Observing and Quantifying Fibroblast-mediated Fibrin Gel Compaction

Cells embedded in collagen and fibrin gels attach and exert traction forces on the fibers of the gel. These forces can lead to local and global reorganization and realignment of the gel microstructure. This process proceeds in a complex manner that is dependent in part on the interplay between the location of the cells, the geometry of the gel, and the mechanical constraints on the gel. To better understand how these variables produce global fiber alignment patterns, we use time-lapse differential interference contrast (DIC) microscopy coupled with an environmentally controlled bioreactor to observe the compaction process between geometrically spaced explants (clusters of fibroblasts). The images are then analyzed with a custom image processing algorithm to obtain maps of the strain. The information obtained from this technique can be used to probe the mechanobiology of various cell-matrix interactions, which has important implications for understanding processes in wound healing, disease development, and tissue engineering applications.     

纤溶活性蛋白检测方法研究进展

迄今为止,对纤溶活性蛋白(fibrinolytic protein)的检测主要有4种方法:纤维平板法(fibrin plate method)、显色底物法(colorimetric assay using chromogenic substrates)、反相纤维蛋白自显影法(reverse fibrin autography)和纤维蛋白酶谱法(fibrin zymography)。纤维平板法可以用来快速判断样品是否具有纤溶活性,同时,纤维平板法和显色底物法也可以用来对纤溶活性蛋白进行半定量分析。反相自显影法和纤维蛋白酶谱法则是两种较新的技术,主要用来对纤溶活性蛋白进行定性分析。详细阐述了这几种技术的发展过程、原理、优缺点和应用范围。     

The interference of plasmic degradation products of human crosslinked fibrin with clot formation

The role of plasmic degradation products of human crosslinked fibrin on polymerization of fibrin monomer and clot formation was studied. Both reactions were inhibited by Fragment DD, which formed a complex with fibrin monomer in a molar ratio 1 : 1. The rate of polymerization was slightly increased by Fragment E but it was not affected by (DD)E complex and Fragment A. Approximately the same amount of fibrin was formed in the presence and absence of Fragments A, E and the complex. It was concluded that of the degradation products of crosslinked fibrin, only Fragment DD is a potent anticoagulant at physiologic pH. The (DD)E complex is inert and Fragments A and E have only marginal effects.     

The clearance of human fibrinogen fragments D1, D2, D3 and fibrin fragment D1 dimer in mice

The clearance of human fibrinogen fragments D₁, D₂, D₃ and fibrin fragment D₁ dimer were studied in the mouse model. Clearance of these fragments is a complex process involving clearance from blood into three other compartments. The overall clearance of fragment D₁ and its dimer were essentially identical. Fragments D₂ and D₃ cleared at a progressively slower rate. Competition studies were performed between ¹²⁵I-labeled fragment D₁ and large molar excesses of unlabelled human fragments D₁, D₂, D₃, D₁ dimer, fragment E, fibrinogen, macroalbumin, mannan and asialooroscomucoid. Of these ligands only the fragment D variants competed for the clearance of ¹²⁵I-labeled fragment D₁. Cross-competition was observed when ¹²⁵I-labeled fragment D₁ dimer was cleared in the presence of large molar excesses of fragment D₁. Autopsies demonstrated that injected fragments D₁, D₂, D₃ and D₁ dimer cleared primarily in liver and kidneys. In some clearance studies, livers were perfused with tissue culture fluid, subjected to light microscopic autoradiography, and silver grain counts performed to localize cleared fragment D₁. These experiments indicated that 80% of the liver uptake was in hepatocytes. However, when silver grain counts were normalized for the number of parenchymal and nonparenchymal cells, the distribution of silver grains was essentially identical (1.8 and 1.6 grains per cell, respectively). It is concluded that fragments D₁, D₂, D₃ and D₁ dimer are recognized by a similar clearance pathway. Since neither fibrinogen nor fragment E competed for the clearance of fragment D₁, it is suggested that determinants present in the fragment D domain become exposed after plasmin attack on fibrinogen and are responsible for clearance.     

The role of ligand-ligand interactions in competition by fibrinogen and fibrin degradation products for fibrinogen binding to human platelets

Binding to human platelets of radioiodinated human fibrinogen and fragments X, Y, D, D₁ dimer and E was studied to determine the domain of the fibrinogen molecule responsible for binding to the platelet receptor. Although the fragments did not bind, some wer able to complete for the binding of fibrinogen to platelets. It was postulated that the fragments bound to fibrinogen and subsequently interfered with its binding to the receptor. Two approaches were developed to test this hypothesis. In the first technique, molecular exclusion on Sephacryl S-200 superfine was utilized to examine the interaction of radiolabeled fragments with fibrinogen. In the second seties of studies, fibrinogen-Sepharose was prepared and the binding of degradation products directly determined. A spin dialysis apparatus was employed in each case to achieve rapid separation of bound and free radioligand. These studies demonstrated that fragments D and E bind to fibrinogen. Therefore, the mechanism by which degradation products interfere with fibrinogen binding to the platelet receptor is ligand-ligand interaction rather than binding of the fragments to the receptor. Since none of the radiolabeled degradation products bound to platelets, it appears that receptor recognition requires the intact molecule.     

Purification and identification of two structural variants of porcine tissue plasminogen activator by affinity adsorption on fibrin

Porcine tissue plasminogen activator has been purified from delipidized heart tissue by affinity adsorption to fibrin. A crude fraction is prepared from an acid tissue extract by precipitation with ammonium sulphate. The tissue activator of this fraction is isolated by adsorption on fibrin and elution with KSCN. The procedure also includes chromatography on arginine-Sepharose and two gel-filtration steps. The final product has a specific activity of 250 000 IU/mg (±16 000) as compared to an international urokinase reference preparation. The yield calculated from the active ammonium sulphate precipitate is about 28%. An approx. 7 000-fold increase of specific activity is obtained, most of which is achieved in the fibrin step. The native tissue plasminogen activator consists of a single chain molecule with a molecular weight of 64 000 as measured by SDS-polyacrylamide gel electrophoresis. In a previous report, it was claimed that the activator is composed of two disulphide-connected polypeptide chains. These results were due to a preparation artefact, caused by proteolytic activity present in the tissue extracts. The introduction of the protease inhibitor aprotinin and 6-amino-hexanoic acid in the purification procedure has abolished the effect of the protease contaminant, leading to the production of a one-chain activator. Treatment with plasmin transforms the native, one-chain tissue activator into a variant composed of two chains of about equal size (M_r 32 000) connected by disulphide bonding. This modified activator is indistinguishable from the one obtained at insufficient protection against proteolytic enzymes. The cleavage by plasmin causes about an 8-fold increase of amidolytic activity as measured on $\text{H}\text{-}\text{D}\text{-}\text{Val}\text{-}\text{Gly}\text{-}\text{Arg}\text{-p-}\text{nitroanalide}$. The fibrinolytic activity as measured by clot lysis is only slightly increased. The physiological significance of the cleavage is discussed.