Kindlin-3 Undergoes Endoproteolysis in Stored Platelets and After Platelet Stimulation

Abstract 1255

Kindlins are a family of FERM domain proteins that are essential for inside-out integrin activation. In particular, kindlin-3 is required for the conversion of the major platelet integrin αIIbβ3 from its resting conformation to its active ligand binding conformation. Moreover, naturally-occurring kindlin-3 mutations result in the inherited disorder leukocyte adhesion deficiency III, one component of which is defective platelet function that mimics Glanzmann thrombasthenia. Despite the importance of kindlin-3 in initiating αIIbβ3 function in platelets, little is known about its regulation in resting platelets or its fate in activated platelets. To address these questions, we purified full-length kindlin-3 from outdated human platelets where it is present in substantial amounts and also developed a procedure to synthesize substantial amounts of recombinant kindlin-3 in SF9 cells. We found that in stored human platelets, kindlin-3 is cleaved into two fragments as a function of the time of storage. We also found that kindlin-3 is cleaved into identical fragments when fresh human platelets are stimulated with the thrombin receptor activating peptide (TRAP) for 5 minutes. To identify the site of kindlin-3 cleavage, as well as the responsible protease, we used a proteomics method in which an engineered peptide ligase, subtiligase, was used to selectively biotinylate the unblocked α amines of proteins obtained from platelet lysates (Mahrus et al, Cell 134:866–76, 2008). Biotinylated proteins were digested with trypsin and the resulting biotinylated peptide fragments were then captured using avidin agarose and identified using tandem mass spectrometry. Using this method, we identified the kindlin-3 peptide (G)SAPTDVLDSLTTIPELKDHL in lysates of stored platelets, thereby mapping the cleavage site to residues 335–336. We obtained identical results using proteins isolated from TRAP-stimulated platelets. Further, we were able to recapitulate these results in vitro using purified kindlin-3 and the calcium-activated protease calpain, implying that calpain is the responsible protease in vivo. Kindlin-3 is thought to initiate αIIbβ3 function by binding to the distal NITY motif in the β3 cytosolic tail in an interaction that also involves S752. Previously, we reported a model for αIIbβ3 regulation based on an NMR structure of the β3 cytosolic tail (Metcalf et al, PNAS 107:24775–83, 2010). In this structure, the NITY motif is located in a distal dynamic amphiphilic helix where the motif is transiently masked by interacting with the membrane. To validate this model, we have studied the interaction of both purified and recombinant kindlin-3 with the β3 tail using surface plasmon resonance (SPR). A peptide corresponding to β3 residues 719–762, encompassing the complete β3 tail, was immobilized on a CM5 chip and kindlin-3 was flowed over the chip surface. The resulting sensorgrams could then be fit to two binding events with dissociation constants of 2.2 nM and 2.8 μM. The biphasic behavior could have resulted from heterogeneity of the β3 tail on the chip surface or heterogeneity of the interaction between kindlin-3 and the carboxymethylated dextran. Similar SPR experiments measuring binding of the talin-1 FERM domain to the β3 tail also could be fit to two binding events with dissociation constants of 155 nM and 3.5 μM. Thus, under these experimental conditions, kindlin-3 binds approximately 70-fold more tightly to the β3 tail than does the talin-1 FERM domain. In summary, these studies demonstrate that kindlin-3 undergoes calpain-mediated endoproteolysis during platelet storage, an event that may contribute to the development of the platelet storage lesion. Kindlin-3 also undergoes an identical cleavage following platelet stimulation by agonists such as thrombin. Since high affinity binding of kindlin-3 to the β3 cytosolic tail is required for physiologic αIIbβ3 activation, it is possible that kindlin-3 cleavage attenuates αIIbβ3 activity.