Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.3.1 (alkaline phosphatase)
 47,916 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Highly purified alkaline phosphatase [orthophosphoric-monoester phosphohydrolase (alkaline optimum), EC 3.1.3.1] from calf intestine inactivates the glucocorticoid-binding capacity of soluble preparations from mouse fibroblasts (L cells) and rat liver. The unbound receptor is sensitive to inactivation whereas the steroid-bound receptor is unaffected. The ability of the enzyme preparation to inactivate the receptor, like its ability to dephosphorylate p-nitrophenyl phosphate, is dependent on zinc and inhibited by arsenate. Both the dephosphorylating and receptor inactivating activities coelute during DEAE-cellulose purification of the enzyme. There is no detectable proteolytic activity in the purified alkaline phosphatase preparation. In a mixed system containing both glucocorticoid and estrogen receptors, the glucocorticoid receptor is selectively inactivated. Although these observations do not prove that the receptor molecule itself is the substrate, they are consistent with the proposal that the glucocorticoid receptor can be inactivated by dephosphorylation and that only the phosphorylated form of the molecule is capable of binding steroid. A phosphorylation-dephosphorylation mechanism may be responsible for determining the level of active receptor in the cell.
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PMID:Evidence that dephosphorylation inactivates glucocorticoid receptors. 26 81

The human placenta was found to contain a cytosol receptor for glucocorticoids. The concentration of this receptor in term placenta was 27-fold higher than that found in cytosol from first trimester placenta. The levels of cytosol glucocorticoid receptor in three trophoblastic cell lines (JAr, BeWo, and JEG) were also determined and all were found to be low. The ability of prednisolone, a potent glucocorticoid, to stimulate heat-stable alkaline phosphatase activity found in these cells was tested. Although control experiments demonstrated that the conditions were adequate to stimulate HeLa cell alkaline phosphatase, none of the trophoblastic lines responded to prednisolone administration. This result may be explained by the observation that the JAr cells lacked any detectable glucocorticoid receptor and the receptor levels in cytosol prepared from JEG and BeWo cells were 12% and 2%, respectively, of those measured in HeLa cytosol. Our studies also suggest that the increase in serum levels of heat-stable alkaline phosphatase observed during pregnancy may reflect increasing placental sensitivity to glucocorticoids as a result of increased receptor levels.
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PMID:The ontogony of the human placental glucocorticoid receptor and inducibility of heat-stable alkaline phosphatase. 43 82

To study hormone responsive genes in differentiated epithelial cells and as a model for endometrial carcinoma, lines were established from primary rat endometrial cells by infection with replication-defective retroviruses carrying oncogenes and the selectable gene neo. The initial step involved immortalization through the large T antigen of SV40 to generate a line we designate RENT4, or with the E1a gene of adenovirus to generate lines referred to as RENE1 and RENE2. Additionally, lines generated by large T antigen of SV40 were superinfected with a replication-defective retrovirus harboring the v-Ha-ras oncogene and selected by the ability to form colonies in soft agar. The latter cell lines appeared fully transformed and were designated RENTR01 and RENTR03. Five established lines were characterized for steroid hormone receptors, alkaline phosphatase activity and their complement of the intermediate filaments vimentin and cytokeratin. With the exception of the RENE1 cells all other lines have normal levels of glucocorticoid receptor, whereas only RENE1, RENE2 and RENT4 were positive for the progesterone receptor. RENTR01, RENTR03 and, to a lesser extent, RENE1 exhibited differential expression of cytokeratins dependent upon whether the cells were grown on a substrata of NIH3T3 cells. When grown on formalin-fixed NIH3T3 cells, RENTR01 and RENTR03 cells appeared to differentiate or rearrange themselves in culture. Individual islands of cells showed a heterogeneous pattern of intermediate filaments with vimentin-positive cells localized to the outer portion of the islands whereas cytokeratin-positive cells are seen on the insides of these structures.
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PMID:Establishment of rat endometrial cell lines by retroviral mediated transfer of immortalizing and transforming oncogenes. 169 89

Fluoride, in the presence of aluminum ions, reversibly inhibits the temperature-mediated inactivation of unoccupied glucocorticoid receptors in cytosol preparations from mouse L cells. The effect is concentration-dependent, with virtually complete stabilization of specific glucocorticoid-binding capacity at 2 mM fluoride and 100 microM aluminum. These concentrations of aluminum and fluoride are ineffective when used separately. Aluminum fluoride also stabilizes receptors toward inactivation by gel filtration and ammonium sulfate precipitation. Aluminum fluoride prevents temperature-dependent transformation of steroid-receptor complexes to the DNA-binding state. Aluminum fluoride does not inhibit calf intestine alkaline phosphatase, and unoccupied receptors inactivated by this enzyme in the presence of aluminum fluoride can be completely reactivated by dithiothreitol. The effects of aluminum fluoride are due to stabilization of the complex between the glucocorticoid receptor and the 90-kDa mammalian heat-shock protein hsp90, which suggests that aluminum fluoride interacts directly with the receptor. Endogenous thermal inactivation of receptors in cytosol is not accompanied by receptor dephosphorylation. However, inactivation is correlated with dissociation of hsp90 from the unoccupied receptor. These results support the proposal that hsp90 is required for the receptor to bind steroid and dissociation of hsp90 is sufficient to inactivate the unoccupied receptor.
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PMID:Aluminum fluoride inhibition of glucocorticoid receptor inactivation and transformation. 219 18

RU 486 is a synthetic steroid that binds avidly to glucocorticoid receptors without promoting their transformation into activated transcription factors. A significant part of this behavior has been shown to be due to a failure of the RU 486 bound receptor to be efficiently released from a larger (sedimenting at 8-9 S) multimeric complex containing the 90-kDa heat shock protein. Our studies have found that in vitro at 15 degrees C the RU 486-receptor was slowly released from the 8-9S complex and converted into a DNA binding protein by a process that could be blocked by sodium fluoride. Moreover, this transition was significantly accelerated by treatment with alkaline phosphatase. High-resolution anion-exchange chromatography showed that the profile of receptor subspecies released from the 8-9S complex (in the absence of phosphatase treatment) was different for the RU 486 bound receptor when compared to the receptor occupied by the agonist triamcinolone acetonide. Production of the earliest eluting receptor form (peak A) was inhibited with RU 486. Peak A had previously been shown to be the predominant form of the receptor possessing a capacity to bind DNA. Treatment of the RU 486-receptor with alkaline phosphatase increased the formation of the peak A subspecies as well as the capacity of receptor to bind DNA-cellulose. Taken together, the results indicate that phosphorylation of the receptor or a tightly bound factor contributes to defining the capacity with which individual steroids can promote dissociation of the 8-9S complex and conversion of the glucocorticoid receptor into a DNA-binding protein.
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PMID:Transformation of glucocorticoid receptors bound to the antagonist RU 486: effects of alkaline phosphatase. 226 52

The glucocorticoid receptor can be transformed into a DNA-binding protein by a process that is both hormone and temperature dependent. We have used a modification of the conventional method of anion-exchange chromatography to separate and analyze a variety of receptor subspecies that result from this transition. One receptor form (peak A) was found to have a capacity to bind DNA-cellulose which was significantly greater than that of the other species. Under conditions of mild heating (15 degrees C), the relative abundance of peak A in the receptor population and the rate of receptor transformation were both increased as a result of incubating samples with alkaline phosphatase. The mechanism appears to involve the conversion of the more "acidic" forms into that of peak A. The results indicate that receptor transformation is a multistep process which may be promoted by the removal of phosphate from either the receptor or a receptor-bound regulatory factor.
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PMID:Transformed glucocorticoid receptors consist of multiple subspecies with differing capacities to bind DNA-cellulose. 274 21

Rat hepatic cytosol was treated with alkaline phosphatase in order to determine if dephosphorylation altered the ability of Ah receptor to bind 2,3,7,8-[3H]tetrachlorodibenzo-p-dioxin (TCDD). Glucocorticoid receptor was studied for comparison. As previously had been shown in other laboratories, treatment of cytosol with purified alkaline phosphatase dramatically reduced the subsequent ability of glucocorticoid receptor to bind hormone. However, alkaline phosphatase had no effect on the ability of Ah receptor to bind [3H]TCDD. If either glucocorticoid receptor or Ah receptor was occupied by its ligand prior to exposure to alkaline phosphatase there was no loss in ligand binding capacity. Crude alkaline phosphatase (containing some protease activity) substantially reduced the ability of glucocorticoid receptor to bind hormone and shifted the sedimentation position of the glucocorticoid receptor from approximately 8 S to approximately 2 S. Crude alkaline phosphatase did not reduce the ability of Ah receptor to bind [3H]TCDD and did not alter sedimentation of the 9 S [3H]TCDD. Ah receptor complex. Although the Ah receptor appears to be a member of the steroid receptor superfamily, the lack of effect of alkaline phosphatase on Ah receptor (compared to the sensitivity of glucocorticoid receptor) highlights another significant difference in molecular characteristics between the Ah receptor and the receptors for steroid hormones.
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PMID:Ah receptor for 2,3,7,8-tetrachlorodibenzo-p-dioxin in rat liver: lack of sensitivity to alkaline phosphatase when compared with that of glucocorticoid receptor. 277 62

Digestion of the rat liver glucocorticoid receptor with chymotrypsin results in the generation of a 42-kDa fragment which contains the steroid-binding and DNA-binding domains and the antigenic site for the BuGR anti-glucocorticoid receptor monoclonal antibody, while digestion with trypsin generates a 15-kDa receptor fragment containing only the DNA-binding function and the BuGR epitope (Eisen, L.P., Reichman, M.E., Thompson, E.B., Gametchu, B., Harrison, R. W., and Eisen, H.J. (1985) J. Biol. Chem. 260, 11805-11810). In this paper, glucocorticoid receptor of mouse L cells that were grown in the presence of [32P]orthophosphate was digested with trypsin or chymotrypsin (either before or after immune purification with BuGR antibody) and analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, autoradiography, and Western blotting. The receptor is endogenously phosphorylated only on serine residues. Chymotrypsin digestion results in a 32P-labeled 42-kDa receptor fragment which contains steroid-binding, DNA-binding, and BuGR-reactive sites. Trypsin digestion generates a 27-kDa steroid-bound fragment (meroreceptor) which is not labeled with 32P and a 32P-labeled 15-kDa fragment which contains both the DNA-binding domain and the BuGR epitope. We have calculated that there are 4 times as many phosphate residues in the intact receptor than in the 42-kDa chymotrypsin fragment. From examination of 32P-labeled receptor fragments, we have deduced that one phosphate is located between amino acids 398 and 447, a region containing the BuGR epitope and about one-third of the DNA-binding domain, and the remaining three phosphates appear to be clustered just to the amino-terminal side of the BuGR epitope in a region defined by amino acids 313 to 369. Treatment of intact 32P-labeled receptor in cytosol with alkaline phosphatase removes these three phosphates, but it does not remove the phosphate from the DNA-binding-BuGR-reactive fragment and it does not affect the ability of the transformed receptor to bind to DNA-cellulose.
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PMID:Localization of phosphorylation sites with respect to the functional domains of the mouse L cell glucocorticoid receptor. 304 15

Addition of bovine intestinal alkaline phosphatase to mouse AtT-20 cell cytosol increases the rate of glucocorticoid receptor transformation, as evidenced by a change in sedimentation rate from 9.1S to 5.2S. Acid phosphatases are completely ineffective in this regard. Alkaline phosphatase-promoted receptor transformation is both time- and dose-dependent. A variety of phosphatase inhibitors are effective in inhibiting this process, the most potent being transition metal oxyanions such as molybdate, tungstate, and arsenate. The ability of the various inhibitors to suppress alkaline phosphatase-promoted receptor transformation does not correspond well with their potencies for inhibiting para-nitrophenyl phosphate hydrolysis. However, a better correspondence between the inhibition of endogenous receptor transformation and total cytosolic phosphatase activity is observed, and both sodium fluoride and glucose-1-phosphate inhibit endogenous receptor transformation. The protease inhibitors phenyl-methylsulfonyl fluoride and antipain have no effect on receptor transformation. Surprisingly, leupeptin is effective in inhibiting alkaline phosphatase-promoted receptor transformation. Although this raises the possibility of a contaminating protease activity in the alkaline phosphatase enzyme preparation, treatment of covalently affinity-labeled receptor with the enzyme shows no proteolysis of the receptor or any other non-specifically labeled cytosolic protein. Thus, it is possible that a novel action of leupeptin, unrelated to its protease-inhibitory activity, may be involved in the suppression of receptor transformation. The studies presented here suggest that dephosphorylation of some component in cytosol is involved in the destabilization of receptor subunit interactions, resulting in glucocorticoid receptor transformation.
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PMID:A possible role for dephosphorylation in glucocorticoid receptor transformation. 311 67

We have recently purified the modulator of the glucocorticoid-receptor complex from rat liver. Purified modulator inhibits glucocorticoid-receptor complex activation and stabilizes the steroid-binding ability of the unoccupied glucocorticoid receptor. Since these activities are shared by exogenous sodium molybdate, modulator appears to be the endogenous factor that sodium molybdate mimics. In this report, we present additional evidence for the mechanism of action of purified modulator. (i) Molybdate and modulator inhibit receptor activation as measured by DNA-cellulose binding, DEAE-cellulose chromatography, and Sepharose 4B gel filtration. (ii) The ability of molybdate and modulator to inhibit receptor activation and stabilize the unoccupied receptor appears to be additive. (iii) Scatchard analysis of heat-destabilized unoccupied receptors indicates that the number of steroid-binding sites is reduced during destabilization, whereas the steroid dissociation constant remains unchanged. Molybdate and modulator stabilize the receptor by maintaining the number of steroid-binding sites. (iv) Molybdate and modulator do not inhibit alkaline phosphatase-induced destabilization of the unoccupied receptor. However, alkaline phosphatase-induced destabilization is reversed by the addition of dithiothreitol in the presence, but not in the absence, of molybdate or modulator. These results suggest that the mechanism of action for modulator is identical to that of sodium molybdate, and we propose that modulator is the endogenous molybdate factor for the glucocorticoid receptor.
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PMID:Evidence that the modulator of the glucocorticoid-receptor complex is the endogenous molybdate factor. 342 44


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