Conversion of Fibrinogen to Fibrin: Mechanism of Exposure of TPA- and Plasminogen-binding Sites

Overview

Journal Biochemistry

Specialty Biochemistry

Date 2000 Dec 22

PMID 11123898

Citations 40

Authors

S Yakovlev

E Makogonenko

N Kurochkina

W Nieuwenhuizen

K INGHAM

L Medved

Affiliations

Soon will be listed here.

Abstract

Conversion of fibrinogen into fibrin results in the exposure of cryptic interaction sites and modulation of various activities. To elucidate the mechanism of this exposure, we tested the accessibility of the Aalpha148-160 and gamma312-324 fibrin-specific epitopes that are involved in binding of plasminogen and its activator tPA, in several fragments derived from fibrinogen (fragment D and its subfragments) and fibrin (cross-linked D-D fragment and its noncovalent complex with the E(1) fragment, D-D. E(1)). Neither D nor D-D bound tPA, plasminogen, or anti-Aalpha148-160 and anti-gamma312-324 monoclonal antibodies, indicating that their fibrin-specific epitopes were inaccessible. The Aalpha148-160 epitope became exposed only upon proteolytic removal of the beta- and gamma-modules from D. At the same time, both epitopes were accessible in the D-D.E(1) complex, indicating that the DD.E interaction resulted in their exposure. This exposure was reversible since the dissociation of the D-D.E(1) complex made the sites unavailable, while reconstitution of the complex made them exposed. The results indicate that upon fibrin assembly, driven primarily by the interaction between complementary sites of the D and E regions, the D regions undergo conformational changes that cause the exposure of their plasminogen- and tPA-binding sites. These changes may be involved in the regulation of fibrin assembly and fibrinolysis.

Citing Articles

The sequence 581Ser-610Val in the fibrinogen Aα chain is responsible for the formation of complexes between plasminogen and αC-regions of fibrin(ogen).

Kapustianenko L, Grinenko T, Rebriev A, Tykhomyrov A Heliyon. 2024; 10(23):e40852.

PMID: 39687172 PMC: 11648866. DOI: 10.1016/j.heliyon.2024.e40852.

Deconstructing fibrin(ogen) structure.

Risman R, Sen M, Tutwiler V, Hudson N J Thromb Haemost. 2024; 23(2):368-380.

PMID: 39536819 PMC: 11786978. DOI: 10.1016/j.jtha.2024.10.024.

Internal fibrinolysis of fibrin clots is driven by pore expansion.

Risman R, Paynter B, Percoco V, Shroff M, Bannish B, Tutwiler V Sci Rep. 2024; 14(1):2623.

PMID: 38297113 PMC: 10830469. DOI: 10.1038/s41598-024-52844-4.

Identification of Neural (N)-Cadherin as a Novel Endothelial Cell Receptor for Fibrin and Localization of the Complementary Binding Sites.

Yakovlev S, Tjandra N, Strickland D, Medved L Biochemistry. 2023; 63(2):202-211.

PMID: 38156948 PMC: 10848343. DOI: 10.1021/acs.biochem.3c00475.

Functional properties of individual sub-domains of the fibrin(ogen) αC-domains.

Stohnii Y, Yatsenko T, Nikulina V, Kucheriavyi Y, Hrabovskyi O, Slominskyi O BBA Adv. 2023; 3:100072.

PMID: 37082262 PMC: 10074951. DOI: 10.1016/j.bbadva.2023.100072.