RESUMEN
This report identifies a novel variant form of the inherited bleeding disorder Glanzmann thrombasthenia, exhibiting only mild bleeding in a physically active individual. The platelets cannot aggregate ex vivo with physiologic agonists of activation, although microfluidic analysis with whole blood displays moderate ex vivo platelet adhesion and aggregation consistent with mild bleeding. Immunocytometry shows reduced expression of αIIbß3 on quiescent platelets that spontaneously bind/store fibrinogen, and activation-dependent antibodies (ligand-induced binding site-319.4 and PAC-1) report ß3 extension suggesting an intrinsic activation phenotype. Genetic analysis reveals a single F153Sß3 substitution within the ßI-domain from a heterozygous T556C nucleotide substitution of ITGB3 exon 4 in conjunction with a previously reported IVS5(+1)G>A splice site mutation with undetectable platelet messenger RNA accounting for hemizygous expression of S153ß3. F153 is completely conserved among ß3 of several species and all human ß-integrin subunits suggesting that it may play a vital role in integrin structure/function. Mutagenesis of αIIb-F153Sß3 also displays reduced levels of a constitutively activated αIIb-S153ß3 on HEK293T cells. The overall structural analysis suggests that a bulky aromatic, nonpolar amino acid (F,W)153ß3 is critical for maintaining the resting conformation of α2- and α1-helices of the ßI-domain because small amino acid substitutions (S,A) facilitate an unhindered inward movement of the α2- and α1-helices of the ßI-domain toward the constitutively active αIIbß3 conformation, while a bulky aromatic, polar amino acid (Y) hinders such movements and restrains αIIbß3 activation. The data collectively demonstrate that disruption of F153ß3 can significantly alter normal integrin/platelet function, although reduced expression of αIIb-S153ß3 may be compensated by a hyperactive conformation that promotes viable hemostasis.
