EC:2.5.1.18 - FACTA Search

Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:2.5.1.18 (glutathione S-transferase)
22,582 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

A 39-kDa protein copurifies with the low-density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor (LRP) and inhibits the binding and/or cellular uptake of ligands by this receptor. We recently utilized glutathione S-transferase (GST)-39-kDa fusion protein constructs to demonstrate that constructs encoding amino-terminal residues 1-114 and carboxy-terminal residues 115-319 of the 39-kDa protein independently bind to purified LRP and to LRP on hepatoma cells with similar affinities as the full-length GST-39-kDa protein (Kd approximately 8-10 nM). These regions, however, inhibit ligand binding to LRP differently: GST/1-114 inhibits both tissue-type plasminogen activator (t-PA) and alpha 2-macroglobulin-methylamine (alpha 2M*) binding whereas GST/115-319 only potently inhibits t-PA binding. Four domains, containing residues 18-24 and 100-107 within amino-terminal constructs and residues 200-225 and 311-319 within carboxy-terminal constructs, are required for inhibition of ligand binding. In the present study, we generated additional 39-kDa protein constructs to precisely define residues within each domain required for inhibition of t-PA and alpha 2M* binding to LRP. The potential importance of these residues in mediating direct binding both to purified LRP and to LRP on hepatoma cells was examined. Within amino-terminal residues 1-114, alanine 103 and leucine 104 are required for inhibition of t-PA and alpha 2M* binding. These residues, however, are not required for binding either to purified LRP or to LRP on hepatoma cells. Within domain 18-24, arginine 21 is required for inhibition of t-PA and alpha 2M* binding as well as for the direct binding of amino-terminal constructs to LRP. Within carboxy-terminal domains 200-225 and 311-319, leucine 222 and leucine 319 are both required for inhibition of t-PA binding. Deletion of leucine 319 changes the ligand specificity from inhibition of t-PA binding to inhibition of alpha 2M* binding. Thus, leucine 319 is not required for direct binding to LRP whereas leucine 222 is required for high-affinity binding to LRP.
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PMID:Sites within the 39-kDa protein important for regulating ligand binding to the low-density lipoprotein receptor-related protein. 753 37

The low density lipoprotein receptor-related protein/alpha 2-macroglobulin receptor (LRP/alpha 2MR) binds and internalizes several plasma proteins including tissue-type plasminogen activator (t-PA) and alpha 2-macroglobulin-protease complexes (alpha 2M*). A 39-kDa protein that copurifies with LRP/alpha 2MR inhibits the binding and uptake of ligands by LRP/alpha 2MR, including t-PA and alpha 2M*. To define domains on the 39-kDa protein which are essential for inhibition of t-PA and alpha 2M* binding to LRP/alpha 2MR, we have generated bacterial expression constructs encoding discrete regions of the 39-kDa protein as fusion proteins with glutathione S-transferase. Inhibition of t-PA and alpha 2M* binding to LRP/alpha 2MR on rat hepatoma MH1C1 cells are shown to require amino acid residues 18-24 and 100-107 on the 39-kDa protein. Inhibition of t-PA but not alpha 2M* binding to LRP/alpha 2MR is also mediated by residues 200-225 and 311-319. The same 39-kDa protein constructs that inhibit alpha 2M* and t-PA binding to MH1C1 cells are able to bind directly to purified LRP/alpha 2MR immobilized on nitrocellulose. Thus, our studies demonstrate several specific regions on the 39-kDa protein which are required for the inhibition of t-PA and alpha 2M* binding to LRP/alpha 2MR.
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PMID:Identification of domains on the 39-kDa protein that inhibit the binding of ligands to the low density lipoprotein receptor-related protein. 769 21

The catabolism of the novel plasminogen activator reteplase (BM 06.022) was described. For this purpose BM 06.022 was radiolabelled with 125I or with the accumulating label 125I-tyramine cellobiose (125I-TC). BM 06.022 was injected at a pharmacological dose of 380 micrograms/kg b.w. and it was cleared from the plasma in a biphasic manner with a half-life of about 1 min in the alpha-phase and t1/2 of 20-28 min in the beta-phase. 28% and 72% of the injected dose was cleared in the alpha-phase and beta-phase, respectively. Initially liver, kidneys, skin, bones, lungs, spleen, and muscles contributed mainly to the plasma clearance. Only liver and the kidneys, however, were responsible for the uptake and subsequent degradation of BM 06.022 and contributed for 75% to the catabolism of BM 06.022. BM 06.022 was degraded in the lysosomal compartment of both organs. Parenchymal liver cells were responsible for 70% of the liver uptake of BM 06.022. BM 06.022 associated rapidly to isolated rat parenchymal liver cells and was subsequently degraded in the lysosomal compartment of these cells. BM 06.022 bound with low-affinity to the parenchymal liver cells (550 nM) and the binding of BM 06.022 could be displaced by t-PA (IC50 5.6 nM), indicating that the low-density lipoprotein receptor-related protein (LRP) could be involved in the binding of BM 06.22. GST-RAP, which is an inhibitor of LRP, could in vivo significantly inhibit the uptake of BM 06.022 in the liver. It is concluded that BM 06.22 is metabolized primarily in the liver and the kidneys. These organs take up and degrade BM 06.022 in the lysosomes. The uptake mechanism of BM 06.022 in the kidneys is unknown, while LRP is responsible for a low affinity binding and uptake of BM 06.022 in parenchymal liver cells.
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PMID:Uptake, internalization and degradation of the novel plasminogen activator reteplase (BM 06.022) in the rat. 877 28

Cytokeratin 8 (CK8) is an intermediate filament protein that penetrates to the external surfaces of breast cancer cells and is released from cells in the form of soluble heteropolymers. CK8 binds plasminogen and tissue-type plasminogen activator (t-PA) and accelerates plasminogen activation on cancer cell surfaces. The plasminogen-binding site is located at the C-terminus of CK8. In this study, we prepared GST-fusion proteins which contained either 174 amino acids from the C-terminus of CK8 (CK8f) or 134 amino acids from the C-terminus of CK18 (CK18f). A third GST-CK fusion protein was identical to CK8fexcept that the C-terminal lysine was mutated to glutamine (CK8fK483Q). CK8f bound plasminogen; the K(D) was 0.5 microM. Binding was completely inhibited by epsilonACA. CK8fK483Q also bound plasminogen, albeit with decreased affinity (K(D) approximately 1.5 microM). CK18f did not bind plasminogen at all. All three fusion proteins bound t-PA equivalently, providing the first evidence that CK18 may function as a t-PA receptor, t-PA and plasminogen cross-competed for binding to CK8f. Thus, t-PA and plasminogen cannot bind to the same CK8f monomer simultaneously. Nevertheless, CK8f still promoted plasminogen activation, probably reflecting the fact that CK8f was purified in dimeric or tetrameric form. These studies demonstrate that CK8 may promote plasminogen activation by t-PA only when present in an oligomerized state. CK18 may participate in the oligomer, together with CK8, based on its ability to bind t-PA.
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PMID:Characterization of the binding sites for plasminogen and tissue-type plasminogen activator in cytokeratin 8 and cytokeratin 18. 998 31

Several clinical studies have demonstrated an inverse relationship between circulating levels of estrogen and tissue-type plasminogen activator (t-PA). The present study was designed to test the hypothesis that estrogens lower plasma levels of t-PA by increasing its clearance from the bloodstream. 17alpha-Ethinyl estradiol (EE) treatment resulted in a significant increase in the clearance rate of recombinant human t-PA in mice (0.46 mL/min in treated mice v 0. 32 mL/min in controls; P <.01). The clearance of endogenous, bradykinin-released t-PA in rats was also significantly increased after EE treatment (area under the curve [AUC], 24.9 ng/mL. min in treated animals v 31.9 ng/mL. min in controls; P <.05). Two distinct t-PA clearance systems exist in vivo: the low-density lipoprotein receptor-related protein (LRP) on liver parenchymal cells and the mannose receptor on mainly liver endothelial cells. Inhibition of LRP by intravenous injection of receptor-associated protein (RAP) as a recombinant fusion protein with Salmonella japonicum glutathione S-transferase (GST) significantly retarded t-PA clearance in control mice (from 0.41 to 0.25 mL/min; n = 5, P <.001) and EE-treated mice (from 0.66 to 0.35 mL/min; n = 5, P <.005), but did not eliminate the difference in clearance capacity between the 2 experimental groups. Similar results were obtained in mice in which LRP was inhibited via overexpression of the RAP gene in liver by adenoviral gene transduction. In contrast, administration of mannan, a mannose receptor antagonist, resulted in identical clearances (0.22 mL/min in controls and 0.24 mL/min in EE-treated mice). Northern blot analysis showed a 6-fold increase in mannose receptor mRNA expression in the nonparenchymal liver cells of EE-treated mice, whereas the parenchymal LRP mRNA levels remained unchanged. These findings were confirmed at the protein level by ligand blotting and Western blotting analysis. Our results demonstrate that EE treatment results in increased plasma clearance rate of t-PA via induction of the mannose receptor and could explain for the inverse relationship between estrogen status and plasma t-PA concentrations as observed in humans.
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PMID:Increased clearance explains lower plasma levels of tissue-type plasminogen activator by estradiol: evidence for potently enhanced mannose receptor expression in mice. 1043 21

Even small increases in the frequency of thrombotic disease in users of OCs have general health impact because of their widespread use, which is currently expanding to potential risk groups. The present investigations were launched to study the effects of OCs containing 20-40 micrograms of EE combined with the latest developed gonane progestogens on biochemical risk markers within metabolic systems involved in the development of arterial thrombotic disease. The studies included evaluation of carbohydrate and lipid metabolism as well as the haemostatic system and were performed in non-diabetic women and in women with IDDM, who are prone to the development of arterial thrombosis. In the evaluation of the carbohydrate metabolism in non-diabetic women, we found no effect on fasting glucose or insulin and no effect on the insulin response to oral glucose in women using monophasic OCs containing EE combined with DSG or GST. This contrasts the evaluation of triphasic OCs containing EE combined with GST or NGT, which increased fasting insulin and reduced insulin sensitivity without affecting the glucose-effectiveness or the beta-cell function. Impaired glucose tolerance developed in 10% of the women after 6 months. These finding suggest that OCs are able to induce a state of insulin resistance, which should be considered in the prescription for women with potential disturbed insulin sensitivity or reduced beta-cell secretory capacity e.g. women with ovarian hyperandrogenism, obesity, previous GDM or perimenopausal women. We found no change in glycaemic control in 22 women with well-regulated IDDM treated with a monophasic combination of EE and GST for one year and none of the women developed microalbuminuria during treatment. In the women with diabetes we observed an increase in fasting levels of triglycerides, a decrease in LDL-cholesterol, and unchanged concentrations of total cholesterol and HDL-cholesterol during treatment. In non-diabetic women treated with the same compound or an OC containing EE and DSG we found similar changes in triglycerides and total cholesterol, but increased levels of HDL-cholesterol and unchanged LDL-cholesterol concentrations. In the women with IDDM there was a negative correlation between daily insulin requirement and HDL-cholesterol before and during treatment, but no other statistically significant correlation between estimates of glycaemic control and lipids and lipoproteins were observed. In the non-diabetic women, changes in the haemostatic system included an increase in the procoagulant factors fibrinogen and Factor VIIc; the concentration of active t-PA increased, mainly because of decreased inhibition by PAI-1. The ratio between molecular markers of the activity of the coagulation system and the efficacy of fibrinolysis was unchanged. This was also found in the women with IDDM, who showed evidence of increased fibrin formation and an attenuated fibrinolytic response during treatment. The regulation of the t-PA/PAI system was studied in non-diabetic women in order to elucidate if the effects of OCs are caused by a direct effect on synthesis or clearance of these variables or if they are secondary to changed insulin sensitivity, as described in individuals with atherosclerosis. We found no indications that insulin resistance is involved in the regulation of t-PA and PAI-1 antigen levels, neither before nor during intake of OCs. We showed, however, that the decreased t-PA antigen concentration observed in OC users is caused by reduced synthesis outside the splanchnic circulation. The studies indicate that low-dose OCs containing newer gonane progestogens are able to induce insulin resistance and to impair glucose tolerance. Lipoproteins were not adversely influenced by the OCs neither in the diabetic nor the non-diabetic women; on the contrary, there was a tendency towards increased plasma levels of HDL-cholesterol and decreased LDL-cholesterol which are associated with a decreased risk of atherosclerosis. The changes observed within the haemostatic system were in accordance with a maintained balance between coagulation and fibrinolysis although the rate of fibrin formation may be increased in the women with IDDM. Irrespective of OC use, the interrelationships between metabolic systems in young non-diabetic women are different from those reported in individuals with atherosclerosis or insulin resistance. The effects of OCs on the t-PA/PAI system seem to be mediated by a direct effect on the vessel wall and not by changes in the hepatic clearance. The present findings were obtained in diabetic women without vascular complications, so the conclusion that women with IDDM can use OCs without metabolic alterations of known clinical significance is therefore restricted to those without evidence of diseased vessels. When evaluating the results obtained in the non-diabetic women, it should be remembered that women with recognised risk factors were excluded. The results may therefore be of limited value when evaluating the risk of arterial thrombosis in predisposed populations. In healthy individuals, the present integrated evaluation of biochemical markers does not indicate an increased risk of arterial thrombosis during use of low-dose OCs containing newer gonane progestogens; thus, the findings are in accordance with the recent epidemiological studies on these compounds. The application of relevant biochemical markers facilitate the understanding of the non-reproductive effects of sex steroids which have increasing importance because of their expanding use, not only as contraceptives, but also in the treatment of benign gynaecological disorders, as hormone replacement therapy and as prophylactic agents against specific degenerative conditions. Moreover, they may prove to be helpful in the future identification of women, who have increased susceptibility to the metabolic effects of sex steroids due to genetic predisposition.
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PMID:Pharmacodynamic effects of oral contraceptive steroids on biochemical markers for arterial thrombosis. Studies in non-diabetic women and in women with insulin-dependent diabetes mellitus. 1189 23

Within the kidney, angiotensin II type 2 (AT(2)) receptor mediates phospholipase A(2) (PLA(2)) activation, arachidonic acid release, epidermal growth factor (EGF) receptor transactivation, and mitogen-activated protein kinase activation. Arachidonic acid mimics this transactivation by an undetermined mechanism. The role of c-Src in mediating angiotensin II and arachidonic acid signaling was determined by employing immunocomplex kinase assay, Western blotting analysis, and protein immunoblotting on co-precipitated EGF receptor (EGFR) proteins and agarose conjugates of glutathione S-transferase fusion proteins containing the c-Src homology 2 (SH2) and SH3 domains. Angiotensin II induced extracellular signal-regulated kinase (ERK) activation in primary cultures of rabbit proximal tubule cells via the activation of c-Src and association of the EGFR with the c-Src SH2 domain, effects that were mimicked by arachidonic acid and its inactive analogue eicosatetraynoic acid. Inhibition of PLA(2) by mepacrine and methyl arachidonyl fluorophosphate, AT(2) receptor by PD123319, Src family kinases by, 1-(tert-butyl)-3-(4-chlorophenyl)-4-aminopyrazolo[3,4-d] pyrimidine (PP2) and c-Src by overexpression of a dominant-negative mutant of c-Src abrogated these effects. However, inhibitors of arachidonic acid metabolic pathways did not block these effects. The present work provides a new and novel paradigm for transactivation of a kinase receptor linked to a fatty acid, which may apply to activation of a variety of phospholipases and accompanying arachidonic acid release.
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PMID:Arachidonic acid induces ERK activation via Src SH2 domain association with the epidermal growth factor receptor. 1659 96

The mechanisms involved in regulating mammary cell turnover during the pregnancy-lactation cycle in dairy cows are unclear. The objective of present experiment was to describe expression of genes encoding proteins known to be involved in pathways regulating mammary cell proliferation, apoptosis, differentiation, cell survival, and tissue remodeling. Mammary gland biopsies were taken 7 times during the pregnancy-lactation cycle of 10 dairy cows, and samples were analyzed by immunohistochemistry and real-time PCR. Cell proliferation was greatest during the dry period and apoptosis was high in early dry period and early lactation. Based on Fas (tumor necrosis factor receptor superfamily member 6), Fas ligand, and caspase-3, caspase-8, and caspase-9 gene expression, no indication was found of a stage-dependent shift between the extrinsic and intrinsic pathways leading to apoptosis. Gene expression of microsomal glutathione S-transferase (mGST) did not vary significantly, whereas B-cell leukemia/lymphoma 2 (Bcl-2) and BCL2-associated X protein (Bax) gene expression was greatest during the dry period and early lactation and coincided with high cell turnover. Gene expression of early response genes c-Fos, c-Jun, and c-Myc correlated to neither rate of cell proliferation nor plasma concentration of insulin-like growth factor (IGF)-I and insulin. Gene expression of nuclear factor of kappa light chain gene enhancer in B-cells (NFkappaB) and NFkappaB inhibitor alpha was greatest in the periparturient period, and NFkappaB gene expression coincided with an anticipated need for cell survival factors. Expression of transforming growth factor beta (TGF-beta) receptor 1 and 2 mRNA was greatest in early lactation, whereas TGF-beta1 did not vary significant during the pregnancy-lactation cycle. Even though our results on the TGF-beta system did not comply with other studies, the gene expression pattern of the TGF-beta receptors indicates a role in regulating apoptosis in early lactation. Signal transducer and activator of transcription 5 (STAT5) gene expression was high in the periparturient period, which suggests a role for STAT5 in regulation of mammary cell proliferation and differentiation in dairy cows. Expression of tissue-plasminogen activator, plasminogen activator inhibitor-1, and IGF binding protein 5 genes was greatest in early lactation, suggesting a role for IGF binding protein 5 in coordinating regulation of apoptosis and tissue remodeling.
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PMID:Cellular mechanisms in regulating mammary cell turnover during lactation and dry period in dairy cows. 1848 54

Staphylokinase (SAK) is reported to have a serine protease domain with no proteolytic activity unlike other plasminogen activators like tissue plasminogen activator (t-PA) and urokinase. A unique protease property of Staphylokinase was observed when SAK was expressed as a fusion protein in inducible Escherichia coli expression vectors. This finding was further investigated by cloning and expressing different SAK fusions, both native and N-terminal deletions, with fusion tags like glutathione S-transferase (GST) and signal sequence of SAK in bacterial system. While all the N-terminal SAK fusions were found to self-cleave in crude and purified preparations, the C-terminal SAK fusion was stable. The cleavage property of Staphylokinase fusion proteins, inhibited by reduced glutathione and PMSF, was independent of its thrombolytic activity and also independent on the type of host employed for its expression. The serine protease domain of the SAK gene possibly lies between 20th to 77th amino acid and serine 41 of this region appears critical for such a cleavage property.
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PMID:Novel self-cleavage activity of Staphylokinase fusion proteins: An interesting finding and its possible applications. 1963 10

The fibrinolytic activity of blood is regulated by expressing tissue-type plasminogen activator (t-PA) and its specific inhibitor, type-1 plasminogen activator inhibitor (PAI-1), from vascular endothelial cells. Since t-PA is a major plasminogen activator in blood, it is considered that the binding protein for t-PA, which exists on endothelial cell membrane, immobilizes t-PA on the surface of endothelial cells and enhances their antithrombotic property. Recently, we have found a new t-PA binding protein in endothelial cells. Its amino acid sequence has matched that of human adenine nucleotide translocase-1 (ANT1). The aims of this study are to confirm the binding of t-PA to ANT1, and to clarify the effect of ANT1 on fibrinolytic activity around endothelial cells. ANT1 is prepared from recombinant glutathione S-transferase (GST)-ANT1 fusion protein, and reveals t-PA binding activity in a ligand blot assay. In addition, ANT1 is exclusively expressed on endothelial cell membrane by using pDisplay vector. Interaction of t-PA with ANT1, which is expressed on the surface of endothelial cells, is confirmed by IAsys binding analysis and chromogenic assay. The heterologous expression of ANT1 on endothelial cell membrane enhances the t-PA binding ability of endothelial cells and the effect of ANT1 expression on fibrinolytic activity is demonstrated by increasing t-PA-catalyzed plasminogen activation. These results suggest that a novel t-PA-binding protein, ANT1, may concentrate t-PA on the surface of cells and enhance fibrinolytic properties around endothelial cells; therefore, ANT1 can be a powerful tool for regulating the plasminogen activation system in the vessel.
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PMID:Enhancement of fibrinolytic activity in vascular endothelial cells by heterologous expression of adenine nucleotide translocase-1. 2016 Jun 40

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