对虾的不同发育阶段对有机磷农药的敏感性及其机理初探

对硫磷、甲基异柳磷和久效磷对中国对虾无节幼虫、蚤状幼虫、糠虾幼虫、仔虾的２４ｈＬＣ５０分别为６．０、４．０、３．８、１８×１０－３ｍｇ·Ｌ－１;８．０、３．５、３．５、３０×１０－３ｍｇ·Ｌ－１;２４、２４、２４、０．９ｍｇ·Ｌ－１;敌敌畏均为４８×１０－３ｍｇ·Ｌ－１;对硫磷对南美白对虾为８．６、８．２、８．０、２．０×１０－３ｍｇ·Ｌ－１．研究结果表明,对虾的幼虫前期对硫代磷酸酯类农药的抗性强,仔虾及以后各期抗性弱,而各幼虫期对磷酸酯类农药的敏感性基本相同．     

Sensitivity of beta-casein phosphopeptide-iron complex to digestive enzymes in ligated segment of rat duodenum

Binding iron to the phosphorylated beta(1-25) peptide derived from beta-casein improves iron bioavailability in the rat. The aim of the present work was to learn how injected beta(1-25) and iron-beta(1-25) complex behave in the duodenum of rats using the technique of intestinal ligation in situ and reversed-phase (RP)-high performance liquid chromatography-electrospray mass spectrometry analysis of the lumen contents. The results demonstrate that beta(1-25) is sensitive to digestive enzymes including proteases/peptidases and phosphatases during duodenal transit. The lumen contents of rats perfused with iron free beta(1-25) contained all peptidic sequences derived from beta(1-25). In contrast, the phosphorylated part of beta(1-25) [i.e., beta(15-24)] was not detected in lumen of rats perfused with iron-beta(1-25) complex.     

Hydrolysis of organophosphorus compounds by microbial enzymes

There are classes of microbial enzymes that have the ability to degrade harmful organophosphorus (OP) compounds that are present in some pesticides and nerve agents. To date, the most studied and potentially important OP-degrading enzymes are organophosphorus hydrolase (OPH) and organophosphorus acid anhydrolase (OPAA), which have both been characterized from a number of organisms. Here we provide an update of what is experimentally known about OPH and OPAA to include their structures, substrate specificity, and catalytic properties. Current and future potential applications of these enzymes in the hydrolysis of OP compounds are also addressed.     

Toxicity of organophosphorus systemic pesticides to predator mites and prey

Three systemic OP insecticides, Di-Syston^®, Meta-Systox-R^® and Systox^® were added at six concentrations (0.002–0.032% active ingredient) to nutrient solutions in which bean plants were cultured. On all concentrations the materials were less toxic to the two-spotted spider mite,Tetranychus urticae Koch feeding on the plant than toNeoseiulus fallacis (Garman) preying on theT. urticae. Of the three, Di-Syston was the least toxic to both mite species. WhenT. urticae were cultured on detached bean leaves, placed on cellucotton in nutrient solutions containing the same pesticide concentrations, their eggs were also toxic toN. fallacis. Longevity studies in conjunction with³²P labelled foliage showed thatN. fallacis are incapable of feeding directly on bean leaves.

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Zusammenfassung Drei systemische Phosphorinsektizide, Di-Syston^®, Meta-Systox^® und Systox^®, wurden, in sechs Konzentrationen (0,002–0,032% Wirkstoff) zu Nährstofflösungen hinzugefügt, in denen Bohnenpflanzen kultiviert wurden. Für die SpinnmilbeTetranychus urticae, die an den Bohnenblättern saugte, waren die drei Insektizide in sämtlichen Konzentrationen weniger toxisch als für die RaubmilbeNeoseiulus fallacis, die sich vonT. urticae ernährte. Es ergab sich demnach keine ökologische Selektivität. Von den drei geprüften Mitteln war Di-Syston für die beiden Milben am wenigsten toxisch. Wenn manT. urticae auf abgetrennten Bohnenblättern, die sich auf Cellucotton in Nährstofflösungen mit den genannten Insektizidkonzentrationen befanden, züchtete, wurden ihre Eier fürN. fallacis ebenfalls toxisch. Lebensdauer-Versuche mit Blättern, die³²P enthielten, zeigten, daßN. fallacis nicht fähig ist, sich direkt von Bohnenblättern zu ernähren.

     

Screening assays for cholinesterases resistant to inhibition by organophosphorus toxicants

Methods to measure resistance to inhibition by organophosphorus toxicants (OP) for mutants of butyrylcholinesterase (EC 3.1.1.8; BChE) and acetylcholinesterase (EC 3.1.1.7; AChE) enzymes were devised. Wild-type cholinesterases were completely inhibited by 0.1 mM echothiophate or 0.001 mM diisopropylfluorophosphate, but human BChE mutants G117H, G117D, L286H, and W231H and snake AChE mutant HFQT retained activity. Tissues containing a mixture of cholinesterases could be assayed for amount of G117H BChE. For example, the serum of transgenic mice expressing human G117H BChE contained 0.5 microg/ml human G117H BChE, 2 microg/ml wild-type mouse BChE, and 0.06 microg/ml wild-type mouse AChE. The oligomeric structure of G117H BChE in the serum of transgenic mice was determined by nondenaturing gel electrophoresis followed by staining for butyrylthiocholine hydrolysis activity in the presence of 0.1 mM echothiophate. Greater than 95% of the human G117H BChE in transgenic mouse serum was a tetramer. To visualize the distribution of G117H BChE in tissues of transgenic mice, sections of small intestine were treated with echothiophate and then stained for BChE activity. Both wild-type and G117H BChE were in the epithelial cells of the villi. These assays can be used to identify OP-resistant cholinesterases in culture medium and in animal tissues.     

Selection of DNA aptamers that bind to four organophosphorus pesticides

Single-stranded DNA (ssDNA) aptamers against four organophosphorus pesticides (phorate, profenofos, isocarbophos and omethoate) were simultaneously isolated from an immobilized random ssDNA library by systematic evolution of ligands by exponential enrichment (SELEX) technique. After 12 rounds of in vitro selection, five ssDNA aptamer candidates were selected and their binding affinities were identified by a novel method using a molecular beacon. Two of the five ssDNA sequences, SS2-55 and SS4-54, demonstrated higher affinities and specificities to the four organophosphorus pesticides. They were defined as broad-spectrum aptamers binding to four different targets and their simulated secondary structures showed highly distinct features with typical stem and loop structures. The dissociation constant of SS2-55 and SS4-54 binding to the four organophosphorus pesticides ranged from 0.8 to 2.5?μM. These aptamers offered application potential in the analysis and/or neutralization of the residues of the four organophosphorus pesticides.     

Chirality of organophosphorus pesticides: Analysis and toxicity

Although the importance of chirality in organophosphorus compounds (OPs) is well recognized in relation to their biological effects, as with most chiral pesticides, OPs are generally marketed, used and released to the environment as racemates (i.e., equimolar mixtures of enantiomers). In addition, research on enantioselective environmental fate and effects of chiral OPs is still limited, particularly in the evaluation of enantioselectivity in their environmental degradation. A large number of OPs are chiral compounds, and yet enantioselectivity in their environmental fate and effects is rarely addressed. This paper highlights the current state of knowledge on the environmental occurrence and behavior of chiral OP pesticides. Developments in enantioselective analytical techniques, specifically gas chromatography (GC), high-performance liquid chromatography (HPLC) and capillary electrophoresis (CE), as applied in the evaluation of enantiomer-specific fate and effects of chiral OPs, are also discussed.     

Enzymatic changes induced by some organophosphorus pesticides in female rats

An evaluation of toxic effects of three organophosphorus pesticides viz. monocrotophos, methyl parathion and dimethoate given orally daily for 90 days was done in terms of enzymatic changes in plasma and liver of female albino rats. A significant decrease was observed in the level of esterases in plasma with all the three pesticides. The activity of acid and alkaline phosphatases and aminotransferases increased significantly in plasma and significantly or marginally in liver with these pesticides. The results are thus indicative of the cellular toxicity of these organophosphates even after their subchronic administration in low doses for a long period.     

Degradation of glyphosate and other pesticides by ligninolytic enzymes

The ability of pure manganese peroxidase (MnP), laccase, lignin peroxidase (LiP) and horseradish peroxidase (HRP) to degrade the widely used herbicide glyphosate and other pesticides was studied in separate in vitro assays with addition of different mediators. Complete degradation of glyphosate was obtained with MnP, MnSO₄ and Tween 80, with or without H₂O₂. In the presence of MnSO₄, with or without H₂O₂, MnP also transformed the herbicide, but to a lower rate. Laccase degraded glyphosate in the presence of (a) 2,2′-azino-bis(3-ethylbenzthiazoline-6-sulphonic acid) (ABTS), (b) MnSO₄ and Tween 80 and (c) ABTS, MnSO₄ and Tween 80. The metabolite AMPA was detected in all cases where degradation of glyphosate occurred and was not degraded. The LiP was tested alone or with MnSO₄, Tween 80, veratryl alcohol or H₂O₂ and in the HRP assay the enzyme was added alone or with H₂O₂ in the reaction mixture. However, these enzymes did not degrade glyphosate. Further experiments using MnP together with MnSO₄ and Tween 80 showed that the enzyme was also able to degrade glyphosate in its commercial formulation Roundup^® Bio. The same enzyme mixture was tested for degradation of 22 other pesticides and degradation products present in a mixture and all the compounds were transformed, with degradation percentages ranging between 20 and 100%. Our results highlight the potential of ligninolytic enzymes to degrade pesticides. Moreover, they suggest that the formation of AMPA, the main metabolite of glyphosate degradation found in soils, can be a result of the activity of lignin-degrading enzymes.     

Sensitivity of brown-adipose-tissue carnitine palmitoyltransferase to inhibition by malonyl-CoA

Overt carnitine palmitoyltransferase in mitochondria isolated from interscapular brown adipose tissue of cold-adapted rats or rats maintained at normal temperature is extremely sensitive to inhibition by malonyl-CoA.     

Simultaneous degradation of organophosphorus pesticides and p-nitrophenol by a genetically engineered Moraxella sp. with surface-expressed organophosphorus hydrolase.

Moraxella sp., a native soil organism that grows on p-nitrophenol (PNP), was genetically engineered for the simultaneous degradation of organophosphorus (OP) pesticides and p-nitrophenol (PNP). The truncated ice nucleation protein (INPNC) anchor was used to target the pesticide-hydrolyzing enzyme, organophosphorus hydrolase (OPH), onto the surface of Moraxella sp., alleviating the potential substrate uptake limitation. A shuttle vector, pPNCO33, coding for INPNC-OPH was constructed and the translocation, surface display, and functionality of OPH were demonstrated in both E. coli and Moraxella sp. However, whole cell activity was 70-fold higher in Moraxella sp. than E. coli. The resulting Moraxella sp. degraded organophosphates as well as PNP rapidly, all within 10 h. The initial hydrolysis rate was 0.6 micromol/h/mg dry weight, 1.5 micromol/h/mg dry weight, and 9.0 micromol/h/mg dry weight for methyl parathion, parathion, and paraoxon, respectively. The possibility of rapidly degrading OP pesticides and their byproducts should open up new opportunities for improved remediation of OP nerve agents in the future.     

Sensitivity of β-casein phosphopeptide-iron complex to digestive enzymes in ligated segment of rat duodenum

Binding iron to the phosphorylated β(1-25) peptide derived from β-casein improves iron bioavailability in the rat. The aim of the present work was to learn how injected β(1-25) and iron-β(1-25) complex behave in the duodenum of rats using the technique of intestinal ligation in situ and reversed-phase (RP)-high performance liquid chromatography-electrospray mass spectrometry analysis of the lumen contents. The results demonstrate that β(1-25) is sensitive to digestive enzymes including proteases/peptidases and phosphatases during duodenal transit. The lumen contents of rats perfused with iron free β(1-25) contained all peptidic sequences derived from β(1-25). In contrast, the phosphorylated part of β(1-25) [i.e., β(15-24)] was not detected in lumen of rats perfused with iron-β(1-25) complex.     

Sensitivity of yeast glycolytic enzymes to chloroquine

Chloroquine at pH 8.0 and 10 mM concentration inhibits about 30% glucose consumption and ethanol formation in yeast cells. Out of the 11 glycolytic enzymes assayed, phosphoglycerate kinase and pyruvate decarboxylase have been found to be most sensitive to chloroquine. Next sensitive are hexokinase, glyceraldehyde-3-phosphate dehydrogenase and pyruvate kinase. Kinetic studies with the three kinases studied revealed competitive inhibition of chloroquine with ATP (hexokinase, phosphoglycerate kinase) or ADP (pyruvate kinase).     

Bioremediation of organophosphorus pesticides by surface-expressed carboxylesterase from mosquito on Escherichia coli

The insecticide resistance-associated esterase, carboxylesterase B1 (CaE B1), from mosquito was used to degrade the organophosphorus compounds. To eradicate the need for enzyme purification and minimize the resistance to mass transport of the substrate and product across the cell membranes, the CaE B1 was displayed on the cell surface of Escherichia coli fused to the C-terminus of the ice nucleation protein (INP). The presence of CaE B1 on the bacterial cell surface was verified by SDS-PAGE, Western blotting analysis, and immunofluorescence microscopy. More than 50% of active CaE B1 is exported across the membrane and anchored onto the cell surface as determined by proteinase accessibility and cell fractionation experiments. In contrast, only a 6% drop in activity for proteinase K-treated cells was detected from E.coli cells containing pET-B1. From the degradation experiment, more than 80% of the malathion was degraded by whole cells containing plasmid pUC-NC-B1. Constitutive expression of CaE B1 on the surface using INPNC resulted in no cell lysis, and the suspended cultures also exhibited good stability. Because of their high biodegradation activity and superior stability, these "live biocatalysts" are promising for detoxification of organophosphorus pesticides.     

The inhibition of enzymes by beryllium

1. The action of beryllium on the following enzymes has been examined: alkaline phosphatase (Escherichia coli and kidney), acid phosphatase, phosphoprotein phosphatase, apyrase (potato), adenosine triphosphatase (liver nuclei, liver mitochondria, brain microsomes), glucose 6-phosphatase, polysaccharide phosphorylases a and b, phosphoglucomutase, hexokinase, phosphoglyceromutase, ribonuclease, A-esterase (rabbit serum), cholinesterase (horse serum), chymotrypsin. Alkaline phosphatase and phosphoglucomutase are inhibited by 1mum-beryllium sulphate whereas the other enzymes are largely unaffected by 1mm-beryllium sulphate. 2. Possible mechanisms for the inhibition of phosphoglucomutase and alkaline phosphatase are discussed.     

Sensitive detection of organophosphorus pesticides using a needle type amperometric acetylcholinesterase-based bioelectrode. Thiocholine electrochemistry and immobilised enzyme inhibition

An acetylcholinesterase (AChE) based amperometric bioelectrode for a selective detection of low concentrations of organophosphorus pesticides has been developed. The amperometric needle type bioelectrode consists of a bare cavity in a PTFE isolated Pt-Ir wire, where the AChE was entrapped into a photopolymerised polymer of polyvinyl alcohol bearing styrylpyridinium groups (PVA-SbQ). Cyclic voltammetry, performed at Pt and AChE/Pt disk electrodes, confirmed the irreversible, monoelectronic thiocholine oxidation process and showed that a working potential of +0.410 V vs. Ag/AgCl, KCl(sat) was suitable for a selective and sensitive amperometric detection of thiocholine. The acetylthiocholine detection under enzyme kinetic control was found in the range of 0.01-0.3 U cm(-2) of immobilised AChE. The detection limit, calculated for an inhibition ratio of 10%, was found to reach 5 microM for dipterex and 0.4 microM for paraoxon. A kinetic analysis of the AChE-pesticide interaction process using Hanes-Woolf or Lineweaver-Burk linearisations and secondary plots allowed identification of the immobilised enzyme inhibition process as a mixed one (non/uncompetitive) for both dipterex and paraoxon. The deviation from classical Michaelis Menten kinetics induced from the studied pesticides was evaluated using Hill plots.