Melissa M. Linehan

Vaginal Submucosal Dendritic Cells, but Not Langerhans Cells, Induce Protective Th1 Responses to Herpes Simplex Virus-2

Herpes simplex virus (HSV) type 2 infection occurs primarily at the genital mucosal surfaces and is a leading cause of ulcerative lesions. Despite the availability of animal models for HSV-2 infection, little is known regarding the mechanism of immune induction within the vaginal mucosa. Here, we examined the cell types responsible for the initiation of protective Th1 immunity to HSV-2. Intravaginal inoculation of HSV-2 led to a rapid recruitment of submucosal dendritic cells (DCs) to the infected epithelium. Subsequently, CD11c+ DCs harboring viral peptides in the context of MHC class II molecules emerged in the draining lymph nodes and were found to be responsible for the stimulation of IFNγ secretion from HSV-specific CD4+ T cells. Other antigen-presenting cells including B cells and macrophages did not present viral peptides to T cells in the draining lymph nodes. Next, we assessed the relative contribution to immune generation by the Langerhans cells in the vaginal epithelium, the submucosal CD11b+ DCs, and the CD8α+ lymph node DCs. Analysis of these DC populations from the draining lymph nodes revealed that only the CD11b+ submucosal DCs, but not Langerhans cell–derived or CD8α+ DCs, presented viral antigens to CD4+ T cells and induced IFNγ secretion. These results demonstrate a previously unanticipated role for submucosal DCs in the generation of protective Th1 immune responses to HSV-2 in the vaginal mucosa, and suggest their importance in immunity to other sexually transmitted diseases.

Bifurcation of Toll-Like Receptor 9 Signaling by Adaptor Protein 3

Location Matters Plasmacytoid dendritic cells (pDCs), an immune cell specialized to respond to viral infections, use Toll-like receptors (TLRs) 7 and 9 expressed in endosomes to sense viral nucleic acids. Triggering of TLR7 or 9 results in the induction of two distinct signaling pathways, one that leads to the production of proinflammatory cytokines and another that induces the expression of antiviral type I interferons. How one receptor can trigger two distinct signaling pathways, however, is not clear. Sasai et al. (p. 1530) now show that subcellular localization is key. Cells from mice deficient in the Adapter Protein 3 (AP-3) complex, which regulates protein sorting to intracellular vesicles, did not produce type I interferons in response to TLR9 ligand, but proinflammatory cytokine production remained intact. AP-3 was required for trafficking of TLR9 from early endosomes, where proinflammatory signaling can occur, to lysosome-related organelles, where the signaling machinery required for type I interferon induction is located. Such spatial segregation may represent a common mechanism whereby activation of one receptor can result in the induction of multiple independent signaling cascades. Compartmentalization of signaling components allows induction of distinct pathways downstream of a pathogen receptor. Endosomal Toll-like receptors (TLRs) 7 and 9 recognize viral pathogens and induce signals leading to the activation of nuclear factor κB (NF-κB)–dependent proinflammatory cytokines and interferon regulatory factor 7 (IRF7)–dependent type I interferons (IFNs). Recognition of viral nucleic acids by TLR9 requires its cleavage in the endolysosomal compartment. Here, we show that TLR9 signals leading to the activation of type I IFN, but not proinflammatory cytokine genes, require TLR9 trafficking from endosomes to a specialized lysosome-related organelle. Furthermore, we identify adapter protein-3 as the protein complex responsible for the trafficking of TLR9 to this subcellular compartment. Our results reveal an intracellular mechanism for bifurcation of TLR9 signals by selective receptor trafficking within the endosomal system.

Dual recognition of herpes simplex viruses by TLR2 and TLR9 in dendritic cells

Dendritic cells (DCs) express multiple Toll-like receptors (TLR) in distinct cellular locations. Herpes simplex viruses (HSV) have been reported to engage both the surface TLR2 and intracellular TLR9 in conventional DCs. However, the contributions of these TLRs in recognition of HSV and the induction of proinflammatory cytokines in DCs remain unclear. Here, we demonstrate that a rare population of HSV, both in laboratory strains and in primary clinical isolates from humans, has the capacity to activate TLR2. This virus population is recognized through both TLR2 and TLR9 for the induction of IL-6 and IL-12 secretion from bone marrow-derived DCs. Further, we describe a previously uncharacterized pathway of viral recognition in which TLR2 and TLR9 are engaged in sequence within the same DC. Live viral infection results in two additional agonists of TLR2 and TLR9. These results indicate that in cells that express multiple TLRs, pathogens that contain multiple pathogen-associated molecular patterns can be detected in an orchestrated sequence and suggest that the innate immune system in DCs is optimized to linking uptake and degradation of pathogens to microbial recognition.

CCL9 Is Secreted by the Follicle-Associated Epithelium and Recruits Dome Region Peyer’s Patch CD11b+ Dendritic Cells

The follicle-associated epithelium (FAE) secretes chemokines important in the recruitment of various cell types including CCL20 (MIP-3α). CCL20 is chemotactic to the CD11b+ dendritic cells (DCs) distributed in the subepithelial dome regions of the Peyer’s patches, and mice deficient in the receptor for CCL20, CCR6, have been reported to be devoid of the CD11b+ DCs in the dome regions. Here, we describe another chemokine specifically secreted from the FAE of mouse Peyer’s patches, CCL9 (MIP-1γ, CCF18, MRP-2). By in situ hybridization, we demonstrated that CCL9 mRNA was expressed by the FAE but not by the villus epithelium. At the protein level, CCL9 was detected on the FAE and on extracellular matrix structures within the dome regions of the Peyer’s patches. By RT-PCR, we demonstrated that one of the putative receptors for CCL9, CCR1, was expressed by the Peyer’s patch CD11b+ DCs and in a chemotaxis assay, CD11b+ DCs migrated toward CCL9. To compare the abilities of the chemokines CCL20 and CCL9 to recruit CD11b+ DCs to the dome regions, we examined the in vivo distribution of these cells in CCR6-deficient, CCL9-blocked wild type, or CCL9-blocked CCR6-deficient mice. To our surprise, using a sensitive immunofluorescence analysis, we observed that CD11b+ DCs were present in the dome regions of the CCR6-deficient mice. In contrast, Ab neutralization of CCL9 in vivo resulted in significant reduction of the CD11b+ DC number in the subepithelial dome regions of Peyer’s patches of both wild type and CCR6 −/− mice. Taken together, these results demonstrate an important role of CCL9 in CD11b+ DC recruitment to the dome regions of mouse Peyer’s patches.

CD301b+ Dermal Dendritic Cells Drive T Helper 2 Cell-Mediated Immunity

Unlike other types of T helper (Th) responses, whether the development of Th2 cells requires instruction from particular subset of dendritic cells (DCs) remains unclear. By using an in vivo depletion approach, we have shown that DCs expressing CD301b were required for the generation of Th2 cells after subcutaneous immunization with ovalbumin (OVA) along with papain or alum. CD301b⁺ DCs are distinct from epidermal or CD207⁺ dermal DCs (DDCs) and were responsible for transporting antigen injected subcutaneously with Th2-type adjuvants. Transient depletion of CD301b⁺ DCs resulted in less effective accumulation and decreased expression of CD69 by polyclonal CD4⁺ T cells in the lymph node. Moreover, despite intact cell division and interferon-γ production, CD301b⁺ DC depletion led to blunted interleukin-4 production by OVA-specific OT-II transgenic CD4⁺ T cells and significantly impaired Th2 cell development upon infection with Nippostrongylus brasiliensis. These results reveal CD301b⁺ DDCs as the key mediators of Th2 immunity.

Cutting Edge: Plasmacytoid Dendritic Cells Provide Innate Immune Protection against Mucosal Viral Infection In Situ

Dendritic cells (DCs) are powerful APCs capable of activating naive lymphocytes. Of the DC subfamilies, plasmacytoid DCs (pDCs) are unique in that they secrete high levels of type I IFNs in response to viruses but their role in inducing adaptive immunity remains divisive. In this study, we examined the importance of pDCs and their ability to recognize a virus through TLR9 in immunity against genital HSV-2 infection. We show that a low number of pDCs survey the vaginal mucosa at steady state. Upon infection, pDCs are recruited to the vagina and produce large amounts of type I IFNs in a TLR9-dependent manner and suppress local viral replication. Although pDCs are critical in innate defense against genital herpes challenge, adaptive Th1 immunity developed normally in the absence of pDCs. Thus, by way of migrating directly into the peripheral mucosa, pDCs act strictly as innate antiviral effector cells against mucosal viral infection in situ.

Dendritic cells and B cells maximize mucosal Th1 memory response to herpes simplex virus

Although the importance of cytotoxic T lymphocytes and neutralizing antibodies for antiviral defense is well known, the antiviral mechanism of Th1 remains unclear. We show that Th1 cells mediate noncytolytic antiviral protection independent of direct lysis through local secretion of IFN-γ after herpes simplex virus (HSV) 2 infection. IFN-γ acted on stromal cells, but not on hematopoietic cells, to prevent further viral replication and spread throughout the vaginal mucosa. Importantly, unlike other known Th1 defense mechanisms, this effector function did not require recognition of virally infected cells via MHC class II. Instead, recall Th1 response was elicited by MHC class II+ antigen-presenting cells at the site of infection. Dendritic cells (DCs) were not required and only partially sufficient to induce a recall response from memory Th1 cells. Importantly, DCs and B cells together contributed to restimulating memory CD4 T cells to secrete IFN-γ. In the absence of both DCs and B cells, immunized mice rapidly succumbed to HSV-2 infection and death. Thus, these results revealed a distinct mechanism by which memory Th1 cells mediate noncytolytic IFN-γ–dependent antiviral protection after recognition of processed viral antigens by local DCs and B cells.

Differential roles of migratory and resident DCs in T cell priming after mucosal or skin HSV-1 infection

Although mucosal surfaces represent the main portal of entry for pathogens, the mechanism of antigen presentation by dendritic cells (DCs) that patrol various mucosal tissues remains unclear. Instead, much effort has focused on the understanding of initiation of immune responses generated against antigens delivered by injection. We examined the contributions of migratory versus lymph node–resident DC populations in antigen presentation to CD4 and CD8 T cells after needle injection, epicutaneous infection, or vaginal mucosal herpes simplex virus (HSV) 1 infection. We show that upon needle injection, HSV-1 became lymph-borne and was rapidly presented by lymph node–resident DCs to CD4 and CD8 T cells. In contrast, after vaginal HSV-1 infection, antigens were largely presented by tissue-derived migrant DCs with delayed kinetics. In addition, migrant DCs made more frequent contact with HSV-specific T cells after vaginal infection compared with epicutaneous infection. Thus, both migrant and resident DCs play an important role in priming CD8 and CD4 T cell responses, and their relative importance depends on the mode of infection in vivo.

Immunofluorescence Analysis of Poliovirus Receptor Expression in Peyer’s Patches of Humans, Primates, and CD155 Transgenic Mice: Implications for Poliovirus Infection

Oral transmission of poliovirus is restricted to humans and certain primate species. The expression of the human poliovirus receptor (CD155) within gastrointestinal-associated lymphoid tissues from species that are susceptible (human) or resistant (rhesus macaque and CD155 transgenic [Tg] mice) to oral poliovirus infection was examined. Sensitivity to oral infection correlated with CD155 expression not only in the intestinal epithelium, including the follicle-associated epithelium (FAE) and microfold (M) cells of Peyers patches, but also in germinal centers within the Peyers patches. CD155 expression in rhesus macaques was reduced in FAE and, significantly, absent in germinal centers. In CD155 Tg mice, CD155 expression was barely observable in the intestinal epithelium, absent in germinal centers, but prominent in the tunica muscularis. This suggests that productive poliovirus infection of the gut is dependent on the expression of CD155 within the FAE, including the M cells, and on cells within Peyers patches, most likely within germinal centers.

Vaginal epithelial dendritic cells renew from bone marrow precursors

Dendritic cells (DCs) represent key professional antigen-presenting cells capable of initiating primary immune responses. A specialized subset of DCs, the Langerhans cells (LCs), are located in the stratified squamous epithelial layer of the skin and within the mucosal epithelial lining of the vaginal and oral cavities. The vaginal mucosa undergoes cyclic changes under the control of sex hormones, and the renewal characteristics of the vaginal epithelial DCs (VEDCs) remain unknown. Here, we examined the origin of VEDCs. In contrast to the skin epidermal LCs, the DCs in the epithelium of the vagina were found to be repopulated mainly by nonmonocyte bone-marrow-derived precursors, with a half-life of 13 days under steady-state conditions. Upon infection with HSV-2, the Gr-1hi monocytes were found to give rise to VEDCs. Furthermore, flow cytometric analysis of the VEDCs revealed the presence of at least three distinct populations, namely, CD11b+F4/80hi, CD11b+F4/80int, and CD11b−F4/80−. Importantly, these VEDC populations expressed CD207 at low levels and had a constitutively more activated phenotype compared with the skin LCs. Collectively, our results revealed mucosa-specific features of the VEDCs with respect to their phenotype, activation status, and homeostatic renewal potential.