Spontaneous fibrinolysis in whole human plasma. Identification of tissue activator-related protein as the major plasminogen activator causing spontaneous activity in vitro

Spontaneous fibrinolysis of plasma clots was studied by following the lysis of the clots formed in 125I-fibrinogen-supplemented citrated plasma. Lysis of the clots invariably follows sigmoidal kinetics with S50 (the time required for 50% clot lysis) ranging from 3.5 to 4.7 days in 8 samples of pooled blood bank plasma and in the majority of apparently healthy donor plasmas. The spontaneous lysis of factor XII-deficient and prekallikrein-deficient plasmas was found to be similar to that of normal plasma. Addition of ellagic acid or antibodies against kallikrein or urokinase to normal pooled plasma did not alter significantly its rate of spontaneous lysis. On the other hand the addition of antibody against tissue activator (t-PA) inhibited over 80% of the spontaneous fibrinolysis in a 7-day incubation period at 37 degrees C, and the clot visually persisted for more than a month. Therefore, the factor XII-dependent components and prourokinase/urokinase system do not contribute significantly in whole plasma fibrinolysis in vitro, while the t-PA-related protein appears to be the major plasminogen activator responsible for initiating spontaneous fibrinolysis in whole plasma. Exogenous addition of increasing amounts of purified HeLa cell t-PA to normal pooled plasma in the ng/ml range cause progressively faster clot lysis. By extrapolation, normal pooled plasma is found to contain endogenous tissue activator in an amount functionally equivalent to 2 ng/ml of purified 60-kDa t-PA. The molecular nature of the t-PA-related proteins in plasma was studied by zymographic and immunological methods. The major t-PA-related protein in plasma was found to have a molecular mass of 100 kDa as determined by zymography. By incubating purified HeLa 60-kDa t-PA with a t-PA-depleted plasma, the 100-kDa component can be generated in plasma, suggesting that the latter is formed as a result of the binding of 60-kDa t-PA to a binding protein in plasma.     

An inhibitor of plasminogen activation from human placenta. Purification and characterization

Placental extracts contain inhibitors of human urinary urokinase. These extracts form a heterogeneous population of complexes with 125I-urokinase that are recognizable by changes in gel filtration profile and mobility during sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Treatment with reducing agents eliminated the size heterogeneity without loss of activity, thereby allowing the placental inhibitor to be purified. Active inhibitor has been isolated in apparently homogeneous form after an eight-step procedure that included salt extraction, ammonium sulfate fractionation, column chromatography on CM-cellulose, DEAE-Sepharose, and hydroxylapatite, chromatofocusing, preparative gel electrophoresis, and hydrophobic chromatography. The purified inhibitor has Mr = 47,000. The inhibitor is relatively specific for plasminogen activators since it does not inhibit the action of plasmin, factor XIIa, plasma kallikrein, or thrombin. The inhibitor forms complexes with 1:1 stoichiometry that block the active sites of urokinase (but not prourokinase) and both one- and two-chain forms of tissue plasminogen activator. The stability of these complexes in sodium dodecyl sulfate-polyacrylamide gel electrophoresis suggest that they are based on covalently bonded structures. Although both types of plasminogen activator are inhibited, the rate of interaction is significantly faster with urokinase, tissue plasminogen activator being inhibited less efficiently. The complexes formed can be dissociated by mild alkali or hydroxylamine, thereby regenerating both enzymes and inhibitor at their original molecular weights. The results suggest that the complexes are stabilized by ester-like bonds; these might involve the hydroxyl of serine at the active site of the proteases and a carboxyl group in the inhibitor.     

Advances in the molecular biology of plant seed storage proteins

Plant seed storage proteins were among the first proteins to be isolated (20); however, only recently, as a result of using molecular biology techniques, have the amino acid sequences of many of these proteins been determined. With the accumulation of amino acid sequence data for many vicilin-type storage proteins much has been learned concerning the location of conserved amino acid regions and other regions which can tolerate amino acid sequence variation. Combining this knowledge with recent advances in plant gene transfer technologies will allow molecular biologists to correct (by using amino acid replacement mutations) the sulfur amino acid deficiency inherent to bean seed storage proteins. The development of more nutritious soybean and common bean seeds will be of benefit to programs involving human and animal nutrition.     

Transformation of Soybean (Glycine max) by Infecting Germinating Seeds with Agrobacterium tumefaciens

The transfer of genetic material into soybean tissue was accomplished by using an avirulent strain of Agrobacterium tumefaciens which contained the binary vector pGA482. The method used for transformation requires no tissue culture steps as it involves the inoculation of the plumule, cotyledonary node, and adjacent cotyledon tissues of germinating seeds. The identification of neomycin phosphotransferase (NPT) II enzyme activity in the tissues of 16 (R₀) soybean plants indicated that the plant expressible Nos-NPT II gene, contained within the T-DNA region from pGA482, had been transferred at least into somatic tissues. Putative transformed R₀ soybean plants were advanced to produce R₁ plants which were also assayed for the presence of the transferred Nos-NPT II gene. The combined results of these assays indicated that about 0.7% of the surviving inoculated seeds yielded transformed tissues in the R₀ plant, and that about 1/10 of these plants yielded transformed R₁ plants. The presence of the Nos-NPT II gene in DNAs isolated from both R₀ and R₁ plant was demonstrated by using genomic blot hybridization and polymerase chain reaction methods. Integration of this gene into the soybean genome was demonstrated for three R₁ soybean plants.     

Plasminogen activation: biochemistry, physiology, and therapeutics

The mammalian serine protease zymogen, plasminogen, can be converted into the active enzyme plasmin by vertebrate plasminogen activators urokinase (uPA), tissue plasminogen activator (tPA), factor XII-dependent components, or by bacterial streptokinase. The biochemical properties of the major components of the system, plasminogen/plasmin, plasminogen activators, and inhibitors of the plasminogen activators, are reviewed. The plasmin system has been implicated in a variety of physiological and pathological processes such as fibrinolysis, tissue remodeling, cell migration, inflammation, and tumor invasion and metastasis. A defective plasminogen activator/inhibitor system also has been linked to some thromboembolic complications. Recent studies of the mechanism of fibrinolysis in human plasma suggest that tPA may be the primary initiator and that overall fibrinolytic activity is strongly regulated at the tPA level. A simple model for the initiation and regulation of plasma fibrinolysis based on these studies has been formulated. The plasminogen activators have been used for thrombolytic therapy. Three new thrombolytic agents--tPA, pro-uPA, and acylated streptokinase-plasminogen complex--have been found to possess better properties over their predecessors, urokinase and streptokinase. Further improvements of these molecules using genetic and protein engineering tactics are being pursued.     

Enzymatic multiplex DNA sequencing.

The problem of reading DNA sequence films has been reformulated using an easily implemented, multiplex version of enzymatic DNA sequencing. By utilizing a uniquely tagged primer for each base-specific sequencing reaction, the four reactions can be pooled and electrophoresed in a single lane. This approach has been previously proposed for use with fluorescently labelled probes (1), and is analogous to the principle used in four-dye fluorescence sequencing except that the signals are resolved following electrophoresis (2). After transfer to a nylon membrane, images are obtained separately for each of the four reactions by hybridization using oligonucleotide probes. The images can then be superimposed to reconstitute a complete sequence pattern. In this way the correction of gel distortion effects and accurate band registration are considerably simplified, as each of the four base-specific ladders require very similar corrections. The methods therefore provide the basis for a second generation of more accurate and reliable film reading programs, as well as being useful for conventional multiplex sequencing. Unlike the original multiplex protocol (3), the approach described is suitable for small projects, as multiple cloning vectors are not used. Although more than one vector can be utilized, only a library of fragments cloned into any single phage, phagemid or plasmid vector is actually required, together with a set of tagged oligonucleotide primers.     

Receptor-mediated internalization and degradation of urokinase is caused by its specific inhibitor PAI-1.

The receptor for urokinase plasminogen activator (uPA) has been previously shown not to internalize its ligand, but rather to focalize its activity at the cell surface, allowing a regulated cell surface plasmin dependent proteolysis. The receptor in fact binds the proenzyme pro-uPA and allows its very efficient conversion to the active two chains form. Receptor bound active uPA can also interact with its specific type 1 inhibiror (PAI-1) which is therefore able to inhibit the cell surface plasmin formation. In this paper we show that the uPA-PAI-1 complex bound to the uPA receptor is internalized and degraded. U937 cells were incubated at 4 degrees C with labeled uPA-PAI-1 (and other ligands), the temperature then raised to 37 degrees C and the fate of the ligand followed for 3 h thereafter. The uPA-PAI-1 complex was internalized into the cells (i.e. could not be dissociated by acid treatment) and thereafter degraded (i.e. appeared in the supernatant in a non TCA-precipitable form). Other ligands (free uPA, ATF and DFP-treated uPA) were not internalized nor degraded. The degradation of the uPA-PAI-1 complex is preceded by internalization and is inhibited by chloroquine, an inhibitor of lysosomal protein degradation. These data suggest the existence of a cellular cycle of uPA. After synthesis pro-uPA is secreted, bound to the receptor and activated to two chain uPA. On the surface, uPA can activate surface bound plasminogen to produce surface bound plasmin. In the presence of PAI-1 uPA activity is inhibited and plasmin production interrupted, while the uPA-PAI-1 complex is internalized and degraded.