Pathways utilized by dendritic cells for binding, uptake, processing and presentation of antigens derived from HIV-1

The outcome following HIV infection depends on the nature and durability of the HIV-specific T cell response induced initially. The activation of protective T cell responses depends upon dendritic cells (DC), antigen-presenting cells which have the capacity to process and present viral antigens. DC pulsed with aldrithiol-2-inactivated HIV and delivered in vivo were reported to induce immune responses and promote virologic control in chronically HIV-1-infected subjects. To gain an understanding of this phenomenon, we characterized the steps involved in the presentation of antigens derived from aldrithiol-2-treated vs. infectious HIV-1 by DC. Antigen presentation, on both MHC class I and II, was independent of DC-specific ICAM-3-grabbing integrin, DEC-205 and macrophage mannose receptor, C-type lectins expressed by the DC. Inhibitor studies showed that presentation on MHC class I was dependent on viral fusion in a CD4/coreceptor-dependent manner, both at the cell surface and within endosomes, and access to the classical endosomal processing pathway. MHC class II presentation of HIV-associated antigens was dependent on active endocytosis, probably receptor-mediated, and subsequent degradation of virions in acidified endosomes in the DC. Our study brings forth new facts regarding the binding, uptake, and processing of chemically inactivated virions leading to efficient antigen presentation and should aid in the design of more effective HIV vaccines.     

Targeting antigen to bone marrow stromal cell‐2 expressed by conventional and plasmacytoid dendritic cells elicits efficient antigen presentation

Bone marrow stromal cell‐2 (BST‐2) has major roles in viral tethering and modulation of interferon production. Here we investigate BST‐2 as a receptor for the delivery of antigen to dendritic cells (DCs). We show that BST‐2 is expressed by a panel of mouse and human DC subsets, particularly under inflammatory conditions. The outcome of delivering antigen to BST‐2 expressed by steady state and activated plasmacytoid DC (pDC) or conventional CD8⁺ and CD8^? DCs was determined. T‐cell responses were measured for both MHC class I (MHCI) and MHC class II (MHCII) antigen presentation pathways in vitro. Delivering antigen via BST‐2 was compared with that via receptors DEC205 or Siglec‐H. We show that despite a higher antigen load and faster receptor internalisation, when antigen is delivered to steady state or activated pDC via BST‐2, BST‐2‐targeted activated conventional DCs present antigen more efficiently. Relative to DEC205, BST‐2 was inferior in its capacity to deliver antigen to the MHCI cross‐presentation pathway. In contrast, BST‐2 was superior to Siglec‐H at initiating either MHCI or MHCII antigen presentation. In summary, BST‐2 is a useful receptor to target with antigen, given its broad expression pattern and ability to access both MHCI and MHCII presentation pathways with relative efficiency.     

Redirecting soluble antigen for MHC class I cross‐presentation during phagocytosis

Peptides presented by MHC class I molecules are mostly derived from proteins synthesized by the antigen‐presenting cell itself, while peptides presented by MHC class II molecules are predominantly from materials acquired by endocytosis. External antigens can also be presented by MHC class I molecules in a process referred to as cross‐presentation. Here, we report that mouse dendritic cell (DC) engagement to a phagocytic target alters endocytic processing and inhibits the proteolytic activities. During phagocytosis, endosome maturation is delayed, shows less progression toward the lysosome, and the endocytosed soluble antigen is targeted for MHC class I cross‐presentation. The antigen processing in these arrested endosomes is under the control of NAPDH oxidase associated ROS. We also show that cathepsin S is responsible for the generation of the MHC class I epitope. Taken together, our results suggest that in addition to solid structure uptake, DC phagocytosis simultaneously modifies the kinetics of endosomal trafficking and maturation. As a consequence, external soluble antigens are targeted into the MHC class I cross‐presentation pathway.     

DC contact with HIV‐1‐infected cells leads to high levels of Env‐mediated virion endocytosis coupled with enhanced HIV‐1 Ag presentation

In HIV‐infected patients, DC are likely to interact with both cell‐free HIV and HIV‐infected cells. We were interested in investigating the mechanism of virus transmission occurring upon contact between HIV‐1‐infected cells and DC, as well as the consequences for HIV‐1 Ag‐presenting activity. By comparing mixed co‐cultures with trans‐well cultures, we observed that cell‐to‐cell contact strongly increased HIV‐1 Env‐mediated virion endocytosis in target DC. This endocytosis was independent of HIV‐1 tropism, de novo infection, HIV‐1 Env‐CD4‐dependent fusion, and immature DC activation/maturation. We also found that augmentation of HIV‐1 endocytosis was closely correlated with strong, Env‐dependent HIV‐1 Ag presentation by DC. Our results provide a better understanding of the mechanisms underlying the induction of the anti‐HIV adaptive immune response.     

Chaperone BAG6 is dispensable for MHC class I antigen processing and presentation

Antigen processing for direct presentation on MHC class I molecules is a multistep process requiring the concerted activity of several cellular complexes. The essential steps at the beginning of this pathway, namely protein synthesis at the ribosome and degradation via the proteasome, have been known for years. Nevertheless, there is a considerable lack of factors identified to function between protein synthesis and degradation during antigen processing. Here, we analyzed the impact of the chaperone BAG6 on MHC class I cell surface expression and presentation of virus-derived peptides. Although an essential role of BAG6 in antigen processing has been proposed previously, we found BAG6 to be dispensable in this pathway. Still, interaction of BAG6 and the model antigen tyrosinase was enhanced during proteasome inhibition pointing towards a role of BAG6 in antigen degradation. Redundant chaperone pathways potentially mask the contribution of BAG6 to antigen processing and presentation.     

Polyphenol administration impairs T‐cell proliferation by imprinting a distinct dendritic cell maturational profile

Currently little is known as to how nutritionally derived compounds may affect dendritic cell (DC) maturation and potentially prevent inappropriate inflammatory responses that are characteristic of chronic inflammatory syndromes. Previous observations have demonstrated that two polyphenols quercetin and piperine delivered through reconstituted oil bodies (ROBs‐QP) can influence DC maturation in response to LPS leading to a modulated inflammatory response. In the present study, we examined the molecular effects of ROBs‐QP exposure on DC differentiation in mice and identified a unique molecular signature in response to LPS administration that potentially modulates DC maturation and activity in inflammatory conditions. Following LPS administration, ROBs‐QP‐exposed DCs expressed an altered molecular profile as compared with control DCs, including cytokine and chemokine production, chemokine receptor repertoire, and antigen presentation ability. In vivo ROBs‐QP administration suppresses antigen‐specific T‐cell division in the draining lymph nodes resulting from a reduced ability to create stable immunological synapse. Our data demonstrate that polyphenols exposure can drive DCs toward a new anti‐inflammatory molecular profile capable of dampening the inflammatory response, highlighting their potential as complementary nutritional approaches in the treatment of chronic inflammatory syndromes.     

Rat cytomegalovirus infection depletes MHC II in bone marrow derived dendritic cells

While cytomegalovirus (CMV) infects and replicates in a multitude of cell types, the ability of the virus to replicate in antigen presenting cells (APCs) is believed to play a critical role in the viral dissemination and latency. CMV infection of APCs and manipulation of their function are important areas of investigation. CMV down regulation of MHC II is reportedly mediated by the HCMV proteins US2, US3, UL83, UL111a (vIL10) or through the induction of cellular IL10. In this study, we demonstrate that rat CMV (RCMV) significantly reduces MHC II expression neither by mechanisms that do not involve orthologues of the known HCMV genes nor by an increase in cellular IL10. Rat bone marrow derived dendritic cells (BMDC) were highly susceptible to infection with RCMV and a recombinant RCMV expressing eGFP. RCMV infection of BMDCs depleted both surface and intracellular MHC II to nearly undetectable levels as well as reduced surface expression of MHC I. The effect on MHC II only occurred in the infected GFP positive cells and is mediated by an immediate early or early viral gene product. Furthermore, treatment of uninfected immature DCs with virus-free conditioned supernatants from infected cells failed to down regulate MHC II. RCMV depletion of MHC II was sensitive to treatment with lysosomal inhibitors but not proteasomal inhibitors suggesting that the mechanism of RCMV-mediated down regulation of MHC II occurs through endocytic degradation. Since RCMV does not encode homologues of US2, US3, UL83 or UL111a, these data indicate a novel mechanism for RCMV depletion of MHC II.     

Simvastatin inhibits the MHC class II pathway of antigen presentation by impairing Ras superfamily GTPases

Statins are widely used hypocholesterolemic drugs that inhibit 3-hydroxy-3-methyl-glutaryl-coenzyme A reductase, a rate-limiting enzyme of the mevalonate pathway whose biosynthetic endproduct is cholesterol. As a result of this activity, statins may perturb the composition of cell membranes, resulting in lipid raft disruption. Furthermore, by inhibiting protein prenylation, a process also dependent on mevalonate, statins block membrane targeting and activity of small GTPases. Antigen uptake, processing and presentation involve the interplay of Rab and Rho family GTPases. Furthermore, lipid rafts have been implicated both in antigen internalization by the BCR and in MHC class II clustering at the immunological synapse. Here we have addressed the effects of simvastatin on antigen processing and presentation by human B cells and dendritic cells. The results show that simvastatin potently suppresses tetanus toxoid processing and presentation to CD4+ T cells by HLA-DR by inhibiting protein antigen uptake through both receptor-mediated endocytosis and macropinocytosis. This effect can be largely accounted for by defective prenylation of Rho and Rab GTPases in the absence of any measurable perturbation of lipid rafts. In addition, simvastatin was found to preferentially affect the invariant chain-dependent MHC class II pathway, thereby identifying this route of antigen processing and presentation as a selective target of statins.     

树突状细胞摄取和提呈颗粒化抗原的能力与颗粒载体的大小相关

目的：研究体外小鼠骨髓树突状细胞对2种不同大小bead-OVA复合物（0.04 μm bead和1.0μm bead）的摄取及class I途径抗原提呈能力。方法：以2h骨髓粘附细胞为前体细胞，用GM－CSF（1000U／ml）和IL－3（10ng/ml）培养5d，观察细胞对FITC标记的2种bead-OVA复合物的摄取，PMA、amiloride、cytochalasin D对摄取的抑制，以及细胞摄取后表达MHC分子和共刺激分子的情况，同时用OVA表位特异性T细胞杂交检测细胞摄取后通过class I途径活化CTL应答的能力。结果：树突状细胞对1．0μm bead-OVA的摄取明显高于对0．04μm bead-OVA，前者被上述3种抑制剂显著抑制，后者仅对amiloride和PMA抑制作用敏感，CCD无明显抑制作用。与摄取结果相反，0．04μm bead－OVA较1．0μm bead－OVA诱导更强的CD8细胞免疫应答，表型分析显示，细胞摄取0．04μm bead后，MHC分子和共刺激分子表达显著高于1．0μm的bead。结论：树突状细胞对2种bead的摄取能力和摄取机制不一样，0．04μm bead尽管摄取效率不如1．0μm bead，但通过class I途径提呈抗原的效率显著高于后者。     

RNAi screen for kinases and phosphatases that play a role in antigen presentation by dendritic cells

Effective CD8(+) T-cell responses against tumor or microbial antigens that are not directly expressed in antigen-presenting cells (APCs) depend on the cross-presentation of these antigens on MHC class I in APCs. To identify signaling molecules that regulate cross-presentation, we used lentiviral-based RNA interference to test the roles of hundreds of kinases and phosphatases in this process. Our study uncovered eight previously unknown genes, consisting of one positive and seven negative regulators of antigen cross-presentation. Depletion of Acvr1c, a type I receptor for TGF-β family of signaling molecules, led to an increase in CD80 and CD86 co-stimulator surface expression and secreted IL-12 in mouse bone marrow-derived DCs, as well as antigen-specific T-cell proliferation.     

Carbon monoxide impairs mitochondria‐dependent endosomal maturation and antigen presentation in dendritic cells

Heme‐oxygenase 1 (HO‐1) prevents T cell‐mediated inflammatory disease by producing carbon monoxide (CO) and impairing DC immunogenicity. However, the cellular mechanisms causing this inhibition are unknown. Here, we show that CO impairs mitochondrial function in DCs by reducing both the mitochondrial membrane potential and ATP production, and resembling the effect of a nonlethal dose of a classical mitochondria uncoupler carbonyl cyanide m‐chlorophenyl hydrazone (CCCP). Moreover, both CO and CCCP reduced cargo transport, endosome‐to‐lysosome fusion, and antigen processing, dampening the production of peptide‐MHC complexes on the surface of DCs. As a result, the inhibition of naive CD4⁺ T‐cell priming was observed. Furthermore, mitochondrial dysfunction in DCs also significantly reduced CD8⁺ T cell‐dependent type 1 diabetes onset in vivo. These results showed for the first time that CO interferes with T‐cell priming by blocking an unknown mitochondria‐dependent antigen‐processing pathway in mature DC. Interestingly, other immune functions in DCs such as antigen capture, cytokine secretion, costimulation, and cell survival relied on glycolysis, suggesting that oxidative phosphorylation might only play a key role for the maturation of antigen‐containing endosomes. In conclusion, CO produced by HO‐1 impairs antigen‐dependent inflammation by regulating DC immunogenicity by a mitochondria‐dependent mechanism.     

Polyubiquitination of lysine‐48 is an essential but indirect signal for MHC class I antigen processing

Peptides presented on major histocompatibility complex (MHC) class I molecules are generated via cytosolic proteolysis. However, the nature of the endogenous peptide precursors and the intracellular processing steps preceding protein degradation remain poorly defined. Here, we assessed whether ubiquitination is an essential signal for proteasomal cleavage of antigen substrates in human cells. Conversion into antigenic peptides occurred in the absence of any detectable N‐terminal ubiquitination of the model antigens, and did not require the presence of any of the four types, nor a minimum number of ubiquitinatable amino acids within the antigen substrate. However, the knockdown of ubiquitin, expression of a lysine 48 (K48) ubiquitin mutant, or inhibition of proteasome‐associated deubiquitinases significantly impaired antigen presentation. The results presented here are consistent with a model in which the binding of the antigen substrate by an adaptor protein leads to its K48‐polyubiquitination and the subsequent delivery of the antigen cargo for degradation by the 26S proteasome. Altogether, these findings show an important but indirect role of K48‐polyubiquitination in preproteasomal antigen sampling.     

Induction of immunosuppressive functions of dendritic cells in vivo by CD4+CD25+ regulatory T cells: role of B7-H3 expression and antigen presentation

Suppressive functions of CD4+CD25+ regulatory T cells (Treg) are mainly studied by their interaction with conventional T cells. However, there is evidence that Treg also interact with antigen-presenting cells (APC), leading to suppression of APC function in in vitro coculture systems. Studying the in vivo distribution of Treg after injection, we found that Treg are located in direct proximity to dendritic cells (DC) and affect their functional maturation status. After contact to Treg, DC up-regulate the inhibitory B7-H3 molecule and display reduced numbers of MHC-peptide complexes, leading to impaired T cell stimulatory function. When Treg-exposed DC were used to immunize animals against antigens, the DC failed to produce a robust immune response as compared to control DC. Thus, these data indicate that Treg are able to inhibit DC activation and produce an inhibitory phenotype of DC. Accordingly, Treg may recruit DC for the amplification of immunosuppression by restraining their maturation in vivo and inducing an immunosuppressive phenotype of DC.     

Alternative processing for MHC class I presentation by immature and CpG-activated dendritic cells

Exogenous proteins can be processed by antigen-presenting cells for the generation of MHC class I-restricted T cell responses. Where this occurs is not clear, although both transfer of internalized antigen into the cytosol and alternative processing in endolysosomes and phagosomes have been reported. Here we have studied the capacity of bone marrow-derived mouse myeloid dendritic cells (DC) to process the OVA protein for peptide presentation by H2-K(b). We have found that immature DC (iDC), both wild-type and transporter associated with antigen processing (TAP)-deficient cells, can transiently process OVA in a pathway which is resistant to inhibitors of the classical MHC class I pathway including the Golgi inhibitor Brefeldin A (BFA) and the proteasome inhibitor lactacystin. This alternative pathway is not found in subcultured DC with an intermediate maturity (imDC) or in resting, IL-3 expanded macrophages but can be re-expressed in imDC if these are activated by an immunostimulatory CpG oligonucleotide. Both iDC and CpG-activated DC were found to process OVA by regurgitation. In addition, we found that iDC secrete proteolytic enzymes into the supernatant, which can process OVA in the extracellular phase. These results suggest that multiple pathways exist for the processing of exogenous protein antigens into MHC class I-binding peptides.     

Alloantigen presentation by ethylcarbodiimide-treated dendritic cells induces T cell hyporesponsiveness, and prolongs organ graft survival

Ethylcarbodiimide (ECDI) couples soluble antigens (Ag) to lymphoid cells bestowing tolerizing potential. We examined whether ECDI-treated allogeneic dendritic cells (DC) could promote Ag-specific T cell unresponsiveness and prolong graft survival. Exposure of murine myeloid DC to ECDI did not affect surface immunophenotype but reduced their ability to cluster with T cells, enhanced their apoptotic death, and markedly reduced their allostimulatory activity. Anti-donor proliferative and cytotoxic T cell responses of mice primed with ECDI-treated DC were markedly inhibited. Secretion of both Th1 (IFNgamma) and Th2 cytokines (IL-5, IL-10) was suppressed. Cardiac allograft survival in mice preconditioned with a single injection of ECDI-DC was prolonged significantly. These results indicate that ECDI-treated DC promote T cell unresponsiveness to donor alloAgs and prolong transplant survival. The effects are not associated with sparing of Th2 responses, but may reflect inhibitory effects of apoptotic donor DC on host immune reactivity.     

Sustained cross‐presentation capacity of murine splenic dendritic cell subsets in vivo

An exclusive feature of dendritic cells (DCs) is their ability to cross‐present exogenous antigens in MHC class I molecules. We analyzed the fate of protein antigen in antigen presenting cell (APC) subsets after uptake of naturally formed antigen‐antibody complexes in vivo. We observed that murine splenic DC subsets were able to present antigen in vivo for at least a week. After ex vivo isolation of four APC subsets, the presence of antigen in the storage compartments was visualized by confocal microscopy. Although all APC subsets stored antigen for many days, their ability and kinetics in antigen presentation was remarkably different. CD8α⁺ DCs showed sustained MHC class I‐peptide specific CD8⁺ T‐cell activation for more than 4 days. CD8α^? DCs also presented antigenic peptides in MHC class I but presentation decreased after 48 h. In contrast, only the CD8α^? DCs were able to present antigen in MHC class II to specific CD4⁺ T cells. Plasmacytoid DCs and macrophages were unable to activate any of the two T‐cell types despite detectable antigen uptake. These results indicate that naturally occurring DC subsets have functional antigen storage capacity for prolonged T‐cell activation and have distinct roles in antigen presentation to specific T cells in vivo.     

Different cytokines regulate antigen uptake and presentation of a precursor dendritic cell line

Langerhans cells (LC) and dendritic cells (DC) need to be activated in order to perform their antigen-presenting function. In this study, we explored the influence of cytokines on the uptake and presentation of protein antigens by the retrovirally immortalized myeloid cell line FSDC. This cell line was generated from mouse fetal skin and was previously shown to have the characteristics of early DC precursors. Both FSDC and bone marrow-derived DC (BM-DC) were more effective in the pinocytosis of FITC-conjugated ovalbumin (FITC-OVA) and dextran (FITC-DX) than B cells or macrophages. Pretreatment of FSDC with granulocyte/macrophage colony-stimulating factor (GM-CSF) ± interleukin (IL)-4 enhanced the pinocytic uptake of FITC-OVA and FITC-DX, but did not induce antigen-presenting capacity. In contrast, untreated FSDC or FSDC pre-incubated with GM-CSF ± IL-4 suppressed T cell responses. Treatment of FSDC with IFN-γ reduced pinocytosis but increased the expression of MHC and co-stimulatory/adhesion molecules and promoted efficient presentation of OVA protein or peptide to the specific DO11.10 T cell hybridoma or to naive CD4⁺ T cells from DO11.10 TCR-transgenic mice. The results suggest that antigen uptake and antigen presentation in DC are regulated by different cytokine signals provided by the surrounding tissue.     

Blood‐stage Plasmodium berghei infection leads to short‐lived parasite‐associated antigen presentation by dendritic cells

Despite extensive evidence that Plasmodium species are capable of stimulating the immune system, the association of malaria with a higher incidence of other infectious diseases and reduced responses to vaccination against unrelated pathogens suggests the existence of immune suppression. Recently, we provided evidence that blood‐stage Plasmodium berghei infection leads to suppression of MHC class I‐restricted immunity to third party (non‐malarial) antigens as a consequence of systemic DC activation. This earlier study did not, however, determine whether reactivity was also impaired to MHC class II‐restricted third party antigens or to Plasmodium antigens themselves. Here, we show that while P. berghei‐expressed antigens were presented early in infection, there was a rapid decline in presentation within 4 days, paralleling impairment in MHC class I‐ and II‐restricted presentation of third party antigens. This provides important evidence that P. berghei not only causes immunosuppression to subsequently encountered third party antigens, but also rapidly limits the capacity to generate effective parasite‐specific immunity.     

Hantaviral mechanisms driving HLA class I antigen presentation require both RIG‐I and TRIF

Hantaviruses are emerging human pathogens. They induce an unusually strong antiviral response of human HLA class I (HLA‐I) restricted CD8⁺ T cells that may contribute to tissue damage and hantavirus‐associated disease. In this study, we analyzed possible hantaviral mechanisms that enhance the HLA‐I antigen presentation machinery. Upon hantavirus infection of various human and primate cell lines, we observed transactivation of promoters controlling classical HLA molecules. Hantavirus‐induced HLA‐I upregulation required proteasomal activity and was associated with increased TAP expression. Intriguingly, human DCs acquired the capacity to cross‐present antigen upon hantavirus infection. Furthermore, knockdown of TIR domain containing adaptor inducing IFN‐β or retinoic acid inducible gene I abolished hantavirus‐driven HLA‐I induction. In contrast, MyD88‐dependent viral sensors were not involved in HLA‐I induction. Our results show that hantaviruses strongly boost the HLA‐I antigen presentation machinery by mechanisms that are dependent on both retinoic acid inducible gene I and TIR domain containing adaptor inducing IFN‐β.