The maturation of dendritic cells results in postintegration inhibition of HIV-1 replication.

Maturation of dendritic cells (DC) is known to result in decreased capacity to produce HIV due to postentry block of its replicative cycle. In this study, we compared the early phases of this cycle in immature DC (iDC) and mature DC (mDC) generated from monocytes cultured with GM-CSF and IL-4, trimeric CD40 ligand (DC(CD40LT)), or monocyte-conditioned medium (DC(MCM)) being added or not from day 5. Culture day 8 cells exposed to X4 HIV-1(LAI) or R5 HIV-1(Ba-L) were analyzed by semiquantitative R-U5 PCR, which detects total HIV DNA. CXC chemokine receptor 4(low) (CXCR4(low)) CCR5(+) iDC harbored similar viral DNA amounts when exposed to either strain. HIV-1(LAI) entered more efficiently into DC(CD40LT) or DC(MCM) with up-regulated CXCR4. CCR5(low) DC(CD40LT) still allowed entry of HIV-1(Ba-L), whereas CCR5(-) DC(MCM) displayed reduced permissivity to this virus. Comparing amounts of late (long terminal repeat (LTR)-gag PCR) and total (R-U5 PCR) viral DNA products showed that HIV-1(Ba-L) reverse transcription was more efficient than that of HIV-1(LAI), but was not affected by DC maturation. Southern blot detection of linear, circular, and integrated HIV DNA showed that maturation affected neither HIV-1 nuclear import nor integration. When assessing virus transcription by exposing iDC to pNL4-3.GFP or pNL4-3.Luc viruses pseudotyped with the G protein of vesicular stomatitis virus (VSV-G), followed by culture with or without CD40LT or MCM, GFP and luciferase activities decreased by 60-75% in mDC vs iDC. Thus, reduced HIV replication in mDC is primarily due to a postintegration block occurring mainly at the transcriptional level. We could not relate this block to altered expression and nuclear localization of NF-kappa B proteins and SP1 and SP3 transcription factors.

Soluble glycosaminoglycans Do not potentiate RANTES antiviral activity on the infection of primary macrophages by human immunodeficiency virus type 1.

Macrophages play an important role in human immunodeficiency virus (HIV)-1 infection. They exist in various differentiation and activation states in vivo, a heterogeneity that may affect their interactions with HIV-1 and susceptibility to drugs. Here, we found that RANTES and MIP-1beta, heparin, or soluble chondroitin sulfate B, but not chondroitin sulfate A, inhibited HIV-1(BaL) infection of macrophages obtained as the adherent cells of 5-day cultures of blood mononuclear cells (PBMC), followed by 2 days without either nonadherent PBMC or added cytokines (MDM-5d), whereas they did not affect infection of macrophages obtained as the adherent cells recovered from 1-h incubation of PBMC and subsequent 7-day culture with macrophage colony-stimulating factor (MDM-MCSF). Such different behavior was not related to differences in HIV-1 binding but rather to postbinding steps, as HIV-1(BaL) attached similarly to MDM-5d and MDM-MCSF, a binding that was affected by soluble glycosaminoglycans but not by RANTES. Of note, CCR5 expression on both types of MDM was comparable, and it was not downregulated by RANTES on either. Mixing RANTES with each of the glycosaminoglycans did not restore inhibition of MDM-MCSF infection by HIV-1; however, heparin at concentrations that had low antiviral activity for MDM-5d counteracted RANTES anti-HIV-1 activity for these cells, whereas chondroitin sulfate B had no additive effect on that of RANTES. Both glycosaminoglycans affected RANTES binding to MDM. Thus, in contrast to cell surface proteoglycans that contribute to the attachment of RANTES to macrophages and enhance its anti-HIV-1 activity, soluble glycosaminoglycans do not facilitate, and may even offset, the anti-HIV-1 activity of RANTES.

Identification of mature and immature human thymic dendritic cells that differentially express HLA-DR and interleukin-3 receptor in vivo.

We have previously shown that thymic CD34+ cells have a very limited myeloid differentiation capacity and differentiate in vitro mostly into CD1a+-derived but not CD14+-derived dendritic cells (DC). Herein we characterized the human neonatal thymic DC extracted from the organ in relationship with the DC generated from CD34+ cells in situ. We show that in vivo thymic DC express E cadherin, CLA, CD4, CD38, CD40, CD44, and granulocyte-macrophage colony-stimulating factor-R (GM-CSF-R; CD116) but no CD1a. According to their morphology, functions, and surface staining they could be separated into two distinct subpopulations: mature HLA-DRhi, mostly interleukin-3-R (CD123)-negative cells, associated with thymocytes, some apoptotic, and expressed myeloid and activation markers but no lymphoid markers. In contrast, immature HLA-DR+ CD123hi CD36+ cells with monocytoid morphology lacked activation and myeloid antigens but expressed lymphoid antigens. The latter express pTalpha mRNA, which is also found in CD34+ thymocytes and in blood CD123hi DC further linking this subset to lymphoid DC. However, the DC generated from CD34+ thymic progenitors under standard conditions were pTalpha-negative. Thymic lymphoid DC showed similar phenotype and cytokine production profile as blood/tonsillar lymphoid DC but responded to GM-CSF, and at variance with them produced no or little type I interferon upon infection with viruses and did not induce a strict polarization of naive T cells into TH2 cells. Their function in the thymus remains therefore to be elucidated.

Characterization of dendritic cell differentiation pathways from cord blood CD34(+)CD7(+)CD45RA(+) hematopoietic progenitor cells.

To better characterize human dendritic cells (DCs) that originate from lymphoid progenitors, the authors examined the DC differentiation pathways from a novel CD7(+)CD45RA(+) progenitor population found among cord blood CD34(+) cells. Unlike CD7(-)CD45RA(+) and CD7(+)CD45RA(-) progenitors, this population displayed high natural killer (NK) cell differentiation capacity when cultured with stem cell factor (SCF), interleukin (IL)-2, IL-7, and IL-15, attesting to its lymphoid potential. In cultures with SCF, Flt3 ligand (FL), granulocyte-macrophage colony-stimulating factor (GM-CSF), and tumor necrosis factor (TNF)-alpha (standard condition), CD7(+)CD45RA(+) progenitors expanded less (37- vs 155-fold) but yielded 2-fold higher CD1a(+) DC percentages than CD7(-)CD45RA(+) or CD7(+)CD45RA(-) progenitors. As reported for CD34(+)CD1a(-) thymocytes, cloning experiments demonstrated that CD7(+)CD45RA(+) cells comprised bipotent NK/DC progenitors. DCs differentiated from CD7(-)CD45RA(+) and CD7(+)CD45RA(+) progenitors differed as to E-cadherin CD123, CD116, and CD127 expression, but none of these was really discriminant. Only CD7(+)CD45RA(+) or thymic progenitors differentiated into Lag(+)S100(+) Langerhans cells in the absence of exogenous transforming growth factor (TGF)-beta 1. Analysis of the DC differentiation pathways showed that CD7(+)CD45RA(+) progenitors generated CD1a(+)CD14(-) precursors that were macrophage-colony stimulating factor (M-CSF) resistant and CD1a(-)CD14(+) precursors that readily differentiated into DCs under the standard condition. Accordingly, CD7(+)CD45RA(+) progenitor-derived mature DCs produced 2- to 4-fold more IL-6, IL-12, and TNF-alpha on CD40 ligation and elicited 3- to 6-fold higher allogeneic T-lymphocyte reactivity than CD7(-)CD45RA(+) progenitor-derived DCs. Altogether, these findings provide evidence that the DCs that differentiate from cord blood CD34(+)CD7(+)CD45RA(+) progenitors represent an original population for their developmental pathways and function. (Blood. 2000;96:3748-3756)

CD13/N-aminopeptidase is involved in the development of dendritic cells and macrophages from cord blood CD34(+) cells.

Expression of CD13/N-aminopeptidase may reflect cell activation and growth. We examined its role regarding cell growth in cultures of cord blood CD34(+) cells with stem cell factor/Flt-3 ligand/granulocyte-macrophage colony-stimulating factor/tumor necrosis factor-alpha. Indeed, 82% +/- 6% of cells from culture day 5 were CD13(hi), 25% +/- 8% of which were still Lin-. About 50% of CD13(hi)Lin- cells, which comprise progenitors of dendritic cells (DC), monocytes/macrophages and granulocytes, and 30% of CD13(lo)Lin- cells were CD34(+). Sorted CD34(+)CD13(hi)Lin- cells, cultured further for 7 days with the same cytokines, expanded 31-fold and CD34(-)CD13(hi)Lin- cells 7-fold, but CD34(+)CD13(lo)Lin- and CD34(-)CD13(lo)Lin- cells did not grow. Thus, cell growth correlated with CD13 expression, all the more so that cells were CD34(+). Actinonin, the most potent N-aminopeptidase inhibitor, was used to engage CD13 on sorted CD13(hi)Lin- cells and on culture day-7 bulk cells. In both cases, this resulted in reversible cell growth arrest, with 30% to 60% fewer cells in the G2/S-M phase than in controls. Interestingly, similar effects were noted with CD13 monoclonal antibody TUK1, which does not inhibit N-aminopeptidase activity, but not with N-aminopeptidase-blocking antibodies WM15 and F23. All cycling cells appeared susceptible to actinonin, which induced cell apoptosis at the same time as Bcl-2 was downregulated and caspase-3 activity increased, but finally percentages and yields of DC and macrophage precursors were affected more than those of granulocytic cells. Thus, through engagement of N-aminopeptidase enzymatic site but possibly also of an independent determinant, CD13 plays a role in the growth of DC/macrophage progenitors and precursors. (Blood. 2000;95:453-460)

Glycan and glycosaminoglycan binding properties of stromal cell-derived factor (SDF)-1alpha.

We show here that cell surface glycosaminoglycans (GAGs) are involved in the binding of stromal cell-derived factor (SDF)-1alpha to CD4(+)lymphoid CEM or monocytic U937 cells, inasmuch as pretreating the cells with heparitinase or chondroitinase inhibits SDF-1alpha binding by 40-41% and 31-35%, respectively. Soluble heparin or chondroitin sulfate partially but significantly inhibits SDF-1alpha binding to the cells by 45-52% and 42-56%, respectively, while dextran has no significant effect. Taken together, these results indicate the role of GAGs in SDF-1alpha attachment to the cells. However, the effects of heparitinase and chondroitinase as well as those of heparin and chondroitin sulfate are not additive, which suggests that SDF-1alpha may attach to the cells through different GAGs, and also through other ligands. Soluble mannan also inhibits SDF-1alpha binding to the cells by 30-33%. Additivity between this effect and that of heparin or chondroitin sulfate is observed. Therefore, beside GAGs, mannose-containing species may also be involved in SDF-1alpha attachment to the cells. Accordingly, SDF-1alpha specifically binds to heparin-agarose and mannose-divinylsulfone agarose affinity matrices, and these interactions are inhibited respectively by soluble heparin, chondroitin sulfate, and mannan. We have previously shown that gp120 of X4 strain HIV-1LAI presents specific carbohydrate-binding properties for mannosylated derivatives, including mannan, and for GAGs including heparin. The present data therefore indicate that, in the same manner as HIV-1 Env, SDF-1alpha can interact with GAGs and glycans at the cell surface.

Rational engineering of a miniprotein that reproduces the core of the CD4 site interacting with HIV-1 envelope glycoprotein.

Protein-protein interacting surfaces are usually large and intricate, making the rational design of small mimetics of these interfaces a daunting problem. On the basis of a structural similarity between the CDR2-like loop of CD4 and the beta-hairpin region of a short scorpion toxin, scyllatoxin, we transferred the side chains of nine residues of CD4, central in the binding to HIV-1 envelope glycoprotein (gp120), to a structurally homologous region of the scorpion toxin scaffold. In competition experiments, the resulting 27-amino acid miniprotein inhibited binding of CD4 to gp120 with a 40 microM IC(50). Structural analysis by NMR showed that both the backbone of the chimeric beta-hairpin and the introduced side chains adopted conformations similar to those of the parent CD4. Systematic single mutations suggested that most CD4 residues from the CDR2-like loop were reproduced in the miniprotein, including the critical Phe-43. The structural and functional analysis performed suggested five additional mutations that, once incorporated in the miniprotein, increased its affinity for gp120 by 100-fold to an IC(50) of 0.1-1.0 microM, depending on viral strains. The resulting mini-CD4 inhibited infection of CD4(+) cells by different virus isolates. Thus, core regions of large protein-protein interfaces can be reproduced in miniprotein scaffolds, offering possibilities for the development of inhibitors of protein-protein interactions that may represent useful tools in biology and in drug discovery.

Safety and immunogenicity of a live recombinant canarypox virus expressing HIV type 1 gp120 MN MN tm/gag/protease LAI (ALVAC-HIV, vCP205) followed by a p24E-V3 MN synthetic peptide (CLTB-36) administered in healthy volunteers at low risk for HIV infection. AGIS Group and L'Agence Nationale de Recherches sur Le Sida.

A live recombinant canarypox vector expressing HIV-1 gpl20 MN tm/gag/protease LAI (ALVAC-HIV, vCP205) alone or boosted by a p24E-V3 MN synthetic peptide (CLTB-36) was tested in healthy volunteers at low risk for HIV infection for their safety and immunogenicity. Both antigens were well tolerated. ALVAC-HIV (vCP205) induced low levels of neutralizing antibodies against HIV-1 MN in 33% of the volunteers. None of them had detectable neutralizing antibodies against a nonsyncytium-inducing HIV-1 clade B primary isolate (Bx08). After the fourth injection of vCP205, CTL activity was detected in 33% of the volunteers and was directed against Env, Gag, and Pol. This activity was mediated by both CD4+ and CD8+ lymphocytes. On the other hand, the CLTB-36 peptide was poorly immunogenic and induced no neutralizing antibodies or CTLs. Although the ALVAC-HIV (vCP205) and CLTB-36 prime-boost regimen was not optimal, further studies with ALVAC-HIV (vCP205) are warranted because of its clear induction of a cellular immune response and utility as a priming agent for other subunit antigens such as envelope glycoproteins, pseudoparticles, or new peptides.

The susceptibility to X4 and R5 human immunodeficiency virus-1 strains of dendritic cells derived in vitro from CD34(+) hematopoietic progenitor cells is primarily determined by their maturation stage.

Dendritic cells (DC) were sorted on day 8 from cultures of CD34(+) cells with stem cell factor/Flt-3 ligand/ granulocyte-macrophage colony-stimulating factor (GM-CSF)/tumor necrosis factor-alpha (TNF-alpha)/interleukin-4 (IL-4). Exposing immature CCR5(+)CXCR4(lo/-) DC to CCR5-dependent human immunodeficiency virus (HIV)-1Ba-L led to productive and cytopathic infection, whereas only low virus production occurred in CXCR4-dependent HIV-1LAI-exposed DC. PCR analysis of the DC 48 hours postinfection showed efficient entry of HIV-1Ba-L but not of HIV-1LAI. CD40 ligand- or monocyte-conditioned medium-induced maturation of HIV-1Ba-L-infected DC reduced virus production by about 1 Log, while cells became CCR5(-). However, HIV-1Ba-L-exposed mature DC harbored 15-fold more viral DNA than their immature counterparts, ruling out inhibition of virus entry. Simultaneously, CXCR4 upregulation by mature DC coincided with highly efficient entry of HIV-1LAI which, nonetheless, replicated at the same low level in mature as in immature DC. In line with these findings, coculture of HIV-1Ba-L-infected immature DC with CD3 monoclonal antibody-activated autologous CD4(+) T lymphocytes in the presence of AZT decreased virus production by the DC. Finally, whether they originated from CD1a+CD14(-) or CD1a-CD14(+) precursors, DC did not differ as regards permissivity to HIV, although CD1a+CD14(-) precursor-derived immature DC could produce higher HIV-1Ba-L amounts than their CD1a-CD14(+) counterparts. Thus, both DC permissivity to, and capacity to support replication of, HIV is primarily determined by their maturation stage.

Lipopolysaccharide can block the potential of monocytes to differentiate into dendritic cells.

We examined whether priming monocytes (MO) with lipopolysaccharide (LPS) influenced their further differentiation into either macrophages (Mphi) or dendritic cells (DC). LPS-primed MO differentiated into Mphi when cultured further with Mphi colony-stimulating factor (M-CSF) but, if cultured then with granulocyte/Mphi (GM)-CSF and IL-4 (interleukin-4), only about 30% of the cells differentiated into CD1a+ CD14- DC and half became CD1a- CD14+ Mphi. Cytokines present during LPS priming could affect subsequent MO differentiation. Relative to priming with LPS alone, adding M-CSF to LPS did not modify differentiation of MO to Mphi in further culture with M-CSF, nor did it change the way of differentiation of MO into DC was altered if culture was later switched to GM-CSF/IL-4. Using GM-CSF/IL-4 plus LPS upon priming did not modify differentiation of MO to Mphi in further culture with M-CSF, as compared to priming with GM-CSF/IL-4 alone, but it counteracted the effect of LPS on the differentiation of MO to DC in further culture with GM-CSF/IL-4: about 75% of cells then became DC. Alternatively, despite activation by LPS, mature M-CSF-induced Mphi preserved the potential to differentiate into DC on subsequent culture with GM-CSF/IL-4. Thus, LPS, a bacterial product known to sustain maturation of MO/Mphi as well as of DC, may block the differentiation of MO into DC, except if signal triggering DC differentiation is delivered concomitantly, and modulate in this manner the induction of adaptive immune responses to infection.

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.

IL-4 and CD40 ligation affect differently the differentiation, maturation, and function of human CD34+ cell-derived CD1a+CD14- and CD1a-CD14+ dendritic cell precursors in vitro.

We examined the effect of interleukin (IL)-4 or CD40 ligation on the differentiation and maturation of CD1a+CD14- and CD1a-CD14+ dendritic cell (DC) precursors. Cord blood CD34+ cells were cultured with granulocyte-macrophage colony-stimulating factor (GM-CSF) and tumor necrosis factor alpha (TNF-alpha), to which stem cell factor and Flt-3 ligand were added for 5 days. Phenotypic analysis of DC precursors on culture day 7 showed that CD1a+CD14- cells expressed higher CD11c and CD80 levels and lower CD116/GM-CSFR and CCR-5 levels than their CD1a-CD14+ counterparts. Culturing CD1a+CD14- precursors with GM-CSF and TNF-alpha resulted in DC with heterogeneous CD1a, HLA;SMDR (DR), CD11b, and CD83 expression, 10% of which acquired CD14. IL-4 and CD40 ligation affected their differentiation in contrasting ways: IL-4 induced CD1ahiCD14-DRloCD11b+CD83-S100+ DC with reduced MLR-stimulating capacity, whereas CD40 ligation led to CD1alo/-CD14-CD40-DRhiCD11b-CD83+S100+/- DC with stronger MLR-stimulating capacity. Also, both IL-4 and CD40 ligation promoted ReIB expression and nuclear translocation. When CD1a-CD14+ precursors were maintained in only the presence of GM-CSF and TNF-alpha, this led to mixed populations of adherent macrophages and nonadherent CD1a-CD14+ monocytes, and of CD1a+CD14- and CD1a+CD14+ DC, which were DRloCD11b+CD83-S100-. IL-4 or CD40 ligation prevented their differentiation into macrophages and resulted in DC with phenotypes close to those issued from CD1a+CD14- precursors, with only a minority staying CD14+ but most being S100-; their MLR-stimulating capacity also increased but remained lower than that of DC differentiated from CD1a+CD14- precursors. Thus, IL-4 or CD40 ligation induced CD1a+CD14- and CD1a-CD14+ DC precursors to differentiate into phenotypically close but functionally different DC populations, suggesting that DC function is primarily determined by their origin. The heterogeneity of DC should then be related to different developmental pathways and to different stages of maturation/activation.

Synthetic full-length and truncated RANTES inhibit HIV-1 infection of primary macrophages.

OBJECTIVE: To determine the effect of beta-chemokines on HIV-1 infection of primary macrophages, and to search for chemokine derivatives devoid of biological effects but efficient at protecting CD4+ T lymphocytes and macrophages against HIV-1. DESIGN: Use of chemically synthesized molecules devoid of biological contaminants and monocyte-derived macrophages from healthy donors. METHODS: Full-length RANTES was chemically synthesized together with three derivatives, truncated of seven, eight and nine amino acids at the amino-terminus ([8-68]RANTES, [9-68]RANTES and [10-68]RANTES), which were tested for their biological activity and antiviral effects. RESULTS: Whereas full-length and truncated RANTES derivatives bound to beta-chemokine receptor CCR-5 with the same affinity as recombinant RANTES, the truncated forms were not chemotactic and acted as CCR-5 antagonists in this respect, although a partial agonist effect was noted on cell metabolism. Full-length RANTES and [8-68]RANTES protected T lymphocytes and macrophages from infection by HIV-1, although 10-fold higher concentrations of the truncated analogues were necessary to achieve the same effect as full-length RANTES. With regard to the effect of RANTES on HIV-1 infection of primary macrophages, our results contrast with most previously reported data. CONCLUSION: These data indicate that through binding to CCR-5, truncated RANTES derivatives that are devoid of detectable biological effects may represent candidates as drugs to protect both lymphocytes and macrophages from HIV- 1.

Special susceptibility to apoptosis of CD1a+ dendritic cell precursors differentiating from cord blood CD34+ progenitors.

We analyzed the effect of tumor necrosis factor (TNF)-alpha on the differentiation and viability of dendritic cells (DC) generated from cord blood CD34+ progenitors cultured for five days with GM-CSF, Flt-3 ligand (FL), and stem cell factor (SCF), and then with GM-CSF only [TNF(-) cultures]. Adding TNF-alpha from the start [TNF(+) cultures] potentiated progenitor cell proliferation and promoted early differentiation of CD1a+ DC precursors without affecting differentiation of CD14+ cells, which comprise bipotent precursors of DC and macrophages, nor of CD15+ granulocytic cells. Use of TNF-alpha was associated with increased cell mortality, which peaked on culture day 10 and mainly involved CD1a+ DC. Selective apoptosis of CD1a+ DC precursors was confirmed by showing that survival of day-7-sorted CD1a+CD14- cells from TNF(+) cultures was lower than that of CD1a-CD14+ cells. That similar findings were noted for sorted CD1a+CD14- cells of TNF(-) cultures, further cultured with GM-CSF without or with TNF-alpha, indicates that apoptosis of CD1a+ DC precursors was not induced by TNF-alpha. Apoptosis of CD1a+ DC precursors occurred after the cells had lost the capacity to incorporate bromodeoxyuridin. Finally, using higher GM-CSF concentrations or adding interleukin 3 (IL-3) improved viability of CD1a+ cells. Other cytokines, such as IL-4 and transforming growth factor (TGF)-beta1, were ineffective in this respect, though they promoted differentiation of CD1a+ DC. These results indicate that TNF-alpha promotes the differentiation of CD1a+ DC precursors, which display a high susceptibility to apoptosis that can be prevented by high concentrations of GM-CSF or use of IL-3, without affecting the differentiation of the CD14+ DC precursors.

Dendritic cells as the terminal stage of monocyte differentiation.

Monocytes (MO) cultured for > or =5 days with either macrophage-CSF (M-CSF) or granulocyte macrophage (GM)-CSF and IL-4 differentiated without concomitant proliferation into CD14+ macrophages (Mphi) or CD1a+ dendritic cells (DC), respectively. When adherent and nonadherent CD14high Mphi from M-CSF cultures were separated and cultured further in cytokine-free medium or with GM-CSF/IL-4, most cells from both fractions that were exposed to GM-CSF/IL-4 acquired CD1a expression and DC morphology and function. Conversely, GM-CSF/IL-4 withdrawal at day 5 and additional culture of sorted CD1a+ DC for 2 to 7 days in cytokine-free medium led to cells rapidly becoming adherent CD1a-CD14+ Mphi. Replacing GM-CSF/IL-4 with M-CSF hastened the conversion of DC to Mphi without increasing cell numbers. CD1a+CD14-CD83+ mature DC were induced by a > or =2-day exposure to MO-conditioned medium, LPS, or TNF-alpha/IL-1beta. Upon cytokine removal or culture with M-CSF, DC that had been pushed to maturation by conditioned medium or LPS remained stable or died in the new environment. TNF-alpha/IL-1beta-driven DC displayed heterogeneous CD83 expression and could thus be sorted into CD83high and CD83low/- cells; in cytokine-free medium or in M-CSF, most CD83low/- cells converted to Mphi, whereas most CD83high cells remained nonadherent CD1a+CD14- or died and thus appeared truly terminally differentiated. Hence, MO are precursors of Mphi as well as of DC, with each cell type having the capability to convert into the other until late in the differentiation/maturation process. Accordingly, the cytokine environment and the presence of differentiation and/or other stimulatory signals may be the "final decision-making factors" determining whether these cells will acquire DC or Mphi characteristics and function.

[Dendritic cells: a complex cellular system]. / Les cellules dendritiques: un système cellulaire complexe.

Dendritic cells (DC) are the most potent antigen-presenting cells. Thus, ex vivo antigen-pulsed DC are a potentially powerful tool to induce in vivo immunity against tumor-associated or viral antigens. Therefore, culture methods to generate high numbers of DC from bone marrow or blood CD34+ hematopoietic progenitor cells have recently been developed. These methods, which use different combinations of growth factor--mainly granulocyte/macrophage colony-stimulating factor (GM-CSF), tumor necrosis factor (TNF)-alpha and interleukin (IL)-4--make the characterization of DC obtained from CD34+ cells of different origins easier and allow to assess whether DC relate to a unique or distinct differentiation pathways. Monocytes and even macrophages can also directly differentiate into DC in the presence of GM-CSF and IL-4. This has to be reconciled with evidence supporting earlier branching off of the macrophage and DC lineages, and raises questions as to the identity of the latter lineage. Apart from DC of myeloid origin, DC may also originate from lymphoid progenitors. Because the capacity of DC to capture, process and present antigens is known to vary according to their differentiation stage, and lymphoid DC might behave differently from lymphoid DC in this respect, the definition of which type of DC to use for immunotherapy must be more precise, in order to avoid detrimental side effects or results. From a practical point of view, it is also necessary to define the most appropriate cytokine combinations and schedules thereof to optimize proliferation and differentiation of DC from different origins. These conditions should then be applied to generated DC for their efficient and safe use for clinical immunotherapy.