Immunoprecipitation of human immunodeficiency virus type 2 glycoproteins by sera positive for human immunodeficiency virus type 1.

Analysis by radioimmunoprecipitation of serum samples from 27 different human immunodeficiency virus type 1 (HIV-1)-infected individuals residing in Chile showed that the sera of 26% of these individuals also react with glycoprotein gp125 of HIV type 2 (HIV-2). This cross-reaction seems to reflect a qualitative difference among infected individuals, because the titer of antibodies against gp120 of HIV-1 in the cross-reacting samples did not differ significantly from that in the non-cross-reacting samples. Most of the HIV-1-seropositive sera, including many that did not react with gp125 of HIV-2, reacted with gp140, the precursor of HIV-2 glycoproteins. The observed cross-reactions allowed us to distinguish three groups of HIV-1-infected individuals: (i) those whose sera react with both gp140 and gp125, (ii) those whose sera react with gp140, and (iii) those whose sera react with neither of these glycoproteins. The possible cause and significance of these differences is under study.     

Variability of human immunodeficiency virus type 1

The variability of human immunodeficiency virus type 1 (HIV-1) is very high. To date, three distinct lineages of HIVs, type 1 group M, type 1 group O and type 2 are described, suggesting at least three different zoonotic infections. HIV-1 group M is responsible for the global epidemic of AIDS. At least ten subtypes of HIV-1 group M, labelled A through J, have been discovered. Viral sequences from both the gag and the env gene, particularly a part of gp 120 referred to as the V3 region have been used to identify subtypes of HIV-1 group M. The nucleotide distance between viruses of different subtypes is on average 30% for the env gene. The various subtypes are geographically distributed throughout the world. Some of the subtypes were identified as recombinant or mosaic viruses. The existence of different subtypes of HIV-1 have major implication for vaccination. They may also influence the diagnosis of HIV infection. To date, it is unclear whether subtypes of HIV-1 differ with respect to transmissibility or pathogenicity.     

Primary human immunodeficiency virus type 1 infection

Primary human immunodeficiency virus type 1 (HIV-1) infection represents the initial stage of disease that immediately follows viral entry into the body. Primary infection is frequently accompanied by an acute retroviral syndrome with associated high levels of plasma HIV-1 RNA and the development of host immune responses. The identification of subjects during this period requires a high index of suspicion and an understanding of how to make the diagnosis, as standard HIV-1 antibody tests can initially be negative. Identifying these people provides a unique opportunity for early counseling to reduce further transmission, facilitates entry into care, and allows for further study of the immunopathogenesis of disease and the potential role of early antiretroviral therapy.     

Human immunodeficiency virus type 1 tropism for human macrophages.

Human immunodeficiency virus (HIV) infects cells of the monocyte/macrophage lineage in addition to lymphocytes, and infection of these cells may be responsible for viral persistence and dissemination, encephalopathy of the acquired immunodeficiency syndrome and other sequelae of HIV infection. We have developed an in vitro model utilizing peripheral-blood monocyte-derived macrophages to study HIV-1 infection of macrophages. HIV-1 isolates vary greatly in their ability to infect and replicate in macrophages, from highly restricted to highly productive infection. Productively infected macrophages undergo syncytium formation but remain viable in culture and support sustained levels of virus production for prolonged periods. Transformed monocytoid and lymphoid cell lines, however, show very different patterns of permissiveness for HIV-1 strains and do not reflect their corresponding primary cell types in studies of host cell tropism. Studies on viral entry show that the CD4 molecule, known to be the HIV receptor on lymphoid cells, is expressed at low levels on the surface of macrophages as well, where it functions as the receptor for viral entry. Therefore, differential host cell tropism does not result from the use of an alternative macrophage-specific receptor instead of CD4.     

人免疫缺陷病毒1型CRF07_BC毒株准种间的重组

目的 通过研究人类免疫缺陷病毒1型（human immunodeficiency virus1，HIV-1）感染者个体内准种间的差异，探讨HIV的系统进化的发生模式。方法 从HIV-1感染者血浆中提取总RNA，通过逆转录多聚酶链反应（RT-PCR）获得HIV．1gp120全长基因，纯化后装入T载体，转化至TOP10大肠埃希菌内增殖，通过蓝白斑筛选获得阳性克隆，对所获得的目的克隆测序并分析。结果 获得同一患者的16个克隆的gp120全长基因序列，通过系统进化树分析，克隆序列均为CRF07_BC亚型，但在系统进化树上16个克隆可明显分为A、B两群，其中13个克隆属于A群，2个克隆属于B群，1个克隆（编号XPD7）位于A、B群之间，通过simplot软件的重组分析，发现XPD7克隆为A群和B群的重组株。结论 发现了我国广泛流行的HIV-1CRF07-BC毒株准种间的重组现象，准种间的重组作为HIV进化的一种有效手段将导致HIV毒株的快速进化的发生，可能更易逃脱宿主的免疫监控。     

DNA vaccines against human immunodeficiency virus type 1

Summary: Development of a vaccine against human immunodeficiency virus type 1 (HIV‐1) is the main hope for controlling the acquired immunodeficiency syndrome pandemic. An ideal HIV vaccine should induce neutralizing antibodies, CD4⁺ helper T cells, and CD8⁺ cytotoxic T cells. While the induction of broadly neutralizing antibodies remains a highly challenging goal, there are a number of technologies capable of inducing potent cell‐mediated responses in animal models, which are now starting to be tested in humans. Naked DNA immunization is one of them. This review focuses on the stimulation of HIV‐specific T cells and discusses in the context of the current ‘state‐of‐art’ of DNA vaccines, the areas where this technology might assist either alone or as a part of more complex vaccine formulations in the HIV vaccine development.     

Effects of human T-lymphotropic virus type II on human immunodeficiency virus type 1 phenotypic evolution

Summary.  Phenotypic change and broader coreceptor usage by HIV-1 have been associated with disease progression. HIV-1 coreceptor usage by primary isolates obtained from HIV-1-infected and HIV-1/HTLV-II-coinfected individuals was determined. HIV-1 was isolated from 15 of 20 HIV-1-infected and 17 of 24 HIV-1/HTLV-II-coinfected individuals. None of the isolates from either the HIV-1-infected or the coinfected group infected CCR5Δ32 PBMCs, suggesting that they all were R5-tropic. Further, both spontaneous and PHA-stimulated production of MIP-1β and RANTES were similar in HIV-1-infected and coinfected individuals. These data indicate that coinfection with HTLV-II has no effect on HIV-1 coreceptor usage or ex vivo β-chemokine production. Received December 23, 2000/Accepted May 16, 2001     

Current status of therapy for human immunodeficiency virus type 1.

The past year has been refinement in our ability to delay the progression of human immunodeficiency virus type 1 infection through the use of nucleoside analogues, singly or in combination. Progress has also been made in our ability to detect drug-resistant isolates of human immunodeficiency virus type 1 and to begin to put the laboratory observations of resistance into a clinical context.     

Actin-binding cellular proteins inside human immunodeficiency virus type 1

Host proteins are incorporated both on and inside human immunodeficiency virus type 1 (HIV-1) virions. To identify cellular proteins inside HIV-1, virion preparations were treated by a protease-digestion technique that removes external host proteins, allowing for the study of the proteins inside the virus. Treated HIV-1 preparations were analyzed by immunoblot, high-pressure liquid chromatography, and protein sequence analyses. These analyses identified several cellular proteins inside HIV-1: elongation factor 1alpha, glyceraldehyde-3-phosphate dehydrogenase, HS-1, phosphatidylethanolamine-binding protein, Pin1, Lck, Nm23-H1, and the C-terminal tail of CD43. Several of these proteins were found as fragments of their full-sized proteins that appear to be generated by our protease treatment of the virions, the HIV-1 protease, or a cellular protease. Recent advances in cell biology and biochemistry have identified some of these proteins as actin-binding proteins. These results support the hypothesis that actin filaments are incorporated into the virion and may provide additional clues for the understanding of the interaction between viral and cellular proteins during assembly and budding.     

Cellular latency of human immunodeficiency virus type 1.

The infection of humans by human immunodeficiency virus type 1 is characterized by a prolonged stage of clinical quiescence. This clinically asymptomatic period may be based, in part, on the development of cell populations within the body that maintain human immunodeficiency virus type 1 in a state of latency. Recent advances in the understanding of the molecular mechanisms involved in various forms of cellular latency of human immunodeficiency virus type 1 have begun to shed light on the variable period of asymptomatic infection. The elucidation of cellular retroviral latency, in vivo, will also be critical to the design of novel therapeutic approaches with which to combat human immunodeficiency virus type 1 infections.     

Molecular clock-like evolution of human immunodeficiency virus type 1

The molecular clock hypothesis states that the rate of nucleotide substitution per generation is constant across lineages. If generation times were equal across lineages, samples obtained at the same calendar time would have experienced the same number of generations since their common ancestor. However, if sequences are not derived from contemporaneous samples, differences in the number of generations may be misinterpreted as variation in substitution rates and hence may lead to false rejection of the molecular clock hypothesis. A recent study has called into doubt the validity of clock-like evolution for HIV-1, using molecular sequences derived from noncontemporaneous samples. However, after separating their within-individual data according to sampling time, we found that what appeared to be nonclock-like behavior could be attributed, in most cases, to noncontemporaneous sampling, with contributions also likely to derive from recombination. Natural selection alone did not appear to obscure the clock-like evolution of HIV-1.     

Enzyme-linked immunoassay for human immunodeficiency virus type 1 envelope glycoprotein 120.

An enzyme-linked immunosorbent assay (ELISA) that can measure picogram quantities of human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein 120 (gp120) in cell culture medium or body fluids has been developed. Recombinant, soluble CD4 immobilized in microtiter trays was used to capture gp120, which was then detected with polyclonal sheep antibody to gp120 followed by biotinylated rabbit anti-sheep immunoglobulin G and an avidin-alkaline phosphatase indicator system. With a reference recombinant gp120, the assay showed a linear relationship between optical density and concentrations ranging from 60 to 6,000 pg/100-microliters well; precision of the assay varied with the concentrations and ranged from +/- 40% with amounts smaller than 200 pg to +/- 10% with amounts larger than 200 pg. In a group of coded samples containing 60 pg (approximately 10(7) molecules) of reference gp120, the assay correctly identified the samples as containing gp120 99% of the time, with no false-positive results recorded for blank samples. Recombinant gp120 prepared in another cell culture system demonstrated a binding coefficient 13-fold lower than that of reference gp120. Mixing standard amounts of reference gp120 with increasing concentrations of human sera reduced assay sensitivity, although the linear relationship between gp120 concentration and optical density remained. With this assay we were able to detect gp120 in HIV-1 suspensions prepared from cultured lymphoblastoid cells and in the sera of HIV-1-infected patients. This ELISA for gp120 should be useful for studying the biological role of gp120 in HIV infection.     

Fluorescence-based quantitative methods for detecting human immunodeficiency virus type 1-induced syncytia

Cell fusion induced by human immunodeficiency virus type 1 (HIV-1) is usually assessed by counting multinucleated giant cells (syncytia) visualized by light microscopy. Currently used methods do not allow quantification of syncytia, nor do they estimate the number of cells involved in cell fusion. We describe two fluorescence-based methods for the detection and quantification of HIV-1-induced in vitro syncytium formation. The lymphoblastoid cell lines MT-2 and SupT1 were infected with syncytium-inducing (SI) HIV-1 isolates. Syncytia were detected by DNA staining with propidium iodide using flow cytometry to determine cell size or by two-color cytoplasmic staining of infected cell populations by using fluorescence microscopy. Both methods were able to detect and quantify HIV-induced syncytia. The methods could distinguish between SI and non-SI HIV isolates and could be used with at least two separate types of CD4(+) T-cell lines. Small syncytia can be readily identified by the two-color cytoplasmic staining method. Both methods were also shown to be useful for evaluating antiretroviral compounds, as demonstrated by the accurate assessment of HIV inhibition by azidothymidine (zidovudine), dideoxycytidine (zalcytibine), and hydroxyurea. These fluorescence-based assays allow a rapid and practical method for measuring HIV replication and anti-HIV activity of potential inhibitory compounds.