Abstract

The goal of the proposed experiments is to determine the structural details of fibrinogen that are critical for the formation of normal clot structure. For each case where an altered clot structure is detected, it will be determined whether or not the altered structure is associated with impaired fibrinolysis. Directed mutagenesis experiments are proposed to better define which features of fibrinogen are critical to generate a normal fibrin clot and which features of the fibrin clot are critical to normal fibrinolysis. It has long been postulated that the association of fibrin monomers into an insoluble fibrin clot occurs in two steps, protofibril formation and lateral aggregation. From the cumulative data of many previous investigators, the residues that participate in protofibril formation have been reasonably well defined, but the residues that promote lateral aggregation remain essentially unknown. The current application proposes a new approach to determine which residues of fibrinogen participate in lateral aggregation by constructing intact variant fibrinogen molecules with specified changes that will test the validity of several current models of lateral aggregation. Many of these variant fibrinogens will form altered fibrin clots. It is planned to determine which clot features influence clot lysis by analysis of these altered clots.

  Funding Agency

Agency
National Institute of Health (NIH)
Institute
National Heart, Lung, and Blood Institute (NHLBI)
Type
Research Project (R01)
Project #
5R01HL031048-11
Application #
2430636
Study Section
Hematology Subcommittee 2 (HEM)
Project Start
1984-04-01
Project End
2000-05-31
Budget Start
1997-06-01
Budget End
1998-05-31
Support Year
11
Fiscal Year
1997
Total Cost
Indirect Cost

  Institution

Name
University of North Carolina Chapel Hill
Department
Pathology
Type
Schools of Medicine
DUNS #
078861598
City
Chapel Hill
State
NC
Country
United States
Zip Code
27599

  Publications

Huang, Lihong; Hsiao, Joe Ping-Lin; Powierza, Camilla et al. (2014) Does topology drive fiber polymerization? Biochemistry 53:7824-34
Hudson, Nathan E; Ding, Feng; Bucay, Igal et al. (2013) Submillisecond elastic recoil reveals molecular origins of fibrin fiber mechanics. Biophys J 104:2671-80
Raynal, Bertrand; Cardinali, Barbara; Grimbergen, Jos et al. (2013) Hydrodynamic characterization of recombinant human fibrinogen species. Thromb Res 132:e48-53
Huang, Lihong; Lord, Susan T (2013) The isolation of fibrinogen monomer dramatically influences fibrin polymerization. Thromb Res 131:e258-63
Park, Rojin; Ping, Lifang; Song, Jaewoo et al. (2013) An engineered fibrinogen variant A?Q328,366P does not polymerise normally, but retains the ability to form ? cross-links. Thromb Haemost 109:199-206
Smith, E L; Cardinali, B; Ping, L et al. (2013) Elimination of coagulation factor XIII from fibrinogen preparations. J Thromb Haemost 11:993-5
Lord, Susan T (2011) Molecular mechanisms affecting fibrin structure and stability. Arterioscler Thromb Vasc Biol 31:494-9
Ping, Lifang; Huang, Lihong; Cardinali, Barbara et al. (2011) Substitution of the human ?C region with the analogous chicken domain generates a fibrinogen with severely impaired lateral aggregation: fibrin monomers assemble into protofibrils but protofibrils do not assemble into fibers. Biochemistry 50:9066-75
Hantgan, Roy R; Stahle, Mary C; Lord, Susan T (2010) Dynamic regulation of fibrinogen: integrin ?IIb?3 binding. Biochemistry 49:9217-25
Hudson, Nathan E; Houser, John R; O'Brien 3rd, E Timothy et al. (2010) Stiffening of individual fibrin fibers equitably distributes strain and strengthens networks. Biophys J 98:1632-40

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