Calmodulin regulates L-selectin adhesion molecule expression and function through a protease-dependent mechanism.

Expression of the L-selectin adhesion molecule is rapidly down-regulated upon cell activation through proteolysis at a membrane-proximal site. Here we demonstrate that calmodulin, an intracellular calcium regulatory protein, specifically coprecipitates with L-selectin through a direct association with the cytoplasmic domain of L-selectin. Furthermore, calmodulin inhibitors disrupt L-selectin-dependent adhesion by inducing proteolytic release of L-selectin from the cell surface. The effects of the calmodulin inhibitors on L-selectin expression and function can be prevented by cotreatment with a hydroxamic acid-based metalloprotease inhibitor. Our results suggest a novel role for calmodulin in regulating the expression and function of an integral membrane protein through a protease-dependent mechanism. These findings may have broader implications for other cell surface proteins that also undergo regulated proteolysis.

Mutational analysis of the membrane-proximal cleavage site of L-selectin: relaxed sequence specificity surrounding the cleavage site.

L-selectin expression is regulated in part by membrane-proximal cleavage from the cell surface of leukocytes and L-selectin-transfected cells. The downregulation of L-selectin from the surface of neutrophils is speculated to be a process involved in the adhesion cascade leading to neutrophil recruitment to sites of inflammation. We previously reported that L-selectin is cleaved between Lys321 and Ser322 in a region that links the second short consensus repeat (SCR) and the transmembrane domain. We demonstrate that replacing this cleavage domain of L-selectin with the corresponding region of E-selectin prevents L-selectin shedding, as judged by inhibiting the generation of the 68-kD soluble and 6-kD transmembrane cleavage products of L-selectin. Unexpectedly, we found that point mutations of the cleavage site, as well as mutations of multiple conserved amino acids within the cleavage domain, do not significantly affect L-selectin shedding. However, short deletions of four or five amino acids in the L-selectin cleavage domain inhibit L-selectin downregulation. Mutations that appeared to inhibit L-selectin shedding resulted in higher levels of cell surface expression, consistent with a lack of apparent proteolysis from the cell membrane. One deletion mutant, I327 delta N332, retains the native cleavage site yet inhibits L-selectin proteolysis as well. Restoring the amino acids deleted between I327 and N332 with five alanine residues restores L-selectin proteolysis. Thus, the proteolytic processing of L-selectin appears to have a relaxed sequence specificity at the cleavage site, and it may depend on the physical length or other secondary structural characteristics of the cleavage domain.

Membrane proximal cleavage of L-selectin: identification of the cleavage site and a 6-kD transmembrane peptide fragment of L-selectin.

Rapid downregulation of L-selectin expression occurs in response to leukocyte activation, and it has been speculated to be an integral process in the adhesion cascade leading to neutrophil recruitment to sites of inflammation. It has previously been proposed that L-selectin is proteolytically cleaved from the cell surface; however, the nature of the cleavage site has been unknown. We have produced polyclonal antisera against the extracellular domain and against the cytoplasmic domain of L-selectin. Both antisera immunoprecipitate the intact form of L-selectin from metabolically labeled phytohemagglutinin-stimulated lymphoblasts and peripheral blood neutrophils. In addition, the anti-cytoplasmic domain serum, but not the antiectodomain serum, immunoprecipitate a 6-kD species from PMA activated lymphoblasts and formylmethionylleucylphenylalanine-activated neutrophils. Conversely, the antiectodomain serum but not the anti-cytoplasmic domain serum immunoprecipitate a 68-kD soluble form of L-selectin from the supernatant of PMA-activated lymphoblasts. The appearance of the 6-kD species on activated cells correlated with the disappearance of the intact form of L-selectin and the appearance of the soluble form of L-selectin. A third polyclonal serum generated against the membrane proximal region of the ectodomain also reacted with the 6-kD species, indicating that this is a transmembrane peptide of L-selectin. That the 6-kD species is derived from L-selectin was confirmed by immunoprecipitation of the 6-kD species from L-selectin transfectants but not from mock transfectants. Radiochemical sequence analysis defined a cleavage site between Lys321 and Ser322, which would predict a transmembrane fragment consistent in size with the observed 6-kD fragment. A Ser-Phe-Ser motif adjacent to the cleavage site is conserved between human, mouse, and rat L-selectin, and a related motif is found proximal to transmembrane domains of other downregulated proteins, such as ACE, CD16-II, and TNF-RII, suggesting the possibility of a common recognition motif.