Platelet Cytoskeletal Force Transmission Through The GPIb-IX-V Complex

The GPIb-IX-V complex contains 4 polypeptides, GPIbα, GPIbβ, GPIX and GPV. Only GPIbα binds VWF, which it does through VWF's A1 domain. GPIbα also attaches the complex to the actin and membrane skeletons through its cytoplasmic domain, with the large skeletal protein filamin functioning as the intermediary. There is strong evidence that the GPIbα-A1 bond is force sensitive, becoming stronger as force is applied to it, a property that defines it as a “catch bond”. For this reason, we investigated the role of GPIbα in transmitting platelet forces using a new tool that we have developed to measure contractile forces generated by platelets. This tool, composed of arrays of nanoposts separated by 2 μm (Figure 1), was fabricated using e-beam lithography. VWF was adsorbed to the tips of the nanoposts and platelets were allowed to adhere, spread, and contract. To assess the contribution of α_IIbβ₃ and GPIbα to force generation, we blocked these receptors with the antibodies 7E3 and AK2, respectively. Treatment with 7E3 significantly lowered the force generated, but did not eliminate it completely (57% reduction). AK2 had a smaller effect (20% reduction), and the combination of the two usually abolished force generation. We observed a similar force reduction (30%) as AK2 treatment when we blocked the VWF A1 domain with recombinant GPIbα N-terminus. Because VWF contains binding sites for more than one platelet receptor, and although purified, could have trace amounts of other plasma proteins, we also evaluated force generation on nanoposts coated with recombinant VWF A1 domain, which should only bind GPIbα. In this case, the platelets generated forces similar to those observed when α_IIbβ₃ was blocked by 7E3, providing further evidence that GPIbα can transmit forces by binding the A1 domain.

As a final test of the ability of GPIbα to support force generation, we examined whether Chinese hamster ovary (CHO) cells expressing the GPIb-IX complex (CHOαβIX, fully functional but lacking GPV) could generate force on VWF or A1 domain (Figure 2). CHOαβIX cells adhered, spread and generated forces of similar magnitude on microposts (larger because of the larger cell size) coated with either substrate. CHOβIX cells, lacking GPIbα, did not adhere to either substrate.