Injury or impaired clearance of apoptotic cells leads to the pathological accumulation of necrotic corpses, which induce an inflammatory response that initiates tissue repair1. In addition, antigens present within necrotic cells can sometimes provoke a specific immune response2-4 and it has been argued that necrosis could explain adaptive immunity in seemingly infection-free situations, such as after allograft transplantation or in spontaneous and therapy-induced tumour rejection5, 6. In the mouse, the CD8α+ subset of dendritic cells (DC) phagocytoses dead cell remnants and crossprimes CD8+ T cells against cell-associated antigens7. Here, we show that CD8α+ DC utilise CLEC9A (DNGR-1), a recently-characterised C-type lectin8-10, to recognise a preformed signal that is exposed on necrotic cells. Loss or blockade of CLEC9A does not impair uptake of necrotic cell material by CD8α+ DC but specifically reduces crosspresentation of dead cell-associated antigens in vitro and decreases the immunogenicity of necrotic cells in vivo. The function of CLEC9A requires a key tyrosine residue within its intracellular tail that allows recruitment and activation of the tyrosine kinase Syk, which is also essential for crosspresentation of dead cell-associated antigens. Thus, CLEC9A functions as a Syk-coupled C-type lectin receptor to mediate sensing of necrosis by the principal DC subset involved in regulating crosspriming to cell-associated antigens.
In mouse, a subset of dendritic cells (DCs) known as CD8α+ DCs has emerged as an important player in the regulation of T cell responses and a promising target in vaccination strategies. However, translation into clinical protocols has been hampered by the failure to identify CD8α+ DCs in humans. Here, we characterize a population of human DCs that expresses DNGR-1 (CLEC9A) and high levels of BDCA3 and resembles mouse CD8α+ DCs in phenotype and function. We describe the presence of such cells in the spleens of humans and humanized mice and report on a protocol to generate them in vitro. Like mouse CD8α+ DCs, human DNGR-1+ BDCA3hi DCs express Necl2, CD207, BATF3, IRF8, and TLR3, but not CD11b, IRF4, TLR7, or (unlike CD8α+ DCs) TLR9. DNGR-1+ BDCA3hi DCs respond to poly I:C and agonists of TLR8, but not of TLR7, and produce interleukin (IL)-12 when given innate and T cell–derived signals. Notably, DNGR-1+ BDCA3+ DCs from in vitro cultures efficiently internalize material from dead cells and can cross-present exogenous antigens to CD8+ T cells upon treatment with poly I:C. The characterization of human DNGR-1+ BDCA3hi DCs and the ability to grow them in vitro opens the door for exploiting this subset in immunotherapy.
DNGR-1 (CLEC9A) is a receptor for necrotic cells required by DCs to cross-prime CTLs against dead cell antigens in mice. It is currently unknown how DNGR-1 couples dead cell recognition to cross-priming. Here we found that DNGR-1 did not mediate DC activation by dead cells but rather diverted necrotic cell cargo into a recycling endosomal compartment, favoring cross-presentation to CD8 + T cells. DNGR-1 regulated crosspriming in non-infectious settings such as immunization with antigen-bearing dead cells, as well as in highly immunogenic situations such as infection with herpes simplex virus type 1. Together, these results suggest that DNGR-1 is a dedicated receptor for cross-presentation of cell-associated antigens. Our work thus underscores the importance of cross-priming in immunity and indicates that antigenicity and adjuvanticity can be decoded by distinct innate immune receptors. The identification of specialized receptors that regulate antigenicity of virus-infected cells reveals determinants of antiviral immunity that might underlie the human response to infection and vaccination.
The CD40–CD40 ligand (CD40L) signaling axis plays an important role in immunological pathways. Consequently, this dyad is involved in chronic inflammatory diseases, including atherosclerosis. Inhibition of CD40L in apolipoprotein E (Apoe)–deficient (Apoe−/−) mice not only reduced atherosclerosis but also conferred a clinically favorable plaque phenotype that was low in inflammation and high in fibrosis. Blockade of CD40L may not be therapeutically feasible, as long-term inhibition will compromise systemic immune responses. Conceivably, more targeted intervention strategies in CD40 signaling will have less deleterious side effects. We report that deficiency in hematopoietic CD40 reduces atherosclerosis and induces features of plaque stability. To elucidate the role of CD40–tumor necrosis factor receptor-associated factor (TRAF) signaling in atherosclerosis, we examined disease progression in mice deficient in CD40 and its associated signaling intermediates. Absence of CD40-TRAF6 but not CD40-TRAF2/3/5 signaling abolishes atherosclerosis and confers plaque fibrosis in Apoe−/− mice. Mice with defective CD40-TRAF6 signaling display a reduced blood count of Ly6Chigh monocytes, an impaired recruitment of Ly6C+ monocytes to the arterial wall, and polarization of macrophages toward an antiinflammatory regulatory M2 signature. These data unveil a role for CD40–TRAF6, but not CD40–TRAF2/3/5, interactions in atherosclerosis and establish that targeting specific components of the CD40–CD40L pathway harbors the potential to achieve therapeutic effects in atherosclerosis.
Steady-state dendritic cells (DCs) maintain peripheral T cell tolerance, whereas mature DCs generate immunity. CD70 is a costimulatory ligand acquired upon DC maturation. To determine its impact on T cell fate, we have generated mice that constitutively express CD70 in conventional DCs (cDCs). In these mice, naive CD4+ and CD8+ T cells spontaneously convert into effector cells. Administration of peptide without adjuvant, which is ordinarily tolerogenic, elicited tumor-eradicating CD8+ T cell responses and robust CD4+ T cell-independent memory. CD70 was also constitutively expressed in cDCs that inducibly present viral epitopes. In this case, tolerance induction was prevented as well. The antigen-presenting DCs generated protective immunity to virus infection and broke a pre-existing state of CD8+ T cell tolerance. Thus, the sole expression of CD70 by otherwise immature cDCs sufficed to convert CD8+ T cell tolerance into immunity, defining the importance of CD27-CD70 interactions at the interface between T cell and DC.
DC NK lectin group receptor-1 (DNGR-1, also known as CLEC9A) is a C-type lectin receptor expressed by mouse CD8α+ DC and by their putative equivalents in human. DNGR-1 senses necrosis and regulates CD8+ T-cell cross-priming to dead-cell-associated antigens. In addition, DNGR-1 is a target for selective in vivo delivery of antigens to DC and the induction of CD8+ T-cell and Ab responses. In this study, we evaluated whether DNGR-1 targeting can be additionally used to manipulate antigen-specific CD4+ T lymphocytes. Injection of small amounts of antigen-coupled anti-DNGR-1 mAb into mice promoted MHC class II antigen presentation selectively by CD8α+ DC. In the steady state, this was sufficient to induce proliferation of antigen-specific naïve CD4+ T cells and to drive their differentiation into Foxp3+ regulatory lymphocytes. Co-administration of adjuvants prevented this induction of tolerance and promoted immunity. Notably, distinct adjuvants allowed qualitative modulation of CD4+ T-cell behavior: poly I:C induced a strong IL-12-independent Th1 response, whereas curdlan led to the priming of Th17 cells. Thus, antigen targeting to DNGR-1 is a versatile approach for inducing functionally distinct CD4+ T-cell responses. Given the restricted pattern of expression of DNGR-1 across species, this strategy could prove useful for developing immunotherapy protocols in humans.
Bcl-2 family member Bid is subject to autoinhibition; in the absence of stimuli, its N-terminal region sequesters the proapoptotic Bcl-2 homology 3 (BH3) domain. Upon proteolytic cleavage in its unstructured loop, Bid is activated, although structural data reveal no apparent resulting conformational change. We found that, upon Bid cleavage, the N-terminal fragment (tBid-N) is ubiquitinated and degraded, thus freeing the BH3 domain in the C-terminal fragment (tBid-C). Ubiquitination of tBid-N is unconventional because acceptor sites are neither lysines nor the N terminus. Chemical approaches implicated thioester and hydroxyester linkage of ubiquitin and mutagenesis implicated serine and possibly threonine as acceptor residues in addition to cysteine. Acceptor sites reside predominantly but not exclusively in helix 1, which is required for ubiquitination and degradation of tBid-N. Rescue of tBid-N from degradation blocked Bid's ability to induce mitochondrial outer membrane permeability but not mitochondrial translocation of the cleaved complex. We conclude that unconventional ubiquitination and proteasome-dependent degradation of tBid-N is required to unleash the proapoptotic activity of tBid-C.
For optimal quality, memory CD8+ T cells require CD4+ T cell help. We have examined whether CD4+ T cells require CD27 to deliver this help, in a model of intranasal OVA protein immunization. CD27 deficiency reduced the capacity of CD4+ T cells to support Ag-specific CD8+ T cell accumulation at the tissue site after primary and secondary immunization. CD27-dependent CD4+ T cell help for the memory CD8+ T cell response was delivered during priming. It did not detectably affect formation of CD8+ memory T cells, but promoted their secondary expansion. CD27 improved survival of primed CD4+ T cells, but its contribution to the memory CD8+ T cell response relied on altered CD4+ T cell quality rather than quantity. CD27 induced a Th1-diagnostic gene expression profile in CD4+ T cells, which included the membrane molecule MS4A4B. Accordingly, CD27 increased the frequency of IFN-γ- and IL-2-producing CD4+ T cells. It did not affect CD40L expression. Strikingly, MS4A4B was also identified as a unique marker of CD8+ memory T cells that had received CD27-proficient CD4+ T cell help during the primary response. This apparent imprinting effect suggests a role for MS4A4B as a downstream effector in CD27-dependent help for CD8+ T cell memory.
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