Gene/Protein
Disease
Symptom
Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
Symptom
Drug
Enzyme
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Target Concepts:
Gene/Protein
Disease
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Drug
Enzyme
Compound
Query: UMLS:C0023890 (
cirrhosis
)
42,195
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Serpin
polymerization is the underlying cause of several diseases, including thromboembolism, emphysema,
liver cirrhosis
, and angioedema. Understanding the structure of the polymers and the mechanism of polymerization is necessary to support rational design of therapeutic agents. Here we show that polymerization of antithrombin is sensitive to the addition of synthetic peptides that interact with the structure. A 12-m34 peptide (homologous to P14-P3 of antithrombin reactive loop), representing the entire length of s4A, prevented polymerization totally. A 6-mer peptide (homologous to P14-P9 of antithrombin) not only allowed polymerization to occur, but induced it. This effect could be blocked by the addition of a 5-mer peptide with s1C sequence of antithrombin or by an unrelated peptide representing residues 26-31 of cholecystokinin. The s1C or cholecystokinin peptide alone was unable to form a complex with native antithrombin. Moreover, an active antitrypsin double mutant, Pro 361-->Cys, Ser 283-->Cys, was engineered for the purpose of forming a disulfide bond between s1C and s2C to prevent movement of s1C. This mutant was resistant to polymerization if the disulfide bridge was intact, but, under reducing conditions, it regained the potential to polymerize. We have also modeled long-chain serpin polymers with acceptable stereochemistry using two previously proposed loop-A-sheet and loop-C-sheet polymerization mechanisms and have shown both to be sterically feasible, as are "mixed" linear polymers. We therefore conclude that the release of strand 1C must be an element of the mechanism of serpin polymerization.
...
PMID:Importance of the release of strand 1C to the polymerization mechanism of inhibitory serpins. 900 80
Serine proteinase inhibitors (Serpins) are irreversible suicide inhibitors of proteases that regulate diverse physiological processes such as coagulation, fibrinolysis, complement activation, angiogenesis, apoptosis, inflammation, neoplasia and viral pathogenesis. The molecular structure and physical properties of serpins permit these proteins to adopt a number of variant conformations under physiological conditions including the native inhibitory form and several inactive, non-inhibitory forms, such as complexes with protease or other ligands, cleaved, polymerised and oxidised. Alterations of a serpin which affect its structure and/or secretion and thus reduce its functional levels may result in pathology.
Serpin
dysfunction has been implicated in thrombosis, emphysema,
liver cirrhosis
, immune hypersensitivity and mental disorders. The loss of inhibitory activity of serpins necessarily results in an imbalance between proteases and their inhibitors, but it may also have other physiological effects through the generation of abnormal concentrations of modified, non-inhibitory forms of serpins. Although these forms of inhibitory serpins are detected in tissues and fluids recovered from inflammatory sites, the important questions of which conditions result in generation of different molecular forms of serpins, what biological function these forms have, and which of them are directly linked to pathologies and/or may be useful markers for characterisation of disease states, remain to be answered. Elucidation of the biological activities of non-inhibitory forms of serpins may provide useful insights into the pathogenesis of diseases and suggest new therapeutic strategies.
...
PMID:Conformational properties of serine proteinase inhibitors (serpins) confer multiple pathophysiological roles. 1127 63
Repeating intermolecular protein association by means of beta-sheet expansion is the mechanism underlying a multitude of diseases including Alzheimer's, Huntington's and Parkinson's and the prion encephalopathies. A family of proteins, known as the serpins, also forms large stable multimers by ordered beta-sheet linkages leading to intracellular accretion and disease. These 'serpinopathies' include early-onset dementia caused by mutations in neuroserpin,
liver cirrhosis
and emphysema caused by mutations in alpha(1)-antitrypsin (alpha(1)AT), and thrombosis caused by mutations in antithrombin.
Serpin
structure and function are quite well understood, and the family has therefore become a model system for understanding the beta-sheet expansion disorders collectively known as the conformational diseases. To develop strategies to prevent and reverse these disorders, it is necessary to determine the structural basis of the intermolecular linkage and of the pathogenic monomeric state. Here we report the crystallographic structure of a stable serpin dimer which reveals a domain swap of more than 50 residues, including two long antiparallel beta-strands inserting in the centre of the principal beta-sheet of the neighbouring monomer. This structure explains the extreme stability of serpin polymers, the molecular basis of their rapid propagation, and provides critical new insights into the structural changes which initiate irreversible beta-sheet expansion.
...
PMID:Crystal structure of a stable dimer reveals the molecular basis of serpin polymerization. 1897 12
Serine Protease inhibitors (serpins) are a super-family of proteins that controls the proteinases involved in the inflammation, complementation, coagulation and fibrinolytic pathways. Serpins are prone to conformational diseases due to a complex inhibition mechanism that involves large scale conformational change, and their susceptibility to undergo point mutations might lead to functional defects. Serpins are associated with diseases like emphysema/
cirrhosis
, angioedema, familial dementia, chronic obstructive bronchitis and thrombosis.
Serpin
polymerization based pathologies are fairly widespread and devising a cure has been difficult due to lack of clarity regarding its mechanism.
Serpin
can exist in various conformational states and has a variable cofactor binding ability. It has a large genome and proteome database which can be utilized to gain critical insight into their structure, mechanism and defects. Comprehensive computational studies on the serpin family is lacking, most of the work done till date is limited and deals mostly with few individual serpins. We have tried to analyze few aspect of this family using diverse computational biology tools and have shown the following: a) the importance of residue burial linked shift in the conformational stability as a major factor in increasing the polymer propensity in serpins. b) Amino acids involved in the polymerization are in general completely buried in the native conformation. c) An isozyme specific antithrombin study showed the structural basis of improved heparin binding to beta antithrombin as compared to alpha-antithrombin. d) A comprehensive cavity analysis showed its importance in inhibition and polymerizaiton and finally e) an interface analysis of various serpin protease complexes identified critical evolutionary conserved residues in exosite that determines its protease specificity. This work introduces the problem and emphasizes on the need for in-depth computational studies of serpin superfamily.
...
PMID:Structure function analysis of serpin super-family: "a computational approach". 2385 65
