calpain and von-Willebrand-Diseases

calpain has been researched along with von-Willebrand-Diseases* in 2 studies

Other Studies

2 other study(ies) available for calpain and von-Willebrand-Diseases

Article	Year
Evidence that calpains and elastase do not produce the von Willebrand factor fragments present in normal plasma and IIA von Willebrand disease. Blood, 1988, Volume: 72, Issue:2 Recent evidence suggests that proteolysis plays an important role in some forms of inherited and acquired von Willebrand disease (vWD). Because calpains and one or more enzymes released from polymorphonuclear leukocytes are known to proteolyze von Willebrand factor (vWF) in vitro with resultant loss of large multimers similar to that seen in IIA vWD, they have been suggested as being responsible for the proteolysis in vivo. Using monoclonal epitope mapping, we have examined the proteolysis of the vWF subunit by porcine calcium-activated neutral proteases (calpains) and human leukocyte elastase to determine whether they produce the vWF proteolytic cleavage products seen in normal individuals and IIA vWD. Purified vWF was digested with porcine calpains I and II. We found no difference in the size, location, and quantity of the fragments produced by calpain I v calpain II. New fragments were detected of approximately 200, 170, 150, and 125 Kd. There was no evidence for generation of the native 140 and 176 Kd fragments. Some loss of the native fragments was seen, which suggests that they were further cleaved. Epitope mapping of the 170- and 150-Kd calpain-cleaved fragments revealed them to be from different parts of the molecule than the regions from which the native 176- and 140-Kd fragments derived. This was further supported by determination of the amino-terminal sequence of the calpain-cleaved 170- and 150-Kd fragments. Digestion of vWF with human leukocyte elastase produced new fragments at 210/205, 190, 170/165, 145/140, and 130/125 Kd. No generation of native fragments was detected. Monoclonal epitope mapping of the 145/140-Kd elastase-cleaved band proved that it derived from the carboxyl-terminal portion of the vWF molecule, whereas the native 140-Kd fragment is derived from the amino-terminal end. Neither calpains nor human leukocyte elastase produced the proteolyzed fragments present in normal and IIA vWD and, therefore, probably do not cause the loss of large multimers that is seen in that disorder. Topics: Amino Acid Sequence; Calpain; Humans; Pancreatic Elastase; Peptide Fragments; von Willebrand Diseases; von Willebrand Factor	1988
In vitro correction of the abnormal multimeric structure of von Willebrand factor in type IIa von Willebrand's disease. Proceedings of the National Academy of Sciences of the United States of America, 1985, Volume: 82, Issue:17 Type IIa von Willebrand's disease (vWd) has been characterized by the absence of the largest and a reduction in the intermediate-sized multimers of the plasma and platelet von Willebrand factor (vWf) and by the diminished response of the platelet-rich plasma of these patients to ristocetin. Other recently demonstrated abnormalities include the presence of an abnormal triplet structure of vWf. We have studied the plasma and platelets from three patients with this form of vWd and have found that both their plasma and platelets manifest the previously described abnormalities. Because of the heterogeneity of the multimeric structure of the vWf in these patients, we considered the possibility that postsynthetic events may have modified the vWf. When blood was collected in 5 mM EDTA or 5 mM EDTA/leupeptin/N-ethylmaleimide, the abnormal multimeric structure of the plasma and platelet vWf was partially normalized in that the intermediate and the largest vWf multimers were increased, the abnormal multimer structure was no longer as apparent, and the fastest migrating band (an abnormality seen only in the type IIa vWd plasma and platelets) disappeared. The enzymatic activity responsible for this degradation can be classified as a calcium-dependent protease. Studies of normal radiolabeled vWf incubated with platelet lysates from normal subjects and these patients revealed that the patients' platelets did not contain increased amounts of calcium-dependent protease activity as assessed by degradation of normal vWf. These data suggest that patients with type IIa vWd synthesize an abnormal vWf protein that is susceptible to in vitro proteolytic degradation and that proteolytic degradation can play a significant role in the phenotypic expression of vWd by modifying the plasma and platelet vWf multimeric structure. Topics: Blood Coagulation Factors; Calpain; Endopeptidases; Humans; In Vitro Techniques; Macromolecular Substances; Molecular Weight; Phenotype; Protease Inhibitors; von Willebrand Diseases; von Willebrand Factor	1985

Article

Year

Evidence that calpains and elastase do not produce the von Willebrand factor fragments present in normal plasma and IIA von Willebrand disease.

Blood, 1988, Volume: 72, Issue:2

Recent evidence suggests that proteolysis plays an important role in some forms of inherited and acquired von Willebrand disease (vWD). Because calpains and one or more enzymes released from polymorphonuclear leukocytes are known to proteolyze von Willebrand factor (vWF) in vitro with resultant loss of large multimers similar to that seen in IIA vWD, they have been suggested as being responsible for the proteolysis in vivo. Using monoclonal epitope mapping, we have examined the proteolysis of the vWF subunit by porcine calcium-activated neutral proteases (calpains) and human leukocyte elastase to determine whether they produce the vWF proteolytic cleavage products seen in normal individuals and IIA vWD. Purified vWF was digested with porcine calpains I and II. We found no difference in the size, location, and quantity of the fragments produced by calpain I v calpain II. New fragments were detected of approximately 200, 170, 150, and 125 Kd. There was no evidence for generation of the native 140 and 176 Kd fragments. Some loss of the native fragments was seen, which suggests that they were further cleaved. Epitope mapping of the 170- and 150-Kd calpain-cleaved fragments revealed them to be from different parts of the molecule than the regions from which the native 176- and 140-Kd fragments derived. This was further supported by determination of the amino-terminal sequence of the calpain-cleaved 170- and 150-Kd fragments. Digestion of vWF with human leukocyte elastase produced new fragments at 210/205, 190, 170/165, 145/140, and 130/125 Kd. No generation of native fragments was detected. Monoclonal epitope mapping of the 145/140-Kd elastase-cleaved band proved that it derived from the carboxyl-terminal portion of the vWF molecule, whereas the native 140-Kd fragment is derived from the amino-terminal end. Neither calpains nor human leukocyte elastase produced the proteolyzed fragments present in normal and IIA vWD and, therefore, probably do not cause the loss of large multimers that is seen in that disorder.

Topics: Amino Acid Sequence; Calpain; Humans; Pancreatic Elastase; Peptide Fragments; von Willebrand Diseases; von Willebrand Factor

1988

In vitro correction of the abnormal multimeric structure of von Willebrand factor in type IIa von Willebrand's disease.

Proceedings of the National Academy of Sciences of the United States of America, 1985, Volume: 82, Issue:17

Type IIa von Willebrand's disease (vWd) has been characterized by the absence of the largest and a reduction in the intermediate-sized multimers of the plasma and platelet von Willebrand factor (vWf) and by the diminished response of the platelet-rich plasma of these patients to ristocetin. Other recently demonstrated abnormalities include the presence of an abnormal triplet structure of vWf. We have studied the plasma and platelets from three patients with this form of vWd and have found that both their plasma and platelets manifest the previously described abnormalities. Because of the heterogeneity of the multimeric structure of the vWf in these patients, we considered the possibility that postsynthetic events may have modified the vWf. When blood was collected in 5 mM EDTA or 5 mM EDTA/leupeptin/N-ethylmaleimide, the abnormal multimeric structure of the plasma and platelet vWf was partially normalized in that the intermediate and the largest vWf multimers were increased, the abnormal multimer structure was no longer as apparent, and the fastest migrating band (an abnormality seen only in the type IIa vWd plasma and platelets) disappeared. The enzymatic activity responsible for this degradation can be classified as a calcium-dependent protease. Studies of normal radiolabeled vWf incubated with platelet lysates from normal subjects and these patients revealed that the patients' platelets did not contain increased amounts of calcium-dependent protease activity as assessed by degradation of normal vWf. These data suggest that patients with type IIa vWd synthesize an abnormal vWf protein that is susceptible to in vitro proteolytic degradation and that proteolytic degradation can play a significant role in the phenotypic expression of vWd by modifying the plasma and platelet vWf multimeric structure.

Topics: Blood Coagulation Factors; Calpain; Endopeptidases; Humans; In Vitro Techniques; Macromolecular Substances; Molecular Weight; Phenotype; Protease Inhibitors; von Willebrand Diseases; von Willebrand Factor

1985