CCTTT-repeat polymorphism of the inducible nitric oxide synthase is not associated with HIV pathogenesis.

Nitric oxide (NO) produced by the inducible form of nitric oxide synthase (iNOS) has bactericidal and virocidal effects. Although NO synthesis and iNOS expression in macrophages affect several aspects of human immunodeficiency virus (HIV) type-1 pathogenesis, their role in HIV disease remains largely unknown. In humans, the expression of iNOS is influenced by a functional CCTTT-repeat polymorphism in the promoter region of the gene. We investigated the association of this polymorphism with HIV pathogenesis in naive HIV-infected patients before the initiation of antiretroviral therapy. The allele frequencies of the iNOS CCTTT-repeat polymorphism were assessed by PCR in 857 patients from the Swiss HIV Cohort Study, including rapid progressors and long-term nonprogressors, and in 240 healthy volunteers. In HIV-infected patients, the initial viral load and the decline in total CD4 cells was calculated to estimate disease progression. Allele frequencies of the iNOS CCTTT-repeat polymorphism were similar between the HIV-infected and noninfected blood donors. In treatment-naive HIV-positive patients, there was no association of the iNOS polymorphism with viral load or with the course of CD4 cells. Regulation of iNOS expression by the functional CCTTT-polymorphism does not modify HIV pathogenesis.

Mathematical approaches in the study of viral kinetics and drug resistance in HIV-1 infection.

We review some crucial aspects of drug therapy and viral resistance that have been investigated within the framework developed for the modelling of virus kinetics. First, we give a general overview on the use of mathematical models in the field of HIV research. We seek to identify the factors that determine the steady state virus load and show that stable reductions during antiviral therapy are difficult to explain within the standard model of virus dynamics. We discuss possible extensions that enable the models to account for the moderately reduced virus loads during non-suppressive treatment and argue that the residual viremia under suppressive treatment can probably be attributed to the survival of long-lived infected cells, rather than to new rounds of replication. Next, we address the emergence of resistance during suppressive therapy and demonstrate that the resistant virus is more likely to be present already at the start of treatment than to be generated during therapy. The appearance of resistance after a prolonged period of initial suppression indicates that drug efficacy is not continuously maintained over time. We investigate the potential risks and benefits of therapy interruptions. Considering the effect of recombination, we argue that it probably decelerates, rather than accelerates the evolution of multidrug-resistant virus. We also review state-of-the-art methods for the estimation of fitness, which is crucial to the understanding of the emergence of resistance during therapy or the re-emergence of wild type upon the cessation of therapy.

Structured antiretroviral treatment interruptions in chronically HIV-1-infected subjects.

The risks and benefits of structured treatment interruption (STI) in HIV-1-infected subjects are not fully understood. A pilot study was performed to compare STI with continuous highly active antiretroviral therapy (HAART) in chronic HIV-1-infected subjects with HIV-1 plasma RNA levels (VL) <400 copies per ml and CD4(+) T cells >400 per microl. CD4(+) T cells, VL, HIV-1-specific neutralizing antibodies, and IFN-gamma-producing HIV-1-specific CD8(+) and CD4(+) T cells were measured in all subjects. STIs of 1-month duration separated by 1 month of HAART, before a final 3-month STI, resulted in augmented CD8(+) T cell responses in all eight STI subjects (P = 0.003), maintained while on HAART up to 22 weeks after STI, and augmented neutralization titers to autologous HIV-1 isolate in one of eight subjects. However, significant decline of CD4(+) T cell count from pre-STI level, and VL rebound to pre-HAART baseline, occurred during STI (P = 0.001 and 0.34, respectively). CD4(+) T cell counts were regained on return to HAART. Control subjects (n = 4) maintained VL <400 copies per ml and stable CD4(+) T cell counts, and showed no enhancement of antiviral CD8(+) T cell responses. Despite increases in antiviral immunity, no control of VL was observed. Future studies of STI should proceed with caution.

Analysis of total human immunodeficiency virus (HIV)-specific CD4(+) and CD8(+) T-cell responses: relationship to viral load in untreated HIV infection.

Human immunodeficiency virus (HIV)-specific T-cell responses are thought to play a key role in viral load decline during primary infection and in determining the subsequent viral load set point. The requirements for this effect are unknown, partly because comprehensive analysis of total HIV-specific CD4(+) and CD8(+) T-cell responses to all HIV-encoded epitopes has not been accomplished. To assess these responses, we used cytokine flow cytometry and overlapping peptide pools encompassing all products of the HIV-1 genome to study total HIV-specific T-cell responses in 23 highly active antiretroviral therapy naïve HIV-infected patients. HIV-specific CD8(+) T-cell responses were detectable in all patients, ranging between 1.6 and 18.4% of total CD8(+) T cells. HIV-specific CD4(+) T-cell responses were present in 21 of 23 patients, although the responses were lower (0.2 to 2.94%). Contrary to previous reports, a positive correlation was identified between the plasma viral load and the total HIV-, Env-, and Nef-specific CD8(+) T-cell frequency. No correlation was found either between viral load and total or Gag-specific CD4(+) T-cell response or between the frequency of HIV-specific CD4(+) and CD8(+) T cells. These results suggest that overall frequencies of HIV-specific T cells are not the sole determinant of immune-mediated protection in HIV-infection.

Quantification of in vivo replicative capacity of HIV-1 in different compartments of infected cells.

Based on a mathematical model, we analyze the dynamics of CD4+ cells, actively, latently, persistently, and defectively infected cells and plasma virus after initiation of antiretroviral therapy in 14 HIV-1-infected asymptomatic patients. By simultaneous fitting of our model to clinical data of plasma HIV-1 RNA, peripheral blood mononuclear cell (PBMC)-gag RNA, proviral DNA, and CD4+ cell counts, we estimate kinetic parameters to determine the basic reproductive rate (R0) of the virus in different infected cell compartments as a measure of the replicative capacity of the virus in vivo. We find that the basic reproductive rate is larger than 1 before treatment only in actively infected cells (mean R0(act) approximately 2.46) indicating that only in this compartment the virus can maintain an ongoing infection. In latently and persistently infected cells the basic reproductive rate is considerably smaller (R0(lat) approximately 0.03 and R0(pers) approximately 0.008, respectively) indicating that these compartments contribute little to the total basic reproductive rate and cannot maintain an ongoing infection in absence of actively infected cells.

The virological and immunological consequences of structured treatment interruptions in chronic HIV-1 infection.

BACKGROUND: Some individuals with chronic HIV-1 infection have discontinued their drug therapy with consequent plasma virus rebound. In a small number of patients, a delayed or absent rebound in plasma virus load has been noted after drug cessation, apparently associated with prior drug interruptions and autologous boosting of HIV-1 specific immune responses. We hypothesized that cyclic structured treatment interruptions structured treatment interruptions (STI) could augment HIV-1 specific immune responses in chronic HIV-1 infection, which might help to control HIV-1 replication off therapy. METHODS: We initiated an STI pilot study in 10 antiretroviral treatment-naive HIV-1 chronically infected subjects with baseline CD4 T-cell counts > 500 x 10(6) cells/l and plasma viral load > 5000 copies/ml who received highly active antiretroviral therapy (HAART) for 1 year with good response (plasma viral load < 20 copies/ml for at least 32 weeks). Three cycles of HAART interruption were performed. RESULTS: In all of the patients viral load rebounded, but doubling times increased significantly between the first and third stops (P = 0.008), and by the third stop, six out of nine subjects had a virological set-point after a median 12 months off therapy that was lower than baseline before starting HAART (ranging from 0.6 log(10) to 1.3 log(10) lower than baseline) and in four it remained stable below 5000 copies/ml. Those subjects who controlled viral replication developed significantly stronger HIV-1 specific cellular immune responses than subjects lacking spontaneous decline (P < 0.05). During viral rebounds no genotypic or phenotypic changes conferring resistance to reverse trancriptase inhibitors or protease inhibitors was detected, but mean absolute CD4 T-cell counts declined significantly, although never below 450 x 10(6)/l and the mean value at 12 months off therapy was significantly higher than the pre-treatment level (P = 0.004). CONCLUSIONS: Our findings suggest that STI in chronic HIV-1 infection might augment HIV-1-specific cellular immune responses associated with a spontaneous and sustained drop in plasma viral load in some subjects but at the potential cost of lower CD4 T-cell counts.

Cooperation and competition in the evolution of ATP-producing pathways.

Heterotrophic organisms generally face a trade-off between rate and yield of adenosine triphosphate (ATP) production. This trade-off may result in an evolutionary dilemma, because cells with a higher rate but lower yield of ATP production may gain a selective advantage when competing for shared energy resources. Using an analysis of model simulations and biochemical observations, we show that ATP production with a low rate and high yield can be viewed as a form of cooperative resource use and may evolve in spatially structured environments. Furthermore, we argue that the high ATP yield of respiration may have facilitated the evolutionary transition from unicellular to undifferentiated multicellular organisms.

An antigenic threshold for maintaining human immunodeficiency virus type 1-specific cytotoxic T lymphocytes.

BACKGROUND: Using the lymphocytic choriomeningitis virus (LCMV) model in mice, a number of studies show that memory cytotoxic T-lymphocyte (CTL) responses are maintained in the presence of continuous antigenic stimulation. Yet, other groups found that memory CTL specific for LCMV could last for a lifetime in mice without viral antigens. Thus, the extent to which an antigen is required for the maintenance of virus-specific CTL remains controversial. In humans, very few studies have been conducted to investigate the relationship between the quantity of antigen and the magnitude of CTL responses. MATERIALS AND METHODS: We quantified CTL precursors (CTLp) using a limiting-dilution analysis (LDA) and CTL effectors (CTLe) using a new Major Histocompatibility Complex (MHC) class I tetramer technology in six long-term nonprogressors (LTNPs) with human immunodeficiency virus type-1 (HIV-1) infection, as well as in eight patients whose viral loads were well suppressed by antiretroviral therapy. The viremia levels in these patients were measured using an reverse transcription polymerase chain reaction (RT-PCR) assay. The proviral DNA load in peripheral blood mononuclear cell (PBMC) was also measured by PCR in four LTNPs. RESULTS: The LTNPs had high levels of HIV-1-specific memory CTLp and CTLe, while maintaining a low plasma viral load. Despite also having low viral loads, patients whose plasma viremia was well-suppressed by effective therapy had low levels of CTLe. CONCLUSIONS: Our findings suggest that a complex, rather than a monotonic, relationship exists between CTL levels and HIV-1 viremia, including what appears to be an antigenic threshold for the maintenance of CTL at a measurable level. Under conditions of "antigen excess,", CTLe levels correlate inversely with viral load. On the other hand, under conditions that are "antigen limited," the correlation appears to be direct.

Risks and benefits of structured antiretroviral drug therapy interruptions in HIV-1 infection.

BACKGROUND: Structured interruptions of antiretroviral therapy of HIV-1 infected individuals are currently being tested in clinical trials to study the effect interruptions have on the immune responses and control of virus replication. OBJECTIVE: To investigate the potential risks and benefits of interrupted therapy using standard population dynamical models of HIV replication kinetics. METHODS: Standard population dynamical models were used to study the effect of structured therapy interruptions on the immune effector cells, the latent cell compartment and the emergence of drug resistance. CONCLUSIONS: The models suggest that structured therapy interruption only leads to transient or sustained virus control if the immune effector cells increase during therapy. This increase must more than counterbalance the increase in susceptible target cells induced by therapy. The risk of inducing drug resistance by therapy interruptions or the risk of repopulating the pool of latent cells during drug-free periods may be small if the virus population remains at levels considerably below baseline. However, if the virus load increases during drug-free periods to levels similar to or higher than baseline before therapy, both these risks increase dramatically.

Evolution of virulence in a heterogeneous host population.

There is a large body of theoretical studies that investigate factors that affect the evolution of virulence, that is parasite-induced host mortality. In these studies the host population is assumed to be genetically homogeneous. However, many parasites have a broad range of host types they infect, and trade-offs between the parasite virulence in different host types may exist. The aim of this paper is to study the effect of host heterogeneity on the evolution of parasite virulence. By analyzing a simple model that describes the replication of different parasite strains in a population of two different host types, we determine the optimal level of virulence in both host types and find the conditions under which strains that specialize in one host type dominate the parasite population. Furthermore, we show that intrahost evolution of the parasite during an infection may lead to stable polymorphisms and could introduce evolutionary branching in the parasite population.

Production of resistant HIV mutants during antiretroviral therapy.

HIV drug therapy often fails because of the appearance of multidrug-resistant virus. There are two possible scenarios for the outgrowth of multidrug-resistant virus in response to therapy. Resistant virus may preexist at low frequencies in drug-naive patients and is rapidly selected in the presence of drugs. Alternatively, resistant virus is absent at the start of therapy but is generated by residual viral replication during therapy. Currently available experimental methods are generally too insensitive to distinguish between these two scenarios. Here we use deterministic and stochastic models to investigate the origin of multidrug resistance. We quantify the probabilities that resistant mutants preexist, and that resistant mutants are generated during therapy. The models suggest that under a wide range of conditions, treatment failure is most likely caused by the preexistence of resistant mutants.

Quantification of cell turnover kinetics using 5-bromo-2'-deoxyuridine.

5-Bromo-2'-deoxyuridine (BrdU) is frequently used to measure the turnover of cell populations in vivo. However, due to a lack of detailed mathematical models that describe the uptake and loss of BrdU in dividing cell populations, assessments of cell turnover kinetics have been largely qualitative rather than quantitative. In this study, we develop a mathematical framework for the analysis of BrdU-labeling experiments. We derive analytical expressions for the fraction of labeled cells within cell populations that are growing, declining, or at equilibrium. Fitting the analytical functions to data allows us to quantify the rates of cell proliferation and cell loss, as well as the rate of cell input from a source. We illustrate this for the BrdU labeling of T lymphocytes of uninfected and SIV-infected rhesus macaques.

Passive infusion of immune serum into simian immunodeficiency virus-infected rhesus macaques undergoing a rapid disease course has minimal effect on plasma viremia.

Antibody responses are often considered to play only a limited role in controlling viremia during chronic infections with human or simian immunodeficiency virus (SIV). We investigated this by determining the effect of passively infused antibody on plasma viremia in infected rhesus macaques. The emphasis of the study was to understand the mechanism(s) underlying any observed effects. We infused serum immunoglobulins (SIVIG) purified from SIV(mac)251-infected macaques into other SIV(mac)251-infected macaques. The rapid progressor recipients had high viral loads but negligible titers of antibodies to SIV. Thus, we could significantly increase antibody titers with exogenous SIVIG. Despite restoring anti-SIV titers to levels typical of macaques with a normal disease course, SIVIG had only a modest effect on plasma SIV RNA and cell-associated viral load; the maximum, transient, reduction was threefold. The decrease in plasma RNA commenced within 1-2 h of SIVIG infusion, the nadir was at 12 h, and then a rebound occurred. A two- to threefold drop in cell-associated viral RNA was simultaneous with the decrease in plasma RNA. The kinetics of the viremia changes are inconsistent with neutralization of new cycles of infection. More likely, perhaps unexpectedly, is that infused antibodies killed SIV-infected cells, via an effector mechanism such as antibody-dependent cellular cytotoxicity.

High frequency of cytomegalovirus-specific cytotoxic T-effector cells in HLA-A*0201-positive subjects during multiple viral coinfections.

How the cellular immune response copes with diverse antigenic competition is poorly understood. Responses of virus-specific cytotoxic T lymphocytes (CTL) were examined longitudinally in an individual coinfected with human immunodeficiency virus type 1 (HIV-1), Epstein-Barr virus (EBV), and cytomegalovirus (CMV). CTL responses to all 3 viruses were quantified by limiting dilution analysis and staining with HLA-A*0201 tetrameric complexes folded with HIV-1, EBV, and CMV peptides. A predominance of CMV-pp65-specific CTL was found, with a much lower frequency of CTL to HIV-1 Gag and Pol and to EBV-BMLF1 and LMP2. The high frequency of CMV-specific CTL, compared with HIV-1- and EBV-specific CTL, was confirmed in an additional 16 HLA-A*0201-positive virus-coinfected subjects. Therefore, the human immune system can mount CTL responses to multiple viral antigens simultaneously, albeit with different strengths.

Rapid production and clearance of HIV-1 and hepatitis C virus assessed by large volume plasma apheresis.

BACKGROUND: In chronic HIV-1 infection, dynamic equilibrium exists between viral production and clearance. The half-life of free virions can be estimated by inhibiting virion production with antiretroviral agents and modelling the resulting decline in plasma HIV-1 RNA. To define HIV-1 and hepatitis C virus (HCV) dynamics, we used plasma apheresis to increase virion clearance temporarily while leaving virion production unaffected. METHODS: Plasma virus loads were measured frequently before, during, and after apheresis in four HIV-1-infected patients, two of whom were also co-infected with HCV. Rates of virion clearance were derived by non-linear least-square fitting of plasma virus load to a model of viral dynamics. FINDINGS: Virion clearance rate constants were 0.0063/min (9.1/day) to 0.025/min (36.0/day; half-life 28-110 min) for HIV-1 and 0.0038/min (5.5/day) to 0.0069/min (9.9/day; half-life 100-182 min) for HCV. These values provided estimates of daily particle production of 9.3 log10-10.2 log10 particles for HIV-1 and 11.6 log10-13.0 log10 particles for HCV. INTERPRETATION: Our findings confirm that HIV-1 and HCV are produced and cleared extremely rapidly. New estimates for HIV-1 clearance are up to ten times higher than previous ones, whereas HCV clearance is similar to previous estimates.

HIV-1-specific immune responses in subjects who temporarily contain virus replication after discontinuation of highly active antiretroviral therapy.

Therapeutic intervention with highly active antiretroviral therapy (HAART) can lead to suppression of HIV-1 plasma viremia to undetectable levels for 3 or more years. However, adherence to complex drug regimens can prove problematic, and subjects may temporarily discontinue HAART for variable periods. We studied 6 HIV-1-infected individuals who stopped therapy. Off HAART, levels of viremia were suppressed to fewer than 500 copies/mL in 2 subjects for more than 12 and more than 24 months, respectively, and in 1 subject for 4 months on 1 occasion. Three subjects failed to contain plasma viremia. Broad and strong HIV-1-specific immune responses were detected in subjects with prolonged suppression of viral replication. This longitudinal study suggests that containment of HIV-1 replication to low or undetectable levels after discontinuation of HAART is associated with strong virus-specific immune responses. Boosting of HIV-1-specific immune responses should be considered as an adjunctive treatment strategy for HIV-1-infected individuals on HAART.

Phenotypic changes in drug susceptibility associated with failure of human immunodeficiency virus type 1 (HIV-1) triple combination therapy.

The emergence of drug-resistant human immunodeficiency virus type 1 is a frequent cause of failure of combination therapies comprising reverse transcriptase and protease inhibitors. Rational design of salvage therapies requires new methods to assess drug susceptibility. A novel phenotypic drug susceptibility assay was developed and used to measure the drug susceptibilities of viruses obtained from 2 patients treated with zidovudine, lamivudine, and nelfinavir. Results showed that phenotypic drug resistance may be detectable before virus load rebound, treatment failure does not always imply viral resistance to all drugs in a treatment regimen, and persons with similar antiviral treatment histories and clinical courses may have different phenotypic drug resistance profiles at the time that treatment fails.

A stochastic model for primary HIV infection: optimal timing of therapy.

OBJECTIVE: To investigate the optimal time point for the initiation of therapy in HIV infection from the perspective of drug resistance. BACKGROUND: The enormous genetic diversity of HIV within an infected individual represents one of the greatest challenges for effective therapy, because the viral population may harbour drug-resistant mutants that rapidly outgrow the wild-type virus once the patient starts treatment. To determine the optimal timing of therapy it is crucial to know how long it takes for the viral population to build up sufficient diversity to enable the virus to escape from therapy. METHOD: A stochastic model of the viral diversification during primary infection was used to study the behaviour of small population sizes of mutant virus. RESULTS AND CONCLUSIONS: The simulations suggest that from the perspective of viral diversity, therapy should be started at the viral set-point. Starting treatment earlier involves a risk of the selective outgrowth of drug-resistant mutants, which are transiently present at the viral peak during primary infection.

Molecular tracking of an Human Immunodeficiency Virus nef specific cytotoxic T-cell clone shows persistence of clone-specific T-cell receptor DNA but not mRNA following early combination antiretroviral therapy.

The mechanisms that lead to maintenance of an active effector cytotoxic T-cell (CTL) response in Human Immunodeficiency Virus type-1 (HIV-1) infection are not well understood. We have investigated the role of antigen in maintenance of an HIV-1 specific CTL response by studying a patient (313-7) whose antigenic stimulus was reduced using antiretroviral drug therapy started within 90 days of HIV-1 infection. This patient made a primary monospecific CTL response to an HLA-C*0802 restricted epitope in nef (KAAVDLSHFL) prior to treatment. Within 7 days of starting treatment the nef specific CTL precursor frequency (CTLp) had decreased from 60/10(6) to 4/10(6) peripheral blood mononuclear cells (PBMC), coincident with a decline in viremia from 18 470 to 615 copies/ml. Both plasma viremia and nef specific CTLp remained at low levels for 180 days. The nef-specific CTL clone T-cell receptor (TCR) mRNA transcripts also decreased after treatment, but clone specific TCR DNA persisted. It appears that removal of antigen alters the state of HIV specific CTL from an activated effector population (detected in the CTLp assay and by measurement of clone specific RNA) to a non-activated quiescent population (detected by measurement of clone-specific DNA). This latter population may represent persisting HIV specific memory CTL.

Population biology, evolution, and infectious disease: convergence and synthesis.

Traditionally, the interest of population and evolutionary biologists in infectious diseases has been almost exclusively in their role as agents of natural selection in higher organisms. Recently, this interest has expanded to include the genetic structure and evolution of microparasite populations, the mechanisms of pathogenesis and the immune response, and the population biology, ecology, and evolutionary consequences of medical and public health interventions. This article describes recent work in these areas, emphasizing the ways in which quantitative, population-biological approaches have been contributing to the understanding of infectious disease and the design and evaluation of interventions for their treatment and prevention.