Studies were conducted which examined urinary excretion and papillary production of cyclic-AMP in... more Studies were conducted which examined urinary excretion and papillary production of cyclic-AMP in the rat following vasopressin (ADH) stimulation in the presence or absence of inorganic fluoride ion (F). In one set of experiments, six anesthetized Fischer 344 rats were administered 5 munits arginine vasopressin during iv saline and sodium fluoride (NaF) infusions. Urinary cyclic-AMP concentration was unchanged by ADH but declined during NaF infusion, while urinary cyclic
The Journal of pharmacology and experimental therapeutics, 1981
The hydro-osmotic response of the toad bladder to antidiuretic hormone and cyclic AMP was inhibit... more The hydro-osmotic response of the toad bladder to antidiuretic hormone and cyclic AMP was inhibited by the methoxyflurane metabolite, fluoride. The osmotic transfer of water in the absence of hormone was unaffected by fluoride as was the hydroosmotic response due to hypertonicity of the serosal bathing media. Osmotic water movements across N-ethylmaleimide-"fixed" vasopressin or cyclic AMP-stimulated bladders were likewise unchanged by fluoride, suggesting that fluoride is exerting an action subsequent to the endogenous formation of cyclic AMP but before the final effector mechanism. Fluoride increased intracellular cyclic AMP concentrations even in the presence of added hormone. Fluoride suppressed calmodulin activity and prevented its activation of phosphodiesterase. Fluoride had no effect on oxygen consumption of toad urinary bladder cells but reduced lactate formation and anerobic metabolism. This decrease in the glycolytic energy source did not contribute to the inhib...
Journal of Ocular Pharmacology and Therapeutics, Aug 1, 2005
A significant loss and remodeling of the lamina cribrosa tissue leading to the excavation of the ... more A significant loss and remodeling of the lamina cribrosa tissue leading to the excavation of the optic nerve is seen in glaucoma. Elevated endothelin-1 (ET-1) levels are detected in the aqueous humor of patients of open-angle glaucoma and in the plasma of patients with normal- tension glaucoma. Optic nerve damage, including axonal loss, can be mimicked by ET-1 injection near the optic nerve. ET-1 is produced from its precursor Big ET-1 (38 amino acids) by endothelin-converting enzyme (ECE). Although ET-1 and its receptors have been identified in the retina, little is known of the distribution of ECE at the optic nerve. Presently, ET-1 receptors and Big ET-1 converting activities were characterized in bovine optic nerve and the retina. The ET(B) receptor was detected in both the optic nerve and retina by immunoblotting and cross-linking, using 125I-ET-1. However, the ET(A) receptor was detected only in the retina. Big ET-1 conversion activities were detected in the plasma membrane (PM) of bovine retina, but not in the PM of the optic nerve. The retinal PM Big ET-1 converting activity was inhibited by phosphoramidon, thiorphan, and acidification. Furthermore, ECE cytosolic activities were detected in both the optic nerve and retina. Unlike the PM-ECE, cytosolic Big ET-1 converting activities were activated by acidification (pH 6.4), suggesting the involvement of ECE-2-like activity and/or cathepsin activity. Pepstatin, a potent inhibitor of cathepsins, inhibited the optic nerve (ON) cytosolic conversion of Big ET-1 peptide by 50%, and the combination of pepstatin and phosphoramidon, a potent inhibitor of ECE, inhibited the ON cytosolic activity by 86%. By contrast, the combination of both inhibitors weakly inhibited the cytosolic retinal Big ET-1 converting activity. Western blotting revealed the presence of ECE-1 at the PM of the retina not the ON. ECE-2 and cathpesins B, D, and L were detected only in the cytosol of both the retina and ON. In summary, it appears that ET-1 could be produced in the retina and optic nerve by at least two ECE subtypes and, perhaps, cathepsins. Big ET-1 converting activity may be an important target in preventing ET-1-induced optic nerve pathology.
Serosal ADH stimulation enhances water flow under an imposed osmotic gradient through insertion o... more Serosal ADH stimulation enhances water flow under an imposed osmotic gradient through insertion of water channels (aggrephores) into the mucosal plasma membrane of toad urinary bladder sacs. Following cessation of ADH actions, water channels are retrieved as endosomes that can be visualized by mucosal inclusion of horseradish peroxidase (HRP) into round vesicles, long tubules and multivesicular bodies within the cytosol (1,2,3). Endosomes also occur adjacent to golgi bodies or lysosomes (1,2,3). However, true nature of endosomes including their formation at the mucosal surface and their shuttling in granular cells is still unclear (4,5). Current studies were undertaken to understand the role of endosomes in water channel cycling in this renal membrane model.Urinary bladder sacs removed surgically from doubly-pithed toads, were suspended at ends of glass tubes. Control (no hormone) and experimental bladder sacs were exposed to ADH for 10 min in the absence of osmotic gradient.
Studies were conducted which examined urinary excretion and papillary production of cyclic-AMP in... more Studies were conducted which examined urinary excretion and papillary production of cyclic-AMP in the rat following vasopressin (ADH) stimulation in the presence or absence of inorganic fluoride ion (F). In one set of experiments, six anesthetized Fischer 344 rats were administered 5 munits arginine vasopressin during iv saline and sodium fluoride (NaF) infusions. Urinary cyclic-AMP concentration was unchanged by ADH but declined during NaF infusion, while urinary cyclic
The Journal of pharmacology and experimental therapeutics, 1981
The hydro-osmotic response of the toad bladder to antidiuretic hormone and cyclic AMP was inhibit... more The hydro-osmotic response of the toad bladder to antidiuretic hormone and cyclic AMP was inhibited by the methoxyflurane metabolite, fluoride. The osmotic transfer of water in the absence of hormone was unaffected by fluoride as was the hydroosmotic response due to hypertonicity of the serosal bathing media. Osmotic water movements across N-ethylmaleimide-"fixed" vasopressin or cyclic AMP-stimulated bladders were likewise unchanged by fluoride, suggesting that fluoride is exerting an action subsequent to the endogenous formation of cyclic AMP but before the final effector mechanism. Fluoride increased intracellular cyclic AMP concentrations even in the presence of added hormone. Fluoride suppressed calmodulin activity and prevented its activation of phosphodiesterase. Fluoride had no effect on oxygen consumption of toad urinary bladder cells but reduced lactate formation and anerobic metabolism. This decrease in the glycolytic energy source did not contribute to the inhib...
Journal of Ocular Pharmacology and Therapeutics, Aug 1, 2005
A significant loss and remodeling of the lamina cribrosa tissue leading to the excavation of the ... more A significant loss and remodeling of the lamina cribrosa tissue leading to the excavation of the optic nerve is seen in glaucoma. Elevated endothelin-1 (ET-1) levels are detected in the aqueous humor of patients of open-angle glaucoma and in the plasma of patients with normal- tension glaucoma. Optic nerve damage, including axonal loss, can be mimicked by ET-1 injection near the optic nerve. ET-1 is produced from its precursor Big ET-1 (38 amino acids) by endothelin-converting enzyme (ECE). Although ET-1 and its receptors have been identified in the retina, little is known of the distribution of ECE at the optic nerve. Presently, ET-1 receptors and Big ET-1 converting activities were characterized in bovine optic nerve and the retina. The ET(B) receptor was detected in both the optic nerve and retina by immunoblotting and cross-linking, using 125I-ET-1. However, the ET(A) receptor was detected only in the retina. Big ET-1 conversion activities were detected in the plasma membrane (PM) of bovine retina, but not in the PM of the optic nerve. The retinal PM Big ET-1 converting activity was inhibited by phosphoramidon, thiorphan, and acidification. Furthermore, ECE cytosolic activities were detected in both the optic nerve and retina. Unlike the PM-ECE, cytosolic Big ET-1 converting activities were activated by acidification (pH 6.4), suggesting the involvement of ECE-2-like activity and/or cathepsin activity. Pepstatin, a potent inhibitor of cathepsins, inhibited the optic nerve (ON) cytosolic conversion of Big ET-1 peptide by 50%, and the combination of pepstatin and phosphoramidon, a potent inhibitor of ECE, inhibited the ON cytosolic activity by 86%. By contrast, the combination of both inhibitors weakly inhibited the cytosolic retinal Big ET-1 converting activity. Western blotting revealed the presence of ECE-1 at the PM of the retina not the ON. ECE-2 and cathpesins B, D, and L were detected only in the cytosol of both the retina and ON. In summary, it appears that ET-1 could be produced in the retina and optic nerve by at least two ECE subtypes and, perhaps, cathepsins. Big ET-1 converting activity may be an important target in preventing ET-1-induced optic nerve pathology.
Serosal ADH stimulation enhances water flow under an imposed osmotic gradient through insertion o... more Serosal ADH stimulation enhances water flow under an imposed osmotic gradient through insertion of water channels (aggrephores) into the mucosal plasma membrane of toad urinary bladder sacs. Following cessation of ADH actions, water channels are retrieved as endosomes that can be visualized by mucosal inclusion of horseradish peroxidase (HRP) into round vesicles, long tubules and multivesicular bodies within the cytosol (1,2,3). Endosomes also occur adjacent to golgi bodies or lysosomes (1,2,3). However, true nature of endosomes including their formation at the mucosal surface and their shuttling in granular cells is still unclear (4,5). Current studies were undertaken to understand the role of endosomes in water channel cycling in this renal membrane model.Urinary bladder sacs removed surgically from doubly-pithed toads, were suspended at ends of glass tubes. Control (no hormone) and experimental bladder sacs were exposed to ADH for 10 min in the absence of osmotic gradient.
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Papers by Thomas Yorio