IntroductionMorphogen gradients are essential in the patterning of diverse tissues during development. Thus, morphogens stem from a tissue source and act on target cells by modifying programs of gene expression. Members of the hedgehog (Hh) morphogen family include Sonic (Shh), Indian, and Desert hedgehog signaling molecules. 1 Hh precursor is first cleaved and the resulting 22-kDa N-terminal active peptide is modified by addition of a palmitate group and a cholesterol molecule and becomes associated with cholesterol-rich raftlike membrane microdomains. 2,3 Such modifications play a critical role in regulating Hh binding to the plasma membrane and long-range activity. 4,5 Once shed, Hh protein binds to the patched (Ptc) receptor, releasing the latent inhibition of smoothened (Smo), which is the signaling component of the Hh-receptor complex in the target cell. 6 In vivo, Hh proteins play a key role during embryonic development, regulating not only the patterning of the central nervous system, but also cell differentiation and proliferation. Indeed, activation of Shh signaling pathway favors angiogenesis 7,8 and promotes in vitro hematopoietic 9 and thymocyte differentiation. 10 Free diffusion of soluble Hh molecules in the extracellular space has been proposed as a model to explain the formation of morphogen gradients. 11,12 Other studies have shown that membrane fragments, also termed argosomes, transporting morphogens such as wingless, might be used as a vehicle and be involved in tissue patterning, but no mechanistic insight was provided. 13,14 Chen et al 5 have reported that palmitoylation is required for producing Hh multimeric complexes able to form a morphogen gradient. In addition, the effects of Hh morphogens are not only dictated by a temporal gradient, but a spatial gradient seems also necessary. 15,16 Indeed, as recently described by Williams and colleagues 12 different morphogens in different developmental contexts may use different means of transport.Vesiculation or microvesicle (MV) release occurs during activation of virtually all cell types by various agonists, shear stress, or apoptosis. [17][18][19] The release of MVs or apoptotic bodies from senescent cells is a conserved event of the apoptosis execution phase. 20 MVs, also termed microparticles, are small plasma membrane fragments (0.05-1 m) shed by cells after membrane blebbing. At their surface MVs bear antigens characteristic of the cell of origin and carry other membrane and cytoplasmic constituents. They exhibit negatively charged phospholipids at their surface, accounting for their procoagulant character, and carry components responsible for their proinflammatory properties. Elevated levels of circulating MVs have been detected under pathologic situations, such as systemic lupus erythematosus, atherosclerosis, acute coronary syndrome, sepsis, and diabetes. [21][22][23][24][25] Although the majority of in vivo circulating MVs are derived from platelets, the proportions of the different origins can differ. Thus, in For personal use only....
