Five patients with plasma HIV-1-RNA levels of less than 500 copies/ml for at least 3 months and less than 50 copies/ml at the time of sampling were initially selected, followed by an additional five patients with viral loads of less than 50 copies/ml for 3 months or more.

METHODS

Monocytes were isolated from blood by plastic adherence, then further purified by a second adherence step or CD3 depletion before co-culture with CD8-depleted donor peripheral blood mononuclear cells. Virus isolates were examined for mutations conferring resistance to reverse transcriptase or protease inhibitors and for genotype. The highly purified monocytes were also analysed for the presence of proviral and unintegrated viral DNA and multiply spliced (MS) viral mRNA by polymerase chain reaction.

RESULTS

Virus was recovered from monocytes of five patients. Sequencing of the recovered viruses did not reveal multiple drug resistance, and was consistent with a non-syncytium-inducing/CCR5 phenotype. Proviral DNA was detectable in monocytes from all subjects, and unintegrated HIV-1 DNA and MS RNA was found in four out of five populations examined.

CONCLUSION

Recovery of replication-competent virus from some HAART patients indicates that monocytes can also harbour HIV-1. Detection of circular, viral DNA and spliced RNA, albeit at very low levels, in these cells suggests that their infection is recent and transcriptionally active rather than latent.

Development of virus-specific immune responses in SHIV(KU)-infected macaques treated with PMPA

Therapeutic intervention with highly active antiretroviral therapy (HAART) can lead to the suppression of HIV viremia below the threshold of detection for several years. However, impact of HAART on reconstitution of virus-specific immune responses remains poorly understood. In this study, four macaques were infected with pathogenic SHIV(KU). One week postinoculation two of the four animals were treated with PMPA [9-R-(2-phosphophomethoxypropyl)adenine] daily for 83 days. Two other macaques, that did not receive treatment, exhibited explosive virus replication accompanied by a near total loss of CD4(+) T cells and succumbed to AIDS-related complications within 6 months of infection. These animals did not develop any virus-specific immune responses. On the contrary, the animals that received PMPA showed transient loss of CD4(+) T cells that recovered during the treatment period. The virus burden declined below the level of detection that rebounded soon after cessation of PMPA therapy. The virus replicated productively for several weeks before both animals controlled the productive replication of virus. This control of virus replication was found to be associated with the development of virus-specific neutralizing antibodies, T-helper cells, and CTLs. Although PMPA did not eliminate virus from the animals, it provided them with enough time to mount virus-specific immune responses that eventually controlled the virus replication in the blood. Our results suggest that antiretroviral therapy, if initiated early during infection, would help the host in mounting virus-specific immune responses that might control productive replication of the virus.

Suppression of HIV replication in the resting CD4+ T cell reservoir by autologous CD8+ T cells: implications for the development of therapeutic strategies

CD8+ T cell-mediated antiviral activity against HIV has been described consistently in infected individuals; however, the role of this activity in controlling replication of HIV in the latently infected, resting CD4+ T cell reservoir is unclear. By using an ex vivo system, we show that replication of HIV in this viral reservoir is effectively suppressed in coculture by autologous CD8+ T cells in long-term nonprogressors (LTNPs) and in patients whose viremia was controlled by highly active antiretroviral therapy (HAART), but not in therapy-naive patients who had substantial levels of plasma viremia. This antiviral activity was largely independent of cytotoxic CD8+ T lymphocytes (CTL). When the role of soluble CD8+ T cell-derived factors was examined, we found that CC-chemokines played a major role in inhibition of viral replication in the latent viral reservoir in some LTNPs and patients receiving HAART, but not in chronically infected patients who were not receiving antiretroviral therapy. Potent antiviral activity, independent of CC-chemokines, was found mainly in patients in whom HAART was initiated shortly after the acute phase of HIV infection. These results indicate that CD8(+) T cells provide potent suppressive activity against HIV replication in the latent viral reservoir via direct cellular contact in patients who are naturally LTNPs or in those who are treated with HAART. Furthermore, the profound antiviral activity exerted by non-CC-chemokine soluble factors in infected patients who began HAART early in HIV infection suggests that preservation of this HIV-suppressive mechanism by early initiation of therapy may play an important role in the containment of viral replication in infected patients following interruption of therapy.

Paediatric HIV infection: correlates of protective immunity and global perspectives in prevention and management

The impact of the HIV epidemic on child health globally is beginning to be appreciated. With the burden of new infections falling on young women, there is a skyrocketing number of AIDS orphans, and a rapidly increasing number of children infected via mother-to-child-transmission (MTCT). An estimated 600,000 new paediatric infections occur each year, of which some 1500/day (> 90%) occur in sub-Saharan Africa. But whereas children account for only 4% of those currently living with HIV infection, 20% of AIDS deaths have been in children. This reflects the rapid progression to disease in paediatric HIV infection. Whereas a dramatic reduction in viraemia follows acute adult infection, corresponding to the appearance of a vigorous anti-HIV cytotoxic T lymphocyte response, virtually no impact of the immune response is observed in acute paediatric infection following MTCT. Two specific challenges for the paediatric immune response are: (i) infection occurs before the immune system itself is fully developed; and (ii) the viruses transmitted by MTCT have already evaded an immune system sharing close genetic relatedness to that of the child. Accumulating evidence indicates that the immune system is potentially capable of effective control of HIV infection, and that events occurring in acute infection critically determine the ultimate outcome. Technological advances that have transformed the study of T-cell immunity now enable the developing immune system in childhood to be better understood. Via novel immunotherapeutic approaches described, it may be possible to modulate the infant's immune response to reach effective and durable suppression of HIV, as can be achieved by the rare long-term non-progressors of HIV infection. The feasibility of adopting these approaches globally are as yet untested. Finally, the striking disparity between the burden of paediatric HIV infection and access to the necessary infrastructure and therapeutic options required for its optimal management is addressed in a comparison between three sites of paediatric HIV care: Durban, South Africa; London, UK; and Boston, USA.

Immune interventions

A better understanding of the immune response to HIV and the deleterious effect that HIV infection may have on the immune system in general, allows us to consider how best to restore protective immune responses to HIV and other opportunistic pathogens in the immunocompromised host. In this chapter, we summarise areas of current innovation and provide an update of the current state of knowledge concerning interventions which could result in the immunocompromised state being reversed. We describe the kinds of immune responses, which are thought to be useful in combating both the human immunodeficiency virus and other pathogenic organisms, and methods which are being considered to stimulate such responses. Lessons which may be learned from other disease states, which lead to immunodeficiency and methods for measuring successful outcome of treatment will be described.

HIV-1 integrase: the next target for AIDS therapy?

HIV-1 is the aetiological agent of AIDS. Present treatment of AIDS uses a combination therapy with reverse transcriptase and protease inhibitors. Recently, the integrase (IN), the third enzyme of HIV-1 which is necessary for the integration process of proviral DNA into the host genome, has reached as a legitimate new drug target. Several families of inhibitors of the catalytic core domain of HIV-1 IN exhibiting submicromolar activities have now been identified. Our contribution in this field was related to the development of new polyhydroxylated styrylquinolines. The latter compounds have proved to be potent HIV-1 IN inhibitors, that block the replication of HIV-1 in cell culture, and are devoid of cytotoxicity. The crystal structure of the catalytically active core domain of a HIV-1 IN mutant has been determined. The active site region is identified by the position of two of the conserved carboxylate residues essential for catalysis, Asp64 and Asp116, which coordinate a Mg2+ ion, whereas the third catalytic residue, Glu152 does not participate in metal binding. However, a recent molecular dynamics simulation of the HIV-1 IN catalytic domain provides support to the hypothesis that a second metal ion is likely to be carried into the HIV-1 IN active site by the DNA substrate. The structure of a complex of the HIV-1 IN core domain with the inhibitor 5-CITEP has been recently reported. The inhibitor binds centrally in the active site of the IN and makes a number of close contacts with the protein, particularly with Lys156, Lys159 and Gln148, amino acids which were identified to be near the active site of the enzyme, through site-directed mutagenis and photo-crosslinking experiments. The exact mechanism by which HIV-1 IN inhibitors block the catalytic activity of the protein remains unknown. However, several putative pharmacophore components have been characterized. All these groups lie in a possible coordination to a divalent ion, supporting thus the hypothesis that the interaction causing the inhibition is mediated by one or two cations. Finally, among the HIV-1 IN inhibitors, three classes have proved to exhibit significant antiviral activities. Thus, it seems likely that the efficient use of HIV-1 IN as a target for rational design will become possible in the next future, possibly through the use of combination regimens including IN inhibitors.

Pilot study of a combination of highly active antiretroviral therapy and cytokines to induce HIV-1 remission

A pilot study of a combination of highly active antiretroviral therapy (HAART) and cytokines in early HIV-1 infection has been undertaken to test the hypothesis that HIV-1 remission can be reached with this strategy by flushing latently infected viral reservoirs. Ten previously antiretroviral naive patients have received a combination of zidovudine, lamivudine, didanosine, saquinavir, and ritonavir for 72 weeks. Between weeks 12 and 48, three courses of interleukin (IL)-2 (7.5 millions of international units [MUI] twice a day for 5 consecutive days) and 2 courses of gamma-interferon (IFN) (100 microg every other day during 2 weeks) were administered subcutaneously. All patients reached plasma HIV-1 RNA levels < 20 copies/ml within 12 +/- 4 weeks. Transient increases in plasma levels (< 120 copies/ml) were observed during administration of IL-2, but less frequently during gamma-IFN administration. HIV-1 RNA decreased in lymph node cells by approximately 4 log, then remained stable after week 24. A mean drop of -0.8 log in peripheral blood mononuclear cell (PBMC) proviral DNA was observed during the trial. Isolation of potentially infectious HIV-1 was successful in each case by coculture of CD4+ T cells taken at week 72. The 2 patients who stopped therapy at the end of the trial showed rebounding plasma HIV-1 RNA levels within a few weeks. No additional mutations were selected in comparison with those present at baseline in 8 patients. In addition, 2 patients developed new mutations in the reverse transcriptase or protease gene and in 1 case, resistance selection was found in lymphoid tissue HIV-1 RNA but not in latently infected cells. In all cases, a rapid increase in both naive and memory CD4+ T cells was observed, with a reduction in activation markers and preservation of the CD8+CD28+ subset. Consequently, an aggressive regimen of HAART and cytokines administered in early stage disease is associated with a positive effect in terms of proviral load reduction and immune reconstitution but is unable to induce HIV-1 remission, allowing low levels of viral replication to persist in lymphoid reservoirs.

Decay of cell-associated HIV-1 DNA correlates with residual replication in patients treated during acute HIV-1 infection

OBJECTIVES

To evaluate the decay rate of cell-associated HIV-1 RNA and DNA and to identify factors associated with residual viral load in patients treated at the time of primary HIV-1 infection.

PATIENTS

A group of 15 patients adherent to highly active antiretroviral therapy (HAART) with sustained undetectable HIV-1 viremia for at least 24 months.

METHODS

Viremia, cell-associated HIV-1 RNA and DNA in blood and lymph node mononuclear cells were measured using ultrasensitive assays.

RESULTS

Viremia decreased rapidly in all patients; HIV RNA remained < 3 copies/ml in nine patients and fluctuated between 3 and 50 copies/ml in five patients and between 50 and 200 copies/ml in one patient. Decay rates of cell-associated RNA and DNA presented an inflexion point at 1 and 3 months, respectively: first-phase mean half-lives were 0.15 and 0.84 months, respectively, and second-phase mean half-lives were 13.7 and 6.6 months, respectively (95% confidence interval 4.4-13.8). The second phase decay rates were markedly slower, with a DNA decay rate that was highly associated with the mean levels of cell-associated RNA measured in blood from 6 to 33 months (P= 0.001) and in lymph nodes collected at 14 months (P= 0.02).

CONCLUSIONS

The clearance of HIV-1 infected cells is correlated with the extent of viral replication as measured by cell-associated RNA levels in both blood and lymph nodes. Quantification of cell-associated RNA and DNA further defines treatment efficacy in 'aviremic' patients.

Highly restricted spread of HIV-1 and multiply infected cells within splenic germinal centers

The tremendous dynamics of HIV infection finds expression in the tempo of sequence diversification. Genetic diversity calculations require the clearance of a majority of infected cells, the obvious predator being anti-HIV immune responses. Indeed, infiltration of germinal centers (GCs) by HIV-specific CD8(+) cytotoxic T lymphocytes has been described. A corollary to this description would be limited diffusion of virus within lymphoid structures. HIV efficiently infects and replicates mainly in activated CD4(+) T lymphoblasts. These cells are found within GCs after their activation in the adjacent periarteriolar lymphoid sheath (PALS). Here GCs and PALS have been dissected from consecutive 10-micrometer sections through splenic tissue from three HIV-1-infected patients. Nested PCR amplification of the two first hypervariable regions of the env gene indicated that 38-78% of sections contained HIV-infected cells. Since there are several hundred CD4(+) T cells per GC section, approximately 0.09-0.64% harbor proviral DNA. Such a low frequency not only suggests that virions on the follicular dendritic cell surfaces do not readily infect adjacent T cells but also indicates highly restricted spread of HIV within GCs and the PALS. Sections were heavily infiltrated by CD8(+) cells, which, together with a large body of extant data, suggests that the majority of infected cells are destroyed by HIV-specific cytotoxic T lymphocytes before becoming productively infected. Finally, sequence analysis revealed that those HIV-positive cells were multiply infected, which helps explain widespread recombination despite a low overall frequency of infected cells.

Mutation takes no vacation: can structured treatment interruptions increase the risk of drug-resistant HIV-1?

We use a mathematical model to study the dynamics of HIV-1 replication during structured treatment interruptions (STIs) in infected patients. The model predicts rapid viral rebound, restoration of a latently infected cell pool, and critically, partially resistant mutant rebound that may be missed because of high levels of wild type virus. Because partially resistant viruses are capable of mutating to full resistance, a substantial increase in their numbers represents a threat to therapeutic response durability. Compared with continued treatment, STIs may increase the chance of mutation to full resistance by several thousandfold.

HIV RNA and HIV DNA in peripheral blood mononuclear cells are consistent markers for estimating viral load in patients undergoing long-term potent treatment

The aim of this study was to evaluate residual viral replication by assessing the HIV load of circulating infected cells in patients given an effective antiprotease-containing treatment for 1 year. PBMC HIV RNA and HIV DNA was quantified by techniques standardized and evaluated by interlaboratory quality control testing. Viral markers identified in a multicenter study were validated in a cross-sectional study of 121 patients beginning treatment. A longitudinal study of 3 viral markers was carried out in 18 patients, each of whom had fewer than 200 copies of HIV RNA per milliliter of plasma after 12 months of treatment. The cross-sectional study showed that viral replication in PBMCs was correlated with the number of circulating infected cells (Spearman rank correlation; p = 0.0001, r = 0.35) and the concentration of virus particles in the plasma (Spearman; p = 0.0001, r = 0.54). The longitudinal study showed that the decrease in HIV RNA levels was smaller in PBMCs than in the plasma. The largest decrease in HIV DNA levels after 12 months of treatment was recorded in patients with low levels of intracellular replication (Spearman; p = 0.005, r = 0.69). PBMC HIV RNA and HIV DNA levels were very informative markers, complementary to plasma HIV RNA levels. They should be used in future trials evaluating the long-term efficacy of new associations of highly active antiretroviral treatments.

Establishment of latent HIV-1 infection of resting CD4(+) T lymphocytes does not require inactivation of Vpr

The introduction of highly active antiretroviral therapy (HAART) for the treatment of HIV-1 infection has allowed dramatic reductions in plasma virus levels to below the limit of detection in many patients. However, latently infected CD4(+) memory T lymphocytes persist as an important reservoir for the virus in the presence of this aggressive therapy and represent a major barrier to HIV-1 eradication with HAART. The mechanism through which the latent compartment is formed has not yet been established. It may involve actively proliferating CD4(+) T-cell intermediates that are infected with HIV-1 and revert back to a resting state, carrying integrated provirus at some low frequency. The HIV-1 accessory protein Vpr, which mediates G(2) cell cycle arrest in host cells, may interfere with the formation of the latently infected T cells by preventing them from exiting the cell cycle to return to a resting state. To investigate the role of the Vpr in the formation of latently infected memory T cells, we cloned and characterized vpr genes from viruses in the latent reservoir. Both sequence analysis and functional assays demonstrated that the vpr gene products of the viruses isolated from the latent pool did not differ significantly from those of a functional Vpr (NL4-3). These results indicate that the generation of resting G(0) memory T lymphocytes that carry latent HIV-1 provirus occurs despite the G(2) arrest function of the vpr gene product.

Biologic approaches to the prevention of sexual transmission of human immunodeficiency virus

HIV prevention science has made progress, especially in Thailand and some sub-Saharan African countries. New cases of HIV in the United States, however, have not diminished and explosive epidemics in India and the People's Republic of China seem inevitable. Therefore, HIV prevention activities must move forward in parallel. Funding for biologic and behavioral research efforts must be balanced. Behavioral research must inform biologic strategies. In addition, HIV prevention efforts have been distorted by forces that require further consideration. First, the stigmatization associated with a diagnosis of HIV infection led to prevention efforts that virtually ignore the index case. Focusing entirely on the susceptible population puts intense and unrealistic pressure on behavior change and vaccine development. Although development of an HIV vaccine is desirable, there is no evidence that this goal can be achieved in the near future. Blind faith in vaccine technology detracts from pursuit of alternative aspects of prevention science. Vaccine development is but one of several key components to a broad-based prevention strategy. The history of control of infectious diseases has shown the need for targeting index cases. This certainly will prove important in HIV over the next few years. In developed countries, antiretroviral therapy for established HIV infection has become the standard of care. Increased knowledge of the biology of transmission of HIV suggests use of ART to prevent transmission. Such intervention must be accompanied by safer sex behavior in the index cases, and ultimately could lead to some form of monitoring and directly observed therapy. At this time, the latter approach seems unrealistic in developing countries, where the expense of drugs renders them unavailable. But there is every reason to believe that cheaper, more appropriate drugs will be developed before an effective vaccine. Furthermore, targeted use of ART might have disproportionate benefits in some countries. Women are the fastest growing HIV risk group. Several issues, both biologic and social, make this trend a concern. Increases in the number of HIV-infected women will lead to greater vertical transmission. Women possibly have different risk factors for acquisition and transmission than men. Information about the effects of vaginal ecology, specifically, the role of bacterial vaginosis, in the acquisition of HIV is essential because bacterial vaginosis can be reversed, at least transiently. To allow women to take an active role in HIV prevention methods, development of a topical microbicide is vital and may prove easier than a vaccine. Finally, HIV prevention efforts require knowledgeable, central leadership. All prevention efforts should be developed and implemented in parallel, to gain a synergistic result. Few vaccine experts are enthusiastic about microbicides, and HIV caregivers only rarely focus on the public health considerations of their patients. Stopping the spread of HIV requires a coordinated, concerted efforts using "all the tools in the toolbox."

Clinical monitoring of HIV-1 infection in the ERA of antiretroviral resistance testing

Viral replication of HIV-1 in the human body is a dynamic process. Incomplete suppression of replication during antiretroviral therapy ultimately selects for resistance that imparts an adaptive advantage to HIV-1. Therefore, the goal of antiretroviral therapy is complete suppression of viral replication. Viral suppression to below the lowest possible limits of detection has been associated with an optimal clinical response and delay of drug resistance. An ultrasensitive viral load assay with a very low threshold of detection remains our best laboratory tool to monitor the response to therapy. Patients may fail HAART for many reasons. Only when other potential causes of treatment failure are excluded should antiretroviral resistance testing be considered. Genotypic and phenotypic assays for assessing resistance are now available, and recent retrospective and prospective data support their use in clinical management as an adjunct to helping to choose among different antiretroviral drugs. Despite the growing enthusiasm for these tests, improvements in sensitivity, turnaround time, and quality control are still needed. A practitioner's decision about when to initiate or change therapy in an HIV-infected patient should depend primarily on viral load results, and not on antiretroviral resistance test results. Moreover, resistance testing is no substitute for a thorough clinical and drug history. As we approach the third decade of the HIV epidemic, we will learn how to use antiretroviral resistance tests in conjunction with (not in lieu of) proven clinical and laboratory tools.

Rapid restoration of CD4 T cell subsets in subjects receiving antiretroviral therapy during primary HIV-1 infection

OBJECTIVE

To compare the effect of highly active antiretroviral therapy on immune reconstitution in subjects with acute and chronic HIV-1 infection.

DESIGN

Prospective study including 58 treatment-naive subjects who commenced indinavir or nelfinavir and two nucleosides during primary (PHI; n = 28) or chronic HIV-1 infection (CHI; n = 30).

METHODS

Naive (CD45RA+ 62L+), memory (CD45RA-) and activated (CD38+ HLA-DR+) T cell subsets were quantified at 1-2 monthly time intervals using 4-colour flow cytometry.

RESULTS

At 1 year, HIV-1 RNA declined in both cohorts to undetectable levels (< 50 copies/ml), while median CD4 lymphocyte count increased from 470 to 758 x 10(6) cells/l in PHI and from 204 to 310 x 10(6) cells/l in CHI, reaching > 500 x 10(6) cells/l in 93% of PHI, but only in 37% of CHI subjects (P < 0.001). Naive CD4 lymphocytes increased from 106 to 176 x 10(6) cells/l in PHI and from 41 to 44 x 10(6) cells/l in CHI (PHI versus CHI at 12 months: P = 0.003), while memory cells rose from 368 to 573 x 10(6) cells/l in PHI and from 148 to 223 x 10(6) cells/l in CHI (P < 0.001). Early increases (< 3 months) of CD4 lymphocytes were larger in subjects with PHI, consisting of naive CD45RA+ CD62L+ as well as memory CD45RA- CD62L+ cells (P = 0.001). CD4 activation declined from 5 to 2% in PHI and from 13 to 6% in CHI (P = 0.001), while CD8 cell activation was reduced from 33 to 15% in PHI and from 42 to 19% in CHI (P = 0.02).

CONCLUSION

Immune reconstitution was more complete, occurred earlier and comprised both naive and memory CD4 T lymphocytes in subjects who commenced antiretroviral therapy during primary HIV-1 infection.

Therapeutic targeting of human immunodeficiency virus type-1 latency: current clinical realities and future scientific possibilities

Factors affecting HIV-1 latency present formidable obstacles for therapeutic intervention. As these obstacles have become a clinical reality, even with the use of potent anti-retroviral regimens, the need for novel therapeutic strategies specifically targeting HIV-1 latency is evident. However, therapeutic targeting of HIV-1 latency requires an understanding of the mechanisms regulating viral quiescence and activation. These mechanisms have been partially delineated using chronically infected cell models and, clearly, HIV-1 activation from latency involves several key viral and cellular components. Among these distinctive therapeutic targets, cellular factors involved in HIV-1 transcription especially warrant further consideration for rational drug design. Exploring the scientific possibilities of new therapies targeting HIV-1 latency may hold new promise of eventual HIV-1 eradication.

Delavirdine: a review of its use in HIV infection

Delavirdine, a bisheteroarylpiperazine derivative, is a non-nucleoside reverse transcriptase inhibitor (NNRTI) that allosterically binds to HIV-1 reverse transcriptase, inhibiting both the RNA- and DNA-directed DNA polymerase functions of the enzyme. Delavirdine in combination with nucleoside reverse transcriptase inhibitors (NRTIs) produced sustained reductions in plasma viral loads and improvements in immunological responses in large randomised, double-blind, placebo-controlled studies of 48 to 54 weeks' duration. In patients with advanced HIV infection, triple therapy with delavirdine, zidovudine and lamivudine, didanosine or zalcitabine for 1 year significantly prolonged the time to virological failure compared with dual therapy (delavirdine plus zidovudine or 2 NRTIs; p < 0.0001). After 50 weeks' treatment, plasma HIV RNA levels were below the limit of detection (LOD; <50 copies/ml) for 40% of patients receiving triple therapy but for only 6% of those receiving dual NRTI therapy. Preliminary results suggest that delavirdine also has beneficial effects on surrogate markers as a component of protease inhibitor-containing triple or quadruple regimens. At 16 to 48 weeks, the minimum mean reduction in plasma viral load from baseline was 2.5 log10 copies/ml and mean CD4+ counts increased by 100 to 313 cells/microl. The proportion of patients with plasma HIV RNAlevels below the LOD (usually 200 to 500 copies/ml) ranged from 48 to 100% after > or = 16 weeks. Delavirdine was also effective as a component of saquinavir soft gel capsule-containing salvage regimens. Since delavirdine shares a common metabolic pathway (cytochrome P450 3A pathway) with other NNRTIs, HIV protease inhibitors and several drugs used to treat opportunistic infections in patients infected with HIV, the drug is associated with a number of pharmacokinetic interactions. Some of these drug interactions are clinically significant, necessitating dosage adjustments or avoidance of co-administration. Delavirdine is not recommended for use with lovastatin, simvastatin, rifabutin, rifampicin, sildenafil, ergot derivatives, quinidine, midazolam, carbamazepine, phenobarbital or phenytoin. Importantly, the drug favourably increases the plasma concentration of several protease inhibitors. Delavirdine is generally well tolerated. Skin rash is the most frequently reported adverse effect, occurring in 18 to 50% of patients receiving delavirdine-containing combination therapy in clinical trials. Although a high proportion of patients developed a rash, it was typically mild to moderate in intensity, did not result in discontinuation or adjustment of treatment in most patients and resolved quickly. The occurrence of Stevens-Johnson syndrome was rare (1 case in 1,000 patients). A retrospective analysis of pooled clinical trial data indicated that there was no significant difference in the incidence of liver toxicity, liver failure or noninfectious hepatitis between delavirdine-containing and non-delavirdine-containing antiretroviral treatment groups. In addition, the incidence of lipodystrophy, metabolic lipid disorders, hyperglycaemia and hypertriglyceridaemia was not significantly different between these 2 treatment groups.

CONCLUSIONS

In combination with NRTIs. delavirdine produces sustained improvements in surrogate markers of HIV disease and prolongs the time to virological failure in adult patients with HIV infection. Preliminary data of delavirdine as a component of protease inhibitor-containing triple or quadruple highly active antiretroviral therapy regimens indicate that patients achieve marked improvements in virological and immunological markers. The drug is generally well tolerated, with a transient skin rash, typically of mild to moderate intensity, being the most common adverse effect. Delavirdine is an effective component of recommended antiretroviral treatment strategies for adult patients with HIV infection and, in combination with 2 NRTIs as a first-line therapy, the drug has the advantage of sparing protease inhibitors for subsequent use. Since delavirdine favourably increases plasma concentrations of several protease inhibitors, the drug may also be beneficial as a component of salvage therapy in combination with protease inhibitors.

Mechanisms of HIV-associated lymphocyte apoptosis

Infection with the human immunodeficiency virus (HIV) is associated with a progressive decrease in CD4 T-cell number and a consequent impairment in host immune defenses. Analysis of T cells from patients infected with HIV, or of T cells infected in vitro with HIV, demonstrates a significant fraction of both infected and uninfected cells dying by apoptosis. The many mechanisms that contribute to HIV-associated lymphocyte apoptosis include chronic immunologic activation; gp120/160 ligation of the CD4 receptor; enhanced production of cytotoxic ligands or viral proteins by monocytes, macrophages, B cells, and CD8 T cells from HIV-infected patients that kill uninfected CD4 T cells; and direct infection of target cells by HIV, resulting in apoptosis. Although HIV infection results in T-cell apoptosis, under some circumstances HIV infection of resting T cells or macrophages does not result in apoptosis; this may be a critical step in the development of viral reservoirs. Recent therapies for HIV effectively reduce lymphoid and peripheral T-cell apoptosis, reduce viral replication, and enhance cellular immune competence; however, they do not alter viral reservoirs. Further understanding the regulation of apoptosis in HIV disease is required to develop novel immune-based therapies aimed at modifying HIV-induced apoptosis to the benefit of patients infected with HIV.

Limits to potent antiretroviral therapy

The availability of potent combination antiretroviral therapy (ART), also known as highly active antiretroviral therapy or HAART has changed the prognosis of HIV infection. However, the benefits have to be seen in the context of deficiencies of current therapy: failure to eradicate the virus, the slow and potentially incomplete recovery of the immune system, the high prevalence of resistance, and the potential for long-term toxicity. Treatment strategies need to take into account these limits to better target those HIV-infected patients who could benefit the most from antiretroviral therapy.

Mechanisms of HIV-associated lymphocyte apoptosis

Infection with the human immunodeficiency virus (HIV) is associated with a progressive decrease in CD4 T-cell number and a consequent impairment in host immune defenses. Analysis of T cells from patients infected with HIV, or of T cells infected in vitro with HIV, demonstrates a significant fraction of both infected and uninfected cells dying by apoptosis. The many mechanisms that contribute to HIV-associated lymphocyte apoptosis include chronic immunologic activation; gp120/160 ligation of the CD4 receptor; enhanced production of cytotoxic ligands or viral proteins by monocytes, macrophages, B cells, and CD8 T cells from HIV-infected patients that kill uninfected CD4 T cells; and direct infection of target cells by HIV, resulting in apoptosis. Although HIV infection results in T-cell apoptosis, under some circumstances HIV infection of resting T cells or macrophages does not result in apoptosis; this may be a critical step in the development of viral reservoirs. Recent therapies for HIV effectively reduce lymphoid and peripheral T-cell apoptosis, reduce viral replication, and enhance cellular immune competence; however, they do not alter viral reservoirs. Further understanding the regulation of apoptosis in HIV disease is required to develop novel immune-based therapies aimed at modifying HIV-induced apoptosis to the benefit of patients infected with HIV.