Thrombin‐like inhibitory action of trypsin and trypsin‐like proteases on human platelet adenylate cyclase

Jakobs, Karl H.; Grandt, R

doi:10.1111/j.1432-1033.1988.tb13881.x

Cited by 8 publications

(7 citation statements)

References 18 publications

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“…Trypsin mimics the effects of thrombin on platelets [42][43][44]. Moreover the time course, magnitude and pertussis-toxin sensitivity of the trypsin response are indistinguishable from those of thrombin in the megakaryocytic cell line HEL [45].…”

Section: Cleavage Of the Thrombin Receptor By Pancreatic Serine Protementioning

confidence: 99%

Cleavage of the thrombin receptor: identification of potential activators and inactivators

Parry

Myles

Tschopp

et al. 1996

Biochemical Journal

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The kinetic parameters were determined for the hydrolysis of a peptide based on the activation site of the thrombin receptor (residues 38-60) by thrombin and 12 other proteases. The kcat and Km values for the cleavage of this peptide (TR39-40) by thrombin were 107 s-1 and 1.3 microM; the kcat/Km of TR39-40 is among the highest observed for thrombin. A model is presented that reconciles the parameters for cleavage of the peptide with the concentration dependence of cellular responses to thrombin. Cleavage of TR39-40 was not specific for thrombin. The pancreatic proteases trypsin and chymotrypsin hydrolysed TR39-40 efficiently (kcat/Km > 10(6) M-1.s-1). Whereas trypsin cleaved TR39-40 at the thrombin activation site (Arg41-Ser42), chymotrypsin hydrolysed the peptide after Phe43. This chymotryptic cleavage would result in inactivation of the receptor. The efficient cleavage of TR39-40 by chymotrypsin (kcat/Km approximately 10(6) M-1.s-1) was predominantly due to a low Km value (2.8 microM). The proteases factor Xa, plasmin, plasma kallikrein, activated protein C and granzyme A also hydrolysed TR39-40 at the Arg41-Ser43 bond, but exhibited kcat/Km values that were at least 10(3)-fold lower than that observed with thrombin. Both tissue and urokinase plasminogen activators as well as granzyme B and neutrophil elastase were unable to cleave TR39-60 at appreciable rates. However, neutrophil cathepsin G hydrolysed the receptor peptide after Phe55. Like the chymotryptic cleavage, this cleavage would lead to inactivation of the receptor, but the cathepsin G reaction was markedly less efficient; the kcat/K(m) value was almost four orders of magnitude lower than that for thrombin. In addition to the above cleavage sites, a secondary site for thrombin and other arginine-specific proteases was identified at Arg46, but the cleavage at this site only occurred at very low rates and is unlikely to be significant in vivo.

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Section: Cleavage Of the Thrombin Receptor By Pancreatic Serine Protementioning

confidence: 99%

Cleavage of the thrombin receptor: identification of potential activators and inactivators

Parry

Myles

Tschopp

et al. 1996

Biochemical Journal

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“…Trypsin is a prototype of a family of serine protease and can mimic several actions of thrombin including vasorelaxation (De Mey et al , 1982; Rapoport et al , 1984) and platelet activation (Ruggiero & Lapetina, 1985; Jakobs & Grandt, 1988; Brass et al , 1992; Finotti, 1992). In fact, trypsin has been found to possess a partial agonist activity for the cloned thrombin receptor (Vu et al , 1991).…”

Section: Introductionmentioning

confidence: 99%

The involvement of a novel mechanism distinct from the thrombin receptor in the vasocontraction induced by trypsin

Komuro

Miwa

Minowa

et al. 1997

British J Pharmacology

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1 The vasocontracting e ect of a serine protease trypsin and its mechanisms were investigated by monitoring the isometric tension in endothelium-denuded rings of rabbit thoracic aortae and its e ects on intracellular free Ca 2+ concentrations ([Ca 2+ ] i ) in dispersed rabbit vascular smooth muscle cells with a Ca 2+ indicator fura-2. The actions of trypsin were compared with those of thrombin. 2 Both thrombin and trypsin reversibly contracted aortic rings without endothelium in a concentrationdependent manner. The vasocontraction induced by trypsin was well correlated with the protease activity of trypsin actually added to the tissue baths containing the aortic rings and was completely blocked by soybean trypsin inhibitor and phenylmethylsulphonyl¯uoride (PMSF), a serine protease inhibitor. 3 The trypsin-induced contractions of the aortic rings were not the result of irreversible damage to vascular smooth muscle cells, since the contractile responses induced by noradrenaline or 30 mM KCl were una ected by pretreatment with trypsin. 4 The contractions induced by either thrombin or trypsin were reduced to about 30% of control responses after removal of extracellular Ca 2+ , indicating that most of the contraction is dependent on extracellular Ca 2+ . By contrast, the contractions induced by either of the proteases were reduced by an antagonist of L-type voltage-operated Ca 2+ channels, nifedipine, to about 70% of control responses, indicating that both nifedipine-sensitive and -resistant Ca 2+ channels are involved in these contractions. 5 In the aortic rings precontracted by a maximally e ective concentration of thrombin, the second application of thrombin virtually failed to induce contractions but trypsin could still induce contractions amounting to 10% of control values by it's protease activity. 6 After the ®rst application of a maximal concentration of thrombin, the second application of thrombin could not induce an increase in [Ca 2+ ] i , but an application of trypsin could still induce an increase in [Ca 2+ ] i in dispersed rabbit vascular smooth muscle cells. 7 These data suggest that in addition to activation of a thrombin receptor, trypsin can contract rabbit aortae by a proteinase-activated receptor 2 or a novel mechanism.

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“…In the cases of the proteases which do possess inducing activity, a number of possible mechanisms for signal transduction exist. There are several studies of the effects of trypsin and other proteases on the activity of cell-surface enzymes and ion channels such as adenylate cyclase (1,13) and potassium channels (15, 21). The proteases appear to cleave exposed peptides of the membrane protein to enhance or inhibit function through conformational changes.…”

Section: Discussionmentioning

confidence: 99%

Protease‐Induced Formation of the Sperm Acrosomal Filament

Lindsay¹,

Clark²

1992

Dev Growth Differ

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Filament extension during the sperm acrosome reaction in Sicyonia ingentis is triggered by an egg trypsin-like protease whose action can be mimicked using trypsin. Using biotinylated trypsin and either a fluorescently-labeled or colloidal gold-labeled antibody to biotin, trypsin binding was localized to the anterior granule of the sperm which is exposed upon acrosomal exocytosis. The binding was to proteinaceous material at the base of the granule juxtaposed to the inner acrosomal membrane. Other labeled proteins also bound in the same pattern but only in the presence of unlabeled trypsin; non-proteolytic proteins did not induce filament formation.A minimum of 30 min of trypsin exposure was required in order to trigger filament formation, and increasing trypsin concentration did not reduce this time requirement. These results indicate that the protease slowly uncovers a binding site for itself (or other proteins), and then its proteolytic activity is again required to induce filament formation. The protease kallikrein appeared to be a more potent inducer than trypsin, while thrombin and clostripain had no apparent inducing activity.Binding of all proteins tested occurred slowly over a period of about 30 min.

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Thrombin‐like inhibitory action of trypsin and trypsin‐like proteases on human platelet adenylate cyclase

Cited by 8 publications

References 18 publications

Cleavage of the thrombin receptor: identification of potential activators and inactivators

Cleavage of the thrombin receptor: identification of potential activators and inactivators

The involvement of a novel mechanism distinct from the thrombin receptor in the vasocontraction induced by trypsin

Protease‐Induced Formation of the Sperm Acrosomal Filament

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