Retinoids regulate survival and antigen presentation by immature dendritic cells

Maturation of dendritic cells (DCs) is a critical step for the induction of an immune response. We have examined the role of retinoid nuclear receptor pathways in this process. Retinoids induce DC apoptosis, in the absence of inflammatory signals, through retinoic acid receptor (RAR)alpha/retinoic X receptor (RXR) heterodimers. In contrast, via a cross talk with inflammatory cytokines, retinoids increase DNA binding activity of nuclear factor kappaB in DCs, trigger membrane major histocompatibility complex class II and costimulatory molecule expression, induce the differentiation of immature DCs into mature DCs, and enhance antigen-specific T cell response. This maturation of DCs is mediated via a RXR-dependent/RAR-independent pathway and via an RARalpha/RXR pathway distinct from the one responsible for apoptosis. Apoptosis and activation, mediated through distinct nuclear retinoid receptor pathways, can be dissociated from each other with selective synthetic retinoids. We identify a novel cellular function for retinoids and suggest that selective retinoids might be of interest for controlling antigen presentation.     

Fate mapping reveals origin and dynamics of lymph node follicular dendritic cells

Follicular dendritic cells (FDCs) regulate B cell function and development of high affinity antibody responses but little is known about their biology. FDCs associate in intricate cellular networks within secondary lymphoid organs. In vitro and ex vivo methods, therefore, allow only limited understanding of the genuine immunobiology of FDCs in their native habitat. Herein, we used various multicolor fate mapping systems to investigate the ontogeny and dynamics of lymph node (LN) FDCs in situ. We show that LN FDC networks arise from the clonal expansion and differentiation of marginal reticular cells (MRCs), a population of lymphoid stromal cells lining the LN subcapsular sinus. We further demonstrate that during an immune response, FDCs accumulate in germinal centers and that neither the recruitment of circulating progenitors nor the division of local mature FDCs significantly contributes to this accumulation. Rather, we provide evidence that newly generated FDCs also arise from the proliferation and differentiation of MRCs, thus unraveling a critical function of this poorly defined stromal cell population.Follicular DCs (FDCs) represent the follicular stromal cell compartment in charge of organizing B cell homeostasis and immune responses in secondary lymphoid organs (SLOs), including the development and production of high affinity antibodies. In the absence of FDCs, B cells would not migrate, form follicles, or mount humoral immune responses (Cyster et al., 2000; Bajénoff et al., 2006; Allen and Cyster, 2008; Wang et al., 2011).FDCs were characterized decades ago as large follicle-associated dendritic-like cells displaying multiple long centrifugal processes in constant interaction with B cells (Szakal and Hanna, 1968; Chen et al., 1978; Klaus et al., 1980; Mandel et al., 1981). They secrete the B cell follicle homing chemokine CXCL13 and constitute a cellular scaffold for B cell migration (Ansel et al., 2000; Bajénoff et al., 2006). During immune responses, FDCs act as antigen-presenting and -retaining cells that remodel the primary follicular network into germinal centers (GCs), a specialized structure in which B cells proliferate, undergo somatic hypermutation, and carry out class switching (Allen et al., 2007; Garin et al., 2010; Victora and Nussenzweig, 2012). Elucidating FDC biology is thus critical for a better understanding of humoral immunity.Although several studies brought definitive evidence of the mesenchymal origin of FDCs (Endres et al., 1999; Muñoz-Fernández et al., 2006; Wilke et al., 2010; Krautler et al., 2012), the identity and localization of LN FDC progenitors remain unknown. Krautler et al. (2012) described a population of splenic perivascular mural cells that express Mfge8 (milk fat globule–EGF factor 8 protein) and NG2, respond to LTβR signals, depend on lymphoid tissue inducer (LTi) cells, and are capable of generating FDC networks. Importantly, the so-called mural pre-FDCs are absent from LN stroma based on published markers (not depicted). Using lineage tracing and transplant experiments, Castagnaro et al. (2013) reported that the Nkx2-5⁺ Islet-1⁺ mesenchymal lineage gave rise to splenic fibroblastic reticular cells (FRCs), FDCs, marginal reticular cell (MRCs), and mural cells but was not involved in the generation of LN and Peyer’s patch stroma. Although these studies identified the ontogenic precursors of splenic FDCs, they did not address the origin of LN FDCs. Therefore, LN and splenic FDCs appear to rely on different developmental mechanisms and caution should be paid when extrapolating conclusions obtained from one organ to the other.Shortly after birth, the very first BM-derived B cells invade neonatal LNs, triggering the primary development of lymphoid follicles (van Rees et al., 1985; Bajénoff and Germain, 2009). A few weeks later, follicles mature and accumulate FDCs associated in intricate 3D meshworks. Once established, FDC networks are not rigid matrices but are still able to undergo tremendous remodeling. For instance, upon inflammation, adult FDC networks rapidly remodel to support GC development but the cellular mechanisms underlying this crucial phase of FDC biology remain elusive. In summary, we still don’t know whether the initial establishment of the LN FDC network and its subsequent remodeling rely on the recruitment and/or the local proliferation of either mature FDCs or unknown precursors belonging to the FDC lineage.Why do we know so little about LN FDC biology? FDCs are rare, stellate, and highly interconnected cells, meant to function as large 3D networks that are very difficult to isolate and culture from nonmanipulated LNs (Muñoz-Fernández et al., 2006; Wilke et al., 2010; Usui et al., 2012). Therefore, in vitro methods only offer a limited understanding of the genuine immunobiology of FDCs in their complex native environment.The recent development of multicolor fate mapping systems based on Cre-lox technology has created new tools to study cell dynamics in situ (Livet et al., 2007; Snippert et al., 2010; Tabansky et al., 2013). Here, we used various multicolor fate-mapping systems to track LN FDCs in vivo and unravel key features of LN FDC ontogeny and remodeling during inflammation.     

Spatiotemporally separated antigen uptake by alveolar dendritic cells and airway presentation to T cells in the lung

Asthma pathogenesis is focused around conducting airways. The reasons for this focus have been unclear because it has not been possible to track the sites and timing of antigen uptake or subsequent antigen presentation to effector T cells. In this study, we use two-photon microscopy of the lung parenchyma and note accumulation of CD11b(+) dendritic cells (DCs) around the airway after allergen challenge but very limited access of these airway-adjacent DCs to the contents of the airspace. In contrast, we observed prevalent transepithelial uptake of particulate antigens by alveolar DCs. These distinct sites are temporally linked, as early antigen uptake in alveoli gives rise to DC and antigen retention in the airway-adjacent region. Antigen-specific T cells also accumulate in the airway-adjacent region after allergen challenge and are activated by the accumulated DCs. Thus, we propose that later airway hyperreactivity results from selective retention of allergen-presenting DCs and antigen-specific T cells in airway-adjacent interaction zones, not from variation in the abilities of individual DCs to survey the lung.     

Cytokines regulate proteolysis in major histocompatibility complex class II-dependent antigen presentation by dendritic cells

Endo/lysosomal proteases control two key events in antigen (Ag) presentation: the degradation of protein Ag and the generation of peptide-receptive major histocompatibility complex (MHC) class II molecules. Here we show that the proinflammatory cytokines tumor necrosis factor alpha and interleukin (IL)-1beta rapidly increase the activity of cathepsin (cat) S and catB in human dendritic cells (DCs). As a consequence, a wave of MHC class II sodium dodecyl sulfate stable dimer formation ensues in a catS-dependent fashion. In contrast, the antiinflammatory cytokine IL-10 renders DCs incapable of upregulating catS and catB activity and in fact, attenuates the level of both enzymes. Suppressed catS and catB activity delays MHC class II sodium dodecyl sulfate stable dimer formation and impairs Ag degradation. In DCs exposed to tetanus toxoid, IL-10 accordingly reduces the number of MHC class II-peptide complexes accessible to tetanus toxoid-specific T cell receptors, as analyzed by measuring T cell receptor downregulation in Ag-specific T cell clones. Thus, the control of protease activity by pro- and antiinflammatory cytokines is an essential feature of the Ag presentation properties of DCs.     

Enhanced antigen presentation and immunostimulation of dendritic cells using acid-degradable cationic nanoparticles.

Acid-degradable cationic nanoparticles encapsulating a model antigen (i.e., ovalbumin) were prepared by inverse microemulsion polymerization with acid-cleavable acetal cross-linkers. Incubation of these degradable nanoparticles with dendritic cells derived from bone marrow (BMDCs) resulted in the enhanced presentation of ovalbumin-derived peptides, as quantified by B3Z cells, a CD8+ T cell hybridoma. The cationic nature of the particles contributed to the increased surface endocytosis (or phagocytosis) observed with BMDCs, which is the first barrier to overcome for successful antigen delivery. The acid sensitivity of the particles served to direct more ovalbumin antigens to be processed into the appropriately trimmed peptide fragments and presented via the major histocompatibility complex (MHC) class I pathway following hydrolysis within the acidic lysosomes. It was also shown that adjuvant molecules such as unmethylated CpG oligonucleotides (CpG ODN) and anti-interleukin-10 oligonucleotides (AS10 ODN) could be co-delivered with the protein antigen for maximized cellular immune response.     

Constitutive presentation of a natural tissue autoantigen exclusively by dendritic cells in the draining lymph node

The major histocompatibility complex (MHC)-dependent presentation of processed tissue-specific self-antigens can contribute to either peripheral (extrathymic) tolerance or the differentiation of autoreactive T cells. Here, we have studied the MHC class II molecule presentation of gastric parietal cell (PC)-specific H(+)/K(+)-ATPase, which induces a destructive autoimmune gastritis in BALB/c mice lacking CD4(+) CD25(+) regulatory T cells. Immunofluorescence microscopy showed physical association of CD11c(+) dendritic cells (DCs) with PCs in the gastric mucosa. H(+)/K(+)-ATPase protein was found within vesicular compartments of a few CD11c(+) DCs only in the draining gastric lymph node (LN) and these antigen-containing DCs increased markedly in number with the onset of tissue destruction in autoimmune animals. Both CD8alpha(hi) and CD8alpha(lo) gastric DCs, but not peripheral or mesenteric DCs, showed evidence of constitutive in vivo processing and presentation of H(+)/K(+)-ATPase. These data provide direct support for a widely held model of local tissue antigen uptake and trafficking by DCs in normal animals and demonstrate that DCs in the draining LN can present a tissue-specific self-antigen under noninflammatory conditions without fully deleting autoreactive T cells or inducing active autoimmunity.     

Characterization of sheep afferent lymph dendritic cells and their role in antigen carriage

We have ablated peripheral lymph nodes in sheep and subsequently cannulated the pseudo-afferent lymphatic vessel that arises as a consequence of afferent lymphatic vessels reanastomosing with the former efferent duct. This technique allows the collection of lymph with a cellular composition that resembles true afferent fluid, and in particular, containing 1-10% dendritic cells. A 16-h collection of this lymph may contain between 10(6) and 10(7) dendritic cells. This dendritic cell population may be enriched to greater than 75% by a single-density gradient centrifugation step. We have generated a mAb that recognizes sheep CD1. This monoclonal not only reacts with afferent dendritic cells, but with dendritic cells in the skin and paracortical T cell areas of lymph nodes. The expression of CD1 suggests afferent dendritic cells are related to skin Langerhans' cells and other dendritic cells that act as accessory cells for T cell responses. Consistent with this is the high level of expression by dendritic cells of molecules involved in antigen recognition by T cells, including MHC class I and class II. Afferent dendritic cells express high levels of the cellular adhesion molecule LFA-3, and at the same time express a ligand for this molecule, namely CD2. The accessory functions of afferent dendritic cells resemble those displayed by mature Langerhans' cells and by lymph node interdigitating cells. These include clustering with resting T cells and stimulating their proliferation in a primary response to antigen. Afferent dendritic cells are capable of acquiring soluble protein antigen in vivo or in vitro and presenting the material directly to autologous T cells in an antigen-specific manner. We conclude that afferent dendritic cells represent a lymph-borne Langerhans' cell involved in antigen carriage to the lymph node.     

Plasmid DNA adsorbed onto cationic microparticles mediates target gene expression and antigen presentation by dendritic cells

Dendritic cells (DC) play a key role in antigen presentation and activation of specific immunity. Much current research focuses on harnessing the potency of DC for vaccines, gene therapy, and cancer immunotherapy applications. However, DC are not readily transfected in vitro by traditional nonviral techniques. A novel DNA vaccine formulation was used to determine if DC are transfected in vitro. The formulation consists of plasmid DNA adsorbed on to cationic microparticles composed of the biodegradable polymer polylactide-co-glycolide (PLG) and the cationic surfactant, cetyltrimethylammonium bromide (CTAB). Using preparations of fluorescent-labeled plasmid DNA formulated on PLG-CTAB microparticles to study internalization by macrophages and dendritic cells in vitro and in vivo, we found that most, but not all, of the fluorescence was concentrated in endosomal compartments. Furthermore, uptake of plasmid DNA encoding HIV p55 gag adsorbed to PLG-CTAB microparticles by murine bone marrow-derived dendritic cells resulted in target gene expression, as detected by RT-PCR. The antigen was subsequently processed and presented, resulting in stimulation of an H-2kd-restricted, gag-specific T cell hybridoma. Activation of the hybridoma, detected by IL-2 production, was dose-dependent in the range of 0.1-20 microg DNA (10-2000 microg PLG) and was sustained up to 5 days after transfection. Thus, adsorption of plasmid DNA on PLG-CTAB microparticles provides a potentially useful nonviral approach for in vitro transfection of dendritic cells. Gene Therapy (2000) 7, 2105-2112.     

奥美沙坦对大鼠树突细胞抗原递呈功能作用的研究

目的:探讨奥美沙坦对大鼠树突细胞（dendritic cells,DCs）抗原递呈功能的影响。方法:取雌性Lewis大鼠髓源DCs,加入奥美沙坦（终浓度10 μmol/L）和等体积的DMSO,分别记为奥美沙坦修饰的DCs（olmesartan modified dendritic cells,OLM-DCs）和未经奥美沙坦修饰的DCs（control DCs,Con-DCs）。使用流式细胞仪分别测定DCs表面CD80、CD86和MHC Ⅱ平均荧光强度（mean fluorescence intensity, MFI）及DCs中IL-10和TGF-β的表达。OLM-DCs和Con-DCs分别与卵白蛋白（OVA）致敏的淋巴结CD4 + T细胞共培养,流式细胞仪检测T淋巴细胞增殖,ELISA检测细胞培养上清液中IFN-γ、IL-10水平。 结果:奥美沙坦抑制了DCs表面MHC Ⅱ分子的表达,促进了IL-10的产生。与Con-DCs组比较,OLM-DCs抑制了T淋巴细胞增殖反应和IFN-γ的产生。结论:在体外,奥美沙坦能够诱导产生耐受性DCs,后者能够抑制T淋巴细胞增殖、抑制Th1细胞因子的水平。     

Regulation of lymph node vascular growth by dendritic cells

Lymph nodes grow rapidly and robustly at the initiation of an immune response, and this growth is accompanied by growth of the blood vessels. Although the vessels are critical for supplying nutrients and for controlling cell trafficking, the regulation of lymph node vascular growth is not well understood. We show that lymph node endothelial cells begin to proliferate within 2 d of immunization and undergo a corresponding expansion in cell numbers. Endothelial cell proliferation is dependent on CD11c+ dendritic cells (DCs), and the subcutaneous injection of DCs is sufficient to trigger endothelial cell proliferation and growth. Lymph node endothelial cell proliferation is dependent on vascular endothelial growth factor (VEGF), and DCs are associated with increased lymph node VEGF levels. DC-induced endothelial cell proliferation and increased VEGF levels are mediated by DC-induced recruitment of blood-borne cells. Vascular growth in the draining lymph node includes the growth of high endothelial venule endothelial cells and is functionally associated with increased cell entry into the lymph node. Collectively, our results suggest a scenario whereby endothelial cell expansion in the draining lymph node is induced by DCs as part of a program that optimizes the microenvironment for the ensuing immune response.     

Salmonella-induced apoptosis of infected macrophages results in presentation of a bacteria-encoded antigen after uptake by bystander dendritic cells

Salmonella typhimurium is a gram-negative bacterium that survives and replicates inside vacuolar compartments of macrophages. Infection of macrophages with S. typhimurium grown under conditions allowing expression of the type III secretion system results in apoptotic death of the infected cells. Here, we show that infection of bone marrow-derived macrophages (MPhi) with wild-type S. typhimurium 14028 results in presentation of epitopes derived from a bacteria-encoded antigen on major histocompatibility complex (MHC) class I and MHC class II molecules after internalization of apoptotic MPhi by bystander dendritic cells (DCs). In contrast, infection of MPhi with the phoP constitutive mutant strain CS022, which does not induce apoptosis in infected MPhi, does not result in presentation of a bacteria-derived antigen by bystander DCs unless the infected MPhi are induced to undergo apoptosis by treatment with lipopolysaccharide and ATP. DCs appear to be unique in their ability to present antigens derived from MPhi induced to undergo apoptosis by Salmonella, as bystander MPhi are not capable of presenting the bacteria-derived antigen despite the fact that they efficiently internalize the apoptotic cells. These data suggest that apoptosis induction by bacterial infection of MPhi may not be a quiescent death that allows the bacteria to escape recognition by the immune system, but rather may contribute to an antimicrobial immune response upon engulfment by bystander DCs.     

累及全身淋巴结的滤泡树突状细胞肉瘤临床病理观察

目的 探讨滤泡树突状细胞肉瘤(FDCS)的临床病理学特征、生物学行为、治疗和预后.方法 对1例累及全身多处淋巴结的FDCS进行临床病理学分析、免疫组化染色及EBV编码的小RNA原位杂交检测,并结合文献进行讨论.结果 患者病变累及全身多处淋巴结,伴随全身荨麻疹和关节肿痛.瘤组织排列成束状、席纹状.瘤细胞胞膜欠清,胞质淡伊红染,胞核卵圆形,有异型,核膜清晰,呈空泡状,核仁明显,可见病理性核分裂象2～4个/10HPF.瘤组织中散在少量淋巴细胞、浆细胞和嗜酸性粒细胞.免疫组化瘤细胞clusterin、SNA和vimentin弥漫(+),CD21+35和S-100局部(+),CD1a、desmin、CK8/18和CD68(-).EBER原位杂交(-).结论 滤泡树突状细胞肉瘤是罕见的起源于淋巴结和结外淋巴组织间质细胞的恶性肿瘤,诊断依赖于组织病理学和免疫组化.     

Specific migratory dendritic cells rapidly transport antigen from the airways to the thoracic lymph nodes

Antigen transport from the airway mucosa to the thoracic lymph nodes (TLNs) was studied in vivo by intratracheal instillation of fluorescein isothiocyanate (FITC)-conjugated macromolecules. After instillation, FITC(+) cells with stellate morphology were found deep in the TLN T cell area. Using flow cytometry, an FITC signal was exclusively detected in CD11c(med-hi)/major histocompatibility complex class II (MHCII)(hi) cells, representing migratory airway-derived lymph node dendritic cells (AW-LNDCs). No FITC signal accumulated in lymphocytes and in a CD11c(hi)MHCII(med) DC group containing a CD8 alpha(hi) subset (non-airway-derived [NAW]-LNDCs). Sorted AW-LNDCs showed long MHCII(bright) cytoplasmic processes and intracytoplasmatic FITC(+) granules. The fraction of FITC(+) AW-LNDCs peaked after 24 h and had reached baseline by day 7. AW-LNDCs were depleted by 7 d of ganciclovir treatment in thymidine kinase transgenic mice, resulting in a strong reduction of FITC-macromolecule transport into the TLNs. Compared with intrapulmonary DCs, AW-LNDCs had a mature phenotype and upregulated levels of MHCII, B7-2, CD40, and intracellular adhesion molecule (ICAM)-1. In addition, sorted AW-LNDCs from FITC-ovalbumin (OVA)-instilled animals strongly presented OVA to OVA-TCR transgenic T cells. These results validate the unique sentinel role of airway DCs, picking up antigen in the airways and delivering it in an immunogenic form to the T cells in the TLNs.     

Major histocompatibility complex class II presentation of cell-associated antigen is mediated by CD8alpha+ dendritic cells in vivo

Antigen-specific B cells express major histocompatibility complex class II and can present antigen directly to T cells. Adoptive transfer experiments using transgenic B and T cells demonstrated that antigen-specific B cells can also efficiently transfer antigen to another cell for presentation to T cells in vivo. To identify the antigen-presenting cell that receives antigens from B cells, a strategy was developed to follow the traffic of B cell-derived proteins in vivo. B cells were labeled with the fluorescent dye CFSE and loaded with antigen, before adoptive transfer into recipient mice. Populations of splenocytes from the recipient mice were later assayed for the presence of fluorescent proteins and for the ability to activate T cells. A small number of CD8alpha+CD4-CD11b(lo) dendritic cells (DCs) contain proteins transferred from B cells and these DCs effectively present antigens derived from the B cells to T cells. The results suggest that CD8alpha+ DCs sample the cells and membranes in their environment for presentation to T cells circulating through the T cell zone. This function of CD8alpha+ DCs may be relevant to the priming of an immune response or the induction of T cell tolerance.     

MHC class II presentation of endogenously expressed antigens by transfected dendritic cells

Dendritic cells (DC) present immunogenic epitopes of antigens in the context of MHC class I and class II molecules in association with costimulatory molecules, and efficiently activate both cytotoxic T cells and T helper cells. Gene modified DC expressing antigen encoding cDNA represent a particularly attractive approach for the immunotherapy of disease. We previously described a gene delivery system for DC based on receptor-mediated endocytosis of ligand/polyethylenimine (PEI) DNA transfer complexes that target cell surface receptors which are abundantly expressed on DC. Employing this gene delivery system, DC were generated that express chicken ovalbumin (OVA) cDNA as a model antigen and introduce antigen into the MHC class I presentation pathway. We demonstrate here that modification of OVA cDNA as transferrin receptor (TfR) or invariant chain (Ii) fusions effectively generate MHC class II specific immune responses in addition to MHC class I responses. TfR-OVA contains the membrane anchoring region of transferrin receptor and represents a membrane-bound form of OVA for access to the MHC class II compartment. Ii-OVA fusions directly target the MHC class II processing pathway. Thus, modification of antigen encoding cDNA represents a convenient and effective means to direct antigens to MHC class II presentation and thus to generate T cell help.     

Antigen acquisition by dendritic cells: intestinal dendritic cells acquire antigen administered orally and can prime naive T cells in vivo

In the rat, mesenteric lymphadenectomy allows collection of dendritic cells (DC) derived from the small intestine after cannulation of the thoracic duct. We prepared rats this way and administered antigens by oral feeding or intraintestinal injection. DC enriched from the thoracic duct lymph collected over the first 24 h from these animals are able to stimulate sensitized T cells in vitro and to prime popliteal lymph node CD4+ T cells after footpad injection, while B and T cells from the same thoracic duct lymph are inert in priming. 500 or less DC pulsed in vitro with antigen can prime T cells in vivo, whereas 100 times more B cells or macrophages pulsed in vitro are quite inert. 1 mg of ovalbumin administered orally is sufficient to load DC for in vivo priming of T cells. Antigen could not be detected directly in DC but was present in macrophages in the lamina propria. Direct presentation of antigen by DC to T cells was demonstrated by injecting F1 recipients with parental DC and showing restriction of T cell sensitization to the major histocompatibility complex of the injected DC. Antigen-bearing DC do not induce a detectable primary antibody response but a small secondary antibody response can be detected after a boosting injection. These results show that acquisition of antigens by DC in the intestine is very similar to what occurs in vitro or in other tissues, suggesting that there may be no special difference in antigen handling at mucosal surfaces. One implication of these results is that hypotheses designed to explain oral tolerance must take into account the presence of immunostimulatory, antigen-bearing DC in animals that have received oral antigens.     

MHC class II antigen-bearing dendritic cells in pulmonary tissues of the rat. Regulation of antigen presentation activity by endogenous macrophage populations

Collagenase digestion of tissue slices from perfused, lavaged SPF rat lung released approximately 10(8) viable mononuclear cells per gram tissue, which comprised 35% T lymphocytes and up to 26% macrophages. A subset of these cells that were Ia+, surface Ig-, nonadherent, FcR- and of ultra low density (putative dendritic cells [DC]), presented protein antigen to immune T cells in vitro, and this function was inhibited by the presence of low numbers of endogenous adherent, FcR+ cells (putative macrophages). APCs were also identified in digests from tracheal epithelium, and were shown to bind antigen in immunogenic form as a result of natural (inhalation) exposure in vivo. Immunoperoxidase staining of frozen sections revealed populations of strongly Ia+ cells with prominent DC-like morphology within the alveolar septal walls and the tracheal epithelium; in both areas, they were closely associated with pleiomorphic cells that expressed macrophage surface markers. We accordingly postulate that interactions between Ia+ antigen-presenting DCs and endogenous tissue macrophages play an important role in regulating T cell activity in the respiratory tract.     

Adenoviral transgene ubiquitination enhances mouse immunization and class I presentation by human dendritic cells

Therapeutic vaccination aims at a strong stimulation of antigen-specific CD8(+) T-cells, so that they differentiate into effectors active in vivo against antigenic targets. Two adenovirus vectors (Ad) encoding two HLA-A*0201-restricted HIV epitope sequences (pol 476 and pol 589) were constructed. The Ad differ by the presence or absence of a ubiquitin monomer sequence (AdUb(+) and AdUb(-)). The effect of transgene product ubiquitination was analyzed on (1) in vivo, the immunization of Ad vaccinated HLA-A*0201 humanized HHD mice and (2) in vitro, the presentation of the transgene encoded peptides by transduced human dendritic cells (DC). In vivo, we found that immunization of humanized HHD mice with AdUb(+) elicited a transgene product-specific interferon (INF)-gamma CD8(+) T-cell response detectable by enzyme-linked immunospot (ELISPOT), whereas the AdUb(-) construction did not. Antigen-specific cytotoxic T lymphocytes (CTL) were also generated in HHD mice immunized with AdUb(+) and not with AdUb(-). In vitro, using human AdUb(+)-transduced DC, a sizeable expansion of pol 476 and pol 589 tetramer positive CD8(+) T cells as well as CD8(+) CTL were obtained in healthy donors. Compared to AdUb(-)-transduced DC, AdUb(+)-transduced DC triggered a higher number of pol 476-specific IFN-gamma-secreting CD8(+) T cells. In agreement, AdUb(+) transduced DC, used as target in a (51)Cr-release assay, were more efficiently lysed by peptide-specific CTL than AdUb(-)-transduced DC. In conclusion, the addition of an ubiquitin sequence to the adenoviral transgene, used as an antigen source, resulted in both in vivo enhanced CD8(+) T-cell immunogenicity in HHD mice and in vitro increased HLA class I-restricted presentation of encoded peptides by human DC.