Comment on Lasser et al, page 423
C1q-TNF–related protein-1 (CTRP-1) is a new endogenous vascular cell wall regulator of collagen-induced platelet activation.
Lasser and colleagues describe in this issue of Blood how a novel member of the C1q-related family, C1q-TNF–related protein-1 (CTRP-1), is an endogenous inhibitor of collagen-induced platelet aggregation in vitro and in vivo. C1q is a critical component of the classic complement pathway, which sits at the junction between innate and acquired immunity.1,2 In its conventional role, C1q binds immune complexes through its C-terminal C1q globular domain, recruiting serine proteases through its collagen region, leading eventually to activation of the terminal membrane attack complex used in antimicrobial defence. The C1q signature domain is, however, found in many related proteins, including CTRP-1, many of which are noncomplement extracellular structural proteins. Common to most of these proteins is their trimeric arrangement, where 3 globular C1q heads sit in a quaternary arrangement that forms the protein interaction recognition domain. Structural analysis of this quaternary arrangement revealed an evolutionary link between C1q and tumor necrosis factor (TNF) proteins,3 and the recognition of the C1q-TNF superfamily, of which CTRP-1 is a member.FIG1
C1q-TNF superfamily members are variously insoluble structural proteins or freely soluble proteins found in serum and other fluid compartments of the body. CTRP-1 is produced predominantly by vascular smooth muscle cells, but also by endothelial cells, and its modular structure comprises a C-terminal globular C1q domain attached to a collagen-like region, which is typical of this family and is illustrated in the figure.
In this issue of Blood, Lasser et al provide compelling evidence to show that soluble CTRP-1 binds fibrillar collagen type I, inhibiting collagen-induced platelet activation. There appear to be 2 sites of interaction within collagen for CTRP-1: a high-affinity and much more abundant site completely distinct from the classic GPP repeat recognition site for GPVI and a lower affinity site that overlaps with the GPVI binding motif. But the major mechanism by which CTRP-1 blocks collagen-dependent platelet function is through disruption of the interaction between VWF and collagen. In particular, VWF A3 domain has been shown to be the major interacting site with collagen, and CTRP-1 is shown here to compete with collagen for binding to VWF A3 domain.
The work presented has 2 important implications. First, CTRP-1 may represent an important novel endogenous mechanism regulating platelet responsiveness to exposed subendothelial surfaces. This requires much additional work but opens up a new field for study of endogenous negative regulatory processes. Second, because of the soluble nature of the protein, it has potential as a new therapeutic for control of arterial thrombosis. It will now be important to dissect further the interaction motifs in CTRP-1 for collagen and VWF, and in collagen for CTRP-1. I have speculated in the figure that the globular C1q domain may interact with collagen, whereas the collagen domain of CTRP-1 may interact with VWF A3 domain. The evidence for this is lacking at present, and is not investigated by Lasser et al in this study. The multiple inhibitory functions of CTRP-1 also make it difficult at this stage to assess which of its protein-protein interactions is pre-eminent in its antithrombotic role and in its ability to block collagen-induced platelet activation. In summary though, the identification of CTRP-1 as an endogenous and exogenous inhibitor of platelet responsiveness to collagen in vitro and in vivo opens up important new possibilities for both basic and applied platelet cell biology. ▪
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