Mast Cells and Basophils in the Defense against Ectoparasites: Efficient Degradation of Parasite Anticoagulants by the Connective Tissue Mast Cell Chymases.

Ticks, lice, flees, mosquitos, leeches and vampire bats need to prevent the host's blood coagulation during their feeding process. This is primarily achieved by injecting potent anticoagulant proteins. Basophils frequently accumulate at the site of tick feeding. However, this occurs only after the second encounter with the parasite involving an adaptive immune response and IgE. To study the potential role of basophils and mast cells in the defense against ticks and other ectoparasites, we produced anticoagulant proteins from three blood-feeding animals; tick, mosquito, and leech. We tested these anticoagulant proteins for their sensitivity to inactivation by a panel of hematopoietic serine proteases. The majority of the connective tissue mast cell proteases tested, originating from humans, dogs, rats, hamsters, and opossums, efficiently cleaved these anticoagulant proteins. Interestingly, the mucosal mast cell proteases that contain closely similar cleavage specificity, had little effect on these anticoagulant proteins. Ticks have been shown to produce serpins, serine protease inhibitors, upon a blood meal that efficiently inhibit the human mast cell chymase and cathepsin G, indicating that ticks have developed a strategy to inactivate these proteases. We show here that one of these tick serpins (IRS-2) shows broad activity against the majority of the mast cell chymotryptic enzymes and the neutrophil proteases from human to opossum. However, it had no effect on the mast cell tryptases or the basophil specific protease mMCP-8. The production of anticoagulants, proteases and anti-proteases by the parasite and the host presents a fascinating example of an arms race between the blood-feeding animals and the mammalian immune system with an apparent and potent role of the connective tissue mast cell chymases in the host defense.

Polysulfated trehalose as a novel anticoagulant agent with dual mode of action.

Physiological hemostatic balance is a coordinated outcome of counteracting coagulation and fibrinolytic systems. An imbalance of procoagulant and anticoagulant factors may result in life threatening thromboembolism. Presently, anticoagulant administration is the first line of therapy for the treatment of these conditions and several anticoagulants have been approved, including various forms of heparin. However, the polyanionic nature and multispecificity of heparin pose several complications. Generally, the polysulfated compounds with antithrombotic potential are thought to have feasible synthetic procedures with much less bleeding, thus having favourable safety profiles. Here we report the synthesis of a novel compound, trehalose octasulfate and the assessment of its anticoagulation potential. Molecular docking of trehalose and trehalose octasulfate with antithrombin showed a specificity switch in binding affinity on sulfation, where trehalose octasulfate interacts with critical residues of AT that are either directly involved in heparin binding or in the conformational rearrangement of AT on heparin binding. An in vitro analysis of trehalose octasulfate demonstrated prolonged clotting time. Lead compound when intravenously injected in occlusion induced thrombotic rats showed remarkable reduction in the size and weight of the clot at a low dose. Delay in coagulation time was observed by analysing blood plasma isolated from rats preinjected with trehalose octasulfate. A decrease in Adenosine 5'-Diphosphate (ADP) induced platelet aggregation indicated a probable dual anticoagulant and antiplatelet mechanism of action. To summarize, this study presents trehalose octasulfate as a novel, effective, dual acting antithrombotic agent.

Antiangiogenic function of antithrombin is dependent on its conformational variation: implication for other serpins.

Endogenous angiogenesis inhibitor that specifically decreases tumor cell proliferation can be used to treat cancer since angiogenesis is required at every step of tumor progression and metastasis. Endothelial cells are the main target for the antiangiogenic therapy because they are non-transformed and easily accessible to angiogenic inhibitors. Antithrombin functions as a principal plasma protein inhibitor of blood coagulation proteinases and belongs to the family of serine protease inhibitors (serpins) which have common mechanism of inhibition. Antithrombin acquires a potent antiangiogenic activity upon conversion of the native molecule to cleaved or latent conformation. Cleaved and latent preparations of bovine and human plasma derived antithrombin inhibits capillary endothelial cell proliferation and the growth of human SK-NAS neuroblastoma and Lewis lung carcinoma tumors in mice but not the native antithrombin's. The native form of antithrombin binds with high affinity to vascular heparan sulfate proteoglycans containing a specific pentasaccharide sequence and it is this cofactor interaction that activates antithrombin to maximal rate of thrombin inhibition. Upon inhibitory complex formation with target proteinases the antithrombin undergoes stressed to relaxed transformation and lose their high affinity for pentasacchride. Low affinity relaxed conformation with reduced heparin binding like cleaved and latent are antiangiogenic but native high affinity heparin binding stressed conformation is not, indicating the critical importance of heparin affinity in antithrombin antiangiogenic function. Based on evidence of interactions of the endothelial cell growth factors bFGF (basic fibroblast growth factor) and VEGF (vascular endothelial cell growth factor) with heparin like molecule in matrix, the possibility of antiangiogenic antithrombin to interfere with endothelial cell growth and angiogenesis through heparin mediated mechanism deserves serious consideration and investigation. It is also possible that cleaved and latent conformations with reduced affinity for heparins can also induce conformational change in the antithrombin which can open an epitope on the antithrombin surface for appropriate interactions on the endothelial surface for better antiangiogenic activity. This review illustrates the potential of antithrombin and other serpin family members as endogenous antiangiogenic proteins.

High level expression of recombinant human antithrombin in the mammary gland of rabbits by adenoviral vectors infection.

Expression of recombinant pharmaceutical proteins in the mammalian mammary gland is of great interest for the medical industry. This study was designed to express recombinant human antithrombin (rhAT) in the mammary gland of rabbits by adenovirus vectors infection. Replication-defective adenovirus encoding human antithrombin complementary DNA (cDNA) was constructed and directly infused into the mammary gland of rabbits via the teat canal. The milk serum was collected from the infected mammary gland 48 h post-infection and subjected to Western blot analysis, Enzyme-linked immunosorbent assay (ELISA), and antithrombotic activity assay. In this way, the target protein was verified, and a high expression level of rhAT up to 4.8 g/L was obtained, and antithrombotic activity of the rhAT was not different than that of a standard human antithrombin protein (p > 0.05). Compared to previous attempts to produce human antithrombin in the mammary gland of transgenic animals or fractionation the plasma of blood donors, the method for rhAT expression we established would reduce production cost and further increase production efficacy.

Platelet-mediated proteolytic down regulation of the anticoagulant activity of protein S in individuals with haematological malignancies.

The natural anticoagulant protein S contains a so-called thrombin- sensitive region (TSR), which is susceptible to proteolytic cleavage. We have previously shown that a platelet-associated protease is able to cleave protein S under physiological plasma conditions in vitro . The aim of the present study was to investigate the relation between platelet-associated protein S cleaving activity and in vivo protein S cleavage, and to evaluate the impact of in vivo protein S cleavage on its anticoagulant activity. Protein S cleavage in healthy subjects and in thrombocytopenic and thrombocythaemic patients was evaluated by immunological techniques. Concentration of cleaved and intact protein S was correlated to levels of activated protein C (APC)-dependent and APC-independent protein S anticoagulant activity. In plasma from healthy volunteers 25% of protein S is cleaved in the TSR. While in plasma there was a clear positive correlation between levels of intact protein S and both APC-dependent and APC-independent protein S anticoagulant activities, these correlations were absent for cleaved protein S. Protein S cleavage was significantly increased in patients with essential thrombocythaemia (ET) and significantly reduced in patients with chemotherapy-induced thrombocytopenia. In ET patients on cytoreductive therapy, both platelet count and protein S cleavage returned to normal values. Accordingly, platelet transfusion restored cleavage of protein S to normal values in patients with chemotherapy-induced thrombocytopenia. In conclusion, proteases from platelets seem to contribute to the presence of cleaved protein S in the circulation and may enhance the coagulation response in vivo by down regulating the anticoagulant activity of protein S.