Gene/Protein
Disease
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Drug
Enzyme
Compound
Pivot Concepts:
Gene/Protein
Disease
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Target Concepts:
Gene/Protein
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Query: EC:3.4.15.1 (
ACE
)
18,300
document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)
Alveolar macrophages protect the lungs against noxious agents. Proteases and peptidases are essential for this defense and many metabolic activities. Human alveolar macrophages were evaluated for the presence of six important peptidases. Deamidase, a serine peptidase identical with the lysosomal protective protein and possibly with cathepsin A, had high specific activity in alveolar macrophages and is also present in cultured mouse J774A.1 and human U937 cells, used for the sake of comparison. In fractionated J774A cells, most of the deamidase activity was in the lysosomal fraction and in the final supernatant. Deamidase in human alveolar macrophages, obtained by bronchoalveolar lavage from 23 patients, cleaved dansyl-Phe-Leu-Arg at a rate of 2.26 mumol/h/mg protein and hydrolyzed the chemotactic peptide N-f-Met-Leu-Phe even faster, at a rate of 53.1 mumol/h/mg protein, the highest activity for this enzyme with any of the cells we tested. Rabbit antiserum, elicited with the recombinant partial sequence of the enzyme, immunoprecipitated 77-88% of the macrophage deamidase. In immunocytochemistry, this antiserum localized deamidase within the human macrophages. The enzyme was inhibited by diisopropylfluorophosphate (DFP; 1 mM) and by ebelactone B (10 microM), noncompetitively. The mRNA of deamidase was detected in mouse macrophages by Northern blot; the two protein chains of deamidase were shown in human macrophages by Western blot. In addition, two other serine peptidases were also highly active in macrophages: dipeptidyl peptidase IV (1.38 mumol/h/mg protein) and
prolylcarboxypeptidase
(0.72 mumol/h/mg protein). The activity of plasma membrane zinc metallopeptidases, neutral endopeptidase 24.11 and carboxypeptidase M, in contrast, was low or absent (angiotensin I converting enzyme;
kininase II
).(ABSTRACT TRUNCATED AT 250 WORDS)
...
PMID:Plasma membrane-bound and lysosomal peptidases in human alveolar macrophages. 762 87
Understanding the physiological role of the plasma kallikrein-kinin system (KKS) has been hampered by not knowing how the proteins of this proteolytic system, when assembled in the intravascular compartment, become activated under physiological conditions. Recent studies indicate that the enzyme
prolylcarboxypeptidase
, an ANG II inactivating enzyme, is a prekallikrein activator. The ability of
prolylcarboxypeptidase
to act in the KKS and the renin-angiotensin system (RAS) indicates a novel interaction between these two systems. This interaction, along with the roles of
angiotensin converting enzyme
, cross talk between bradykinin and angiotensin-(1-7) action, and the opposite effects of activation of the ANG II receptors 1 and 2 support a hypothesis that the plasma KKS counterbalances the RAS. This review examines the interaction and cross talk between these two protein systems. This analysis suggests that there is a multilayered interaction between these two systems that are important for a wide array of physiological functions.
...
PMID:The kallikrein-kinin and the renin-angiotensin systems have a multilayered interaction. 1279 84
The plasma kinin-forming cascade can be activated by contact with negatively charged macromolecules leading to binding and autoactivation of factor XII, activation of prekallikrein to kallikrein by factor XIIa, and cleavage of high molecular weight kininogen (HK) by kallikrein to release the vasoactive peptide bradykinin. Once kallikrein formation begins, there is rapid cleavage of unactivated factor XII to factor XIIa, and this positive feedback is favored kinetically over factor XII autoactivation. Examples of surface initiators that can function in this fashion are endotoxin, sulfated mucopolysaccharides, and aggregated Abeta protein. Physiological activation appears to occur along the surface of endothelial cells both by the aforementioned contact-initiated reactions as well as bypass pathways that are independent of factor XII. Factor XII binds primarily to cell surface u-PAR (urokinase plasminogen activator receptor); HK binds to gC1qR via its light chain (domain 5) and to cytokeratin 1 by its heavy chain (domain 3) and, to a lesser degree, by its light chain. Prekallikrein circulates bound to HK (as does coagulation factor XI), and prekallikrein is thereby brought to the surface as HK binds. All cell-binding reactions are dependent on zinc ion. Endothelial cells (HUVECs) have bimolecular complexes of u-PAR-cytokeratin 1 and gC1qR-cytokeratin 1 at the cell surface plus free gC1qR, which is present in substantial molar excess. Factor XII appears to interact primarily with the u-PAR-cytokeratin 1 complex, whereas HK binds primarily to the gC1qR-cytokeratin 1 complex and to free gC1qR. Release of endothelial cell heat shock protein 90 (Hsp90) or the enzyme
prolylcarboxypeptidase
leads to activation of the bradykinin-forming cascade by activating the prekallikrein-HK complex. In contrast to factor XIIa, neither will activate prekallikrein in the absence of HK, both reactions require zinc ion, and the stoichiometry suggests interaction of one molecule of Hsp90 (for example) with one molecule of prekallikrein-HK complex. The presence of factor XII, however, leads to a marked augmentation in reaction rate via the kallikrein feedback as well as to a change to classic enzyme-substrate kinetics. The circumstances in which activation is initiated by factor XII autoactivation or by these factor XII bypasses are yet to be defined. The pathologic conditions in which bradykinin generation appears important include hereditary and acquired C1 inhibitor deficiency, cough and angioedema due to
ACE
inhibitors, endotoxin shock, with contributions to conditions as diverse as Alzheimer's disease, stroke, control of blood pressure, and allergic diseases.
...
PMID:Formation of bradykinin: a major contributor to the innate inflammatory response. 1570 22
Anaphylaxis is a term that implies symptoms that are present in many organs, some of which are potentially fatal. The pathogenic process can either be IgE-dependent or non-IgE-dependent; the latter circumstance may be referred to as anaphylactoid. Bradykinin is frequently responsible for the manifestations of IgE-independent reactions. Blood levels may increase because of overproduction; diseases such as the various forms of C1 inhibitor deficiency (hereditary or acquired) or hereditary angioedema with normal C1 inhibitor are examples in this category. Blood levels may also increase because of an abnormality in bradykinin metabolism; the angioedema due to
ACE
inhibitors is a commonly encountered example. Angioedema due to bradykinin has the potential to cause airway obstruction and asphyxia as well as severe gastrointestinal symptoms simulating an acute abdomen. Formation of bradykinin in plasma is a result of a complex interaction among proteins such as factor XII, prekallikrein, and high molecular weight kininogen (HK) resulting in HK cleavage and liberation of bradykinin. These proteins also assemble along the surface of endothelial cells via zinc-dependent interactions with gC1qR, cytokeratin 1, and u-PAR. Endothelial cell expression (or secretion) of heat-shock protein 90 or
prolylcarboxypeptidase
can activate the prekallikrein-HK complex to generate bradykinin in the absence of factor XII, however factor XII is then secondarily activated by the kallikrein that results. Bradykinin is destroyed by carboxypeptidase N and angiotensin-converting enzyme. The hypotension associated with IgE-dependent anaphylaxis maybe mediated, in part, by massive proteolytic digestion of HK by kallikreins (tissue or plasma-derived) or other cell-derived kininogenases.
...
PMID:Kinins, airway obstruction, and anaphylaxis. 2051 82
The plasma bradykinin-forming cascade and the complement pathways share many elements, including cross-activation, common control mechanisms, and shared binding proteins. The C1 inhibitor (C1 INH) is not only the inhibitor of activated C1r and C1s, but it is the key control protein of the plasma bradykinin-forming cascade. It inhibits the autoactivation of Factor XII, the ability of Factor XIIa to activate prekallikrein and Factor XI, the activation of high molecular weight kininogen (HK) by kallikrein, and the feedback activation of Factor XII by kallikrein. Thus in the absence of C1 INH (hereditary angioedema or acquired C1 INH deficiency) there is unimpeded formation of bradykinin leading to angioedema. Activated Factor XII (Factor XIIa, 80,000 kDa) is further cleaved by kallikrein or plasmin to yield Factor XII fragment (Factor XIIf, 30,000 kDa) and Factor XIIf can activate the C1r subcomponent of C1, particularly when C1 INH (which inhibits Factor XIIf) is absent. Once bradykinin is formed, it causes vasodilatation and increased vascular permeability by interaction with constitutively expressed B-2 receptors. However degradation of bradykinin by carboxypeptidase N (in plasma) or carboxypeptidase M (on endothelial cells) yields des-arg-9 (Kerbiriou and Griffin, 1979) bradykinin which interacts with B-1 receptors. B-1 receptors are induced in inflammatory states by cytokines such as Interleukin 1 and its interaction with bradykinin may prolong or perpetuate the vascular response until bradykinin is completely inactivated by
angiotensin converting enzyme
or aminopeptidase P, or neutral endopeptidase. The entire bradykinin-forming cascade is assembled and can be activated along the surface of endothelial cells in zinc dependent reactions involving gC1qR, cytokeratin 1, and the urokinase plasminogen activated receptor (u-PAR). Although Factors XII and HK can be shown to bind to each one of these proteins, they exist in endothelial cells as two bimolecular complexes; gC1qR-cytokeratin 1, which preferentially binds HK, and cytokeratin 1-u-PAR which preferentially binds Factor XII. The gC1qR, which binds the globular heads of C1q is present in excess and can bind either Factor XII or HK however the binding sites for HK and C1q have been shown to reside at opposite ends of gC1qR. Activation of the bradykinin-forming pathway can be initiated at the cell surface by gC1qR-induced autoactivation of Factor XII or direct activation of the prekallikrein-HK complex by endothelial cell-derived heat-shock protein 90 (HSP 90) or
prolylcarboxypeptidase
with recruitment or Factor XII by the kallikrein produced.
...
PMID:The plasma bradykinin-forming pathways and its interrelationships with complement. 2058 91
