Molecular basis of protein S deficiency

Protein S deficiency (PSD) has been the most difficult to study among the classical inherited thrombophilic factors. This is in part due to the peculiar biology of protein S (PS), which has an anticoagulant role but no enzymatic activity, and because it interacts with plasma components that function...

Full description

Saved in:
Bibliographic Details
Published inThrombosis and haemostasis Vol. 98; no. 3; p. 543
Main Authors García de Frutos, Pablo, Fuentes-Prior, Pablo, Hurtado, Begoña, Sala, Núria
Format Journal Article
LanguageEnglish
Published Germany 01.09.2007
Subjects
Amino Acid Sequence
Blood Coagulation
Genetic Predisposition to Disease
Humans
Molecular Sequence Data
Mutation
Protein Conformation
Protein Precursors - genetics
Protein Precursors - metabolism
Protein S - genetics
Protein S - metabolism
Protein S Deficiency - blood
Protein S Deficiency - complications
Protein S Deficiency - genetics
Protein S Deficiency - metabolism
Protein Sorting Signals - genetics
Protein Structure, Tertiary - genetics
Risk Factors
Thromboembolism - blood
Thromboembolism - etiology
Thromboembolism - genetics
Thromboembolism - metabolism
Thrombosis - blood
Thrombosis - etiology
Thrombosis - genetics
Thrombosis - metabolism
Online AccessGet more information

Cover

More Information
Summary:Protein S deficiency (PSD) has been the most difficult to study among the classical inherited thrombophilic factors. This is in part due to the peculiar biology of protein S (PS), which has an anticoagulant role but no enzymatic activity, and because it interacts with plasma components that function in both haemostasis and inflammation. Clinically, it also has been difficult to define and standardise valuable assays to determine PS status and implication in thrombosis. Despite these drawbacks, at present heterozygous PS deficiency is well established as an autosomal dominant trait associated with an increased risk of thrombosis from data on familial and population studies. Almost two-hundred mutations have been characterised in PROS1, and approximately 30% of them have been characterised in vitro, clarifying the mechanisms leading to PSD. Furthermore, recent studies on the presence of large deletions in PROS1 have increased the number of PSD associated to PROS1 mutations. Finally, the discovery of new functions for PS, both in the anticoagulant system as well as in the interaction with cellular components through receptor tyrosine kinases, is broadening the importance of this molecule in the context of biomedicine.
ISSN:0340-6245
DOI:10.1160/TH07-03-0199