Dendritic cell (DC) populations consist of multiple subsets that are essential orchestrators of the immune system. Technological limitations have so far prevented systems-wide accurate proteome comparison of rare cell populations in vivo. Here, we used high-resolution mass spectrometry-based proteomics, combined with label-free quantitation algorithms, to determine the proteome of mouse splenic conventional and plasmacytoid DC subsets to a depth of 5,780 and 6,664 proteins, respectively. We found mutually exclusive expression of pattern recognition pathways not previously known to be different among conventional DC subsets. Our experiments assigned key viral recognition functions to be exclusively expressed in CD4(+) and double-negative DCs. The CD8alpha(+) DCs largely lack the receptors required to sense certain viruses in the cytoplasm. By avoiding activation via cytoplasmic receptors, including retinoic acid-inducible gene I, CD8alpha(+) DCs likely gain a window of opportunity to process and present viral antigens before activation-induced shutdown of antigen presentation pathways occurs.
Host protection from infection relies on the recognition of pathogens by innate pattern-recognition receptors such as Toll-like receptors (TLRs). Here, we show that the orphan receptor TLR13 in mice recognizes a conserved 23S ribosomal RNA (rRNA) sequence that is the binding site of macrolide, lincosamide, and streptogramin group (MLS) antibiotics (including erythromycin) in bacteria. Notably, 23S rRNA from clinical isolates of erythromycin-resistant Staphylococcus aureus and synthetic oligoribonucleotides carrying methylated adenosine or a guanosine mimicking a MLS resistance-causing modification failed to stimulate TLR13. Thus, our results reveal both a natural TLR13 ligand and specific mechanisms of antibiotic resistance as potent bacterial immune evasion strategy, avoiding recognition via TLR13.
In humans and mice, CD8α+ conventional dendritic cells are the primary source of interferon-λ released in response to the adjuvant and Toll-like receptor 3 agonist poly IC.
Poxviruses such as the causative agent of smallpox have developed multiple strategies to suppress immune responses, including the suppression of DC activation. Since poxviruses are large DNA viruses, we hypothesized that their detection by DCs may involve the endosomal DNA recognition receptor TLR9. Indeed, we have shown here that DC recognition of ectromelia virus (ECTV), the causative agent of mousepox, completely depended on TLR9. The importance of TLR9 was highlighted by the fact that mice lacking TLR9 showed drastically increased susceptibility to infection with ECTV. In contrast, we found that the strongly attenuated poxvirus modified vaccinia virus Ankara (MVA) activated DCs by both TLR9-dependent and -independent pathways. We therefore tested whether we could use the broader induction of immune responses by MVA to protect mice from a lethal infection with ECTV. Indeed, MVA given at the same time as a lethal dose of ECTV protected mice from death. Importantly, MVA also rescued TLR9-deficient mice if administered 2 full days after an otherwise lethal infection with ECTV. Therefore, these data suggest an essential role for TLR9 in the defense against poxviruses. In addition, postexposure application of MVA may protect against lethal poxvirus infection.
Given the global impact of persistent infections on the human population, it is of the utmost importance to devise strategies to noncytopathically purge tissues of infectious agents. The central nervous system (CNS) poses a unique challenge when considering such strategies, as it is an immunologically specialized compartment that contains a nonreplicative cell population. Administration of exogenously derived pathogen-specific memory T cells (referred to as adoptive immunotherapy) to mice burdened with a persistent lymphocytic choriomeningitis virus (LCMV) infection from birth results in eradication of the pathogen from all tissues, including the CNS. In this study, we sought mechanistic insights into this highly successful therapeutic approach. By monitoring the migration of traceable LCMV-specific memory CD8+ T cells after immunotherapy, it was revealed that cytotoxic T lymphocytes (CTLs) distributed widely throughout the CNS compartment early after immunotherapy, which resulted in a dramatic elevation in the activity of CNS antigen-presenting cells (APCs). Immunotherapy induced microglia activation as well as the recruitment of macrophages and dendritic cells (DCs) into the brain parenchyma. However, DCs emerged as the only CNS APC population capable of inducing memory CTLs to preferentially produce the antiviral cytokine tumor necrosis factor-α, a cytokine demonstrated to be required for successful immunotherapeutic clearance. DCs were also found to be an essential element of the immunotherapeutic process because in their absence, memory T cells failed to undergo secondary expansion, and viral clearance was not attained in the CNS. These experiments underscore the importance of DCs in the immunotherapeutic clearance of a persistent viral infection and suggest that strategies to elevate the activation/migration of DCs (especially within the CNS) may facilitate pathogen clearance.
Gene gun-mediated DNA immunization is a powerful mode of vaccination against infectious diseases and tumors. Many studies have identified dendritic cells (DC) as the central players in inducing immunity upon biolistic DNA vaccination; however, none of these studies directly quantify DC-mediated responses in comparison with immunity triggered by all Ag- and MHC-expressing cells. In this study we use two different approaches to decipher the relative role of DC vs other cell types in gene gun-induced immunity. First, we directly compared the immunization efficacy of different DNA constructs, which allow Ag expression ubiquitously (CMV promoter) or specifically in DC (CD11c promoter) and would encode either for soluble or membrane bound forms of Ag. Second, we immunized transgenic mice in which only DC can present MHC-restricted Ag, and directly compared the magnitudes of CTL activation with those obtained in wild-type mice. Surprisingly, our combined data suggest that, although DC-specific Ag expression is sufficient to induce humoral responses, DC alone cannot trigger optimal CD4 and CD8 T cell responses upon gene gun vaccination. Therefore, we conclude that DC alone are insufficient to mediate optimal induction of T cell immunity upon gene gun DNA vaccination and that broad Ag expression rather than DC-restricted approaches are necessary for induction of complete immune responses.
Adaptive immune responses in which CD8؉ T cells recognize pathogen-derived peptides in the context of major histocompatibility complex class I molecules play a major role in the host defense against infection with intracellular pathogens.
Due to the continuous need for new vaccines, viral vaccine vectors have become increasingly attractive. In particular, herpes simplex virus type 1 (HSV-1)-based vectors offer many advantages, such as broad cellular tropism, large DNA-packaging capacity and the induction of pro-inflammatory responses. However, despite promising results obtained with HSV-1-derived vectors, the question of whether pre-existing virus-specific host immunity affects vaccine efficacy remains controversial. For this reason, the influence of pre-existing HSV-1-specific immunity on the immune response induced with a replication-defective, recombinant HSV-1 vaccine was investigated in vivo. It was shown that humoral as well as cellular immune responses against a model antigen encoded by the vaccine were strongly diminished in HSV-1-seropositive mice. This inhibition could be observed in mice infected with wild-type HSV-1 or with a replication-defective vector. Although these data clearly indicate that pre-existing antiviral host immunity impairs the efficacy of HSV-1-derived vaccine vectors, they also show that vaccination under these constraints might still be feasible. INTRODUCTIONHerpes simplex virus type 1 (HSV-1) is the causative agent of a variety of diseases [reviewed by Stanberry et al. (2000)]. However, in recent decades it has become possible to exploit the advantageous features of HSV-1 for gene delivery, by stepwise elimination of viral pathogenicity [reviewed by Advani et al. (2002)]. HSV-1-derived vectors, including replication-deficient and infectious single-cycle (DISC) vectors or amplicons, offer many advantages over other viral vectors for gene-therapeutic and vaccine approaches [reviewed by Thomas et al. (2003)]. They can transduce a wide range of cell types, including non-dividing cells (Coffin et al., 1998;Mikloska et al., 2001), show high transduction efficiency (Moriuchi et al., 2000) and have large DNA-packaging capacities (Krisky et al., 1998; WadeMartins et al., 2003). Further, their genomes persist in the cell nucleus as extrachromosomal episomes (Mellerick & Fraser, 1987) and therefore should not induce mutagenesis by DNA insertion in transduced cells (Li et al., 2002). The many applications for HSV-1-derived vectors have recently been reviewed elsewhere (Burton et al., 2001).Upon HSV-1 infection, innate immunity provides the first line of defence, with activated macrophages, dendritic cells (DC), NK cells and cd T cells as key players (Bukowski et al., 1994;Kadowaki et al., 2000;Kodukula et al., 1999;Siegal et al., 1999). Together with cytokines and the complement cascade, these cells limit the spread of epidermal infection by the herpesvirus (Ahmad et al., 2000; Da Costa et al., 1999;Feduchi et al., 1989;Melchjorsen et al., 2002). Neutralizing antibodies specific for the major envelope glycoproteins gB, gD and gH/L, as well as CD4 + and CD8 + T lymphocytes recognizing HSV antigens (Ags) can be detected after HSV-1 infection (Mikloska & Cunningham, 1998;Mikloska et al., 1996). Despite this HSV-specific immunit...
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