IntroductionA profound impairment of immune functions occurs in individuals infected with human immunodeficiency virus type 1 (HIV-1). Both the cellular and the humoral arms of the immune system are unable to control the infection, which ultimately results in severe exhaustion of several lymphocyte functions and increased susceptibility to secondary and opportunistic infections. Major immunologic defects occur in the B-cell compartment. 1 Polyclonal B-cell activation is demonstrated by hypergammaglobulinemia and spontaneous antibodies' (Abs) production by cultured peripheral lymphocytes 2,3 ; additional signs of B-cell abnormality are the high incidence of B-cell tumors 4 and the deregulated expression of several surface molecules like Fas, Fas ligand (FasL), CD5, CD21, and CD27. 5-8 B-cell hyperactivity is also accompanied by functional defects since humoral immune responses following immunization are severely impaired in HIV-1-infected subjects and B lymphocytes from patients are poorly responsive to in vitro stimulation. [9][10][11] Several mechanisms may account for the B-cell abnormalities in HIV-1 infection. A direct effect of virus replication or viral proteins on B-cell function has been shown 12 and sustained by the observation that polyclonal B-cell activation is strongly reduced following effective antiretroviral treatment. 13-15 HIV-driven unbalanced production of several cytokines like tumor necrosis factor ␣ (TNF-␣), interleukin 6 (IL-6), IL-10, and IL-15 has also been involved in B-cell dysfunctions. [16][17][18] Defective T-cell help may account for B-cell unresponsiveness to T-cell-dependent antigens. 19,20 The defect of B cells in HIV-1 infection appears, however, to be intrinsic since it begins early during infection preceding functional and quantitative defects in T-helper activity and cannot be restored by allogenic normal CD4 ϩ T cells in vitro. 3,21 The mechanisms inducing hypergammaglobulinemia in HIV-1 infection are only partially known. Activation driven by CD4 ϩ T cells, monocytes, and natural killer (NK) cells through CD40-CD40 ligand (CD40L) interaction and an inappropriate cytokine supply may have a relevant role in inducing abnormal differentiation of B cells. 17,22 In addition, HIV-1 itself may directly affect B-cell activation and dysfunction, inducing the appearance of a subset of CD21 Ϫ B cells which have been proposed to contribute to increased antibody production. 23,24 A recent work by Hunziker et al 25 has suggested that naive B cells represent an important source of hypergammaglobulinemia and autoantibody production in chronic viral infections.Because of the lack of protective humoral immunity, HIV-1-infected individuals receive vaccination against several pathogens. However, many studies have reported an impaired humoral immune response in most of the patients after vaccination. [9][10][11]26,27 From the Microbiology and Tumor Biology Center, Karolinska Institutet, and the Gay Men's Health Clinic, The Soder Hospital, Stockholm, Sweden; the Swedish Institute for Infectious...
Circulating memory B cells are severely reduced in the peripheral blood of HIV-1-infected patients. We investigated whether dysfunctional serologic memory to non-HIV antigens is related to disease progression by evaluating the frequency of memory B cells, plasma IgG, plasma levels of antibodies to measles, and Streptococcus pneumoniae, and enumerating measles-specific antibody-secreting cells in patients with primary, chronic, and long-term nonprogressive HIV-1 infection. We also evaluated the in vitro production of IgM and IgG antibodies against measles and S pneumoniae antigens following polyclonal activation of peripheral blood mononuclear cells (PBMCs) from patients. The percentage of memory B cells correlated with CD4 ؉ T-cell counts in patients, thus representing a marker of disease progression. While patients with primary and chronic infection had severe defects in serologic memory, long-term nonprogressors had memory B-cell frequency and levels of antigen-specific antibodies comparable with controls. We also evaluated the effect of antiretroviral therapy on these serologic memory defects and found that antiretroviral therapy did not restore serologic memory in primary or in chronic infection. We suggest that HIV infection impairs maintenance of long-term serologic immunity to HIV-1-unrelated antigens and this defect is initi- IntroductionThe ability to maintain an intact memory B-cell compartment is an essential component of the immune response to (re-) infections. 1 Maintenance of serologic memory is carried out by plasma cells and memory B cells [1][2][3] ; memory B cells play an essential role in the maintenance of antibody (Ab) levels by rapidly generating secondary immune responses upon reinfection or antigenic stimulation. 4 One of the most deleterious effects of HIV-1 infection is B-lymphocyte hyperactivation, which manifests as hypergammaglobulinemia, increased expression of activation markers, high spontaneous Ab production in vitro, and increased incidence of B-cell lymphomas. 5 Paradoxically, HIV-1-infected persons, especially those in advanced stages of disease, also have impaired humoral immune response to vaccination, and their B cells respond poorly to in vitro stimulation by common mitogens such as SAC and PWM. 5 Earlier studies suggest that naive and memory B cells differentially contribute to B-cell dysfunctions in HIV-1 infection. [6][7][8][9][10] Circulating memory B cells in peripheral blood from patients with chronic HIV-1 infection (CHI) are severely reduced and die by apoptosis. 6,11 Serum Abs against measles, tetanus toxoid, and HIV-1 antigens are significantly reduced in patients with low memory B cells, indicating that this phenotypic alteration may severely affect memory B-cell functions. 10 Recently, we reported that during primary HIV-1 infection (PHI), memory B cells are phenotypically and functionally altered though not significantly reduced in number. 12 These alterations were only partially recovered upon antiretroviral therapy (ART), suggesting that PHI sets the stage ...
Early HIV-1 invasion of the central nervous system has been demonstrated by many cerebrospinal fluid studies; however, most HIV-1 carriers remain neurologically unimpaired during the so called "asymptomatic" period lasting from seroconversion to symptomatic AIDS. Therefore, neuropathological studies in the early pre-AIDS stages are very few, and the natural history of central nervous system changes in HIV-1 infection remains poorly understood. Examination of brains of asymptomatic HIV-1 positive individuals who died accidentally and of rare cases with acute fatal encephalopathy revealing HIV infection, and comparison with experimental simian immunodeficiency virus and feline immunodeficiency virus infections suggest that, invasion of the CNS by HIV-1 occurs at the time of primary infection and induces an immunological process in the central nervous system. This includes an inflammatory T-cell reaction with vasculitis and leptomeningitis, and immune activation of brain parenchyma with increased number of microglial cells, upregulation of major histocompatibility complex class II antigens and local production of cytokines. Myelin pallor and gliosis of the white matter are usually found and are likely to be the consequence of opening of the blood brain barrier due to vasculitis; direct damage to oligodendrocytes by cytokines may also interfere. These white matter changes may explain, at least partly, the early cerebral atrophy observed, by magnetic resonance imaging, in asymptomatic HIV-1 carriers. In contrast, cortical damage seems to be a late event in the course of HIV-1 infection. There is no significant neuronal loss at the early stages of the disease, no accompanying increase in glial fibrillary acid protein staining in the cortex, and only exceptional neuronal apoptosis. Although HIV-1 proviral DNA may be demonstrated in a number of brains, viral replication remains very low during the asymptomatic stage of HIV-1 infection. This makes it likely that, although opening of the blood brain barrier may facilitate viral entry into the brain, specific immune responses including both neutralising antibodies and cytotoxic T-lymphocytes, continuously inhibits viral replication at that stage.
Memory B lymphocytes are depleted from peripheral blood in HIV-1-infected subjects. Our ex vivo findings suggest that persistent T-cell activation may contribute to loss of memory B cells through upregulation of Fas/FasL on these cells and terminal differentiation into plasma cells.
A panel of 20 recombinant Fab fragments reactive with the surface glycoprotein gpl20 of human type 1 immunodeficiency virus (HIV-1) were examined for their ability to neutralize MN and hUB strains of the virus. Neutralization was determined as the ability of the Fab fragments to inhibit infection as measured in both a p24 ELISA and a syncytium-formation assay. One group of closely sequencerelated Fab fragments was found to neutralize virus in both assays with a 50% neutralization titer at -1 ,ug/ml. AnotherFab neutralized in the p24 ELISA but not in the syncytium assay. The other Fab fragments showed weak or no neutralizing ability. The results imply that virion aggregation or crosslinking of gp120 molecules on the virion surface is not an absolute requirement for HIV-1 neutralization. Further, all of the Fab fragments were shown to be competitive with soluble CD4 for binding to gpl20 and yet few neutralized the virus effectively, implying that the mechanism of neutralization in this case may not involve receptor blocking. The observation of a preponderance ofhigh-affminty Fab fragments with poor or no neutralizing ability could have implications for vaccine strategies.
B cell dysfunctions found in chronic HIV-1 infection appear during PHI and initiation of antiretroviral therapy early during infection may help to preserve the B cell compartment.
According to their capacity to replicate in vitro, human immunodeficiency virus (HIV) isolates can be divided into two major groups, rapid/high and slow/low. Rapid/high viruses can easily be transmitted to a variety of cell lines of T-lymphoid (CEM, H9, and Jurkat) and monocytoid (U937) origin. In contrast, slow/low viruses replicate transiently, if at all, in these cell lines. Except for a few isolates, the great majority of slow/low viruses replicate in peripheral blood mononuclear cells and Jurkat-tatIII cells constitutively expressing the tatlIl gene of HIV-1. The viruses able to replicate efficiently cause syncytium formation and are regularly isolated from immunodeficient patients. Poorly replicating HIV isolates, often obtained from individuals with no or mild disease, show syncytium formation and single-cell killing simultaneously or, with some isolates, cell killing only.
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