Hepatitis C-specific effector and regulatory CD4 T-cell responses are associated with the outcomes of primary infection.

Clearance of primary hepatitis C virus (HCV) infection has been associated with strong and broadly targeted cellular immune responses. This study aimed to characterize HCV-specific CD4+ effector and regulatory T-cell numbers and cytokine production during primary infection. Antigen-specific CD4+ T-cell responses were investigated in a longitudinal cohort of subjects from pre-infection to postoutcome, including subjects who cleared [n=12] or became chronically infected [n=17]. A cross-sectional cohort with previously cleared, or chronic infection [n=15 for each], was also studied. Peripheral blood mononuclear cells were incubated with HCV antigens and surface stained for T-effector (CD4+CD25high CD134+CD39-) and T-regulatory (CD4+CD25high CD134+CD39+) markers, and culture supernatants assayed for cytokine production. Contrary to expectations, the breadth and magnitude of the HCV-specific CD4+ T-cell responses were higher in subjects who became chronically infected. Subjects who cleared the virus had HCV-specific CD4+ T-cell responses dominated by effector T cells and produced higher levels of IFN-γ, in contrast to HCV-specific CD4+ T-cell responses dominated by regulatory T cells and more IL-10 production in those who became chronically infected. Better understanding of the role of antigen-specific CD4+ T-cell responses in primary HCV will further define pathogenesis and help guide development of a preventative vaccine.

Circulating mycobacterial-reactive CD4+ T cells with an immunosuppressive phenotype are higher in active tuberculosis than latent tuberculosis infection.

BACKGROUND: Previous studies suggest that control of Mycobacterium tuberculosis infection is compromised by the activity of regulatory T cells, including those that express CD39, an ectonucleotidase with immunosuppressive properties. Here, we examine the role of CD39 on CD4+ T cells reacting to M. tuberculosis antigens. METHODS: Cryopreserved PBMC from patients with active TB (n = 31) or individuals with LTBI (n = 30) were cultured with PPD, ESAT-6 or CFP-10 and antigen-reactive CD4+ T cells assessed by: A) intracellular expression of interferon-gamma (IFN-γ), tumour necrosis factor alpha (TNF-α) and interleukin (IL)-2, B) co-expression of CD25 and CD134 with or without CD39, and C) production of IFN-γ, TNF-α and IL-10 in culture supernatants. RESULTS: Active TB patients were not differentiated from individuals with LTBI by intracellular expression of IFN-γ, TNF-α or IL-2 (alone or together), nor by co-expression of CD25 and CD134. However, active TB patients exhibited higher proportions of CD25+, CD134+, CD4+ T cells expressing CD39 in response to all antigens (p ≤ 0.022). Furthermore, in response to PPD, CD39 expression on CD25+, CD134+, CD4+ T cells correlated with IL-10 production (r = 0.41, p = 0.005) and inhibition of CD39 decreased IL-10 production. CONCLUSIONS: Antigen-reactive CD4+ T cells expressing CD39 are more abundant in active TB than LTBI and are associated with production of the immunosuppressive cytokine IL-10. Modulating the effects of CD39 might enhance cellular immune responses against M. tuberculosis.

Membrane-bound oxygen reductases of the anaerobic sulfate-reducing Desulfovibrio vulgaris Hildenborough: roles in oxygen defence and electron link with periplasmic hydrogen oxidation.

Cytoplasmic membranes of the strictly anaerobic sulfate-reducing bacterium Desulfovibrio vulgaris Hildenborough contain two terminal oxygen reductases, a bd quinol oxidase and a cc(b/o)o3 cytochrome oxidase (Cox). Viability assays pointed out that single Δbd, Δcox and double ΔbdΔcox deletion mutant strains were more sensitive to oxygen exposure than the WT strain, showing the involvement of these oxygen reductases in the detoxification of oxygen. The Δcox strain was slightly more sensitive than the Δbd strain, pointing to the importance of the cc(b/o)o3 cytochrome oxidase in oxygen protection. Decreased O2 reduction rates were measured in mutant cells and membranes using lactate, NADH, ubiquinol and menadiol as substrates. The affinity for oxygen measured with the bd quinol oxidase (Km, 300 nM) was higher than that of the cc(b/o)o3 cytochrome oxidase (Km, 620 nM). The total membrane activity of the bd quinol oxidase was higher than that of the cytochrome oxidase activity in line with the higher expression of the bd oxidase genes. In addition, analysis of the ΔbdΔcox mutant strain indicated the presence of at least one O2-scavenging membrane-bound system able to reduce O2 with menaquinol as electron donor with an O2 affinity that was two orders of magnitude lower than that of the bd quinol oxidase. The lower O2 reductase activity in mutant cells with hydrogen as electron donor and the use of specific inhibitors indicated an electron transfer link between periplasmic H2 oxidation and membrane-bound oxygen reduction via the menaquinol pool. This linkage is crucial in defence of the strictly anaerobic bacterium Desulfovibrio against oxygen stress.

Calreticulin, a potential cell surface receptor involved in cell penetration of anti-DNA antibodies.

A 50-kDa protein was purified as a potential receptor, using an affinity matrix containing biotinylated F14.6 or H9.3 anti-DNA mAbs derived from autoimmune (New Zealand Black x New Zealand White)F(1) mouse and membrane extracts from cells. This protein was identified as calreticulin (CRT) by microsequencing. Confocal microscopy and FACS analysis showed that CRT was present on the surface of various cells. CRT protein was recognized by a panel of anti-DNA mAbs in ELISA. The binding of F14.6 to lymphocytes and Chinese hamster ovary cells was inhibited by soluble CRT or SPA-600. Thus, the anti-DNA mAbs used in this study bound to CRT, suggesting that CRT may mediate their penetration into the cells and play an important role in lupus pathogenesis.

The HB-19 pseudopeptide 5[Kpsi(CH2N)PR]-TASP inhibits attachment of T lymophocyte- and macrophage-tropic HIV to permissive cells.

The HB-19 pseudopeptide 5[Kpsi(CH2N)PR]-TASP[psi(CH2N) indicating a reduced peptide bond], which binds the cell surface-expressed nucleolin, is a potent inhibitor of HIV infection. Here, by using primary T lymphocyte cultures and an experimental cell model to monitor HIV entry, we show that HB-19 inhibits in a dose-dependent manner both T lymphocyte- and macrophage-tropic HIV isolates. Similar positively charged control pseudopeptides have no effect on HIV infection even at high concentrations. These observations, and the fact that HB-19 has no effect on SIV-mac and HIV-1 pseudotyped with VSV envelope glycoproteins, confirm the specific nature of this inhibitor against the entry process mediated by the HIV envelope glycoproteins. Finally, association of low doses of HB-19 with beta-chemokines or AZT results in an increased inhibitory effect on HIV infection. HB-19 has no inhibitory effect when added to cells a few hours after HIV entry. On the other hand, in HB-19-pretreated cells, the inhibitory effect persists for several hours, even after washing cells to remove away the unbound pseudopeptide. Under such conditions, the attachment of HIV particles to cells is inhibited as efficiently as by neutralizing monoclonal antibodies directed against the V3 loop. In view of its specific mode of action on various HIV isolates, HB-19 represents a potential anti-HIV drug.

The V3 loop-mimicking pseudopeptide 5[Kpsi(CH2N)PR]-TASP inhibits HIV infection in primary macrophage cultures.

The V3 loop-mimicking pseudopeptide 5[Kpsi(CH2N)PR]-TASP [psi(CH2N) representing a reduced peptide bond], which presents pentavalently the tripeptide Kpsi(CH2N)PR, is a potent inhibitor of HIV entry. By its capacity to bind specifically protein components on the cell surface, 5[Kpsi(CH2N)PR]-TASP blocks the attachment of virus particles to permissive CD4+ cells. Here, the inhibitory effect of 5[Kpsi(CH2N)PR]-TASP was investigated in monocyte-derived macrophages (MDMs) infected by the monocytotropic HIV-1(Ba-L) isolate. We show that 5[Kpsi(CH2N)PR]-TASP inhibits HIV-1(Ba-L) infection in a dose-dependent manner, with more than 90% inhibition at 2 microM concentration. On the other hand, the control 5[QPQ]-TASP construct and the monovalent Kpsi(CH2N)PR tripeptide have no effect even at high concentrations. Under such experimental conditions, the biotin-labeled 5[Kpsi(CH2N)PR]-TASP, but not the Kpsi(CH2N)PR construct, binds specifically to the surface of MDMs and forms a stable complex with the cell surface-expressed nucleolin, as has been demonstrated to be the case in peripheral blood mononuclear cells. Infection of MDMs by HIV-1(Ba-L) could also be inhibited by beta-chemokines RANTES and MIP-1beta. Interestingly, association of low concentrations of 5[Kpsi(CH2N)PR]-TASP and beta-chemokines results in a synergistic inhibitory effect on HIV infection compared with the effect observed with each reagent alone. The inhibitory effect of 5[Kpsi(CH2N)PR]-TASP in primary macrophage cultures point out its potential as an anti-HIV drug in cells, which are the natural viral targets.

Interaction of human immunodeficiency virus type 1 envelope glycoprotein V3 loop with CCR5 and CD4 at the membrane of human primary macrophages.

We show that infection of primary monocyte-derived macrophages (MDMs) and blood lymphocytes (PBLs) by human immunodeficiency virus type 1 (HIV-1) R5 strains, but not that of PBLs by X4 strain HIV-1LAI, is inhibited by beta-chemokines RANTES and MIP-1alpha. A biotinylated disulfide-bridged peptide mimicking the complete loop of clade B consensus V3 domain of gp120 (V3Cs), but not a biotinylated V3LAI peptide or a control beta-endorphin peptide of approximately the same molecular weight (MW), was found to bind specifically to MDM membrane proteins, in particular two proteins of 42 and 62 kDa migrating as sharp bands after electroblotting onto Immobilon, and this was specifically inhibited by anti-V3 antibodies. When biotinylated V3Cs was incubated with intact MDMs, which were then washed and lysed, and the resulting material was incubated with streptavidin-agarose beads and electroblotted onto Immobilon, fresh V3Cs also bound to proteins of the same molecular weight recovered in the V3Cs-interacting material. This binding was inhibited by anti-V3 antibodies, and no binding occurred with the control peptides. V3Cs also bound to soluble recombinant CD4, and CD4 monoclonal antibody Q4120 specifically recognized the V3Cs-interacting 62-kDa protein, which should thus correspond to CD4. Recombinant radiolabeled RANTES, MIP-1alpha, and MIP-1beta, but not IL-8, also bound to a 42-kDa protein on the membrane of MDMs as well as to the V3Cs-interacting 42-kDa protein, and excess unlabeled V3Cs inhibited such binding. This protein was also recognized by antibodies to CCR5, the RANTES/MIP-1alpha/MIP-1beta receptor. These data show that V3Cs binds to MDM membrane proteins that comprise CD4 and CCR5, and that multimolecular complexes involving at least gp120 V3, CD4, and CCR5 are formed on the surface of MDMs as part of V3-mediated postbinding events occurring during HIV-1 infection.

Identification of V3 loop-binding proteins as potential receptors implicated in the binding of HIV particles to CD4(+) cells.

The binding of human immunodeficiency virus (HIV) type 1 particles to CD4(+) cells could be blocked either by antibodies against the V3 loop domain of the viral external envelope glycoprotein gp120, or by the V3 loop mimicking pseudopeptide 5[Kpsi(CH2N)PR]-TASP, which forms a stable complex with a cell-surface-expressed 95-kDa protein. Here, by using an affinity matrix containing 5[Kpsi(CH2N)PR]-TASP and cytoplasmic extracts from human CEM cells, we purified three V3 loop-binding proteins of 95, 40, and 30 kDa, which after microsequencing were revealed to be as nucleolin, putative HLA class II-associated protein (PHAP) II, and PHAP I, respectively. The 95-kDa cell-surface protein was also isolated and found to be nucleolin. We show that recombinant preparations of gp120 bind the purified preparations containing the V3 loop-binding proteins with a high affinity, comparable to the binding of gp120 to soluble CD4. Such binding is inhibited either by 5[Kpsi(CH2N)PR]-TASP or antibodies against the V3 loop. Moreover, these purified preparations inhibit HIV entry into CD4(+) cells as efficiently as soluble CD4. Taken together, our results suggest that nucleolin, PHAP II, and PHAP I appear to be functional as potential receptors in the HIV binding process by virtue of their capacity to interact with the V3 loop of gp120.

Involvement of the HIV-1 external envelope glycoprotein 120 (gp120) C2 region in gp120 oligomerization.

A synthetic peptide resembling the C2 region of human immunodeficiency virus type 1 (HIV-1) gp120 (C2-Lai: amino acids (aa) 273-288), inhibited (C50 = 200 microM) gp120 calcium-dependent binding of N-acetyl-beta-D-glucosaminyl and mannosyl residues exposed on natural glycoprotein bovine fetuin whereas a peptide derived from an aa sequence downstream of C2-Lai (C2-SC19) had no such effect (C50 > 1000 microM). No calcium-carbohydrate-specific binding of C2-Lai to fetuin was detected. In addition, C2-Lai was also found to inhibit the calcium-dependent oligomerization of gp120: while recombinant gp120 (rgp120) was recovered mainly as oligomers (78%) in 10 mM CaCl2, in contrast to 100% monomers in 1mM CaCl2, mostly monomers (67%) were found in 10 mM CaCl2 in the presence of C2-Lai. Peptide C2-SC19 and carbohydrate structures such as fetuin, fucoidin, dextran or mannan did not significantly affect gp120 oligomerization. Electrophoresis and gel filtration analysis also showed that C2-Lai aggregated in the form of 20 kDa compounds, which is compatible with association of 10 molecules. Taken together, these results demonstrate that the C2 domain is involved in gp120 oligomerization and suggest that gp120 oligomers but not monomers have specific carbohydrate binding properties.

HIV type 1 V3 peptide constructs act differently on HIV type 1 infection of peripheral blood lymphocytes and macrophages.

We have previously shown that a multibranched peptide construct derived from the tip of the B clade V3 loop consensus sequence (MPBC1: [GPGRAF]8-[K]4-[K]2-K-beta A-OH), but not V3 monomer peptides, inhibit human immunodeficiency virus type 1 (HIV-1) infection and syncytium formation of CD4+ T cells from immortalized lines. Here, we show that MBPC1 attaches to normal peripheral blood lymphocytes (PBLS) and monocytes but not to erythrocytes. While treatment with 5 microM MBPC1 had no significant antiviral effect on HIV-1Ba-L infection of monocyte-derived macrophages as assessed by p24 production in culture supernatants, this dose inhibited both HIV-1Ba-L and HIV-1LAI infection of PBLs. Virus production was inhibited up to 90% when MBPC1 was added to PBLs immediately after the virus, and was inhibited about 50% when it was added after 3 days; no effect was noted when it was added 7 days postinfection. MBPC1 did not affect PBL growth or IL-2 receptor and CD4 surface expression level. These observations suggest a selective antiviral effect of MBPC1 on CD4+ T lymphocytes and they provide additional circumstantial evidence that HIV-1 enters lymphocytes and monocytes by different mechanisms.

Effect of mannosylated derivatives on HIV-1 infection of macrophages and lymphocytes.

We previously demonstrated that gp120/160 (Env) of HIV-1 interact in a carbohydrate-specific manner with mannosyl/N-acetylglucosaminyl derivatives and that HIV-1LAI infection of monocytic U937 and lymphoid CEM cells was inhibited by CD4-free Concanavalin A-reactive glycopeptides from U937 cells. We report here that the natural glycoproteins bovine fetuin and asialofetuin, human orosomucoid and alpha-fetoprotein, and mannan, which all specifically interact with Env, inhibited infection of primary macrophages by macrophage-tropic HIV-1 strains, whereas dextran had no such effect. This activity was conserved if fetuin, asialofetuin, or orosomucoid were heat-treated, which rules out the role of their three-dimensional structure. Orosomucoid and mannan partially inhibited Env binding to macrophages but not to U937 or CEM cells. This indicates that Env does not bind in the same manner to primary macrophages and to immortalized CD4+ cells, and that orosomucoid and mannan act at CD4-independent stages of virus binding to macrophages. Mannan also inhibited Env binding to surface glycopeptides obtained after trypsin treatment of macrophages. Furthermore, orosomucoid and fetuin interacted with, and they inhibited the binding of a V3 loop B clade consensus peptide to several macrophage membrane proteins, including two 36 and 42 kDa proteins. These data indicate that these glycoproteins interfere with post-binding events during HIV-1 infection of primary macrophages. In contrast, the compounds did not affect infection of U937 or CEM cells by T-cell tropic HIV-1LAI nor infection of peripheral blood lymphocytes by HIV-1LAI or HIV-1(Ba-L). Thus, carbohydrate-specific inhibition of HIV infection depends on the cell type more than on the viral strain, and differences in the glycan structure of cell-type-specific cofactors may be important for HIV entry into cells.

Antiviral activity of derivatized dextrans on HIV-1 infection of primary macrophages and blood lymphocytes.

The present study demonstrates at the molecular level that dextran derivatives carboxymethyl dextran benzylamine (CMDB) and carboxymethyl dextran benzylamine sulfonate (CMDBS), characterized by a statistical distribution of anionic carboxylic groups, hydrophobic benzylamide units, and/or sulfonate moieties, interact with HIV-1 LAI gp120 and V3 consensus clades B domain. Only limited interaction was observed with carboxy-methyl dextran (CMD) or dextran (D) under the same conditions. CMDBS and CMDB (1 microM) strongly inhibited HIV-1 infection of primary macrophages and primary CD4+ lymphocytes by macrophage-tropic and T lymphocyte-tropic strains, respectively, while D or CMD had more limited effects on M-tropic infection of primary macrophages and exert no inhibitory effect on M- or T-tropic infection of primary lymphocytes. CMDBS and CMDB (1 microM) had limited but significant effect on oligomerized soluble recombinant gp120 binding to primary macrophages while they clearly inhibit (> 50%) such binding to primary lymphocytes. In conclusion, the inhibitory effect of CMDB and the CMDBS, is observed for HIV M- and T-tropic strain infections of primary lymphocytes and macrophages which indicates that these compounds interfere with steps of HIV replicative cycle which neither depend on the virus nor on the cell.

Membrane glycolipids and human immunodeficiency virus infection of primary macrophages.

The membrane glycolipids galactosylceramide (GalCer) and sulfatide (SGalCer) have been reported to act as receptors of human immunodeficiency virus (HIV) on CD4- cell lines. We show here that these glycolipids are present on CD4+ cells purified from human blood and on in vitro-differentiated monocyte-derived macrophages (MDMs). We investigated the role they could play in HIV infection. Glycolipids of MDMs were characterized at the molecular level by immunolabeling and thin-layer chromatography immune overlay, using a panel of human-, rabbit-, or murine-specific antibodies. GalCer and SGalCer were expressed at the surface of MDMs as assessed by indirect immunofluorescence and flow cytometry analysis, and they could be characterized with specific antibodies in the cellular glycolipid extracts in addition to GM1, GM3, and GD1b gangliosides. Recombinant 125-I-labeled gp160 specifically bound to GalCer, SGalCer, GM1, and GM3 as well as to phospholipids (phosphatidylethanolamine and phosphatidylserine) from MDM extracts. Anti-SGalCer monoclonal antibodies (MAbs), but not anti-GalCer antibodies, entailed limited (30-40%) but significant inhibition of gp160 binding to MDMs. However, the four human anti-SGalCer MAbs and the three murine or rabbit ant-GalCer antibodies tested did not inhibit HIV infection of MDMs, in contrast to CD4 antibody anti-Leu3a tested in parallel. These findings suggests that although HIV envelope glycoprotein can bind to SGalCer and GalCer from CD4+ MDM extracts, these glycolipids do not apparently act as HIV coreceptors nor are they involved in HIV infection of these cells.

The role of calcium and N-linked glycans in the oligomerization and carbohydrate binding properties of human immunodeficiency virus external envelope glycoprotein.

Envelope glycoproteins of human immunodeficiency virus (gp120 and gp41) occur as oligomers. Here, we show by gel filtration analysis that gp120 oligomerization in vitro is calcium- and temperature-dependent. Recombinant gp120 (rgp120) species were recovered as monomers at 20 degrees C in the absence of calcium, but as tetramers at 37 degrees C in 10 mM CaCl2. Under the latter condition, N-glycanase-deglycosylated rgp120 formed hexamers. Relative to intact rgp120, which has been reported to display carbohydrate-binding properties for N-acetyl-beta-D-glucosaminyl and mannosyl residues, deglycosylation enhanced rgp120 specific binding to mannose-divinylsulfone-agarose, para-aminophenyl-beta-D-GlcNAc-agarose and fetuin-agarose matrices. Taken together, these results rule out the role of homologous lectin-carbohydrate interactions via N-linked glycans in the rgp120 oligomerization, even though its lectin properties may also be calcium-dependent. Deglycosylation may unmask domains of rgp120 polypeptide backbone that independently play a role either in rgp120 lectin activity or in calcium-dependent oligomerization.

A monoclonal antibody directed to sulfatide inhibits the binding of human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein to macrophages but not their infection by the virus.

We show here that human immunodeficiency virus (HIV) envelope glycoproteins (gp160/gp120) bind to sulfatide and galactosyl ceramide. By immunofluorescence labeling with monoclonal antibody (mAb) A2B5, specific for ganglioside/sulfatide, we detect negatively charged glycolipids on CD4+ cells of the macrophage lineage and lymphocytes. Labeling of monocyte-derived macrophages (MDM) with mAb A2B5 was reproducibly found in 29 healthy donors, independently of the culture method and duration up to 11 days. The binding of the mAb to neuraminidase-treated MDM was unchanged relative to control cells, but mAb binding decreased after arylsulfatase treatment, which indicates that MDM membrane sulfatide is its major ligand. Preincubating MDM with the mAb partially (40-60%) but significantly inhibited the binding of HIV-1LAI radiolabeled recombinant gp160 to the cells. Similarly, the mAb entailed limited (32%) but significant inhibition of gp160 binding to cells of the monocytic U937 line but not to lymphoid CEM cells. However, mAb A2B5 did not inhibit the infection of CEM nor of U937 cells by HIV-1LAI strain, nor of MDM by monocytotropic HIV-1BaL. Thus, although sulfatide may be involved in the binding of HIV env glycoprotein to MDM or monocytic U937 cells, this does not play a significant role in HIV infection of these CD4+ cells.

Carbohydrate binding properties of the envelope glycoproteins of human immunodeficiency virus type 1.

Here, we confirm and extend our previous findings on human immunodeficiency virus type 1 (HIV-1) envelope glycoprotein N-acetylglucosaminyl binding properties. We show the occurrence of saturable, temperature, pH, and calcium dependent carbohydrate-specific interactions between recombinant precursor gp160 (rgp160) and two affinity matrices: D-mannose-divinylsulfone-agarose, and natural glycoprotein, fetuin, also coupled to agarose. Binding of rgp160 to the matrices was inhibited by soluble mannosyl derivatives, alpha-D-Man17-BSA and mannan, by beta-D-GlcNAc47-BSA and by glycopeptides from Pronase-treated porcine thyroglobulin, which produces oligomannose and complex N-linked glycans. Glycopeptides from Endoglycosidase H-treated thyroglobulin partially inhibited rgp160 binding, as did the asialo-agalacto-tetraantennary precursor oligosaccharide of human alpha 1-acid glycoprotein for binding to fetuin-agarose. beta-D-Glucan and beta-D-Gal17-BSA had no or only limited effect. Also, surface unit rgp120 specifically interacted with fetuin-agarose and soluble fetuin, but in the latter case with a twofold reduced affinity relative to rgp160. After affinity chromatography, rgp160 was specifically retained by the two matrices and eluted by mannan in both cases, while rgp120 was not retained by fetuin-agarose but only eluted as a significantly retarded peak, which confirms its specific but weak interaction. Thus, rgp160 interacts with both oligomannose type, and the mannosyl core of complex type N-linked glycans, and its gp120 region plays a role in this interaction.(ABSTRACT TRUNCATED AT 250 WORDS)