Simian immunodeficiency virus dramatically alters expression of homeostatic chemokines and dendritic cell markers during infection in vivo

Dendritic cells (DCs) are potent antigen-presenting cells that likely play multiple roles in human immunodeficiency virus type 1 (HIV-1) pathogenesis. We used the simian immunodeficiency virus (SIV)/macaque model to study the effects of infection on homeostatic chemokine expression and DC localization directly in secondary lymphoid tissues. SIV infection altered the expression of chemokines (CCL19/MIP-3beta, CCL21/ 6Ckine, and CCL20/MIP-3alpha) and of chemokine receptors (CCR7 and CCR6) that drive DC trafficking. CCL19/MIP-3beta, CCL20/MIP-3alpha, CCR6, and CCR7 expression increased in lymph nodes during the early systemic burst of viral replication (acute infection), whereas CCL21/6Ckine expression progressively decreased throughout disease to AIDS. Parallel with the SIV-induced perturbations in chemokine expression were changes in the expression of the DC-associated markers, DC-SIGN, DC-LAMP, and DECTIN-1. During AIDS, DC-LAMP mRNA expression levels were significantly reduced in lymph nodes and spleen, and DC-SIGN levels were significantly reduced in spleen. These findings suggest that the disruption of homeostatic chemokine expression is responsible, in part, for alterations in the networks of antigen-presenting cells in lymphoid tissues, ultimately contributing to systemic immunodeficiency.     

SIV/HIV recombinants and their use in studying biological properties.

A series of chimeric clones between human immunodeficiency virus type 1 (HIV-1) and simian immunodeficiency viruses (SIV) were constructed. Viability of the recombinant viruses was dependent on the position of recombination. Infectious chimeric viruses between HIV-1 and SIVAGM (isolated from an African green monkey) and those between HIV-1 and SIVMAC (isolated from a rhesus monkey) were examined for host cell tropism. Viral determinants that restrict the replication of SIVAGM in human MT-4 cells and that of HIV-1 in macaque monkey peripheral blood mononuclear cells (PBMC) mapped to the 5' half of the virus genome. One HIV-1/SIVMAC chimera which contained the HIV-1 env gene was shown to replicate in macaque PBMC in vitro and to infect macaque monkeys in vivo. This HIV-1/SIVMAC chimera will be useful for a variety of AIDS pathogenesis and vaccine studies.     

Rhesus macaque dendritic cells efficiently transmit primate lentiviruses independently of DC-SIGN

Here, we describe the isolation and characterization of the rhesus macaque homolog for human DC-SIGN, a dendritic cell-specific C-type lectin. mac-DC-SIGN is 92% identical to hu-DC-SIGN. mac-DC-SIGN preserves the virus transmission function of hu-DC-SIGN, capturing and efficiently transducing simian and human immunodeficiency virus to target CD4(+) T cells. Surprisingly, however, mac-DC-SIGN plays no discernable role in the ability of rhesus macaque dendritic cells to capture and transmit primate lentiviruses. Expression and neutralization analyses suggest that this process is DC-SIGN independent in macaque, although the participation of other lectin molecules cannot be ruled out. The ability of primate lentiviruses to effectively use human and rhesus dendritic cells in virus transmission without the cells becoming directly infected suggests that these viruses have taken advantage of a conserved dendritic cell mechanism in which DC-SIGN family molecules are significant contributors but not the only participants.     

Infection of a simian B cell line by human and simian immunodeficiency viruses

It is well known that HIV-1 does not establish infection in nonhuman primates, nor in cell lines derived from them, due to the existence of saturable resistance factors. In this study, we show that an in vitro established Macaca fascicularis-derived CD4(-) B cell line (F6) can be productively infected by the laboratory-adapted T-tropic HXBc2/HIV-1 strain at low multiplicity of infection, apparently because it does not express the restriction factor that has been detected in other simian cell lines. Moreover, efficient entry into F6 cells was obtained with pseudotyped recombinant HIV-1 viruses containing the laboratory-adapted T-tropic (HXBc2) or the dual-tropic (89.6) envelope glycoproteins, whereas entry of virus containing the envelope glycoproteins of the M-tropic Ba-L strain was less efficient. Virus containing primary T-tropic (Eli) envelope glycoproteins did not infect F6 cells. Furthermore, although CCR5 was not present on the cell surface and gpr15 and strl33 mRNAs were not expressed in the cells, a high level of infection of F6 cells by the M-tropic simian immunodeficiency virus SIVmac316 was observed. In contrast, F6 cells were poorly infected by T-tropic SIVmac239. Given the unique properties of the F6 cell line, i.e., that it is of simian origin yet is able to be infected by HIV-1 in a CD4-independent manner, F6 cells represent a useful model for studying cellular factors mediating resistance or permissivity to HIV-1 infection and may help to evaluate HIV-1 and SIV cell tropism.     

Human and simian immunodeficiency retroviruses: activation and differential transactivation of gene expression

New West African human immunodeficiency viruses (HIV-2s) and simian immunodeficiency virus (SIV) contain functional transactivator (tat) gene and tat response elements. Their long terminal repeats (LTR) and tat genes are more related among themselves than to HIV-1 LTR and tat gene. The viral gene expression of HIV-2 as well as SIV can be stimulated by T cell activators, such as mitogens and phorbol esters. HIV-2 and SIV display a much broader transactivation response specificity than does HIV-1. The LTR-directed gene expression of HIV-2/SIV is not only transactivated by their own tat gene and by HIV-1 tat gene but also by factors in human T cell leukemia/lymphoma virus type I (HTLV-I) and simian virus 40 (SV40) infected cells, involving HTLV-I tat gene and SV40 T antigens, respectively. HIV-1 LTR-directed gene expression is much less transactivated by HIV-2/SIV tat genes and by factors in HTLV-I- and SV40-infected cells. Immune activation and heterologous transactivation of the LTR-directed gene expression may be relevant to the latency of virus infection and progression toward the acquired immunodeficiency syndrome (AIDS).     

Generation of HIV-1 derivatives that productively infect macaque monkey lymphoid cells

The narrow host range of human immunodeficiency virus type 1 (HIV-1) is caused in part by innate cellular factors such as apolipoprotein B mRNA-editing enzyme-catalytic polypeptide-like 3G (APOBEC3G) and TRIM5alpha, which restrict virus replication in monkey cells. Variant HIV-1 molecular clones containing both a 21-nucleotide simian immunodeficiency virus (SIV) Gag CA element, corresponding to the HIV-1 cyclophilin A-binding site, and the entire SIV vif gene were constructed. Long-term passage in a cynomolgus monkey lymphoid cell line resulted in the acquisition of two nonsynonymous changes in env, which conferred improved replication properties. A proviral molecular clone, derived from infected cells and designated NL-DT5R, was used to generate virus stocks capable of establishing spreading infections in the cynomolgus monkey T cell line and CD8-depleted peripheral blood mononuclear cells from five of five pig-tailed macaques and one of three rhesus monkeys. NL-DT5R, which genetically is >93% HIV-1, provides the opportunity, not possible with currently available SIV/HIV chimeric viruses, to analyze the function of multiple HIV-1 genes in a broad range of nonhuman primate species.     

Mucosal dendritic cells and immunodeficiency viruses

Dendritic cells [DCs] have been implicated in the pathogenesis of human immunodeficiency virus type 1 (HIV-1). When skin was used as a model for mucosae, the cutaneous DC-T cell milieu allowed the growth of HIV-1 and much of the newly produced virus could be detected in multinucleated DC-T cell syncytia. Such virus replication occurs irrespective of the genetic subtype, the syncytium- and non-syncytium-inducing capacities of the viruses, and whether they are classified as T cell- or macrophage-tropic. Similar DC-syncytia have been identified within the mucosal surfaces of the tonsillar tissue of HIV-1-infected persons. More recently, it was demonstrated that DC-T cell mixtures from the skin, mucosae, and blood of healthy macaques similarly support the replication of simian immunodeficiency virus. In both the human and monkey systems, active virus replication requires the presence of both DCs and T cells. Further studies using the macaque model are underway to elucidate the role of DCs in the transmission and spread of HIV infection.     

A nonneutralizing anti-HIV Type 1 antibody turns into a broad neutralizing antibody when expressed on the surface of HIV type 1-susceptible cells. II. Inhibition of HIV type 1 captured and transferred by DC-SIGN

Previously, we demonstrated that the expression of a nonneutralizing human anti-HIV-1 gp41 scFv on the surface of HIV-1-susceptible cells markedly inhibits HIV-1 replication and HIV-1 envelope-mediated cell-cell fusion. The inhibition is at the level of viral entry, specific for the HIV-1 envelope, and independent of virus tropism. In the previous studies, cell-free viruses of laboratory-adapted HIV-1 strains from subtype B were used to infect human CD4 T cell lines. To further test the effectiveness of this membrane-bound scFv (m-scFv) on HIV-1 infection, in this study, we carried out experiments to determine whether the m-scFv can neutralize infection of primary isolates from various HIV-1 subtypes and whether the m-scFv can neutralize HIV-1 captured and transferred by DC-SIGN on the surface of monocytic cell lines or DCs. We demonstrated that the m-scFv markedly inhibits primary isolates derived from various subtypes and significantly blocks HIV-1 captured and transferred by DC-SIGN on monocytic cell lines and on human DCs. Therefore, a nonneutralizing antibody acts as a broad neutralizing antibody when expressed on the cell surface, which significantly inhibits infection of both cell-free and DC-SIGN-captured and transferred virus. Our studies further point out the potential use of m-scFv as a inhibitor against HIV-1 transmission as well as a tool to dissect the mechanism of HIV-1 entry via DC-SIGN capture and transfer to CD4 T cells.     

Pathogenesis of acute infection in rhesus macaques with a lymphocyte-tropic strain of simian immunodeficiency virus.

The simian immunodeficiency virus, SIVmac, causes disease affecting multiple organ systems in macaques similar to human immunodeficiency virus infection in humans. Molecularly cloned SIVmac with a strong lymphocyte tropism was used in pathogenesis experiments to correlate viral cell tropism with disease. In 5 animals, exhaustive analyses on viruses from tissues and identification of infected precursor cells were done at multiple times during infection to ensure the virus had not mutated into a macrophage-tropic variant. Viral replication was measured by infectivity, infectious center assays, and in situ hybridization. Lymphocytes produced most virus in tissues, indicating the virus maintained its cell tropism in vivo. Lymphocytes in bone marrow were latently infected and those in the spleen and lymph nodes were productively infected. The virus failed to replicate in the brain after intracerebral inoculation. SIVmac that maintained a strong tropism for lymphocytes and a corresponding poor tropism for macrophages can cause persistent infection and AIDS but not other diseases such as primary pneumonia and encephalitis in rhesus macaques.     

DC-SIGNR基因绞链区重复序列多态性检测方法的建立与应用

目的建立树突状细胞表面的蛋白质DC-SIGNR基因绞链区重复序列多态性的检测方法，了解宿主因素在抗艾滋病病毒1型（HIV-1）所起的作用。方法设计特定引物，用PCR方法对DC-SIGNR基因绞链区重复序列进行扩增，用凝胶电泳法对其产物进行分析。结果根据DC-SIGNR绞链区重复序列的数量，DC-SIGNR绞链区重复序列具有高度基因多态性，而DC-SIGN则罕见基因多态性。结论所建立的检测DC-SIGNR绞链区重复序列的方法简单，易于掌握。由于DC-SIGNR重复序列数量的改变可能会影响其正常功能，从而影响宿主与HIV-1的结合能力，因此该法为研究宿主因素在抗HIV-1感染中所起作用的一种好方法。     

The human and simian immunodeficiency viruses HIV-1, HIV-2 and SIV interact with similar epitopes on their cellular receptor, the CD4 molecule

The cellular receptor for HIV-1 is the leucocyte differentiation antigen, CD4. Blocking of HIV-1 infectivity can be achieved with monoclonal antibodies (MAbs) to some, but not all epitopes of this antigen. We demonstrate here, by inhibition of virus infection, blocking of syncytium formation and inhibition of pseudotype infection with a panel of CD4 MAbs, that HIV-1, HIV-2 and simian immunodeficiency virus (SIV) isolates share the same cellular receptor, the CD4 glycoprotein. It is also shown that very similar epitopes of this molecule are involved in virus binding. We infer from these data that the binding sites on these viruses are highly conserved regions, and may therefore make good targets for potential vaccines. In addition, we show that cell surface expression of CD4 is similarly modulated after infection of cell lines by all the viruses.     

Envelope glycoproteins from biologically diverse isolates of immunodeficiency viruses have widely different affinities for CD4.

The envelope glycoprotein gp120 of primate immunodeficiency viruses initiates viral attachment to CD4+ cells by binding to the CD4 antigen on host cell surfaces. However, among different CD4+ cell types, different viruses display distinct host cell ranges and cytopathicities. Determinants for both of these biological properties have been mapped to the env gene. We have quantitatively compared the CD4 binding affinities of gp120 proteins from viruses exhibiting different host cell tropisms and cytopathicities. The viral proteins were produced by using a Drosophila cell expression system and were purified to greater than 90% homogeneity. Drosophila-produced gp120 from T-cell tropic human immunodeficiency virus type 1 (HIV-1) BH10 exhibits binding to soluble recombinant CD4 (sCD4) and syncytia inhibition potency identical to that of pure authentic viral gp120. Relative to the affinity of HIV-1 BH10 gp120 for sCD4, that of dual tropic HIV-1 Ba-L is 6-fold lower, that of restricted T-cell tropic simian immunodeficiency virus mac is 70-fold lower, and that of noncytopathic HIV-2 ST is greater than 280-fold lower. Thus, viruses that utilize CD4 for infection do so by using a remarkably wide range of envelope affinities. These differences in affinity may play a role in determining cell tropism and cytopathicity.     

DC-SIGN-mediated transfer of HIV-1 is compromised by the ability of Leishmania infantum to exploit DC-SIGN as a ligand

DC-SIGN (dendritic cell-specific intercellular adhesion molecule 3-grabbing nonintegrin) binds human immunodeficiency virus type 1 (HIV-1) and facilitates transfer of virus to permissive cells. Leishmania parasites also exploit DC-SIGN as a receptor. Here, we report that transfer of HIV-1 to target cells is markedly reduced when DC-SIGN(+) cells are preincubated with Leishmania amastigotes before pulsing with virions. Moreover, binding of HIV-1 to DC-SIGN(+) cells is diminished by the presence of Leishmania amastigotes. Our findings provide novel insight into the complex interactions between HIV-1 and Leishmania parasites. The ability of both HIV-1 and Leishmania parasites to bind to the same cell-surface constituent to gain entry into dendritic cells might have an impact on the immunological and pathological events associated with HIV-1 infection.     

FIV infection induces unique changes in phenotype and cellularity in the medial iliac lymph node and intestinal IEL

Studies of human immunodeficiency virus-1 (HIV-1)-infected patients and simian immunodeficiency virus (SIV)-infected macaques have identified profound depletion of CD4(+) T cells and expansion of CD8(+) T cells in the gastrointestinal lamina propria. Less attention has been given to CD8(+) intraepithelial lymphocytes (IEL), and no studies have concurrently examined inductive sites such as draining lymph nodes. Our preliminary data in the feline immunodeficiency virus (FIV) animal model suggested additional changes in IEL, and marked differences in the responses of lymph nodes draining different mucosal sites. To address this, we quantified the absolute leukocyte yield and examined the phenotype of cells from small intestinal IEL, mesenteric lymph node (MLN), and medial iliac lymph node (ILN) from chronically FIV-infected cats. The cellularity of the ILN was increased 530% in FIV-infected animals with an expansion of CD62L(+) cells, suggesting an increased population of naive T cells. The number of CD4(+), as well as CD8(+), T cells was increased in the ILN, resulting in a CD4:CD8 ratio greater than 1:1. In contrast, reduced cellularity, specific loss of CD4(+) T cells, and inversion of the CD4:CD8 ratio was observed in the MLN, which drains the intestine. In IEL, loss of CD8alpha, CD8beta, and CD4-expressing T cells was found in FIV-infected cats. Furthermore, expression intensity of CD8alpha and CD5, markers known to be important in T cell function, was markedly decreased on IEL. These findings expand the array of immune alterations induced by lentiviral infection and indicate that characterization of multiple mucosal sites will be necessary to fully understand the pathogenesis of HIV-1 infection.     

Repeat-region polymorphisms in the gene for the dendritic cell-specific intercellular adhesion molecule-3-grabbing nonintegrin-related molecule: effects on HIV-1 susceptibility

In 1716 individuals--801 human immunodeficiency virus (HIV)-1-seropositive individuals, 217 high-risk HIV-1-seronegative individuals, and 698 general HIV-1-seronegative individuals--from a Seattle cohort and a Multicenter AIDS Cohort Study cohort, the association between HIV-1 susceptibility and repeat-region polymorphisms in the gene for the dendritic cell-specific intercellular adhesion molecule-3-grabbing nonintegrin-related molecule (DC-SIGNR) was investigated; 16 genotypes were found in the DC-SIGNR repeat region. The DC-SIGNR homozygous 7/7 repeat was found to be associated with an increased risk of HIV-1 infection (17.5% in high-risk HIV-1-seronegative individuals vs. 28.5% in HIV-1-seropositive individuals; P=.0015), whereas the DC-SIGNR heterozygous 7/5 repeat tended to be correlated with resistance to HIV-1 infection (35.5% in high-risk HIV-1-seronegative individuals vs. 27.6% in HIV-1-seropositive individuals; P=.0291). These findings suggest that DC-SIGNR polymorphisms may influence susceptibility to HIV-1.     

The polymorphisms in DC-SIGNR affect susceptibility to HIV type 1 infection

Dendritic cell-specific intercellular adhesion molecule-3 (ICAM-3) grabbing nonintegrin (DC-SIGN) and its homologue DC-SIGNR (DC-SIGN related) have been thought to play an important role in establishing HIV infection by enhancing trans-infection of CD4(+)T cells in the regional lymph nodes. To identify polymorphisms associated with HIV-exposed seronegative (ESN) individuals in Thais, genomic DNA from 102 HIV-seronegative individuals of HIV-seropositive spouses, 305 HIV-seropositive individuals, and 290 HIV-seronegative blood donors was genotyped for two single nucleotide polymorphisms (SNPs) in DC-SIGN promoter (-139A/G and 336A/G), a repeat number of 69 bp in Exon 4 of DC-SIGN and DC-SIGNR, and one SNP in Exon 5 of DC-SIGNR (rs2277998A/G). We found that the proportion of individuals possessing a heterozygous 7/5 and 9/5 repeat and A allele at rs2277998 of DC-SIGNR in HIV-seronegative individuals of HIV-seropositive spouses was significantly higher than HIV-seropositive individuals [p = 0.0373, OR (95% CI) = 0.57 (0.32,1.01); p = 0.0232, OR (95% CI) = 0.38 (0.15,0.98); and p = 0.0445, OR (95% CI) = 0.61 (0.37,1.02), respectively]. Analysis after stratifying by gender showed that these associations were observed only in females but not in males. Moreover, HIV-seropositive females tend to have a homozygous 7/7 repeat more frequently than HIV-seronegative females with a marginal level of significance [p = 0.0556, OR (95% CI) = 1.79 (0.94,3.40)]. Haplotype analysis showed that the proportion of individuals possessing the 5A haplotype in HIV-seronegative females was significantly higher than HIV-seropositive females [p = 0.0133, OR = 0.50 (0.27,0.90)]. These associations suggest that DC-SIGNR may affect susceptibility to HIV infection by a mechanism that is different in females and males. Further studies are warranted to investigate the mechanisms of their function.     

Vpu: a multifunctional protein that enhances the pathogenesis of human immunodeficiency virus type 1

The Vpu protein is the smallest of the proteins encoded by human immunodeficiency virus type 1 (HIV-1). This transmembrane protein interacts with the CD4 molecule in the rough endoplasmic reticulum (RER), resulting in its degradation via the proteasome pathway. Vpu also has been shown to enhance virion release from infected cells. While much has been learned about the function of Vpu in cell culture systems, its exact role in HIV-1 pathogenesis is still unknown. This has been primarily due to the lack of a suitable primate model system since vpu is found only in HIV-1 and simian immunodeficiency viruses isolated from chimpanzees (SIVcpz), and three species of old world monkeys within the genus Cercopithecus. Several laboratories have developed pathogenic molecular clones of simian-human immunodeficiency virus (SHIV) in which the tat, rev, vpu and env genes of HIV-1 are expressed in the genetic background of SIV. The availability of such clones has allowed investigators to assess the role of Vpu in pathogenesis using a relevant animal model. This review will focus on the current understanding of the structure-function relationships of Vpu protein and recent advances using the SHIV model to assess the role of Vpu in HIV-1 pathogenesis.