1dvn

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==Overview==
==Overview==
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Serpins exhibit a range of physiological roles and can contribute to, certain disease states dependent on their various conformations., Understanding the mechanisms of the large-scale conformational, reorganizations of serpins may lead to a better understanding of their, roles in various cardiovascular diseases. We have studied the serpin, plasminogen activator inhibitor 1 (PAI-1), in both the active and the, latent state and found that anionic halide ions may play a role in the, active-to-latent structural transition. Crystallographic analysis of a, stable mutant form of active PAI-1 identified an anion-binding site, between the central beta-sheet and a small surface domain. A chloride ion, was modeled in this site, and its identity was confirmed by soaking, crystals in a bromide-containing solution and calculating a, crystallographic difference map. The anion thus located forms a 4-fold, ligated linchpin that tethers the surface domain to the central beta-sheet, into which the reactive center loop must insert during the, active-to-latent transition. Timecourse experiments measuring active PAI-1, stability in the presence of various halide ions showed a clear trend for, stabilization of the active form with F(-) > Cl(-) > Br(-) >> I(-). We, propose that the "stickiness" of this pin (i.e., the electronegativity of, the anion) contributes to the energetics of the active-to-latent, transition in the PAI-1 serpin.
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Serpins exhibit a range of physiological roles and can contribute to certain disease states dependent on their various conformations. Understanding the mechanisms of the large-scale conformational reorganizations of serpins may lead to a better understanding of their roles in various cardiovascular diseases. We have studied the serpin, plasminogen activator inhibitor 1 (PAI-1), in both the active and the latent state and found that anionic halide ions may play a role in the active-to-latent structural transition. Crystallographic analysis of a stable mutant form of active PAI-1 identified an anion-binding site between the central beta-sheet and a small surface domain. A chloride ion was modeled in this site, and its identity was confirmed by soaking crystals in a bromide-containing solution and calculating a crystallographic difference map. The anion thus located forms a 4-fold ligated linchpin that tethers the surface domain to the central beta-sheet into which the reactive center loop must insert during the active-to-latent transition. Timecourse experiments measuring active PAI-1 stability in the presence of various halide ions showed a clear trend for stabilization of the active form with F(-) > Cl(-) > Br(-) >> I(-). We propose that the "stickiness" of this pin (i.e., the electronegativity of the anion) contributes to the energetics of the active-to-latent transition in the PAI-1 serpin.
==Disease==
==Disease==
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[[Category: Homo sapiens]]
[[Category: Homo sapiens]]
[[Category: Single protein]]
[[Category: Single protein]]
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[[Category: Buckley, D.I.]]
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[[Category: Buckley, D I.]]
[[Category: Graham, H.]]
[[Category: Graham, H.]]
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[[Category: Matthews, D.J.]]
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[[Category: Matthews, D J.]]
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[[Category: Stout, T.J.]]
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[[Category: Stout, T J.]]
[[Category: inhibitor]]
[[Category: inhibitor]]
[[Category: pai-1]]
[[Category: pai-1]]
[[Category: serpin]]
[[Category: serpin]]
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''Page seeded by [http://oca.weizmann.ac.il/oca OCA ] on Fri Feb 15 15:40:59 2008''
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''Page seeded by [http://oca.weizmann.ac.il/oca OCA ] on Thu Feb 21 12:20:57 2008''

Revision as of 10:21, 21 February 2008

Image:1dvn.jpg

1dvn, resolution 2.10Å

Drag the structure with the mouse to rotate

LATENT FORM OF PLASMINOGEN ACTIVATOR INHIBITOR-1 (PAI-1)

Contents

Overview

Serpins exhibit a range of physiological roles and can contribute to certain disease states dependent on their various conformations. Understanding the mechanisms of the large-scale conformational reorganizations of serpins may lead to a better understanding of their roles in various cardiovascular diseases. We have studied the serpin, plasminogen activator inhibitor 1 (PAI-1), in both the active and the latent state and found that anionic halide ions may play a role in the active-to-latent structural transition. Crystallographic analysis of a stable mutant form of active PAI-1 identified an anion-binding site between the central beta-sheet and a small surface domain. A chloride ion was modeled in this site, and its identity was confirmed by soaking crystals in a bromide-containing solution and calculating a crystallographic difference map. The anion thus located forms a 4-fold ligated linchpin that tethers the surface domain to the central beta-sheet into which the reactive center loop must insert during the active-to-latent transition. Timecourse experiments measuring active PAI-1 stability in the presence of various halide ions showed a clear trend for stabilization of the active form with F(-) > Cl(-) > Br(-) >> I(-). We propose that the "stickiness" of this pin (i.e., the electronegativity of the anion) contributes to the energetics of the active-to-latent transition in the PAI-1 serpin.

Disease

Known diseases associated with this structure: Hemorrhagic diathesis due to PAI1 deficiency OMIM:[173360], Thrombophilia due to excessive plasminogen activator inhibitor OMIM:[173360]

About this Structure

1DVN is a Single protein structure of sequence from Homo sapiens. Full crystallographic information is available from OCA.

Reference

Structures of active and latent PAI-1: a possible stabilizing role for chloride ions., Stout TJ, Graham H, Buckley DI, Matthews DJ, Biochemistry. 2000 Jul 25;39(29):8460-9. PMID:10913251

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