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.
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.
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