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  • Title: Localization of an effective fibrin beta-chain polymerization site: implications for the polymerization mechanism.
    Author: Hsieh Kh.
    Journal: Biochemistry; 1997 Aug 05; 36(31):9381-7. PubMed ID: 9235981.
    Abstract:
    To examine whether fibrin N-terminal Aalpha 17-23 and Bbeta 15-25 may contain high-affinity polymerization sites, GPRVVER and GHRPLDKKREE analogs were prepared, and their abilities to inhibit fibrin monomers from repolymerizing were compared in turbidity and clottability assays. Within Aalpha 17-23, GPR is the most active site (IC30 of 0.95-1.36 mM). Its extension into GPRVVER (IC30 of 1.75-2.3 mM) reduced activity. Within Bbeta 15-25, acyl-DKKREE (IC30 of 0.30-0.53 mM) can account for GHRPLDKKREE activity (IC30 of 0. 33-0.44 mM). Comparison of the assays showed that calcium, whose presence induces thick fibrin fibers, elicited a higher turbidity than clottability inhibition. Similarly, the lateral-association-promoting GHRP (IC30 of 1.25-1.43 mM) gave a high turbidity vs clottability inhibition ratio (137%). In contrast, low ratios were found for the linear-association-initiating GPR (73%) and for acyl-DKKREE (34%). Structure-activity correlation showed that fibrinogen-like acyl-GPRP and acyl-GHRP could inhibit D. E association at the millimolar range, but in a manner different from fibrin-related GPR peptides did, which required the NH2 as well as Arg presence. To explain Bbeta 20-25 masking, it is proposed that DKKREE in fibrinogen may engage in ionic and hydrogen bonds with KDSDW, the Aalpha 29-33 sequence implicated in thrombin binding. To explain acyl-GPRP and acyl-GHRP inhibition of D.E association, it is proposed that fibrinogen packing may be mediated by E domain association with alphaC (Aalpha 220-609) fragments of adjacent molecules, and by alphaC-alphaC association. A modified polymerization mechanism is deduced by taking into account fibrinogen N-terminal conformation as well as E domain binding to thrombin vs alphaC fragments. This model proposes the following. (1) Upon thrombin binding to fibrinogen KDSDW, DKKREE may become exposed. (2) Fibrinopeptide A cleavage further unmasks the NH2 and Arg group of GPR, leading to DKKREE and GPR initiation of polymerization. (3) The micromolar-effective thrombin-fibrin(ogen) binding may initiate a partial alphaC repulsion. Subsequent DKKREE and GPR binding to D domains of other fibrin(ogen) will lead to the formation of the trimer and bring additional molecules to fibrin N-terminal region, and the combined steric congestion may lead to a complete alphaC repulsion from the overcrowded E domain. (4) Repulsion of the large Aalpha 220-609 fragments may unmask multiple polymerization sites beyond the fibrin N-terminal region.
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