Helena Païdassi

C1Q Binds Phosphatidylserine and Likely Acts as a Multiligand-Bridging Molecule in Apoptotic Cell Recognition.

Efficient apoptotic cell clearance is critical for maintenance of tissue homeostasis, and to control the immune responses mediated by phagocytes. Little is known about the molecules that contribute “eat me” signals on the apoptotic cell surface. C1q, the recognition unit of the C1 complex of complement, also senses altered structures from self and is a major actor of immune tolerance. HeLa cells were rendered apoptotic by UV-B treatment and a variety of cellular and molecular approaches were used to investigate the nature of the target(s) recognized by C1q. Using surface plasmon resonance, C1q binding was shown to occur at early stages of apoptosis and to involve recognition of a cell membrane component. C1q binding and phosphatidylserine (PS) exposure, as measured by annexin V labeling, proceeded concomitantly, and annexin V inhibited C1q binding in a dose-dependent manner. As shown by cosedimentation, surface plasmon resonance, and x-ray crystallographic analyses, C1q recognized PS specifically and avidly (KD = 3.7–7 × 10−8 M), through multiple interactions between its globular domain and the phosphoserine group of PS. Confocal microscopy revealed that the majority of the C1q molecules were distributed in membrane patches where they colocalized with PS. In summary, PS is one of the C1q ligands on apoptotic cells, and C1q-PS interaction takes place at early stages of apoptosis, in newly organized membrane patches. Given its versatile recognition properties, these data suggest that C1q has the unique ability to sense different markers which collectively would provide strong eat me signals, thereby allowing efficient apoptotic cell removal.

Preferential Expression of Integrin αvβ8 Promotes Generation of Regulatory T Cells by Mouse CD103+ Dendritic Cells

BACKGROUND & AIMS Immune responses in the intestine are controlled by regulatory T cells (Tregs), which prevent inflammation in response to commensal bacteria. A specific population of intestinal dendritic cells (DCs), marked by expression of CD103, generate Tregs more efficiently than other DC populations through mechanisms that involve retinoic acid and transforming growth factor (TGF)-β. However, it is not clear how CD103(+) DCs are specialized for this function. We investigated the ability of CD103(+) DCs to promote Treg generation through activation of TGF-β and the role of integrins with the αv subunit in this process. METHODS Naïve T cells were cultured with purified DCs from mesenteric lymph nodes (MLNs) or intestines of wild-type and αv conditional knockout mice to assess generation of Tregs. Antigens were administered orally to mice, and antigen-specific generation of Tregs was measured in intestinal tissues. Expression of the integrin αv subunit was measured in purified subpopulations of DCs by quantitative polymerase chain reaction and immunoblot analyses. RESULTS In vitro, CD103(+) DCs generated more Tregs in the presence of latent TGF-β than other MLN DCs. Efficient generation of Tregs required expression of the integrin αv subunit by DCs; mice that lacked αv in immune cells did not convert naïve T cells to intestinal Tregs in response to oral antigen. CD103(+) DCs derived from the MLNs selectively expressed high levels of integrin αvβ8 compared with other populations of DCs. CONCLUSIONS Expression of αvβ8 is required for CD103(+) DCs to become specialized and activate latent TGF-β and generate Tregs during the induction of tolerance to intestinal antigens in mice.

Investigations on the C1q-calreticulin-phosphatidylserine interactions yield new insights into apoptotic cell recognition.

Both C1q and calreticulin (CRT) are involved in the recognition of apoptotic cells. CRT was initially characterized as a receptor for the C1q collagen-like fragment (CLF), whereas C1q was shown to bind apoptotic cells through its globular region (GR). Using purified CRT and recombinant CRT domains, we now provide unambiguous experimental evidence that, in addition to its CLF, the C1q GR also binds CRT and that both types of interactions are mediated by the CRT globular domain. Surface plasmon resonance analyses revealed that the C1q CLF and GR domains each bind individually to immobilized CRT and its globular domain with K(D) values of (2.6-8.3) × 10(-7) M. Further evidence that CRT binds to the C1q GR was obtained by electron microscopy. The role of CRT in the recognition of apoptotic HeLa cells by C1q was analyzed. The C1q GR partially colocalized with CRT on the surface of early apoptotic cells, and siRNA (small interfering RNA)-induced CRT deficiency resulted in increased apoptotic cell binding to C1q. The interaction between CRT and phosphatidylserine (PS), a known C1q ligand on apoptotic cells, was also investigated. The polar head of PS was shown to bind to CRT with a 10-fold higher affinity (K(D)=1.5 × 10(-5) M) than that determined for C1q, and, accordingly, the C1q GR-PS interaction was impaired in the presence of CRT. Together, these observations indicate that CRT, C1q, and PS are all closely involved in the uptake of apoptotic cells and strongly suggest a combinatorial role of these three molecules in the recognition step.

X-ray structure of the human calreticulin globular domain reveals a peptide-binding area and suggests a multi-molecular mechanism.

In the endoplasmic reticulum, calreticulin acts as a chaperone and a Ca2+-signalling protein. At the cell surface, it mediates numerous important biological effects. The crystal structure of the human calreticulin globular domain was solved at 1.55 Å resolution. Interactions of the flexible N-terminal extension with the edge of the lectin site are consistently observed, revealing a hitherto unidentified peptide-binding site. A calreticulin molecular zipper, observed in all crystal lattices, could further extend this site by creating a binding cavity lined by hydrophobic residues. These data thus provide a first structural insight into the lectin-independent binding properties of calreticulin and suggest new working hypotheses, including that of a multi-molecular mechanism.

Cutting Edge: C1q Binds Deoxyribose and Heparan Sulfate through Neighboring Sites of Its Recognition Domain

C1q, the recognition subunit of the C1 complex of complement, is an archetypal pattern recognition molecule with the striking ability to sense a wide variety of targets, including a number of altered self-motifs. The recognition properties of its globular domain were further deciphered by means of x-ray crystallography using deoxy-d-ribose and heparan sulfate as ligands. Highly specific recognition of deoxy-d-ribose, involving interactions with Arg C98, Arg C111, and Asn C113, was observed at 1.2 Å resolution. Heparin-derived tetrasaccharide interacted more loosely through Lys C129, Tyr C155, and Trp C190. These data together with previous findings define a unique binding area exhibiting both polyanion and deoxy-d-ribose recognition properties, located on the inner face of C1q. DNA and heparin compete for C1q binding but are poor C1 activators compared with immune complexes. How the location of this binding area in C1q may regulate the level of C1 activation is discussed.

The lectin-like activity of human C1q and its implication in DNA and apoptotic cell recognition

C1q, the binding subunit of the C1 complex of complement, is an archetypal pattern recognition molecule known for its striking ability to recognize a wide variety of targets, ranging from pathogenic non self to altered self. DNA is one of the C1q ligands, but the precise region of C1q and the DNA motifs that support interaction have not been characterized yet. Here, we report for the first time that the peripheral globular region of the C1q molecule displays a lectin‐like activity, which contributes to DNA binding through interaction with its deoxy‐d‐ribose moiety and may participate in apoptotic cell recognition.

Wiskott-Aldrich Syndrome Protein Deficiency in Innate Immune Cells Leads to Mucosal Immune Dysregulation and Colitis in Mice

BACKGROUND & AIMS Immunodeficiency and autoimmune sequelae, including colitis, develop in patients and mice deficient in Wiskott-Aldrich syndrome protein (WASP), a hematopoietic cell-specific intracellular signaling molecule that regulates the actin cytoskeleton. Development of colitis in WASP-deficient mice requires lymphocytes; transfer of T cells is sufficient to induce colitis in immunodeficient mice. We investigated the interactions between innate and adaptive immune cells in mucosal regulation during development of T cell-mediated colitis in mice with WASP-deficient cells of the innate immune system. METHODS Naïve and/or regulatory CD4(+) T cells were transferred from 129 SvEv mice into RAG-2-deficient (RAG-2 KO) mice or mice lacking WASP and RAG-2 (WRDKO). Animals were observed for the development of colitis; effector and regulatory functions of innate immune and T cells were analyzed with in vivo and in vitro assays. RESULTS Transfer of unfractionated CD4(+) T cells induced severe colitis in WRDKO, but not RAG-2 KO, mice. Naïve wild-type T cells had higher levels of effector activity and regulatory T cells had reduced suppressive function when transferred into WRDKO mice compared with RAG-2 KO mice. Regulatory T-cell proliferation, generation, and maintenance of FoxP3 expression were reduced in WRDKO recipients and associated with reduced numbers of CD103(+) tolerogenic dendritic cells and levels of interleukin-10. Administration of interleukin-10 prevented induction of colitis following transfer of T cells into WRDKO mice. CONCLUSIONS Defective interactions between WASP-deficient innate immune cells and normal T cells disrupt mucosal regulation, potentially by altering the functions of tolerogenic dendritic cells, production of interleukin-10, and homeostasis of regulatory T cells.

β8 Integrin Expression and Activation of TGF-β by Intestinal Dendritic Cells Are Determined by Both Tissue Microenvironment and Cell Lineage

Activation of TGF-β by dendritic cells (DCs) expressing αvβ8 integrin is essential for the generation of intestinal regulatory T cells (Tregs) that in turn promote tolerance to intestinal Ags. We have recently shown that αvβ8 integrin is preferentially expressed by CD103+ DCs and confers their ability to activate TGF-β and generate Tregs. However, how these DCs become specialized for this vital function is unknown. In this study, we show that β8 expression is controlled by a combination of factors that include DC lineage and signals derived from the tissue microenvironment and microbiota. Specifically, our data demonstrate that TGF-β itself, along with retinoic acid and TLR signaling, drives expression of αvβ8 in DCs. However, these signals only result in high levels of β8 expression in cells of the cDC1 lineage, CD8α+, or CD103+CD11b− DCs, and this is associated with epigenetic changes in the Itgb8 locus. Together, these data provide a key illustrative example of how microenvironmental factors and cell lineage drive the generation of regulatory αvβ8-expressing DCs specialized for activation of TGF-β to facilitate Treg generation.

Alpha (v) integrins license regulatory T cells to apoptotic cells and self‐associated antigens

Defects in apoptotic cell clearance are thought to contribute to autoimmunity by failure to induce tolerance, coupled with accumulation of immunogenic material. However, little is known about the contribution of apoptosis to immune responses at mucosal sites, where regulatory T cells (Treg cells) and other immune cells play an essential active role in maintaining tolerance to self‐associated antigens. In recent studies, we have found that αv integrins have an important role in apoptotic cell phagocytosis and induction of Treg cells in the intestine, and deletion of αv from myeloid cells causes colitis associated with failed apoptotic cell removal and loss of Treg cells. Our data show that activation of transforming growth factor (TGF)‐β by αvβ8 on dendritic cells (DCs) is essential for generating Treg cells and inducing mucosal tolerance. These results provide a mechanism by which tolerance to apoptotic cell–derived and –associated antigens is maintained by DC “licensing” at sites of high TGF‐β expression.

Apoptotic Cells Can Deliver Chemotherapeutics to Engulfing Macrophages and Suppress Inflammatory Cytokine Production

Background: Cytotoxic agents are used to induce cell death to study apoptotic cell-induced immune regulation. Results: Suppression of macrophage responses by actinomycin D-treated cells does not require phagocytosis but correlates with chemotherapeutic dose and phagocyte apoptosis. Conclusion: Dead cells can deliver actinomycin D to interacting macrophages. Significance: Actinomycin D tumor therapy may suppress secondary antitumor responses from immune cells. Immunosuppression via cell-cell contact with apoptotic cells is a well studied immunological phenomenon. Although the original studies of immune repression used primary cells, which undergo spontaneous cell death or apoptosis in response to irradiation, more recent studies have relied on chemotherapeutic agents to induce apoptosis in cell lines. In this work, we demonstrate that Jurkat cells induced to die with actinomycin D suppressed inflammatory cytokine production by macrophages, whereas cells treated with etoposide did not. This immune repression mediated by actinomycin D-treated cells did not require phagocytosis or cell-cell contact and thus occurs through a different mechanism from that seen with primary apoptotic neutrophils. Moreover, cells induced to die with etoposide and then treated for a short time with actinomycin D also suppressed macrophage responses, indicating that suppression was mediated by actinomycin D independent of the mechanism of cell death. Finally, phagocytosis of actinomycin D-treated cells caused apoptosis in macrophages, and suppression could be blocked by inhibition of caspase activity in the target macrophage. Together, these data indicate that apoptotic cells act as “Trojan horses,” delivering actinomycin D to engulfing macrophages. Suppression of cytokine production by macrophages is therefore due to exposure to actinomycin D from apoptotic cells and is not the result of cell-receptor interactions. These data suggest that drug-induced death may not be an appropriate surrogate for the immunosuppressive activity of apoptotic cells. Furthermore, these effects of cytotoxic drugs on infiltrating immune phagocytes may have clinical ramifications for their use as antitumor therapies.