The toll-like receptor agonist imiquimod is active against prions.

Using a yeast-based assay, a previously unsuspected antiprion activity was found for imiquimod (IQ), a potent Toll-like receptor 7 (TLR7) agonist already used for clinical applications. The antiprion activity of IQ was first detected against yeast prions [PSI (+) ] and [URE3], and then against mammalian prion both ex vivo in a cell-based assay and in vivo in a transgenic mouse model for prion diseases. In order to facilitate structure-activity relationship studies, we conducted a new synthetic pathway which provides a more efficient means of producing new IQ chemical derivatives, the activity of which was tested against both yeast and mammalian prions. The comparable antiprion activity of IQ and its chemical derivatives in the above life forms further emphasizes the conservation of prion controlling mechanisms throughout evolution. Interestingly, this study also demonstrated that the antiprion activity of IQ and IQ-derived compounds is independent from their ability to stimulate TLRs. Furthermore, we found that IQ and its active chemical derivatives inhibit the protein folding activity of the ribosome (PFAR) in vitro.

TLR3 as a biomarker for the therapeutic efficacy of double-stranded RNA in breast cancer.

The discovery of a targeted therapeutic compound along with its companion predictive biomarker is a major goal of clinical development for a personalized anticancer therapy to date. Here we present evidence of the predictive value of TLR3 expression by tumor cells for the efficacy of Poly (A:U) dsRNA in 194 breast cancer patients enrolled in a randomized clinical trial. Adjuvant treatment with double-stranded RNA (dsRNA) was associated with a significant decrease in the risk of metastatic relapse in TLR3 positive but not in TLR3-negative breast cancers. Moreover, we show the functional relevance of TLR3 expression by human tumor cells for the antitumor effects mediated by dsRNA in several preclinical mouse models carried out in immunocompromised animals. These 2 independent lines of evidence relied upon the generation of a novel tool, an anti-TLR3 antibody (40F9.6) validated for routine detection of TLR3 expression on paraffin-embedded tissues. Altogether, these data suggest that dsRNA mediates its therapeutic effect through TLR3 expressed on tumor cells, and could therefore represent an effective targeted treatment in patients with TLR3-positive cancers.

TLR3 and Rig-like receptor on myeloid dendritic cells and Rig-like receptor on human NK cells are both mandatory for production of IFN-gamma in response to double-stranded RNA.

Cross-talk between NK cells and dendritic cells (DCs) is critical for the potent therapeutic response to dsRNA, but the receptors involved remained controversial. We show in this paper that two dsRNAs, polyadenylic-polyuridylic acid and polyinosinic-polycytidylic acid [poly(I:C)], similarly engaged human TLR3, whereas only poly(I:C) triggered human RIG-I and MDA5. Both dsRNA enhanced NK cell activation within PBMCs but only poly(I:C) induced IFN-gamma. Although myeloid DCs (mDCs) were required for NK cell activation, induction of cytolytic potential and IFN-gamma production did not require contact with mDCs but was dependent on type I IFN and IL-12, respectively. Poly(I:C) but not polyadenylic-polyuridylic acid synergized with mDC-derived IL-12 for IFN-gamma production by acting directly on NK cells. Finally, the requirement of both TLR3 and Rig-like receptor (RLR) on mDCs and RLRs but not TLR3 on NK cells for IFN-gamma production was demonstrated using TLR3- and Cardif-deficient mice and human RIG-I-specific activator. Thus, we report the requirement of cotriggering TLR3 and RLR on mDCs and RLRs on NK cells for a pathogen product to induce potent innate cell activation.

Human Langerhans cells express a specific TLR profile and differentially respond to viruses and Gram-positive bacteria.

Dendritic cells (DC) are APCs essential for the development of primary immune responses. In pluristratified epithelia, Langerhans cells (LC) are a critical subset of DC which take up Ags and migrate toward lymph nodes upon inflammatory stimuli. TLR allow detection of pathogen-associated molecular patterns (PAMP) by different DC subsets. The repertoire of TLR expressed by human LC is uncharacterized and their ability to directly respond to PAMP has not been systematically investigated. In this study, we show for the first time that freshly purified LC from human skin express mRNA encoding TLR1, TLR2, TLR3, TLR5, TLR6 and TLR10. In addition, keratinocytes ex vivo display TLR1-5, TLR7, and TLR10. Accordingly, highly enriched immature LC efficiently respond to TLR2 agonists peptidoglycan and lipoteichoic acid from Gram-positive bacteria, and to dsRNA which engages TLR3. In contrast, LC do not directly sense TLR7/8 ligands and LPS from Gram-negative bacteria, which signals through TLR4. TLR engagement also results in cytokine production, with marked differences depending on the PAMP detected. TLR2 and TLR3 ligands increase IL-6 and IL-8 production, while dsRNA alone stimulates TNF-alpha release. Strikingly, only peptidoglycan triggers IL-10 secretion, thereby suggesting a specific function in tolerance to commensal Gram-positive bacteria. However, LC do not produce IL-12p70 or type I IFNs. In conclusion, human LC are equipped with TLR that enable direct detection of PAMP from viruses and Gram-positive bacteria, subsequent phenotypic maturation, and differential cytokine production. This implies a significant role for LC in the control of skin immune responses.

Nucleic acid agonists for Toll-like receptor 7 are defined by the presence of uridine ribonucleotides.

Toll-like receptor 7 (TLR7) mediates innate responses by responding to viral RNA in endocytic compartments. However, the molecular pattern recognised by TLR7 and whether it differs between RNA of viral and self origin remains unclear. Here, we identify nucleic acids that act as TLR7 agonists for mouse and human cells. We show that uridine and ribose, the two defining features of RNA, are both necessary and sufficient for TLR7 stimulation, and that short single-stranded RNA (ssRNA) act as TLR7 agonists in a sequence-independent manner as long as they contain several uridines in close proximity. Consistent with the notion that TLR7 lacks specificity for sequence motifs, we show that it is triggered equally efficiently by viral or self RNA delivered to endosomes. Our results support the notion that TLR7 recognises uracil repeats in RNA and that it discriminates between viral and self ligands on the basis of endosomal accessibility rather than sequence.

MIP-3alpha/CCL20 in renal transplantation and its possible involvement as dendritic cell chemoattractant in allograft rejection.

Graft-infiltrating dendritic cells (DC) and alloreactive T lymphocytes play a critical role in renal allograft rejection. Renal proximal tubular epithelial cells (TEC) are considered as active players in the attraction of leukocytes during renal inflammatory responses. Macrophage inflammatory protein (MIP)-3alpha/CCL20 is a major chemokine expressed by epithelial cells that attracts immature DC. In the present study, we present evidence that also the transplanted kidney can be a major source of MIP-3alpha/CCL20. Renal transplant recipients with rejection showed significantly increased excretion of urinary MIP-3alpha/CCL20 that correlated with transplant function. The tubular staining for MIP-3alpha/CCL20 in renal biopsies of patients with rejection as well as in vitro studies with primary human TEC indicated that TEC might be responsible for the increased urinary MIP-3alpha/CCL20. Furthermore, MIP-3alpha/CCL20 produced by activated TEC was highly potent in the attraction of CD1a+CD34+-derived DC precursors. These data suggest a role for MIP-3alpha/CCL20 in amplification of the immune response during renal allograft rejection by attraction of CCR6+ inflammatory cells, which may include DC, to the site of inflammation.

TNF-alpha enhances phenotypic and functional maturation of human epidermal Langerhans cells and induces IL-12 p40 and IP-10/CXCL-10 production.

Dendritic cells (DC) play a central role in immunity/tolerance decision, depending on their activation/maturation state. TNF-alpha is largely produced in the skin under inflammatory conditions. However, it still remains to be defined how TNF-alpha modulates the activation status of human LC, the most specialized DC controlling skin immunity. Here, we reported that fresh immature LC, highly purified from healthy human skin and exposed for two days to TNF-alpha under serum-free conditions, expressed up-regulated level of co-stimulatory molecules (CD40, CD54, CD86), maturation markers (CD83, DC-LAMP), CCR7 lymph node homing receptor, and down-regulated Langerin level, in a dose-dependent manner. This mature phenotype is closely associated with enhanced LC allostimulatory capacity. Furthermore, TNF-alpha significantly increased the number of viable LC and decreased their spontaneous apoptosis. More importantly, TNF-alpha induced LC to produce both IFN-gamma-inducible-protein IP-10/CXCL10, a Th1-attracting chemokine and IL-12 p40. Bioactive IL-12 p70 was never detected, even after additional CD40 stimulus. The results implicate LC as an effective target through which TNF-alpha may up- or down-regulate the inflammatory skin reactions.

Breast carcinoma cells promote the differentiation of CD34+ progenitors towards 2 different subpopulations of dendritic cells with CD1a(high)CD86(-)Langerin- and CD1a(+)CD86(+)Langerin+ phenotypes.

Primary breast carcinoma are frequently infiltrated by dendritic cells (DC). The mechanisms involved in the localization and status of activation of DC within primary breast carcinoma were investigated. CCL20/MIP3alpha, a chemokine involved in immature DC and their precursors attraction, was detected by immunohistochemistry on cryopreserved tissue sections of primary breast tumors and by ELISA and biological assay in metastatic effusion fluids from breast cancer patients but not from other tumors. In vitro, irradiated breast carcinoma cell lines (BCC) as well as their conditioned media promoted CD34+ cell differentiation into CD1a+ Langerhans cells (LC) precursors as early as day 6, while at day 12, 2 different CCR6+ subpopulations of DC with a Langerhans cell (CD1a(+)Langerin(+)CD86+) and an immature DC (CD1a(high)Langerin-CD86(-)HLA-DR(low)CD40(low)) phenotype were observed. This phenomenon was partly driven by a TGFbeta-dependent mechanism since a pan TGFbeta polyclonal antibody completely blocks BCC-induced LC differentiation and partly reduces immature DC development. These DC failed to maturate in response to sCD40L or LPS stimuli and CD1a(high)Langerin(-)CD86- cells have a reduced T-cell stimulatory capacity in MLR experiments. The absolute number of T cells was reduced by 50% in both the CD4+ or CD8+ compartments, these T cells expressing lower levels of the CD25 Ag and producing less IFNgamma. These results show that breast carcinoma cells produce soluble factors, which may attract DC and their precursors in vivo, and promote the differentiation of the latter into LC and immature DC with altered functional capacities. The infiltration of BCC by these altered DC may contribute to the impaired immune response against the tumor.

In vivo manipulation of dendritic cell migration and activation to elicit antitumour immunity.

Two approaches have been pursued to elicit antitumour immunity: (i) induce recruitment of immature dendritic cells or their precursors at a site of antigen delivery, and (ii) induce activation of tumour-infiltrating dendritic cells (DCs). The recruitment of selected DC subtype conditions the class of the immune response. Each immature DC population displays a unique spectrum of chemokine responsiveness. For examples, Langerhans cells (LCs) migrate selectively in response to CCL20/MIP-3alpha (through CCR6), blood CD11c+ DC to MCP chemokines (through CCR2). All these chemokines are inducible in response to inflammatory stimuli. CCL20/MIP-3alpha in particular is only detected within inflamed epithelium, at the site of antigen entry, which is infiltrated by immature DCs. Furthermore, to reach the site of injury, sequential responsiveness might operate, blood DC precursors are recruited by a set of chemokines (MIP, MCP) while within the tissue other chemokines will direct their navigation (CCL20/MIP-3alpha). Of interest, when injected in vivo together with antigen, MCP-4/CCL13, but not CCL20/MIP-3alpha, recruits blood monocytes or blood DC precursors that promptly differentiate into typical DCs and that improve antitumour immune responses. After antigen uptake, DCs acquire, upon maturation, responsiveness to CCR7 ligands (CCL21/SLC/6Ckine, CCL19/ELC/MIP-3beta) due to receptor up-regulation. In particular, in the periphery, CCL21/SLC/6Ckine expressed by lymphatic vessels may direct into the lymph stream, antigen-loaded maturing DCs leaving the site of infection; while within lymph-node, CCL21/SLC/6Ckine plays a critical role in the entry of naïve T cells from the blood through HEV. In regard to its central role, we decided to investigate whether the expression of CCL21/SLC/6Ckine in tumour may lead to antitumour immune responses. C26 colon carcinoma tumour cell line transduced with CCL21/SLC/6Ckine showed reduced tumorigenicity when injected in vivo into immunocompetent mice. The protection was CD8 dependent and associated with an important intratumoral infiltration of DCs. Most tumour infiltrating DCs (TIDCs) had an immature phenotype, were able to present TAA in the context of MHC class I, but were refractory to stimulation with the combination of LPS, IFNgamma and anti-CD40 antibody. TIDC paralysis could be reverted, however, by in vitro or in vivo stimulation with the combination of a CpG immunostimulatory sequence and an anti-interleukin 10 receptor (IL10R) antibody. CpG or anti-IL10R alone were inactive in TIDC, while CpG triggered activation in normal DC. In particular, CpG plus anti-IL10R enhanced the TAA-specific immune response and triggered de novo IL-12 production. Subsequently, CpG plus anti-IL10R treatment showed robust antitumour therapeutic activity exceeding by far that of CpG alone, and elicited antitumour immune memory.

The inducible CXCR3 ligands control plasmacytoid dendritic cell responsiveness to the constitutive chemokine stromal cell-derived factor 1 (SDF-1)/CXCL12.

The recruitment of selected dendritic cell (DC) subtypes conditions the class of the immune response. Here we show that the migration of human plasmacytoid DCs (pDCs), the blood natural interferon alpha-producing cells, is induced upon the collective action of inducible and constitutive chemokines. Despite expression of very high levels of CXCR3, pDCs do not respond efficiently to CXCR3 ligands. However, they migrate in response to the constitutive chemokine stromal cell-derived factor 1 (SDF-1)/CXCL12 and CXCR3 ligands synergize with SDF-1/CXCL12 to induce pDC migration. This synergy reflects a sensitizing effect of CXCR3 ligands, which, independently of a gradient and chemoattraction, decrease by 20-50-fold the threshold of sensitivity to SDF-1/CXCL12. Thus, the ability of the constitutive chemokine SDF-1/CXCL12 to induce pDC recruitment might be controlled by CXCR3 ligands released during inflammation such as in virus infection. SDF-1/CXCL12 and the CXCR3 ligands Mig/CXCL9 and ITAC/CXCL1 display adjacent expression both in secondary lymphoid organs and in inflamed epithelium from virus-induced pathologic lesions. Because pDCs express both the lymph node homing molecule l-selectin and the cutaneous homing molecule cutaneous lymphocyte antigen, the cooperation between inducible CXCR3 ligands and constitutive SDF-1/CXCL12 may regulate recruitment of pDCs either in lymph nodes or at peripheral sites of inflammation.

Corticosteroids prevent generation of CD34+-derived dermal dendritic cells but do not inhibit Langerhans cell development.

Corticosteroids (CS) have been shown to exert strong inhibitory effects on dendritic cell (DC) differentiation and function. Those studies were mostly performed with monocyte-derived DC, which represents only one subpopulation from the wide variety of DC types. In the present study the effects of the CS dexamethasone and prednisolone were investigated on the differentiation of CD34(+) hemopoietic progenitor cells into 1) Langerhans cells (LC), which differentiate directly into CD1a(+) DC; and 2) dermal/interstitial DC, which differentiate via a CD14(+)CD1a(-) phenotype into CD14(-)CD1a(+) DC. CS present during the entire 11-day culture period, resulting in fully differentiated CD1a(+) DC, increased the percentage of langerin(+) DC within the CD1a(+) population. In line with these data, CS treatment during the first 6 days of differentiation reduced the development of CD14(+) dermal DC precursors and thereby seemed to support the generation of CD1a(+) LC precursors. Addition of CS from day 6 onward specifically blocked the development of CD1a(+) dermal DC by both inhibition of spontaneous and IL-4-induced differentiation of CD14(+) DC precursors into CD1a(+) DC as well as induction of apoptosis in CD14(+) DC precursors. Apoptosis was not found in CD14(+) macrophage precursors derived from the same CD34(+) progenitors. The development and function of LC were not affected by CS, as demonstrated by a normal T cell stimulatory capacity and IL-12 production. These data demonstrate that CS interfere with the normal development of DC from CD34(+) progenitors by specific induction of apoptosis in precursors of dermal/interstitial DC. In view of the different functional capacities of dermal/interstitial DC and Langerhans cells, this might affect the overall cellular immune response.

Sequential involvement of CCR2 and CCR6 ligands for immature dendritic cell recruitment: possible role at inflamed epithelial surfaces.

To reach the site of antigen deposition at epithelial surfaces, dendritic cells (DC) have to traverse the endothelial barrier, progress through the tissue (i.e., dermis) and cross the dermo-epithelial junction (basal membrane). In the present study, we demonstrate that (1) circulating blood DC and monocytes express high levels of CCR2 and primarily respond to monocyte chemotactic protein (MCP) and not to macrophage inflammatory protein (MIP)-3alpha/CCL20; (2) while the CD34(+) hematopoietic progenitor cells (HPC)-derived CD1a(+) precursors committed to Langerhans cell differentiation primarily respond to MIP-3alpha/CCL20, the HPC-derived CD14(+) precursors respond to both MCP and MIP-3alpha/CCL20; (3) in concordance with the sequential expression of CCR2 and CCR6, the HPC-derived CD14(+) precursors initially acquire the ability to migrate in response to MCP-4/CCL13 and subsequently in response to MIP-3alpha/CCL20; and (4) in vivo, in inflamed epithelium, MCP-4/CCL13 and MIP-3alpha/CCL20 form complementary gradients, with MCP-4/CCL13 expressed in basal epithelial cells at the contact of blood vessels, while MIP-3alpha/CCL20 expression is restricted to epithelial cells bordering the external milieu. These observations suggest that the recruitment of DC to the site of infection is controlled by the sequential action of different chemokines: (i) CCR2(+) circulating DC or DC precursors are mobilized into the tissue via the expression of MCP by cells lining blood vessels, and (ii) these cells traffic from the tissue to the site of pathogen invasion via the production of MIP-3alpha/CL20 by epithelial cells and the up-regulation of CCR6 in response to the tissue environment.

Regulation of dendritic cell recruitment by chemokines.

Dendritic cells (DC) are a heterogeneous family of cells that function as sentinels of the immune system. This article summarizes observations suggesting that inflammatory chemokines secreted at the site of pathogen invasion determine the DC subset recruited and influence the class of the immune response initiated. Langerhans cells are selectively recruited by MIP-3alpha/CCL20. In contrast, CCR7 ligands have a key role in the accumulation of antigen-loaded mature DC in T cell-rich areas of the draining lymph node. Improved understanding of the regulation of DC trafficking might offer new opportunities for therapeutic interventions to control immune responses.