HIV感染中的细胞凋亡

CD4^ T细胞的丢失在HIV感染引起免疫缺陷过程中起着重要作用。但造成CD4^ T细胞丢失的具体机制还不清楚,细胞凋亡可能是CD4^ T细胞丢失的一个重要因素,HIV感染以后,病毒蛋白的持续性产出导致免疫系统的持续性激活,引起Th1细胞的丢失,Th1细胞通过合成Ⅰ型细胞因子,抑制淋巴细胞的自发凋亡,另外,病毒蛋白或其他因素能够使CD4^ ,CD8^ T细胞和APC转化为凋亡的效应细胞,通过Fas/FasL或其他途径引起细胞凋亡,HIV感染人体后凋亡细胞不仅有CD4^ T细胞,还包括B细胞,NK细胞,粒细胞,神经细胞和单细胞,凋亡作为机体的自我防护措施,在清除感染细胞的同时,并没有抑制HIV在单细胞/巨噬细胞内的复制,反而造成大量未感染细胞的凋亡,导致对HIV复制的失控,发展为严重的免疫缺陷,引起AIDS相关的机会性感染。     

名刊封面

《病毒学》2010.3 HIV的T细胞突触间传播 众所周知,人类缺陷病毒（HIV）是导致艾滋病的元凶,能够感染并杀伤CD4阳性T细胞以达到摧毁人体免疫系统的目的。目前,研究者通过电子断层扫描显微镜及3D重建技术,描述了HIV在T细胞之间的传播过程。     

名刊封面

<正>《病毒学》2010.3HIV的T细胞突触间传播众所周知,人类缺陷病毒(HIV)是导致艾滋病的元凶,能够感染并杀伤CD4阳性T细胞以达到摧毁人体免疫系统的目的。目前,研究者通过电子断层扫描显微镜及3D重建技术,描述了HIV在T细胞之间的传播过程。     

CD4+CD25+调节性T细胞与人类获得性免疫缺陷病毒感染

CD4 CD25 是调节性T细胞中功能最重要的一类.它是一类具有特殊免疫调节功能的T细胞亚群.它能够抑制自身免疫病的发生和发展,参与肿瘤免疫的调节,同时在感染和移植免疫中也发挥着极其重要的作用.T细胞的这一亚群具有免疫调节和免疫抑制的特性,新近发现它亦与爱滋病的发生、发展关系密切.HIV进入人体后,CD4 CD25 调节性T细胞抑制了机体的免疫效应但它也同时被感染,最终由于细胞毒的作用而死亡.由于调节性T细胞数量的减少不能有效的发挥其抑制作用,HIV持续的过度活化使得T细胞逐渐耗竭说明在HIV发生、发展的不同阶段Treg细胞可能都发挥了免疫抑制作用,但是却对HIV感染与爱滋病发病的进程产生了不同的效应.此外,CD4 CD25 调节性T细胞还与HIV病毒的持续存在密切相关.本文就CD4 CD25 调节性T细胞与人类获得性免疫缺陷病毒(HIV)感染之间关系进行初步的探讨.     

CD4^＋CD25^＋调节性T细胞与人类获得性免疫缺陷病毒感染

CD4^＋CD25^＋是调节性T细胞中功能最重要的一类。它是一类具有特殊免疫调节功能的T细胞亚群。它能够抑制自身免疫病的发生和发展,参与肿瘤免疫的调节,同时在感染和移植免疫中也发挥着极其重要的作用。T细胞的这一亚群具有免疫调节和免疫抑制的特性,新近发现它亦与爱滋病的发生、发展关系密切。HIV进入人体后,CD4^＋CD25^＋调节性T细胞抑制了机体的免疫效应但它也同时被感染,最终由于细胞毒的作用而死亡。由于调节性T细胞数量的减少不能有效的发挥其抑制作用,HIV持续的过度活化使得T细胞逐渐耗竭说明在HIV发生、发展的不同阶段Treg细胞可能都发挥了免疫抑制作用,但是却对HIV感染与爱滋病发病的进程产生了不同的效应。此外,CD4^＋CD25^＋调节性T细胞还与HIV病毒的持续存在密切相关。本文就CD4^＋CD25^＋调节性T细胞与人类获得性免疫缺陷病毒（HIV）感染之间关系进行初步的探讨。     

人类免疫缺陷病毒感染与肠道菌群的变化研究进展

人类免疫缺陷病毒(HIV)感染CD4~+T细胞,造成免疫系统功能紊乱,导致适应性免疫和固有免疫均发生异常。肠道是人体重要的CD4~+T细胞库,因此,肠道也是病毒感染的主要目标,此外,人肠道内居住着数以亿计的微生物,近年来发现这些微生物群在人类健康中起关键作用。HIV感染除了直接改变肠道CD4~+T细胞组成,也改变了肠道微生物的组成和功能。本文综述了HIV引起的肠道微生物改变,并探讨这些改变在HIV感染个体中产生的局部及系统效应与相关的系统病理损伤,以及用肠道微生物进行靶向调节HIV感染和相关治疗的研究进展。     

一类具有CTL作用的HIV感染模型的全局稳定性

通过假设无HIV感染时个体体内的CTL细胞存在常数输入和被感染CD4+T细胞对CTL细胞繁殖的影响具有饱和形式,本文建立了一类具有CTL作用的HIV感染模型,得到了确定模型动力学性态的基本再生数.当基本再生数不大于1时,健康平衡点在可行域上是全局渐近稳定的,即HIV在个体体内最终灭绝;当基本再生数大于1时,模型的惟一感染平衡点在可行域内是全局渐近稳定的,即HIV将在个体体内持续存在,并且其浓度最终趋于一个正常数.     

艾滋病研究进展

应中国预防医学科学院邀请,美国纽约大学医学院Aaron Diamond艾滋病研究中心主任何大一博士(David D Ho,MD)一行两人于1992年5月13日访问病毒所并做了有关艾滋病研究进展的学术报告。 艾滋病的病原体是人类免疫缺损病毒(Human Immunodeficiency Virus),简称HIV。HIV侵入人体最初的数周至数月属于急性感染期,病人有发热、肌痛、皮疹及某些胃肠道系统症状。随着时间的延续,病人血中T_4细胞逐渐降低,免疫损害加重。在感染后的7～8年内,有50％的人病情进入艾滋病期,最终导致病人死亡。从HIV感染到发病需要这么长的时间,这在病毒感染中是异乎寻常的。提示HIV     

艾滋病的分子生物学和防治

艾滋病,即获得性免疫缺损综合症(acquired immune deficiency syndrome, AIDS)是1981年首先在中美洲发现的一种人类传染病。1984年确定其致病因子是艾滋病毒,又称人类免疫缺损病毒(human immunodeficiency virus, HIV);主要侵害免疫系统。游离HIV存在于患者的脑脊液和血液中,其主要靶细胞为T4淋巴细胞(或称辅助性T细胞)。在HIV复制的第一个高峰中有发热、出疹和流感样症状,神经系统疾病也时有发生;随     

一类CD4＋T细胞感染HIV病毒模型的全局稳定性

研究了一类具有标准发生率的CD4＋T细胞感染HIV病毒模型的动力学性质．通过分析,得到了病毒消除与否的阚值一基本再生数．证明了当基本再生数小于1时,未感染病毒平衡点全局渐近稳定,病毒将在宿主体内被清除．当基本再生数大于1时,病毒将在宿主体内持续生存,进一步给出了病毒感染平衡点全局渐近稳定的条件．最后对所得结论进行了数值模拟．     

Modeling the role of macrophages in HIV persistence during antiretroviral therapy

HIV preferentially infects activated CD4+ T cells. Current antiretroviral therapy cannot eradicate the virus. Viral infection of other cells such as macrophages may contribute to viral persistence during antiretroviral therapy. In addition to cell-free virus infection, macrophages can also get infected when engulfing infected CD4+ T cells as innate immune sentinels. How macrophages affect the dynamics of HIV infection remains unclear. In this paper, we develop an HIV model that includes the infection of CD4+ T cells and macrophages via cell-free virus infection and cell-to-cell viral transmission. We derive the basic reproduction number and obtain the local and global stability of the steady states. Sensitivity and viral dynamics simulations show that even when the infection of CD4+ T cells is completely blocked by therapy, virus can still persist and the steady-state viral load is not sensitive to the change of treatment efficacy. Analysis of the relative contributions to viral replication shows that cell-free virus infection leads to the majority of macrophage infection. Viral transmission from infected CD4+ T cells to macrophages during engulfment accounts for a small fraction of the macrophage infection and has a negligible effect on the total viral production. These results suggest that macrophage infection can be a source contributing to HIV persistence during suppressive therapy. Improving drug efficacies in heterogeneous target cells is crucial for achieving HIV eradication in infected individuals.

     

Effect of latent human immunodeficiency virus infection on cell surface phenotype.

Highly active antiretroviral therapy has succeeded in many cases in suppressing virus production in patients infected with human immunodeficiency virus (HIV); however, once treatment is discontinued, virus replication is rekindled. One reservoir capable of harboring HIV in a latent state and igniting renewed infection once therapy is terminated is a resting T cell. Due to the sparsity of T cells latently infected with HIV in vivo, it has been difficult to study viral and cellular interactions during latency. The SCID-hu (Thy/Liv) mouse model of HIV latency, however, provides high percentages of latently infected cells, allowing a detailed analysis of phenotype. Herein we show that latently infected cells appear phenotypically normal. Following cellular stimulation, the virus completes its life cycle and induces phenotypic changes, such as CD4 and major histocompatibility complex class I down-regulation, in the infected cell. In addition, HIV expression following activation did not correlate with expression of the cellular activation marker CD25. The apparently normal phenotype and lack of HIV expression in latently infected cells could prevent recognition by the immune response and contribute to the long-lived nature of this reservoir.     

HIV Latency Is Established Directly and Early in Both Resting and Activated Primary CD4 T Cells

Highly active antiretroviral therapy (HAART) suppresses human immunodeficiency virus (HIV) replication to undetectable levels but cannot fully eradicate the virus because a small reservoir of CD4⁺ T cells remains latently infected. Since HIV efficiently infects only activated CD4⁺ T cells and since latent HIV primarily resides in resting CD4⁺ T cells, it is generally assumed that latency is established when a productively infected cell recycles to a resting state, trapping the virus in a latent state. In this study, we use a dual reporter virus—HIV Duo-Fluo I, which identifies latently infected cells immediately after infection—to investigate how T cell activation affects the estab-lishment of HIV latency. We show that HIV latency can arise from the direct infection of both resting and activated CD4⁺ T cells. Importantly, returning productively infected cells to a resting state is not associated with a significant silencing of the integrated HIV. We further show that resting CD4⁺ T cells from human lymphoid tissue (tonsil, spleen) show increased latency after infection when compared to peripheral blood. Our findings raise significant questions regarding the most commonly accepted model for the establishment of latent HIV and suggest that infection of both resting and activated primary CD4⁺ T cells produce latency.     

Multiploid inheritance of HIV-1 during cell-to-cell infection

During cell-to-cell transmission of human immunodeficiency virus type 1 (HIV-1), many viral particles can be simultaneously transferred from infected to uninfected CD4 T cells through structures called virological synapses (VS). Here we directly examine how cell-free and cell-to-cell infections differ from infections initiated with cell-free virus in the number of genetic copies that are transmitted from one generation to the next, i.e., the genetic inheritance. Following exposure to HIV-1-expressing cells, we show that target cells with high viral uptake are much more likely to become infected. Using T cells that coexpress distinct fluorescent HIV-1 variants, we show that multiple copies of HIV-1 can be cotransmitted across a single VS. In contrast to cell-free HIV-1 infection, which titrates with Poisson statistics, the titration of cell-associated HIV-1 to low rates of overall infection generates a constant fraction of the newly infected cells that are cofluorescent. Triple infection was also readily detected when cells expressing three fluorescent viruses were used as donor cells. A computational model and a statistical model are presented to estimate the degree to which cofluorescence underestimates coinfection frequency. Lastly, direct detection of HIV-1 proviruses using fluorescence in situ hybridization confirmed that significantly more HIV-1 DNA copies are found in primary T cells infected with cell-associated virus than in those infected with cell-free virus. Together, the data suggest that multiploid inheritance is common during cell-to-cell HIV-1 infection. From this study, we suggest that cell-to-cell infection may explain the high copy numbers of proviruses found in infected cells in vivo and may provide a mechanism through which HIV preserves sequence heterogeneity in viral quasispecies through genetic complementation.     

Preferential infection shortens the life span of human immunodeficiency virus-specific CD4+ T cells in vivo

CD4(+) T-cell help is essential for effective immune responses to viruses. In human immunodeficiency virus (HIV) infection, CD4(+) T cells specific for HIV are infected by the virus at higher frequencies than other memory CD4(+) T cells. Here, we demonstrate that HIV-specific CD4(+) T cells are barely detectable in most infected individuals and that the corresponding CD4(+) T cells exhibit an immature phenotype compared to both cytomegalovirus (CMV)-specific CD4(+) T cells and other memory CD4(+) T cells. However, in two individuals, we observed a rare and diametrically opposed pattern in which HIV-specific CD4(+) T-cell populations of large magnitude exhibited a terminally differentiated immunophenotype; these cells were not preferentially infected in vivo. Clonotypic analysis revealed that the HIV-specific CD4(+) T cells from these individuals were cross-reactive with CMV. Thus, preferential infection can be circumvented in the presence of cross-reactive CD4(+) T cells driven to maturity by coinfecting viral antigens, and this physical proximity rather than activation status per se is an important determinant of preferential infection based on antigen specificity. These data demonstrate that preferential infection reduces the life span of HIV-specific CD4(+) T cells in vivo and thereby compromises the generation of effective immune responses to the virus itself; further, this central feature in the pathophysiology of HIV infection can be influenced by the cross-reactivity of responding CD4(+) T cells.     

Evidence for CD8+ antiviral activity in cats infected with feline immunodeficiency virus.

Human immunodeficiency virus (HIV) causes a long, asymptomatic infection characterized by normal to elevated numbers of circulating CD8+ cells and a progressive decline in CD4+ cells. It has been speculated that HIV-specific antiviral activity driven by CD8+ T cells may control viral replication during this period and maintain the clinically asymptomatic stage of disease. The disease induced in cats by feline immunodeficiency virus (FIV) is similar to HIV in that it is characterized by a long asymptomatic stage with a progressive decline in CD4+ cells, culminating in AIDS. In the present study, we demonstrate that FIV is more readily isolated from CD8+ T-cell-depleted peripheral blood mononuclear cells (PBMC) of FIV-infected cats than from unfractionated PBMC cultures. In addition, CD8+ T cells isolated from FIV-positive cats demonstrating anti-FIV activity in PBMC cultures inhibit FIV infection of FCD4E cells in vitro. Anti-FIV activity is not found in FIV- negative cats and is not characteristic of cats acutely infected with FIV but is present in the majority of chronically infected, clinically asymptomatic and symptomatic cats. Decreases in plasma and cell-associated viremia during the acute-stage FIV infection appears to precede the appearance of CD8+ anti-FIV cells in the circulation. In summary, this study demonstrates a population(s) of CD8+ T cells in chronically FIV-infected cats capable of suppressing FIV replication in cultured PBMC. The significance of anti-FIV CD8+ cells in the immunopathogenesis of the infection and disease progression has yet to be determined.     

T-cell subsets that harbor human immunodeficiency virus (HIV) in vivo: implications for HIV pathogenesis

Identification of T-cell subsets that are infected in vivo is essential to understanding the pathogenesis of human immunodeficiency virus (HIV) disease; however, this goal has been beset with technical challenges. Here, we used polychromatic flow cytometry to sort multiple T-cell subsets to 99.8% purity, followed by quantitative PCR to quantify HIV gag DNA directly ex vivo. We show that resting memory CD4(+) T cells are the predominantly infected cells but that terminally differentiated memory CD4(+) T cells contain 10-fold fewer copies of HIV DNA. Memory CD8(+) T cells can also be infected upon upregulation of CD4; however, this is infrequent and HIV-specific CD8(+) T cells are not infected preferentially. Na?ve CD4(+) T-cell infection is rare and principally confined to those peripheral T cells that have proliferated. Furthermore, the virus is essentially absent from na?ve CD8(+) T cells, suggesting that the thymus is not a major source of HIV-infected T cells in the periphery. These data illuminate the underlying mechanisms that distort T-cell homeostasis in HIV infection.     

Latently Infected Cell Activation: A Way to Reduce the Size of the HIV Reservoir?

While antiretroviral drugs can drive HIV to undetectably low levels in the blood, eradication is hindered by the persistence of long-lived, latently infected memory CD4 T cells. Immune activation therapy aims to eliminate this latent reservoir by reactivating these memory cells, exposing them to removal by the immune system and the cytotoxic effects of active infection. In this paper, we develop a mathematical model that investigates the use of immune activation strategies while limiting virus and latent class rebound. Our model considers infection of two memory classes, central and transitional CD4 T cells and the role that general immune activation therapy has on their elimination. Further, we incorporate ways to control viral rebound by blocking activated cell proliferation through anti proliferation therapy. Using the model, we provide insight into the control of latent infection and subsequently into the long term control of HIV infection.     

An initial in vitro investigation into the potential therapeutic use of SupT1 cells to prevent AIDS in HIV-seropositive individuals

HIV infection usually leads to a progressive decline in number and functionality of CD4+ T lymphocytes, resulting in AIDS development. In this study, I investigated the strategy of using inoculated SupT1 cells to move infection from HIV-1 X4 strains toward the inoculated cells, which should theoretically prevent infection and depletion of normal CD4+ T cells, preventing the development of AIDS-related pathologies. Interestingly, the persistent in vitro replication in SupT1 cells renders the virus less cytopathic and more sensitive to antibody-mediated neutralization, suggesting that replication of the virus in the inoculated SupT1 cells may have a vaccination effect in the long run. In order to mimic the scenario of a therapy in which SupT1 cells are inoculated in an HIV-seropositive patient, I used infected SupT1/PBMC cocultures and a series of control experiments. Infections were done with equal amounts of the wild type HIV-1 LAI virus. The SupT1 CD4+CD8+ T cell population was distinguished from the PBMC CD4+CD8- T cell population by FACS analysis. The results of this study show that the virus-mediated killing of primary CD4+ T cells in the SupT1/PBMC cocultures was significantly delayed, suggesting that the preferential infection of SupT1 cells can induce the virus to spare primary CD4+ T cells from infection and depletion. The preferential infection of SupT1 cells can be explained by the higher viral tropism for the SupT1 cell line. In conclusion, this study demonstrates that it's possible in an in vitro system to use SupT1 cells to prevent HIV infection of primary CD4+ T cells, suggesting that further exploration of the SupT1 cell line as a cell-based therapy against HIV-1 may prove worthwhile.     

A kinetic model of CD4+ lymphocytes with the human immunodeficiency virus (HIV).

This report describes a kinetic model of in vitro cytopathology involving interactions of human immunodeficiency virus (HIV) with CD4+ helper T lymphocytes. The model uses nonlinearly coupled, ordinary differential equations to simulate the dynamics of infected and uninfected cells and free virions. It is assumed that resting cells are more readily infected than activated cells, but once infected, only activated cells produce more virus. Resting cells can be activated by some appropriate stimulus (e.g. phytohemagglutinin, soluble antigen). The model predicts that the initial inoculum of virus is taken up by resting cells and without stimulation the system comes to a steady state of two populations, namely infected and uninfected cells. Stimulation of this system produces two additional populations, namely infected and uninfected activated cells which, along with the previous populations, exhibit cyclic behavior of growth, viral expression/release, and death. Additional stimuli enhance or diminish the cyclic behavior depending upon their occurrence in time. These simulations suggest a similar dynamics in human HIV infection and may explain a major factor responsible for the widely varying depletion rate of (CD4+) helper T cells in AIDS patients.