J Crossen1, S L Diamond2. 1. Department of Chemical and Biomolecular Engineering, Institute for Medicine and Engineering, University of Pennsylvania, Philadelphia, PA 19104, United States.. Electronic address: jcrossen@seas.upenn.edu. 2. Department of Chemical and Biomolecular Engineering, Institute for Medicine and Engineering, University of Pennsylvania, Philadelphia, PA 19104, United States.. Electronic address: sld@seas.upenn.edu.
Abstract
BACKGROUND: Thrombin activates fibrinogen and binds the fibrin E-domain (Kd ~ 2.8 μM) and the splice variant γ'-domain (Kd ~ 0.1 μM). We investigated if the loading of D-Phe-Pro-Arg-chloromethylketone inhibited thrombin (PPACK-thrombin) onto fibrin could enhance fibrin stability. METHODS: A 384-well plate thermal shift assay (TSA) with SYPRO-orange provided melting temperatures (Tm) of thrombin, PPACK-thrombin, fibrinogen, fibrin monomer, and fibrin. RESULTS: Large increases in Tm indicated that calcium led to protein stabilization (0 vs. 2 mM Ca2+) for fibrinogen (54.0 vs. 62.3 °C) and fibrin (62.3 vs. 72.2 °C). Additionally, active site inhibition with PPACK dramatically increased the Tm of thrombin (58.3 vs. 78.3 °C). Treatment of fibrinogen with fibrin polymerization inhibitor GPRP increased fibrinogen stability by ΔTm = 9.3 °C, similar to the ΔTm when fibrinogen was converted to fibrin monomer (ΔTm = 8.8 °C) or to fibrin (ΔTm = 10.4 °C). Addition of PPACK-thrombin at high 5:1 M ratio to fibrin(ogen) had little effect on fibrin(ogen) Tm values, indicating that thrombin binding does not detectably stabilize fibrin via a putative bivalent E-domain to γ'-domain interaction. CONCLUSIONS: TSA was a sensitive assay of protein stability and detected: (1) the effects of calcium-stabilization, (2) thrombin active site labeling, (3) fibrinogen conversion to fibrin, and (4) GPRP induced changes in fibrinogen stability being essentially equivalent to that of fibrin monomer or polymerized fibrin. SIGNIFICANCE: The low volume, high throughput assay has potential for use in understanding interactions with rare or mutant fibrin(ogen) variants.
BACKGROUND: Thrombin activates fibrinogen and binds the fibrin E-domain (Kd ~ 2.8 μM) and the splice variant γ'-domain (Kd ~ 0.1 μM). We investigated if the loading of D-Phe-Pro-Arg-chloromethylketone inhibited thrombin (PPACK-thrombin) onto fibrin could enhance fibrin stability. METHODS: A 384-well plate thermal shift assay (TSA) with SYPRO-orange provided melting temperatures (Tm) of thrombin, PPACK-thrombin, fibrinogen, fibrin monomer, and fibrin. RESULTS: Large increases in Tm indicated that calcium led to protein stabilization (0 vs. 2 mM Ca2+) for fibrinogen (54.0 vs. 62.3 °C) and fibrin (62.3 vs. 72.2 °C). Additionally, active site inhibition with PPACK dramatically increased the Tm of thrombin (58.3 vs. 78.3 °C). Treatment of fibrinogen with fibrin polymerization inhibitor GPRP increased fibrinogen stability by ΔTm = 9.3 °C, similar to the ΔTm when fibrinogen was converted to fibrin monomer (ΔTm = 8.8 °C) or to fibrin (ΔTm = 10.4 °C). Addition of PPACK-thrombin at high 5:1 M ratio to fibrin(ogen) had little effect on fibrin(ogen) Tm values, indicating that thrombin binding does not detectably stabilize fibrin via a putative bivalent E-domain to γ'-domain interaction. CONCLUSIONS: TSA was a sensitive assay of protein stability and detected: (1) the effects of calcium-stabilization, (2) thrombin active site labeling, (3) fibrinogen conversion to fibrin, and (4) GPRP induced changes in fibrinogen stability being essentially equivalent to that of fibrin monomer or polymerized fibrin. SIGNIFICANCE: The low volume, high throughput assay has potential for use in understanding interactions with rare or mutant fibrin(ogen) variants.
Authors: Laura M Haynes; Thomas Orfeo; Kenneth G Mann; Stephen J Everse; Kathleen E Brummel-Ziedins Journal: Biophys J Date: 2017-04-25 Impact factor: 4.033
Authors: Fabian Barthels; Stefan J Hammerschmidt; Tim R Fischer; Collin Zimmer; Elisabeth Kallert; Mark Helm; Christian Kersten; Tanja Schirmeister Journal: HardwareX Date: 2022-01-07