Protein C inhibitor (PCI) inhibits multiple plasma serine proteases. T
o determine which residues contribute to its specificity of inhibition
, 19 mutations in the reactive site loop of PCI (from Thr(352) to Arg(
357)) were generated and assayed with thrombin, activated protein C (A
PC), and factor Xa. To identify the intermolecular interactions respon
sible for these kinetics, a molecular model of PCI was generated using
alpha(1)-protease inhibitor and ovalbumin as templates. This model of
PCI was docked with thrombin, followed by extensive energy minimizati
on, to determine a lowest energy complex. The resulting docked complex
was used as a template to form molecular models of PCI-APC and PCI-fa
ctor Xa complexes. The best inhibitors of thrombin contained Pro or Gl
y at the P2 position in place of Phe(353), With 2 and 7-fold increases
in activity, respectively. These substitutions reduced steric interac
tions with the 60-insertion loop unique to thrombin. The best inhibito
rs of APC and factor Xa contained Arg at the P3 position in place of T
hr(352), With 2- and 5-fold increases in inhibition rates, respectivel
y. The molecular model predicts that Arg in this position could form a
salt bridge with Glu(217) of each protease. Changing Arg(357) at the
P3' position had little effect on protease inhibition, consistent with
the observation in the model that this residue points toward the body
of PCI, forming a salt bridge with Glu(220). Given its broad specific
ity of inhibition, PCI has proven very useful in understanding the nat
ure of serpin-protease interactions using multiple mutations in a serp
in assayed with multiple proteases.