A prourokinase-RGDS chimera

A tetrapeptide, RGDS, was inserted into proUK kringle domain G118-L119 by the construction of a mutant proUK-RGDS gene. The gene was expressed in the baculovirus expression system. Immunoaffinity chromatography was used to purify the chimera and protein with purity over 90% was achieved. The chimera was tested for its platelet membrane binding function and showed a calcium-dependent platelet binding activity. Amidolytic activity of the chimera was tested. The result indicated that specific amidolytic activity of plasmin activated chimera was 62 000 IU/mg, comparable to the previously reported 65 355 IU/mg of plasmin activated natural proUK^[1]. Activation of plasminogen by the chimera after plasmin treatment followed Michieal-Menten kinetics, and the Km was 0.97 μmol/L, which was also comparable to 1.64 μmol/L of native urokinase. The chimera also showed intensive ability to inhibit platelet aggregationin vitro. These results indicate that this chimera might be useful as a bifunctional thrombolytic agent.     

A prourokinase-RGDS chimera——Construction, expression and characterization

A tetrapeptide, RGDS, was inserted into proUK kringle domain G118-L119 by the construction of a mutant proUK-RGDS gene. The gene was expressed in the baculovirus expression system. Immunoaffinity chromatography was used to purify the chimera and protein with purity over 90% was achieved. The chimera was tested for its platelet membrane binding function and showed a calcium-dependent platelet binding activity. Amidolytic activity of the chimera was tested. The result indicated that specific amidolytic activity of plasmin activated chimera was 62000 IU/mg, comparable to the previously reported 65 355 IU/mg of plasmin activated natural proUK. Activation of plasminogen by the chimera after plasmin treatment followed Micbieal-Menten kinetics, and the Km was 0.97 μmol/L, which was also comparable to 1.64 μmol/L of native urokinase. The chimera also showed intensive ability to inhibit platelet aggregation in vitro. These results indicate that this chimera might be useful as a bifunctional thrombolytic agent.     

Purification and characterization of a novel low molecular weight form of single-chain urokinase-type plasminogen activator

A low Mr form (Mr 32,000) of single-chain urokinase-type plasminogen activator (scu-PA) was isolated from conditioned culture medium of a human lung adenocarcinoma cell line, CALU-3 (ATCC, HTB-55). The purified material (scu-PA-32k) consists of a single polypeptide chain and is immunologically similar to Mr 33,000 urokinase. Its NH2-terminal sequence is identical to that beginning at Leu-144 of Mr 54,000 urokinase. Whereas low Mr urokinase is derived from mature Mr 54,000 scu-PA by limited hydrolysis by plasmin first of the Lys-158-Ile-159 peptide bond and then of the Lys-136-Lys-137, scu-PA-32k is generated by specific hydrolysis of the Glu-143-Leu-144 peptide bond by an unidentified protease. scu-PA-32k resembles its Mr 54,000 scu-PA counterpart by its very low activity on chromogenic substrates for urokinase, by plasminogen-dependent fibrinolytic activity on fibrin plates, and by the lack of specific binding to fibrin. It activates plasminogen directly with high affinity, Km = 0.9 microM, but low turnover number, kcat = 0.0028 s-1. It is converted to fully active two-chain urokinase by plasmin with Km = 12 microM and kcat = 0.3 s-1. Like Mr 54,000 scu-PA, it causes significant lysis of a 125I-labeled fibrin clot in human plasma with relatively less fibrinogen breakdown as compared to urokinase. scu-PA-32k, which also has conserved fibrin specificity, represents a molecular variant which may be more suitable for large scale production as a fibrin-specific thrombolytic agent by recombinant DNA technology.     

Engineering of a staphylokinase-based fibrinolytic agent with antithrombotic activity and targeting capability toward thrombin-rich fibrin and plasma clots

Current clinically approved thrombolytic agents have significant drawbacks including reocclusion and bleeding complications. To address these problems, a staphylokinase-based thrombolytic agent equipped with antithrombotic activity from hirudin was engineered. Because the N termini for both staphylokinase and hirudin are required for their activities, a Y-shaped molecule is generated using engineered coiled-coil sequences as the heterodimerization domain. This agent, designated HE-SAKK, was produced and assembled from Bacillus subtilis via secretion using an optimized co-cultivation approach. After a simple in vitro treatment to reshuffle the disulfide bonds of hirudin, both staphylokinase and hirudin in HE-SAKK showed biological activities comparable with their parent molecules. This agent was capable of targeting thrombin-rich fibrin clots and inhibiting clot-bound thrombin activity. The time required for lysing 50% of fibrin clot in the absence or presence of fibrinogen was shortened 21 and 30%, respectively, with HE-SAKK in comparison with staphylokinase. In plasma clot studies, the HE-SAKK concentration required to achieve a comparable 50% clot lysis time was at least 12 times less than that of staphylokinase. Therefore, HE-SAKK is a promising thrombolytic agent with the capability to target thrombin-rich fibrin clots and to minimize clot reformation during fibrinolysis.     

Thrombolytic properties of an inactive proenzyme form of human urokinase secreted from human kidney cells

The relative fibrin-binding, fibrinolytic and fibrinogenolytic properties of single-chain pro-urokinase, an inactive proenzyme form of human urokinase purified from cultured human kidney cells, and urokinase were compared. The affinity of single-chain pro-urokinase for fibrin was much higher than that of urokinase. In Vitro thrombolytic studies showed that single-chain pro-urokinase is approximately three times more potent in fibrinolysis than urokinase and that it does not degrade fibrinogen in the plasma at a concentration, at which complete plasma clot lysis takes place; whereas, urokinase extensively degrades the fibrinogen in the plasma. These specific, potent thrombolytic properties of single-chain pro-urokinase seem to be due to its high affinity for fibrin and to its conversion from the inactive single-chain form to the active two-chain form on the thrombus by the catalytic amount of plasmin generated during coagulation. This single-chain pro-urokinase obtained from human kidney cells by tissue culture should prove advantageous than urokinase in thrombolytic therapy.     

尿激酶静脉溶栓治疗急性心肌梗死的疗效观察--附35例报告

目的 观察尿激酶静脉溶栓治疗急性心肌梗死的疗效.方法将66例急性心肌梗塞住院患者随机分成两组,溶栓组35例在常规治疗的同时,用尿激酶静脉溶栓治疗,非溶栓组仅用常规治疗,两组进行比较分析.结果 溶栓组血管再通率74.3%,非溶栓组为25.81%,两组间有明显差异(P<0.05),住院4周的病死率,溶栓组为2.86%,非溶栓组为16.16%,两组间有显著差异(P<0.01).结论 尿激酶静脉溶栓能明显提高急性心肌梗死患者的血管再通率和抢救成功率,降低近期病死率.     

Construction, expression, and characterization of a recombinant annexin B1-low molecular weight urokinase chimera in Escherichia coli

Thrombolytic therapy has been a major advance in thtreatment of myocardial infarction over the last twdecades. Urokinase (UK), streptokinase (SK), and tissuplasminogen activator (t-PA) are the common availablthrombolytic agents. These agents, however, hav…     

Flow-induced permeation of non-occlusive blood clots: an MRI study and modelling

The success of clot thrombolysis very much depends on efficient clot permeation with blood plasma carrying the thrombolytic agent. In this paper clot permeation was studied by dynamic magnetic resonance imaging (MRI) on artificial non-occlusive blood clots inserted in an artificial circulation system filled with blood plasma to which an MRI contrast agent was added. The MRI results revealed that clot permeation is much faster and more efficient at the entrance of the flow channel across the clot. Clot permeation with fluid was simulated numerically as well. The simulation was based on numerical solution of Navier-Stokes equations for the flow in the channel and within the clot. The clot was considered as a porous material with known permeability and porosity. Based on the calculated velocity profiles, concentration profiles of fluid in the clot were modelled. These agreed well with the MRI results. The presented model of clot permeation with fluid may also serve as a useful extension to numerical modelling of dissolution of non-occlusive blood clots during thrombolytic therapy.     

Successes, failures and complications in thrombolytic therapy in peripheral, arterial and venous occlusions]

Thrombocytic therapy in peripheral arterial and venous vessel occlusion represents a clearly described alternative towards the surgery of vessels. A success rate of 36.5% can be found in subacute peripheral arterial thrombosis and 46.3% in subacute thrombotic occlusion of a bypass-graft. Contrary to that, a rate of 29.8% can be found in complications or side-effects respectively. In cases of peripheral deep venous thrombosis, a partial or full success can be found in 72%. However, the rate of complication amounting to 44.2% is comparatively high. The longer thrombolytic therapy with streptokinase or urokinase will last, the more frequently and more serious will be the complications, such as bleedings of different kind as well as increase of temperature to mention the most frequent ones. The application of urokinase is absolutely possible today, however, the use of urokinase seems to be only justified, if a thrombolytic therapy with streptokinase was carried out successfully and a subsequent surgical therapy was not possible. The present costs of this preparation are far too high for urokinase to be applied routinely. A thrombolytic therapy with SK as well as with UK has to be followed by an anticoagulant treatment.     

叶下珠有效部位的溶栓作用及其对PAI-1和tPA活性的影响

采用改良的Charlton和Tomihisa等方法评价叶下珠植物(Phyllanthus urinaria)含corilagin的水溶性有效部位(代号PUW)对电刺激大鼠颈动脉血栓的溶栓作用;应用发色底物方法测定PUW在体内外对血浆tPA、血浆或血小板释放的PAl-1活性的影响。结果显示,5mg／kg的PUW,其再通率为50％,再栓率为60％;10mg／kg PUW的血管再通率为60％,其再栓率为33．3％,低于2万U／kg尿激酶42．9%的再栓率。再通后1h内,血管开放状态表现为,2万U／kg尿激酶组的血管开放状态与5mg／kg PUW组的相似;10mg／kg PUW组,其持续再通率高于2万U／kg的尿激酶组。PUW在体外或静脉注射均明显降低血浆PAI—1活性,同时提高血浆tPA的活性;PUW静注还明显抑制血小板释放的PA1-1活性。本实验结果提示,PUW静脉注射显著提高闭塞颈动脉的再通率,同时降低再通后颈动脉的再栓率;抑制PAI—1活性,同时提高tPA的活性可能是PUW具有较好溶栓作用的分子机制。     

Mechanism of fibrinolysis and thrombolytic therapy

The thrombolytic treatment with plasminogen activators, such as physiological tissue-type plasminogen activator (t-PA), suffers from a number of significant limitations. There is a resistance to reperfusion and acute coronary reocclusion. The peculiarity of t-PA and one-chain urokinase treatment is their using in very high doses. Thus the process of thrombolytic therapy is proceeding with a deviation from the fibrinolytic mechanism, which is needs of a little quantity of tissue-type plasminogen activator and provides the physiologic thrombolysis without systemic complication. The estimation of this disaccordance suggests, the possible reasons of these complications.     

Construction and expression of antibody targeted plasminogen activator*

It has been known that antibody-mediated plasminogen activator will be much more specific than its parent molecular. To get a cheaper and more effective medicine for thrombolytic therapy, we used SZ51, a GMP140 specific monoclonal antibody, and a truncated single-chain urokinase to construct a novel targeted plasminogen activator. PCR was used to amplify the region of VL and VH chains from Fab of SZ51, GMP140 specific monoclonal antibody, and scu-PA-32KD(leu144-leu411) from urokinase gene, respectively. Through suitable linker and appropriate restriction sites, these fragments were joined together and inserted into the expression vector, pET-5a, via NdeI site. The recombinant protein was expressed in BL21 (DE3) plyS, a kind of E. coli. It was shown in Western-blotting and ELISA that the protein could interact with the multiple cloned antibody of urokinase. After partial purification: dialysis, Sephadex G-100, dialysis and Phenyl-Sepharose fast flow, the product had a strong fibrinolytic activity through activating plasminogen on fibrin plate. The specific activity was about 47,000 IU/mg, corresponding to 80,000 IU/mg for the part of rscu-PA-32k, and the activity could be inhibited specifically by urokinase specific antibody. Activation of plasminogen by the chimera followed Michaelis-Menten kinetics, and the K_m was 1.08 uM.     

Oral urokinase: absorption, mechanisms of fibrinolytic enhancement and clinical effect on cerebral thrombosis

The oral administration of the thrombolytic agent urokinase was studied. Its intestinal absorption was demonstrated in dogs by the observation of a prolonged urokinase activity in plasma with a concomitant lytic effect on artificial thrombi after intraduodenal administration. In situ intestine-liver perfusion experiments in dogs revealed that a plasminogen activator, distinct from the administered urokinase--thus presumed to be a tissue plasminogen activator--was liberated into the circulation in association with intestinal absorption of urokinase. Its absorption in men was demonstrated in a cross-over double blind study of oral urokinase on healthy subjects. On the basis of these results a double blind clinical trial of oral urokinase was performed on 101 patients with cerebral thrombosis. The results showed the usefulness of urokinase treatment, particularly in the early phase after the onset of stroke. The clinical effect was influenced by the plasma plasminogen level.     

Simulation,construction and characterization of a multi-functional thrombolytic agent with anti-thrombosis activity

Prourokinase (scu-PA),a thrombolytic agent,was inserted between Glyl 18 and Ilel 19 with foreign anti-thrombosis functional motif (Lys-Gly-Asp-Trp-motif) to construct a multi-functional chimeric molecule.The molecular model of a chimera was simulated and pre-dicted.The recombinant chimeric protein was expressed by the baculovirus-insect cell expression system and puri-fied by affinity chromatography.The physico-chemical characteristics of the chimeric molecule were assayed.The thrombolytic activity was determined to be 90000 IU/mg of fibrinolytic special activity by the fibrin-plate method.The anti-thrombosis activities were also assayed with IC50 of 9.6 μM by an inhibition test of ADP-induced platelet aggregation.     

Identification of myxomaviral serpin reactive site loop sequences that regulate innate immune responses

The thrombolytic serine protease cascade is intricately involved in activation of innate immune responses. The urokinase-type plasminogen activator and receptor form complexes that aid inflammatory cell invasion at sites of arterial injury. Plasminogen activator inhibitor-1 is a mammalian serpin that binds and regulates the urokinase receptor complex. Serp-1, a myxomaviral serpin, also targets the urokinase receptor, displaying profound anti-inflammatory and anti-atherogenic activity in a wide range of animal models. Serp-1 reactive center site mutations, mimicking known mammalian and viral serpins, were constructed in order to define sequences responsible for regulation of inflammation. Thrombosis, inflammation, and plaque growth were assessed after treatment with Serp-1, Serp-1 chimeras, plasminogen activator inhibitor-1, or unrelated viral serpins in plasminogen activator inhibitor or urokinase receptor-deficient mouse aortic transplants. Altering the P1-P1' Arg-Asn sequence compromised Serp-1 protease-inhibitory activity and anti-inflammatory activity in animal models; P1-P1' Ala-Ala mutants were inactive, P1 Met increased remodeling, and P1' Thr increased thrombosis. Substitution of Serp-1 P2-P7 with Ala6 allowed for inhibition of urokinase but lost plasmin inhibition, unexpectedly inducing a diametrically opposed, proinflammatory response with mononuclear cell activation, thrombosis, and aneurysm formation (p < 0.03). Other serpins did not reproduce Serp-1 activity; plasminogen activator inhibitor-1 increased thrombosis (p < 0.0001), and unrelated viral serpin, CrmA, increased inflammation. Deficiency of urokinase receptor in mouse transplants blocked Serp-1 and chimera activity, in some cases increasing inflammation. In summary, 1) Serp-1 anti-inflammatory activity is highly dependent upon the reactive center loop sequence, and 2) plasmin inhibition is central to anti-inflammatory activity.     

尿激酶原的性质、结构、功能及其药代动力学和临床应用效果

溶栓疗法不仅已被常规地用于急性心肌梗死的治疗,而且也已用于其它血栓病的治疗中,如急性缺血性脑血栓、肺栓塞、急性周围动脉血栓等。尿激酶原是双链尿激酶的单链前体,它主要激活纤维蛋白表面的纤溶蛋白原,所以具有选择性溶栓作用。临床结果表明它是一种安全有效的溶栓药物,与t-PA、链激酶或尿激酶伍用均有协同作用。本文综述它了的特性、结构与功能,以及它的药代动力学和临床的治疗效果。     

The biotechnological potential of fibrinolytic enzymes in the dissolution of endogenous blood thrombi

Formation of endogenous thrombi in blood vessels is one of the leading causes of death in our modern life. According to data provided by the World Health Organization (WHO) in 2000, heart diseases are responsible for 29% of the total mortality rate in the world. For this, a tremendous amount of research has been done in the area of prevention and treatment of these diseases. The classical therapy of these thrombi relies upon the use of antiplatelets, anticoagulants, or even surgeries. Relatively recently, the fibrinolytic enzymes produced by microorganisms, snakes, earthworms, insects, plants, and other organisms are being successfully used in the treatment of blood clots, especially with regard to the direct dissolving action on fibrin in tandem with less cost and side effects in comparison with the first‐generation thrombolytic agents, streptokinase and urokinase. Furthermore, recombinant DNA technology has succeeded in improving and decreasing the undesirable effects of the first generation of enzymes. Recombinant PAs or rt‐PAs like alteplase, retelase, saruplase, tenecteplase, lanoteplase, and desmoteplase became available in the drug markets with advantages of less binding loci with PAI‐1 to avoid degradation while providing faster and more complete reperfusion in a greater number of patients with less risk of bleeding and intracranial hemorrhage. This review is the first to cover all the natural and recombinant thrombolytic agents used in enzyme therapy. © 2014 American Institute of Chemical Engineers Biotechnol. Prog., 30:656–672, 2014     

Development of new thrombolytic agents using recombinant DNA technology.

The increasing incidence of thromboembolic diseases has sustained the search for new agents able to stimulate the natural fibrinolytic system. The first generation of antithrombotic agents include bacterial streptokinase and human urine urokinase. Because these molecules lack specificity for the fibrin clot, important efforts have been made to produce, using recombinant DNA technology, agents presenting higher fibrin clot selectivity such as t-PA (tissue-type plasminogen activator) and scu-PA (single chain urokinase-type plasminogen activator). In parallel, several laboratories are presently attempting to create mutants and hybrids plasminogen activators displaying improved thrombolytic properties with respect to the natural molecules. In this paper, we describe briefly the mechanisms of fibrinolysis and the role of the different natural thrombolytic agents. In addition, we review the possibilities of genetic engineering for the production of natural and novel plasminogen activators.     

Simulation, construction and characterization of a multi-functional thrombolytic agent with anti-thrombosis activity

Prourokinase (scu-PA), a thrombolytic agent, was inserted between Gly118 and Ile119 with foreign antithrombosis functional motif (Lys-Gly-Asp-Trp-motif) to construct a multi-functional chimeric molecule. The molecular model of a chimera was simulated and predicted. The recombinant chimeric protein was expressed by the baculovirus-insect cell expression system and purified by affinity chromatography. The physico-chemical characteristics of the chimeric molecule were assayed. The thrombolytic activity was determined to be 90000 IU/mg of fibrinolytic special activity by the fibrin-plate method. The anti-thrombosis activities were also assayed with IC₅₀ of 9.6 μM by an inhibition test of ADP-induced platelet aggregation.     

Characterization of a recombinant chimeric plasminogen activator with enhanced fibrin binding

A recombinant chimeric plasminogen activator (GHRP-scu-PA-32K), consisting of the tetrapeptide Gly-His-Arg-Pro fused to the N-terminus of the low-molecular single-chain urokinase-type plasminogen activator (Leu144-Leu411), was produced by expression in CHO cells. The stable expression cell line was selected for large-scale expression. The product was purified by antibody-Sepharose affinity chromatography with a recovery of 67%. The apparent molecular weight of purified GHRP-scu-PA-32K was 33 kDa according to SDS-PAGE. Its specific activity was 150000 IU/mg protein according to fibrin plate determination. The conversion of single-chain to two-chain molecules mediated by plasmin was comparable for GHRP-scu-PA-32K (K(m)=4.9 microM, k(2)=0.35 s(-1)) and scu-PA-32K. The activation of plasminogen by GHRP-scu-PA-32K (K(m)=1.02 microM, k(2)=0.0028 s(-1)) was also similar to that of scu-PA-32K. The fibrin binding of GHRP-scu-PA-32K was 2.5 times higher than that of scu-PA-32K at a fibrin concentration of 3.2 mg/ml. In contrast to scu-PA-32K in vitro 125I-fibrin-labeled plasma clot lysis, GHRP-scu-PA had a higher thrombolytic potency, whereas it depleted less fibrinogen in plasma. These results show that GHRP-scu-PA-32K as expected is a potential thrombolytic agent.