Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0004153 (atherosclerosis)
 77,401 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Cathepsin S is one of the major cysteine proteases, and is expressed in the lysosome of antigen presenting cells; primarily dendritic cells, B-cells and macrophages. Cathepsin S is most well known for its critical function in the proteolytic digestion of the invariant chain chaperone molecules, thus controlling antigen presentation to CD4+ T-cells by major histocompatibility complex (MHC) class II molecules or to NK1.1+ T-cells via CD1 molecules. Cathepsin S also appears to participate in direct processing of exogenous antigens for presentation by MHC class II to CD4+ T-cells, or in cross-presentation by MHC class I molecules to CD8+ T-cells. In addition, although direct evidence is still lacking, in its secreted form cathepsin S is implicated in degradation of the extracellular matrix, which may contribute to the pathology of a number of diseases, including arthritis, atherosclerosis and chronic obstructive pulmonary disease. Therefore, inhibition of cathepsin S is a promising target for the development of novel therapeutics for a variety of indications.
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PMID:Cathepsin S inhibitors as novel immunomodulators. 1591 60

Lysosomal cysteine proteases, a subgroup of the cathepsin family, are critical for normal cellular functions such as general protein turnover, antigen processing and bone remodeling. In the past decade, the number of identified human cathepsins has more than doubled and their known role in several pathologies has expanded rapidly. Increased understanding of the structure and mechanism of this class of enzymes has brought on a new fervor in the design of small molecule inhibitors with the hope of producing specific, therapeutic drugs for diseases such as arthritis, allergy, multiple sclerosis, atherosclerosis, Alzheimer's disease and cancer.
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PMID:Lysosomal cysteine proteases: structure, function and inhibition of cathepsins. 1649 Nov 62

Although the degradation of cellular or endocytosed proteins comprises the normal function of lysosomal proteinases, these enzymes were also detected extracellularly during diseases such as atherosclerosis. Since lysosomal cysteine cathepsins were demonstrated to transform native LDL particles into a proatherogenic type, the following study was undertaken to characterize the modification of LDL particles and the degradation of apolipoprotein B-100 in more detail. LDL was incubated with cathepsins B, F, K, L, S, and V at pH 5.5 and under physiological conditions (pH 7.4) for 2 h to mimic conditions of limited proteolysis. Gel electrophoretic analysis of the degradation products revealed that cathepsin-mediated proteolysis of apolipoprotein B-100 is a fast process carried out by all enzymes at pH 5.5, and by cathepsin S also at pH 7.4. Electron microscopic analysis showed that cathepsin-mediated degradation of apolipoprotein B-100 rendered LDL particles fusion-competent compared to controls. N-Terminal sequencing of cathepsin cleavage fragments from apolipoprotein B-100 revealed an abundance of enzyme-specific cleavage sites located in almost all structurally and functionally essential regions. Since the cleavage sites superimpose well with results from substrate specificity studies, they might be useful for the development of cathepsin-specific inhibitors and substrates.
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PMID:Degradation of apolipoprotein B-100 by lysosomal cysteine cathepsins. 1697 99

Between 1998 and 1999 we suggested a role for cysteine proteases, particularly cathepsins S and K, in atherosclerosis and abdominal aortic aneurysm (AAA) formation. We also demonstrated the presence and activity of cathepsins S, K, and L in atherosclerotic and aneurysmal lesions in humans. Features unique to this family of extracellular enzymes indicate its likely participation in these vascular diseases. As very potent elastolytic enzymes, cathepsins are strong candidates as key participants in aneurysm development. Importantly, cathepsins express very high elastolytic activity in AAA due to reciprocal correlation with cystatin C, their most abundant endogenous inhibitor. Two opposite processes coexist in aneurysmal tissue: overexpression of elastolytic cathepsins, and severe suppression of cystatin C, probably due to differentially regulated expression and secretion of cathepsins and their inhibitors in response to inflammatory cytokines. Involvement of cathepsins in microvessel formation, a pathophysiological marker of human AAA, and programmed cell death (apoptosis), increases the likelihood of cathepsin participation in AAA formation and growth. We also summarize here results obtained in our and other laboratories that demonstrated reduced atherosclerosis and AAA in in vivo models using mice lacking different cathepsins. Deficiency of cysteine protease inhibitor cystatin C in atherosclerosis-prone ApoE-null mice leads to the development of specific features of AAA such as thinning of the tunica media and aortic dilatation. Taken together, such findings in humans in vitro with different cell types and in vivo in genetically altered mice demonstrate the importance of cysteine protease/protease inhibitor balance in dysregulated arterial integrity and remodeling during atherosclerosis and aortic aneurysm formation.
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PMID:Do cathepsins play a role in abdominal aortic aneurysm pathogenesis? 1718 32

Proteolytic degradation of elastic fibers is associated with a broad spectrum of pathological conditions such as atherosclerosis and pulmonary emphysema. We have studied the interaction between elastins and human cysteine cathepsins K, L, and S, which are known to participate in elastinolytic activity in vivo. The enzymes showed distinctive preferences in degrading elastins from bovine neck ligament, aorta, and lung. Different susceptibility of these elastins to proteolysis was attributed to morphological differences observed by scanning electron microscopy. Kinetics of cathepsin binding to the insoluble substrate showed that the process occurs in two steps. The enzyme is initially adsorbed on the elastin surface in a nonproductive manner and then rearranges to form a catalytically competent complex. In contrast, soluble elastin is bound directly in a catalytically productive manner. Studies of enzyme partitioning between the phases showed that cathepsin K favors adsorption on elastin; cathepsin L prefers the aqueous environment, and cathepsin S is equally distributed among both phases. Our results suggest that elastinolysis by cysteine cathepsins proceeds in cycles of enzyme adsorption, binding of a susceptible peptide moiety, hydrolysis, and desorption. Alternatively, the enzyme may also form a new catalytic complex without prior desorption and re-adsorption. In both cases the active center of the enzymes remains at least partly accessible to inhibitors. Elastinolytic activity was readily abolished by cystatins, indicating that, unlike enzymes such as leukocyte elastase, pathological elastinolytic cysteine cathepsins might represent less problematic drug targets. In contrast, thyropins were relatively inefficient in preventing elastinolysis by cysteine cathepsins.
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PMID:Interaction between human cathepsins K, L, and S and elastins: mechanism of elastinolysis and inhibition by macromolecular inhibitors. 1722 55

Cystatin C, known as an inhibitor of the cathepsin family of cysteine proteases, has been evaluated in several cardiovascular disorders such as atherosclerosis and acute myocardial infarction. The potential interaction between transforming growth factor-beta1 and cystatin C has also been demonstrated in some cell types. Accordingly, we aimed to compare the plasma levels of cystatin C and transforming growth factor-beta1 in patients with coronary artery ectasia coexisting with coronary artery disease and those with coronary artery disease alone. Thirty-nine patients with coronary artery ectasia and coronary artery disease and 35 age and sex-matched patients with coronary artery disease alone were prospectively enrolled in the study. Blood samples of all patients and control participants for measuring plasma cystatin C and transforming growth factor-beta1 levels were drawn>or=24 h after the coronary angiography. Cystatin C concentrations in plasma were measured by latex-enhanced reagent on a Behring Nephelometer II. Plasma levels of transforming growth factor-beta1 were measured by using transforming growth factor-beta1 enzyme-linked immunosorbent assay kit (BioSource International, Inc., Camarillo, California, USA). Plasma level of cystatin C was significantly higher in patients with coronary artery ectasia+coronary artery disease than in patients with coronary artery disease alone (1.05+/-0.30 mg/dl vs. 0.92+/-0.18 mg/mdl, P=0.025, respectively). Transforming growth factor-beta1 was also found to be significantly higher in patients with coronary artery ectasia+coronary artery disease compared with those with coronary artery disease (2.47+/-0.43 vs. 2.22+/-0.43 pg/ml, P=0.02, respectively). The plasma level of cystatin C was significantly but weakly correlated with that of transforming growth factor-beta1 (r=0.217 P=0.02). We conclude that plasma levels of cystatin C and transforming growth factor-beta1 are significantly higher in patients with combined coronary artery ectasia and coronary artery disease than in those with coronary artery disease. Correlation between transforming growth factor-beta1 and cystatin C may also suggest that pathogenesis of coronary artery ectasia might have some different pathways from atherosclerosis with respect to the regulation of extracellular matrix remodeling. Therefore, the role of cystatin in the pathogenesis of coronary artery ectasia and its potential interaction with transforming growth factor-beta1 should be evaluated in further studies.
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PMID:Increased plasma levels of cystatin C and transforming growth factor-beta1 in patients with coronary artery ectasia: can there be a potential interaction between cystatin C and transforming growth factor-beta1. 1742 95

Extracellular matrix (ECM) remodeling is one of the underlying mechanisms in cardiovascular diseases. Cathepsin cysteine proteases have a central role in ECM remodeling and have been implicated in the development and progression of cardiovascular diseases. Cathepsins also show differential expression in various stages of atherosclerosis, and in vivo knockout studies revealed that deficiency of cathepsin K or S reduces atherosclerosis. Furthermore, cathepsins are involved in lipid metabolism. Cathepsins have the capability to degrade low-density lipoprotein and reduce cholesterol efflux from macrophages, aggravating foam cell formation. Although expression studies also demonstrated differential expression of cathepsins in cardiovascular diseases like aneurysm formation, neointima formation, and neovascularization, in vivo studies to define the exact role of cathepsins in these processes are lacking. Evaluation of the feasibility of cathepsins as a diagnostic tool revealed that serum levels of cathepsins L and S seem to be promising as biomarkers in the diagnosis of atherosclerosis, whereas cathepsin B shows potential as an imaging tool. Furthermore, cathepsin K and S inhibitors showed effectiveness in (pre) clinical evaluation for the treatment of osteoporosis and osteoarthritis, suggesting that cathepsin inhibitors may also have therapeutic effects for the treatment of atherosclerosis.
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PMID:Cathepsin cysteine proteases in cardiovascular disease. 1752 80

Cystatin C and cathepsins could play a role in almost all processes involved in atherosclerotic lesion formation by their degradation of extracellular matrix proteins and apolipoprotein B100, the protein moiety of LDL. Several cysteine cathepsins are upregulated in human lesions accompanied by a decrease in cystatin C, the major inhibitor of cysteine cathepsins. Recent research show that atherosclerotic mice deficient in cystatin C display increased elastic lamina degradation as well as larger plaque formation. Cathepsin S- and K-deficient atherosclerotic mice, on the other hand, both have less atherosclerosis, where cathepsin S-/- mice exhibited fewer plaque ruptures and cathepsin K-/- larger foam cells than control mice. This article reviews possible roles of cystatin C and cathepsins in different processes and stages of the atherosclerotic disease.
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PMID:Cystatin C and cathepsins in cardiovascular disease. 1850 21

Calcific aortic stenosis is the most common cause of aortic valve replacement in developed countries, and this condition increases in prevalence with advancing age. The fibrotic thickening and calcification are common eventual endpoint in both non-rheumatic calcific and rheumatic aortic stenoses. New observations in human aortic valves support the hypothesis that degenerative valvular aortic stenosis is the result of active bone formation in the aortic valve, which may be mediated through a process of osteoblast-like differentiation in these tissues. Additionally histopathologic evidence suggests that early lesions in aortic valves are not just a disease process secondary to aging, but an active cellular process that follows the classical "response to injury hypothesis" similar to the situation in atherosclerosis. Although there are similarities with the risk factor and as well as with the process of atherogenesis, not all the patients with coronary artery disease or atherosclerosis have calcific aortic stenosis. This review mainly focuses on the potential vascular and molecular mechanisms involved in the pathogenesis of aortic valve stenosis. Namely extracellular matrix remodeling, angiogenesis, inflammation, and eventually osteoblast-like differentiation resulting in bone formation have been shown to play a role in the pathogenesis of calcific aortic stenosis. Several mediators related to underlying mechanisms, including growth factors especially transforming growth factor-beta1 and vascular endothelial growth factors, angiogenesis, cathepsin enzymes, adhesion molecules, bone regulatory proteins and matrix metalloproteinases have been demonstrated, however the target to be attacked is not defined yet.
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PMID:Molecular and cellular mechanisms of aortic stenosis. 1938 74

Although mast cell functions have classically been related to allergic responses, recent studies indicate that these cells contribute to other common diseases such as multiple sclerosis, rheumatoid arthritis, atherosclerosis, aortic aneurysm and cancer. This study presents evidence that mast cells also contribute to diet-induced obesity and diabetes. For example, white adipose tissue (WAT) from obese humans and mice contain more mast cells than WAT from their lean counterparts. Furthermore, in the context of mice on a Western diet, genetically induced deficiency of mast cells, or their pharmacological stabilization, reduces body weight gain and levels of inflammatory cytokines, chemokines and proteases in serum and WAT, in concert with improved glucose homeostasis and energy expenditure. Mechanistic studies reveal that mast cells contribute to WAT and muscle angiogenesis and associated cell apoptosis and cathepsin activity. Adoptive transfer experiments of cytokine-deficient mast cells show that these cells, by producing interleukin-6 (IL-6) and interferon-gamma (IFN-gamma), contribute to mouse adipose tissue cysteine protease cathepsin expression, apoptosis and angiogenesis, thereby promoting diet-induced obesity and glucose intolerance. Our results showing reduced obesity and diabetes in mice treated with clinically available mast cell-stabilizing agents suggest the potential of developing new therapies for these common human metabolic disorders.
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PMID:Genetic deficiency and pharmacological stabilization of mast cells reduce diet-induced obesity and diabetes in mice. 1963 55


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