Pål Voltersvik

Activation of CD8 T cells normalizes and correlates with the level of infectious provirus in tonsils during highly active antiretroviral therapy in early HIV-1 infection.

OBJECTIVES To study the effects of antiretroviral therapy on T cell activation in blood and tonsils from HIV-1 infected individuals in relation to CD4 cell count, plasma viremia, and infectious HIV-1 provirus. DESIGN A 48-week study of viral load and T cell subsets in blood and tonsils from 12 HIV-1-positive individuals with a mean CD4 cell number of 400 x 10(6) cells/l treated with a combination of zidovudine, lamivudine, and indinavir. METHODS Tonsil biopsies and blood samples were collected at regular intervals. Lymphocytes were phenotyped and quantified by three-color flow cytometry; infectious provirus was quantified by a limiting dilution assay. HIV-1-negative individuals were included as controls. RESULTS The fraction of tonsillar CD8 T cells expressing CD69, CD38, or HLA-DR in the patients with suppressed virus replication declined to levels comparable with that in controls by 48 weeks and showed a strong positive correlation with tonsillar infectious provirus and plasma viremia. The level of CD4 T cell activation was within normal range in tonsils throughout the study. The fraction of HLA-DR+ cells within CD4 and CD8 T cells in blood declined rapidly in parallel with plasma viremia but remained slightly higher compared with that in uninfected individuals. CONCLUSION Antiretroviral therapy normalizes tonsillar CD8 T cell activation in HIV-1-positive individuals in parallel with suppression of viral replication, indicating reduced CD8 cell turnover. Normal tonsillar CD4 T cell activation suggests limited CD4 cell turnover in early HIV infection. Activated CD8 T cells in lymphoid tissue is superior to that in blood as an immunological marker for the virological response to antiretroviral therapy.

Changes in immunoglobulin isotypes and immunoglobulin G (IgG) subclasses during highly active antiretroviral therapy: Anti-p24 IgG1 closely parallels the biphasic decline in plasma viremia

The effects of highly active antiretroviral therapy (HAART) on immunoglobulin isotypes and immunoglobulin G (IgG) subclasses were studied in 12 patients in early stages of HIV-1 infection. Blood samples were obtained at enrollment and 2, 4, 8, 12, 24, 48, and 120 weeks after initiation of HAART. Immunoglobulin concentrations were determined by nephelometry, and anti-p24–specific IgG and IgG1 levels were determined by an enzyme immunoassay. Overall time changes were analyzed in analysis of variance models. IgG and IgG1 levels showed a marked overall decline, whereas other immunoglobulin isotypes and IgG subclasses did not change significantly. Anti-p24–specific IgG1 levels decreased considerably and significantly more in virus isolation–negative patients than in virus isolation–positive patients, as defined according to the ability to isolate HIV-1 from their CD4+ T cells after initiation of therapy. Anti-p24 IgG levels showed a similar but overall weaker decline in the two groups. However, the anti-p24 IgG1 level followed the biphasic decline in plasma viremia more closely than the anti-p24 IgG level, with an initial sharp decline that leveled off with time. These findings suggest that the main reduction in immunoglobulin levels is caused by reduced HIV-1–specific antigen stimulation rather than a general reduction in immune activation. Using anti-p24 IgG1 as a parameter of response to the effect of HAART merits further investigation.

Cathepsin B and Cystatin A as Indicators of a Separate Apoptotic Pathway in HIV-1 Infection

Apoptosis has been proposed to explain the dysfunction in HIV-1 infection and FAS has been given a pivotal role. However, apoptosis in lymphoid follicles has also been explained by a follicular dendritic cell (FDC) dependent pathway regulated by a cathepsin-dependent endonuclease activity in germinal centre (GC) cells. Cystatin A is present in FDCs and is a natural inhibitor of cysteine proteinase, as Cathepsin B. As yet, the Cystatin A and Cathepsin B interaction in HIV-1 infection has not been studied.

Normalization of CD4+ Cell Numbers and Reduced Levels of Memory CD8+ Cells in Blood and Tonsillar Tissue after Highly Active Antiretroviral Therapy in Early HIV Type-1 Infection

Antiretroviral therapy increases the number of both CD4+ and CD8+ T cells in the blood of HIV-1-positive patients with advanced disease. In the present study, we have examined the kinetics of CD4+ and CD8+ T cell restoration in blood and lymphoid tissue in asymptomatic HIV-1-positive individuals with high CD4+ cell counts during highly active antiretroviral treatment. Tonsillar biopsies and blood samples were collected at baseline and at regular intervals during the following 48 weeks and from HIV-1-negative controls. Mononuclear cells from blood and tonsils were phenotyped and quantified by three-color flow cytometry. After 48 weeks of therapy, blood CD4+ cell counts in the HIV-1-infected group were comparable to those found in uninfected controls. Naive CD4+ T cells in blood increased during the initial 2 weeks in parallel with reduced plasma viremia. Both naive and memory CD4+ T cells in blood reached normal numbers by week 48, whereas the CD4+ naive/memory cell ratio in tonsils was within normal range throughout the study. The level of memory CD8+ T cells in blood declined during the first 8 weeks in parallel with a reduction in the tonsillar memory CD8+ T cells. Naive CD8+ T cells in the blood increased after 4 weeks, while the level of naive CD8+ T cells in tonsils remained unaltered. Our data indicate that in the early stages of HIV-1 infection antiretroviral therapy normalizes CD4+ cell counts and causes a decrease in the level of memory CD8+ cells in blood and lymphoid tissue, suggesting reduced CD8+ cell turnover in response to reduced viral replication.

Serum antibodies to viral pathogens and Toxoplasma gondii in HIV-infected individuals

Sera from 38 HIV‐infected individuals were examined longitudinally for antibodies to viruses that may increase morbidity in HIV infection, as well as commensal viruses and Toxoplasma gondii. HTLV infection was seen in Norway for the first time as four patients had antibodies to HTLV‐II and one had antibodies to HTLV‐I. Antibodies to hepatitis B virus (HBV) were found in 47.2%, while 21.6% of the patients had antibodies to hepatitis C virus (HCV). There was no evidence of acquisition of HBV or HVC during the mean observation period of 2 years. A titre increase in CMV antibody with time was observed for 7 out of 21 patients and a decrease for 2 patients. For Epstein‐Barr virus, herpes simplex, varicella‐zoster, rubella and measles viruses, human polyomavirus BK as well as for Toxoplasma gondii, antibody prevalences and titres were within the range seen in normal populations. Also, no longitudinal changes were observed in titres of these antibodies, indicating that humoral immunity remained intact during the study period. The high prevalences of HTLV‐I/II, HBV and HCV antibodies in HIV‐infecled patients reflect common modes of virus transmission, and the fluctuations in CMV antibody titre are indicative of reactivations. Such coinfections may influence disease progression.

Cystatin A and HIV-1 p24 antigen expression in tonsillar lymphoid follicles during HIV-1 infection and during highly active antiretroviral therapy.

Summary: Cystatin A is a natural cysteine proteinase inhibitor and is found in a wide variety of normal cells. The physiologic role of Cystatin A is not fully known, however. Cystatin A is present in large amounts in follicular dendritic cells, which are important in HIV-1 pathogenesis. We analyzed Cystatin A expression in tonsillar sections from 20 patients at various stages of HIV-1 infection. There was a significant (P < 0.001) difference in Cystatin A fractions between patients and controls, with medians (ranges) of 0.61 (0.46-0.83) and 0.86 (0.78-0.90), respectively. Inverse correlations (Spearman &rgr;) existed between Cystatin A and the rate of follicular fragmentation (&rgr; = −0.658) and HIV-1 p24 antigen expression (&rgr; = −0.622) in germinal centers and the amount of HIV-1 RNA in tonsillar tissue (&rgr; = −0.765). The Cystatin A fraction declined from early chronic HIV-1 infection and was significantly lower in patients with a CD4 count below as compared with above 300 cells/&mgr;L of blood (P < 0.001), suggesting a favorable initiation of highly active antiretroviral therapy (HAART) at this level. Regeneration of Cystatin A to normal levels was shown in 11 patients 12 and 48 weeks after initiation of HAART, whereas the rate of follicular fragmentation was still elevated. Thus, we found Cystatin A to be a sensitive marker during HIV-1 infection and for regeneration of follicular lymphoid tissue during HAART.

Residual human immunodeficiency virus type 1 infection in lymphoid tissue during highly active antiretroviral therapy: Quantitation and virus characterization

HIV-1 can persist in infected patients despite undetectable plasma viremia. To characterize the residual viral load, repetitive blood and tonsillar samples were collected from 11 HIV-1-positive individuals before and during 96 weeks of therapy with zidovudine, lamivudine, and indinavir. HIV-1 RNA in tonsils was quantified by RT-PCR and infectious HIV-1 provirus by the limiting dilution assay. Genotypic resistance analyses and biological characterization were performed on plasma virus, blood, and tonsillar isolates. Tonsillar infectious HIV-1 provirus and HIV-1 RNA declined by 2 and 3 log(10), respectively, but 10(3)-10(4) cells, less than 0.5% of the total body CD4(+) T cell population carrying infectious HIV-1 provirus, remained involved in active viral replication of drug-sensitive R5 viruses. Thus, the dominant HIV-1 residual infection consists of < or = 10(6) latently infected CD4(+) cells. Plasma HIV-1 RNA decline of > 1.5 log(10) during the first 2 weeks of therapy may indicate low levels of this latent reservoir. Whereas the reservoir of latently infected cells remains stable, actively replicating HIV-1 continuously declines during prolonged antiretroviral therapy. Thus, although viral eradication seems unlikely, antiretroviral therapy may induce an extended period of virologic latency in HIV-1-positive individuals.

Changes in tonsillar tissue in early HIV-1 infection and during 3 years of antiretroviral therapy

Tonsillar tissue from individuals in the early stages of HIV‐1 infection was studied during the natural course of infection and during antiretroviral therapy with and without a protease inhibitor in order to investigate markers of clinical progression and evaluate the effects of therapy. Tonsillar biopsies and blood samples were collected at regular intervals during 3 years and clinical observations were noted. Tonsillar morphology was evaluated and the fragmentation of the follicular dendritic cell network was quantified by standardised follicular fragmentation rate (FR) analysis. Lymphocyte subsets were phenotyped by flow cytometry, and viral load was calculated by limiting dilution assay. The FRs were higher in the HIV‐1‐infected individuals than in the uninfected controls, although tonsillar tissue from both groups contained follicular fragmentation. During HIV‐1 infection, the FR increased and the tonsillar CD4/CD8 ratio declined. During maximum viral suppression, FR approached that of controls while tonsillar T cell subsets and blood CD4 cell counts normalised. Even when virus suppression was incomplete, tonsillar improvements were observed in parallel with a resolution of the HIV‐1‐related dermatological disorders. However, persistent viral replication paralleled distortion of the tonsillar architecture. We suggest that a normalisation of the lymphoid tissue may have important functional and clinical implications in HIV‐1 infection.

Pulmonary changes in Norwegian fatal cases of pandemic influenza H1N1 (2009) infection: a morphologic and molecular genetic study

During the pandemic outbreak of the 2009 swine influenza (A(H1N1)pdm09), 32 fatal cases occurred in Norway and 19 of these were included in this study.