10 results on '"Mangas, Iris"'
Search Results
2. Lubricating oils
- Author
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Vilanova, Eugenio, primary, Mangas, Iris, additional, Estevez, Jorge, additional, Estevan, Carmen, additional, and Sogorb, Miguel Angel, additional
- Published
- 2024
- Full Text
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3. Petroleum distillates
- Author
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Sogorb, Miguel Á., primary, Mangas, Iris, additional, Estevez, Jorge, additional, Estevan, Carmen, additional, and Vilanova, Eugenio, additional
- Published
- 2023
- Full Text
- View/download PDF
4. Cholinesterase and phenyl valerate-esterase activities sensitive to organophosphorus compounds in membranes of chicken brain.
- Author
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Estévez J, Benabent M, Selva V, Mangas I, Sogorb MÁ, Del Rio E, and Vilanova E
- Subjects
- Animals, Binding, Competitive drug effects, Brain drug effects, Kinetics, Membranes drug effects, Membranes enzymology, Brain enzymology, Carboxylic Ester Hydrolases drug effects, Chickens metabolism, Cholinesterase Inhibitors pharmacology, Cholinesterases drug effects, Organophosphorus Compounds pharmacology
- Abstract
Some effects of organophosphorus compounds (OPs) esters cannot be explained by action on currently recognized targets acetylcholinesterase or neuropathy target esterase (NTE). In previous studies, in membrane chicken brain fractions, four components (EPα, EPβ, EPγ and EPδ) of phenyl valerate esterase activity (PVase) had been kinetically discriminated combining data of several inhibitors (paraoxon, mipafox, PMSF). EPγ is belonging to NTE. The relationship of PVase components and acetylcholine-hydrolyzing activity (cholinesterase activity) is studied herein. Only EPα PVase activity showed inhibition in the presence of acetylthiocholine, similarly to a non-competitive model. EPα is highly sensitive to mipafox and paraoxon, but is resistant to PMSF, and is spontaneously reactivated when inhibited with paraoxon. In this papers we shows that cholinesterase activities showed inhibition kinetic by PV, which does not fit with a competitive inhibition model when tested for the same experimental conditions used to discriminate the PVase components. Four enzymatic components (CP1, CP2, CP3 and CP4) were discriminated in cholinesterase activity in the membrane fraction according to their sensitivity to irreversible inhibitors mipafox, paraoxon, PMSF and iso-OMPA. Components CP1 and CP2 could be related to EPα as they showed interactions between substrates and similar inhibitory kinetic properties to the tested inhibitors., (Copyright © 2018 Elsevier B.V. All rights reserved.)
- Published
- 2018
- Full Text
- View/download PDF
5. New insights on molecular interactions of organophosphorus pesticides with esterases.
- Author
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Mangas I, Estevez J, Vilanova E, and França TC
- Subjects
- Animals, Cholinesterases chemistry, Crystallography, X-Ray, Esterases chemistry, Humans, Organophosphorus Compounds chemistry, Pesticides chemistry, Protein Binding physiology, Protein Structure, Secondary, Spectrometry, Mass, Matrix-Assisted Laser Desorption-Ionization, Cholinesterases metabolism, Esterases metabolism, Organophosphorus Compounds metabolism, Pesticides metabolism
- Abstract
Organophosphorus compounds (OPs) are a large and diverse class of chemicals mainly used as pesticides and chemical weapons. People may be exposed to OPs in several occasions, which can produce several distinct neurotoxic effects depending on the dose, frequency of exposure, type of OP, and the host factors that influence susceptibility and sensitivity. These neurotoxic effects are mainly due to the interaction with enzyme targets involved in toxicological or detoxication pathways. In this work, the toxicological relevance of known OPs targets is reviewed. The main enzyme targets of OPs have been identified among the serine hydrolase protein family, some of them decades ago (e.g. AChE, BuChE, NTE and carboxylesterases), others more recently (e.g. lysophospholipase, arylformidase and KIA1363) and others which are not molecularly identified yet (e.g. phenylvalerate esterases). Members of this family are characterized by displaying serine hydrolase activity, containing a conserved serine hydrolase motif and having an alpha-beta hydrolase fold. Improvement in Xray-crystallography and in silico methods have generated new data of the interactions between OPs and esterases and have established new methods to study new inhibitors and reactivators of cholinesterases. Mass spectrometry for AChE, BChE and APH have characterized the active site serine adducts with OPs being useful to detect biomarkers of OPs exposure and inhibitory and postinhibitory reactions of esterases and OPs. The purpose of this review is focus specifically on the interaction of OP with esterases, mainly with type B-esterases, which are able to hydrolyze carboxylesters but inhibited by OPs by covalent phosphorylation on the serine or tyrosine residue in the active sites. Other related esterases in some cases with no-irreversible effect are also discussed. The understanding of the multiple molecular interactions is the basis we are proposing for a multi-target approach for understanding the organophosphorus toxicity., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)
- Published
- 2017
- Full Text
- View/download PDF
6. Esterases hydrolyze phenyl valerate activity as targets of organophosphorus compounds.
- Author
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Mangas I, Estévez J, and Vilanova E
- Subjects
- Animals, Brain drug effects, Brain enzymology, Humans, Hydrolysis, Kinetics, Esterases metabolism, Organophosphorus Compounds toxicity, Valerates metabolism
- Abstract
OPs are a large diverse class of chemicals used for several purposes (pesticides, warfare agents, flame retardants, etc.). They can cause several neurotoxic disorders: acute cholinergic toxicity, organophosphorus-induced delayed neuropathy, long-term neurobehavioral and neuropsychological symptoms, and potentiation of neuropathy. Some of these syndromes cannot be fully understood with known molecular targets. Many enzyme systems have the potential to interact with OPs. Since the discovery of neuropathy target esterase (NTE), the esterases that hydrolyze phenyl valerate (PVases) have been of interest. PVase components are analyzed in chicken tissue, the animal model used for testing OP-delayed neurotoxicity. Three enzymatic components have been discriminated in serum, and three in a soluble fraction of peripheral nerve, three in a soluble fraction of brain, and four in a membrane fraction of brain have been established according to inhibitory kinetic properties combined with several inhibitors. The criteria and strategies to differentiate these enzymatic components are shown. In the brain soluble fraction three enzymatic components, namely Eα, Eβ and Eγ, were found. Initial interest focused on Eα activity (highly sensitive to paraoxon and spontaneously reactivated, mipafox and resistant to PMSF). By protein separation methods, a subfraction enriched in Eα activity was obtained and 259 proteins were identified by Tandem Mass Spectrometry. Only one had the criteria for being serine-esterase identified as butyrylcholinesterase, which stresses the relationship between cholinesterases and PVases. The identification and characterization of the whole group of PVases targets of OPs (besides AChE, BuChE and NTE) is necessary to clarify the importance of these other targets in OPs neurotoxicity or on detoxication pathways. A systematic strategy has proven useful for the molecular identification of one enzymatic component, which can be applied to identify them all., (Copyright © 2016. Published by Elsevier Ireland Ltd.)
- Published
- 2016
- Full Text
- View/download PDF
7. Acetylcholine-hydrolyzing activities in soluble brain fraction: Characterization with reversible and irreversible inhibitors.
- Author
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Estévez J, Selva V, Benabent M, Mangas I, Sogorb MÁ, and Vilanova E
- Subjects
- Acetylthiocholine metabolism, Animals, Carboxylic Ester Hydrolases antagonists & inhibitors, Carboxylic Ester Hydrolases metabolism, Chickens, Hydrolysis drug effects, Phenothiazines pharmacology, Phosphoramides pharmacology, Solubility, Subcellular Fractions enzymology, Time Factors, Tosyl Compounds pharmacology, Acetylcholine metabolism, Acetylcholinesterase metabolism, Brain enzymology, Cholinesterase Inhibitors pharmacology
- Abstract
Some effects of organophosphorus compounds (OPs) esters cannot be explained through actions on currently recognized targets acetylcholinesterase or neuropathy target esterase (NTE). In soluble chicken brain fraction, three components (Eα, Eβ and Eγ) of pheny lvalerate esterase activity (PVase) were kinetically discriminated and their relationship with acetylcholine-hydrolyzing activity (cholinesterase activity) were studied in previous works. In this work, four enzymatic components (CS1, CS2, CS3 and CS4) of cholinesterase activity have been discriminated in soluble fraction, according to their sensitivity to irreversible inhibitors mipafox, paraoxon, PMSF and iso-OMPA and to reversible inhibitors ethopropazine and BW284C51. Cholinesterase component CS1 can be related to the Eα component of PVase activity and identified as butyrylcholinesterase (BuChE). No association and similarities can be stablished among the other PVase component (Eβ and Eγ) with the other cholinesterase components (CS2, CS3, CS4). The kinetic analysis has allowed us to stablish a method for discriminating the enzymatic component based on a simple test with two inhibitors. It can be used as biomarker in toxicological studies and for monitoring these cholinesterase components during isolation and molecular identification processes, which will allow OP toxicity to be understood by a multi-target approach., (Copyright © 2016 Elsevier Ireland Ltd. All rights reserved.)
- Published
- 2016
- Full Text
- View/download PDF
8. Interaction between substrates suggests a relationship between organophosphorus-sensitive phenylvalerate- and acetylcholine-hydrolyzing activities in chicken brain.
- Author
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Benabent M, Vilanova E, Mangas I, Sogorb MÁ, and Estévez J
- Subjects
- Acetylcholine pharmacology, Animals, Benzenaminium, 4,4'-(3-oxo-1,5-pentanediyl)bis(N,N-dimethyl-N-2-propenyl-), Dibromide pharmacology, Chickens, Hydrolysis, Isoflurophate analogs & derivatives, Isoflurophate pharmacology, Phenylmethylsulfonyl Fluoride pharmacology, Valerates pharmacology, Acetylcholinesterase metabolism, Brain enzymology, Carboxylic Ester Hydrolases metabolism, Organophosphorus Compounds pharmacology
- Abstract
Organophosphorus compounds (OPs) induce neurotoxic disorders through interactions with well-known target esterases, such as acetylcholinesterase and neuropathy target esterase (NTE). However, OPs interact with other esterases of unknown biological function. In soluble chicken brain fractions, three components of enzymatic phenylvalerate esterase activity (PVase) called Eα, Eβ and Eγ, have been kinetically discriminated. These components are studied in this work for the relationship with acetylcholine-hydrolyzing activity. When Eα PVase activity (resistant PVase activity to 1500 μM PMSF for 30 min) was tested with different acetylthiocholine concentrations, inhibition was observed. The best-fitting model to the data was the non-competitive inhibition model (Km=0.12, 0.22 mM, Ki=6.6, 7.6 mM). Resistant acetylthiocholine-hydrolyzing activity to 1500 μM PMSF was inhibited by phenylvalerate showing competitive inhibition (Km=0.09, 0.11 mM; Ki=1.7, 2.2 mM). Eβ PVase activity (resistant PVase activity to 25 μM mipafox for 30 min) was not affected by the presence of acetylthiocholine, while resistant acetylthiocholine-hydrolyzing activity to 25 μM mipafox showed competitive inhibition in the presence of phenylvalerate (Km=0.05, 0.06 mM; Ki=0.44, 0.58 mM). The interactions observed between the substrates of AChE and PVase suggest that part of PVase activity might be a protein with acetylthiocholine-hydrolyzing activity., (Copyright © 2014 Elsevier Ireland Ltd. All rights reserved.)
- Published
- 2014
- Full Text
- View/download PDF
9. Interactions of neuropathy inducers and potentiators/promoters with soluble esterases.
- Author
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Estévez J, Mangas I, Sogorb MÁ, and Vilanova E
- Subjects
- Animals, Brain drug effects, Brain enzymology, Catalytic Domain, Chickens, Esterases chemistry, Isoflurophate analogs & derivatives, Isoflurophate toxicity, Kinetics, Paraoxon toxicity, Phenylmethylsulfonyl Fluoride toxicity, Sciatic Nerve drug effects, Sciatic Nerve enzymology, Solubility, Enzyme Inhibitors toxicity, Esterases antagonists & inhibitors, Nervous System Diseases chemically induced, Nervous System Diseases enzymology, Organophosphorus Compounds toxicity
- Abstract
Organophosphorus compounds (OPs) cause neurotoxic disorders through interactions with well-known target esterases, such as acetylcholinesterase and neuropathy target esterase (NTE). However, the OPs can potentially interact with other esterases of unknown significance. Therefore, identifying, characterizing and elucidating the nature and functional significance of the OP-sensitive pool of esterases in the central and peripheral nervous systems need to be investigated. Kinetic models have been developed and applied by considering multi-enzymatic systems, inhibition, spontaneous reactivation, the chemical hydrolysis of the inhibitor and "ongoing inhibition" (inhibition during the substrate reaction time). These models have been applied to discriminate enzymatic components among the esterases in nerve tissues of adult chicken, this being the experimental model for delayed neuropathy and to identify different modes of interactions between OPs and soluble brain esterases. The covalent interaction with the substrate catalytic site has been demonstrated by time-progressive inhibition during ongoing inhibition. The interaction of sequential exposure to an esterase inhibitor has been tested in brain soluble fraction where exposure to one inhibitor at a non inhibitory concentration has been seen to modify sensitivity to further exposure to others. The effect has been suggested to be caused by interaction with sites other than the inhibition site at the substrate catalytic site. This kind of interaction among esterase inhibitors should be considered to study the potentiation/promotion phenomenon, which is observed when some esterase inhibitors enhance the severity of the OP induced neuropathy if they are dosed after a non neuropathic low dose of a neuropathy inducer., (Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.)
- Published
- 2013
- Full Text
- View/download PDF
10. NTE and non-NTE esterases in brain membrane: kinetic characterization with organophosphates.
- Author
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Mangas I, Vilanova E, and Estévez J
- Subjects
- Animals, Brain drug effects, Carboxylic Ester Hydrolases antagonists & inhibitors, Cell Membrane drug effects, Chickens, Enzyme Activation drug effects, Esterases antagonists & inhibitors, Esterases metabolism, Neuroprotective Agents antagonists & inhibitors, Neuroprotective Agents metabolism, Paraoxon pharmacokinetics, Brain enzymology, Carboxylic Ester Hydrolases metabolism, Cell Membrane enzymology, Organophosphates pharmacokinetics
- Abstract
Some effects of organophosphorus compounds (OPs) esters cannot be explained by action on currently recognized targets. In this work, we evaluate and characterize the interaction (inhibition, reactivation and "ongoing inhibition") of two model compounds: paraoxon (non-neuropathy-inducer) and mipafox (neuropathy-inducer), with esterases of chicken brain membranes, an animal model, tissue and fractions, where neuropathy target esterase (NTE) was first described and isolated. Four enzymatic components were discriminated. The relative sensitivity of time-progressive inhibition differed for paraoxon and mipafox. The most sensitive component for paraoxon was also the most sensitive component for mipafox (EPα: 4.4-8.3% of activity), with I(50) (30 min) of 15-43 nM with paraoxon and 29 nM with mipafox, and it spontaneously reactivated after inhibition with paraoxon. The second most sensitive component to paraoxon (EPβ: 38.3% of activity) had I(50) (30 min) of 1540 nM, and was practically resistant to mipafox. The third component (EPγ: 38.6-47.6% of activity) was paraoxon-resistant and sensitive to micromolar concentrations of mipafox; this component meets the operational criteria of being NTE (target of organophosphorus-induced delayed neuropathy). It had I(50) (30 min) of 5.3-6.6 μM with mipafox. The fourth component (EPδ: 9.8-10.7% of activity) was practically resistant to both inhibitors. Two paraoxon-resistant and mipafox-sensitive esterases were found using the sequential assay removing paraoxon, but only one was paraoxon-resistant and mipafox-sensitive according to the assay without removing paraoxon. We demonstrate that this apparent discrepancy, interpreted as reversible NTE inhibition with paraoxon, is the result of spontaneous reactivation after paraoxon inhibition of a non-NTE component. Some of these esterases' sensitivity to OPs suggests that they may play a role in toxicity in low-level exposure to organophosphate compounds or have a protective effect related with spontaneous reactivation. The kinetic characterization of these components will facilitate further studies for isolation and molecular characterization., (Copyright © 2012 Elsevier Ireland Ltd. All rights reserved.)
- Published
- 2012
- Full Text
- View/download PDF
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