By Pete Lollar, MD
2009-09-01
Dr.
Lollar indicated no relevant conflicts of interest.
Kroh HK, Panizzi P,
and Bock PE.
Von
Willebrand factor-binding protein is a hysteretic conformational activator of
prothrombin. Proc Natl Acad Sci USA. 2009;106:7786-91.
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| Click image to enlarge |
Most of the
trypsin-like serine proteases in the coagulation and fibrinolytic mechanisms are
formed by proteolytic activation from an inactive precursor, called the zymogen.
During this process, a peptide at the NH2-terminus
of the zymogen is cleaved. In a process referred to as molecular sexuality, the
newly formed NH2-terminus of the nascent
enzyme forms an internal salt bridge that results in conformational activation of
the catalytic site. Prothrombin (proT) normally is proteolytically activated to
thrombin by factor Xa. However, staphylocoagulase, a secretory product of Staphylococcusaureus, activates prothrombin non-proteolytically. In 2003, Friedrich et
al., from the laboratory of Paul Bock at Vanderbilt University,
reported that staphylocoagulase accomplishes this by inserting a dipeptide from its NH2-terminus into
proT to substitute for the normal internal salt bridge.¹
Von Willebrand factor-binding protein (vWbp) is another
secretory product of S. aureus and is homologous to staphylocoagulase.
Kroh et al., from the Bock laboratory, now have found that vWbp also is
a potent activator of proT. Like staphylocoagulase, vWbp non-proteolytically
activates proT by a molecular sexuality mechanism. However, unlike staphylocoagulase,
there is a distinct lag period between the addition of vWbp to proT and
the development of enzymatic activity. Approximately 40 years ago, Carl Frieden
used the term hysteresis, from the Greek meaning “lagging behind,” to
describe a mechanism in which enzymes develop activity only after a slow
conformational change that follows the formation of the initial enzyme-substrate
complex.² Bock trained under Frieden, and, thus, he and his co-workers
were prepared to determine whether the vWbp-proT complex is a hysteretic
enzyme. They found that the behavior of the vWbp-proT complex indeed fit a kinetic
model consistent with the hysteretic mechanism. In the model, vWbp binds
rapidly to proT. The resulting complex slowly equilibrates into an
active vWbp-proT* complex that binds the substrate, S, with high affinity
(Figure). There is a lag phase as the substrate (e.g., fibrinogen) waits for
the active vWbp-proT* complex to form. Once formed, the fibrinogen rapidly
latches on and is converted to product.
Kroh et al. propose that during staphylococcal endocarditis
vWbp binds to von Willebrand factor that has been deposited at sites of
vascular injury. Because a substrate is required in vivo to pull the
vWbp-proT complex toward the active state, they suggest that the hysteretic mechanism
restricts activation of proT by vWbp to areas rich in the substrate, fibrinogen.
Thus, the initial formation of fibrin on infected heart valves may be catalyzed
by vWbp-proT, followed by additional staphylocoagulase-mediated fibrin
deposition and vegetation growth.
This study is important because it describes a novel
enzyme, vWbp-proT, and rigorously tests a kinetic mechanism that accounts for
the lag behavior displayed by the enzyme. This behavior is then interpreted in
the context of an important disease setting, staphylococcal endocarditis.
- Friedrich R, Panizzi P, Fuentes-Prior P, et
al. Staphylocoagulase
is a prototype for the mechanism of cofactor-induced zymogen activation. Nature.
2003;425:535-9.
-
Frieden
C. Kinetic aspects of regulation of metabolic processes. The hysteretic enzyme concept.
J.Biol.Chem. 1970;245:5788-99.
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