Alterations in the distribution of cholinesterase molecular forms in maternal and fetal brain following diisopropyl fluorophosphate treatment of pregnant rats

Previous work in this laboratory showed that during intoxication of rats with diisopropyl fluorophosphate at day 20 of pregnancy the recovery of ChE activity was faster in fetal than in maternal brain. In the present study the differences between recovery rates in dam and fetus brain were evaluated in terms of molecular forms and spontaneous reactivation. Using ultracentrifugation on sucrose gradient two molecular forms of ChE, namely 10S (tetrameric globular G₄ form) and 4S (monomeric G₁ form) were detected both in maternal and fetal brain of untreated rats. The ratios 10S/4S were about 5.0 and 0.75 for dams and 20-day fetuses, respectively. DFP administration (1.1 mg/kg sc) inducing at 90 min an about 80% inhibition of ChE in maternal brain caused a shift in its 10S/4S ratio to 1.63, and to 0.53 in fetal brain (in which overall inhibition was about 70%). This means that 10S forms were preferentially inhibited by DFP both in maternal and fetal brain. After 24 and 48 hr there was a negligible recovery of overall ChE in maternal brain with no shift in the ratio. On the other hand, complete recovery of ChE in fetal brain within 48 hr was accompanied by almost total normalization of the 10S/4S ratio. Rapid recovery of fetal ChE appeared not to depend on hydrolysis of DFP-inhibited ChE. In fact, maternal and fetal DFP-inhibited enzyme preparations following the addition of oximes (pralidoxime or obidoxime) in vitro showed similar rates of reactivation. The overall data indicate considerable differences in recovery rate of molecular forms between dams and fetuses, but not in reactivation by dephosphorylation.     

Rat brain acetylcholinesterase turnover in vivo: Use of a radioactive methylphosphonothiate irreversible inhibitor

A new organophosphorus compound was used in its non radioactive and tritiated forms in order to study rat brain acetylcholinesterase. We measured the activity recovery of the total enzyme and of its two main molecular forms (4 S and 10 S) as a function of time following the inhibition. The radioactive compound allowed us to study the disappearence of the inhibitor irreversibly bound to the enzyme in the main cholinergic areas. Both approaches gave similar results: acetylcholinesterase turn-over proceeds in two steps, a rapid one of about 30 mn and a slow one of about 2 days. Our results suggest an in vivo reactivation process concerning a fraction of the bound inhibitor.     

Nano-Intercalated Organophosphorus-Hydrolyzing Enzymes in Organophosphorus Antagonism

A dendritic poly(2-alkyloxazoline)-based polymer was studied as a new carrier system for the organophosphorus-hydrolyzing recombinant enzymes, organophosphorus acid anhydrolase and organophosphorus hydrolase. Paraoxon (PO) and diisopropylfluorophosphate (DFP) were used as model organophosphorus compounds. Changes in plasma cholinesterase activity were monitored. The cholinesterase activity was proportional to the concentrations of DFP or PO. Plasma cholinesterase activity was higher in animals receiving enzyme and oxime before the organophosphates than in the oxime-only pretreated groups. These studies suggest that cholinesterase activity can serve as an indicator for the in vivo protection by the nano-intercalated organophosphorus acid anhydrolase or organophosphorus hydrolase against organophosphorus intoxications. These studies represent a practical application of polymeric nano-delivery systems as enzyme carriers in drug antidotal therapy.     

Lack of desensitization of muscarinic receptor-mediated second messenger signals in rat brain upon acute and chronic inhibition of acetylcholinesterase.

We studied the effects of acute and chronic in vivo inhibition of acetylcholinesterase on both the density and function of brain muscarinic cholinergic receptors. Adult male rats were treated either once or multiple times over a period of 10 days with the irreversible acetylcholinesterase inhibitor diisopropylfluorophosphate (DFP). The concentration and affinity of muscarinic receptors in various brain regions were determined using radioligand binding techniques. Acute DFP treatment resulted in a significant reduction in receptor number only in the brain stem, while chronic treatment caused receptor down-regulation in the brain stem, cerebral cortex, and striatum. There was no change in ligand affinity in any of the brain regions. In sharp contrast, muscarinic receptor function was fully preserved, in terms of coupling of the receptors to increased phosphoinositide hydrolysis in the cerebral cortex, hippocampus, and striatum, or inhibition of cyclic AMP formation in the cerebral cortex or striatum. Therefore, there is a marked lack or correlation between DFP-induced muscarinic receptor down-regulation and receptor desensitization.     

Lack of desensitization of muscarinic receptor–mediated second messenger signals in rat brain upon acute and chronic inhibition of acetylcholinesterase

We studied the effects of acute and chronic in vivo inhibition of acetylcholinesterase on both the density and function of brain muscarinic cholinergic receptors. Adult male rats were treated either once or multiple times over a period of 10 days with the irreversible acetylcholinesterase inhibitor diisopropylfluorophosphate (DFP). The concentration and affinity of muscarinic receptors in various brain regions were determined using radioligand binding techniques. Acute DFP treatment resulted in a significant reduction in receptor number only in the brain stem, while chronic treatment caused receptor downregulation in the brain stem, cerebral cortex, and striatum. There was no change in ligand affinity in any of the brain regions. In sharp contrast, muscarinic receptor function was fully preserved, in terms of coupling of the receptors to increased phosphoinositide hydrolysis in the cerebral cortex, hippocampus, and striatum, or inhibition of cyclic AMP formation in the cerebral cortex or striatum. Therefore, there is a marked lack or correlation between DFP-induced muscarinic receptor down-regulation and receptor desensitization.     

The inhibition of locomotion of the polymorphonuclear leucocyte by organophosphorus compounds

The effects of diisopropylphosphorofluoridate (DFP) and other organophosphorus compounds on the locomotion of rabbit polymorphonuclear leucocytes have been investigated in vitro using time-lapse cinémicrography. Both phosphorylating and non-phosphorylating compounds were observed to inhibit cell locomotion, not only increasing the proportion of stationary cells, but also decreasing the velocity of those cells whose movement continued. This inhibition of locomotion occurred over the same concentration range of organophosphorus compound which was previously found to enhance the effect of leucocidin on the leucocyte. Although the inhibitory effects of low concentrations of organophosphorus compounds were partly reversible, higher concentrations produced effects which continued to increase even after the cells had been returned to normal medium. It is suggested that the supposed effect of organophosphorus compounds on chemotaxis may actually be due to the inhibition of locomotion per se, probably through the detergent properties of these compounds rather than their properties as enzyme inhibitors.     

Organophosphorus inhibition and heat inactivation kinetics of particulate and soluble forms of peripheral nerve neuropathy target esterase

Neuropathy target esterase (NTE) is the proposed target site for the mechanism of initiation of the so-called organophosphorus-induced delayed polyneuropathy (OPIDP). NTE is operationally defined in this article as the phenylvalerate esterase activity which is resistant to inhibition by 40 μM paraoxon and sensitive to 250 μM mipafox. Soluble (S-NTE) and particulate (P-NTE) forms of NTE had first been identified in hen sciatic nerve [E. Vilanova, J. Barril, V. Carrera, and M. C. Pellín (1990). J. Neurochem., 55, 1258–1265]. P-NTE and S-NTE showed different sensitivities to the inhibition by several organophosphorus compounds over a range of inhibitor concentrations for a 30 or 120 minute fixed inhibition time at 37°C. S-NTE was less sensitive to the inhibition by O,O′-diisopropyl phosphorofluoridate (DFP), hexyl 2,5-dichlorophenyl phosphoramidate (H-DCP), and mipafox than P-NTE and brain NTE, while the opposite was true for O,S-dimethyl phosphoroamidothioate (methamidophos). For each of the four inhibitors assayed, S-NTE showed two components of different sensitivity according to the inhibition curves fitted with exponential models. However, the inhibition of P-NTE by mipafox, DFP, and HDCP did not show the presence of a considerable proportion of a second component. The kinetics of heat inactivation showed that P-NTE inactivated faster and to a greater extent than S-NTE. It is concluded that (1) sciatic nerve S-NTE is more different from brain NTE than P-NTE; (2) P-NTE and S-NTE have different sensitivities to the inhibition by the studied organophosphorous compounds; (3) the inhibition curves suggest that S-NTE has two different enzymatic components while these are not so evident for P-NTE. © 1995 John Wiley & Sons, Inc.     

Effect of diisopropylfluorophosphate on muscarinic and gamma-aminobutyric acid receptors in visual cortex of cats.

Administration of diisopropylfluorophosphate (DFP), an organophosphorus (OP) compound, irreversibly inhibits acetylcholinesterase (AChE) and results in cholinergic hyperactivity. This study investigated muscarinic and gamma-aminobutyric acid (GABA) receptor changes in visual cortex of cats following an acute exposure to DFP. A single acute administration of DFP (4 mg/kg) decreased the number of muscarinic receptors at 2, 10, and 20 hours after treatment. GABA receptors were elevated at 2 and 10 hours but returned to within control levels at 20 hours. No significant alteration in muscarinic or GABA receptor affinity was noted. In all cases cortical AChE activity was inhibited 60-90%. These findings show a down regulation of muscarinic receptors after DFP associated with low AChE activity. GABA receptors also are altered, and may be part of a compensatory mechanism to counteract excess cholinergic stimulation.     

Gel-electrophoretic identification of hen brain neurotoxic esterase, labelled with tritiated di-isopropyl phosphorofluoridate.

The particulate fraction from hen brain was labelled with [3H]di-isopropyl phosphorofluoridate (DiPF) and separated by polyacrylamide-gel electrophoresis. Four radioactive protein bands (1--4) of molecular weights 155000, 92000, 60000, and 30000 were resolved. Most of the labelling of bands 2, 3 and 4 was inhibited by preincubation with Paraoxon. The residue in band 4 was sensitive to pH 5.2. Successive treatments with Paraoxon and pH 5.2 resulted in the abolition of bands 3 and 4. Bands 1 and 2 contained one and two polypeptides respectively, whose labelling was sensitive to Mipafox, but one, in band 2, was sensitive to higher concentrations of Paraoxon. The concentrations of the other two polypeptides were 6.7 and 1.95 pmol of DiPF bound/g of brain in bands 1 and 2 respectively. Both were as sensitive to Mipafox as neurotoxic esterase and were also sensitive to phenyl benzylcarbamate. 4-Nitrophenyl di-n-pentylphosphinate given in vivo inhibited neurotoxic esterase and the labelling of the band-1 polypeptide by 82% and 84% respectively, but inhibited the labelling of the band 2 polypeptide by 51%. The phosphinate in vitro produced 98% inhibition of the labelling of the band-1 polypeptide, with only 26% inhibition of the band-2 polypeptide, under conditions sufficient to inhibit neurotoxic esterase totally. Both neurotoxic esterase and the band-1 polypeptide were found in the forebrain at 1.74-fold their concentration in the rest of the brain, whereas the band-2 polypeptide was uniformly distributed. The evidence indicates that the Mipafox-sensitive polypeptide in band 1 is the [3H]DiPF-labelled active-site subunit of neurotoxic esterase. The catalytic-centre activity of the enzyme for phenyl valerate hydrolysis was found to be 2.6 x 10(5) min-1.     

In vivo and in vitro effects of diisopropyl phosphorofluoridate (DFP) on the rate of hen brain tubulin polymerization

Diisopropyl phosphorofluoridate (DFP) produces organophosphorus ester-induced delayed neurotoxicity (OPIDN) in sensitive species. We have investigated the in vivo and in vitro effects of DFP on hen brain tubulin polymerization. Hens were treated with a single dose of DFP (1.7 mg/kg, sc.), and were sacrificed after 18–21 days. Tubulin from DFP-treated hen brains showed small but significant decrease (14.42%) in the rate of polymerization and 11.05% decrease in rise in O.D. at 340 nm in 30 min. DFP in vivo treatment also resulted in decreased concentration of tau and an enhanced concentration of two peptides (45 kDa, 35 kDa) in the brain supernatant. These peptides seemed to be the degradation products of MAP-2. The decrease in the rate of brain tubulin polymerization in treated hens is consistent with neurochemical alterations and the focal degeneration and aggregation of these filamentous structures in OPIDN.Abbreviations DFP Diisopropyl phosphorofluoridate - DMSO dimethyl sulfoxide - DTT dithiothreitol - EGTA ethyleneglycol-bis(-aminoethyl ether)N,N,N,N-tetraacetic acid - EDTA ethylenediaminetetraacetic acid - 2, 5-DH 2, 5-hexanedione - DMHD 3, 4-dimethyl-2, 5-hexanedione - OPIDN organophosphorus ester-induced delayed neurotoxicity - PMSF phenylmethylsulfonyl fluoride - PIPES piperazine-N,N-bis[2-ethanesulfonic acid] - TOCP tri-o-cresyl phosphate     

Depression of acetylcholinesterase synthesis following transient cerebral ischemia in rat: pharmacohistochemical and biochemical investigation

The effect of transient cerebral ischemia on acetylcholinesterase (AChE) synthesis was studied in rats by a modified pharmacohistochemical method. The procedure involved in vivo irreversible inhibition of AChE by administration of the inhibitor diisopropyl fluorophosphate (DFP; 1.2 mg/kg b.w., i.m.) 1 h before 30 min forebrain ischemia (the four-vessel occlusion model). At the onset of ischemia, 70-75% of AChE was inhibited in the brain. Recirculation was followed by histochemical and biochemical investigations of newly synthesized AChE in the striatum, septum, cortex and hippocampus. Control sham-operated animals were treated with the same dose of DFP. For correlation, rats not treated with DFP were subjected to the same ischemic procedures and investigated simultaneously. In these rats, significant decrease in AChE activity was found in the striatum, septum and hippocampus during 24 h recirculation. In DFP treated rats, ischemia markedly depressed resynthesis of AChE; after 4 h recirculation, AChE activity was decreased by 45-60% in all investigated areas in comparison with controls and the AChE histochemistry showed only slightly stained neurons in the striatum and septum. Twenty-four hours after ischemia, these neurons were densely stained and the increase in AChE activity indicated a partial recovery of the enzyme synthesis. These results suggest that the depression of AChE synthesis after forebrain ischemia is probably transient, not accompanied by cholinergic neuron degeneration.     

Effect of acute and chronic cholinesterase inhibition with diisopropylfluorophosphate on muscarinic, dopamine, and GABA receptors of the rat striatum

The effects of acute and chronic administration of diisopropylfluorophosphate (DFP) to rats on acetylcholinesterase (AChE) activity (in striatum, medulla, diencephalon, cortex, and medulla) and muscarinic, dopamine (DA), and gamma-aminobutyric acid (GABA) receptor characteristics (in striatum) were investigated. After a single injection of (acute exposure to) DFP, striatal region was found to have the highest degree of AChE inhibition. After daily DFP injections (chronic treatment), all brain regions had the same degree of AChE inhibition, which remained at a steady level despite the regression of the DFP-induced cholinergic overactivity. Acute administration of DFP increased the number of DA and GABA receptors without affecting the muscarinic receptor characteristics. Whereas chronic administration of DFP for either 4 or 14 days reduced the number of muscarinic sites without affecting their affinity, the DFP treatment caused increase in the number of DA and GABA receptors only after 14 days of treatment; however, the increase was considerably lower than that observed after the acute treatment. The in vitro addition of DFP to striatal membranes did not affect DA, GABA, or muscarinic receptors. The results indicate an involvement of GABAergic and dopaminergic systems in the actions of DFP. It is suggested that the GABAergic and dopaminergic involvement may be a part of a compensatory inhibitory process to counteract the excessive cholinergic activity produced by DFP.     

Organophosphorus anticholinesterases do not mediate analgesia through inhibition of enkephalin degradation

The effect on enkephalin degradation of the four highly potent organophosphorus anticholinesterases, soman, sarin, tabun and DFP was studied in synaptosomal fractions of rat brain striata. None of the agents effected any of the enkephalin degrading enzymes, the puromycin sensitive aminopeptidase, the p-hydroxymercurybenzoate (p-HMB) sensitive dipeptidyl aminopeptidase or the phosphoramidon sensitive enkephalinase. Furthermore, no peptidase function of acetylcholinesterase was found, when Leu-enkephalin was used as substrate at low concentrations (27 nM). Supporting the in vitro data, no difference was obtained in the striatal levels of Met- and Leu-enkephalin between rats receiving a high single dose of soman and controls. The results show that the analgesic effect of anticholinesterases are more likely due to mechanisms other than inhibition of enkephalin degradation.     

Recovery of acetylcholinesterase and of its multiple molecular forms in motor end-plate-free and motor end-plate-rich regions of mouse striated muscle, after irreversible inactivation by an organophosphorus compound (methyl-phosphorothiolate derivative)

Most of mouse diaphragm muscle acetylcholinesterase (AChE) is irreversibly inhibited after a single intraperitoneal injection of a methyl-phosphorothiolate derivative (MPT), an organophosphorus compound which phosphorylates the active site. The muscle recovers its AChE (de novo synthesis) and we studied the time course of reappearance of AChE and its multiple active molecular forms. After inhibition, there is an initial (3 to 15 hr) rapid recovery of total AChE (which evolves from 20-28% to 50-60% of the control values), followed by a slow phase of AChE return. After 3 days, the recovery is still incomplete (reaching 70-80% of control values). Among the main molecular forms present in diaphragm muscle (16 S, 10 S and 4 S, accompanied by minor components), the 16 S and 10 S forms are the most sensitive to MPT treatment. During the rapid initial phase of AChE recovery, the absolute rate of recovery of the 4 S form is faster than for the other forms with a correspondingly much higher relative proportion to total AChE. These observations are consistent with the hypothesized precursor role of the 4 S form. The 16 S form, which is found concentrated in the motor end-plate (MEP)-rich regions and in low amounts in MEP-free regions, is similarly partially recovered in both regions, suggesting that there is 16 S biosynthesis not only in the MEP-rich regions but also in the MEP-free regions.     

Muscarinic receptor plasticity in the brain of senescent rats: down-regulation after repeated administration of diisopropyl fluorophosphate

Potential age-related differences in the response of Fischer 344 rats to subchronic treatment with diisopropylfluorophosphate (DFP) were evaluated in terms of brain cholinesterase (ChE) inhibition and muscarinic receptor sites. Male 3- and 24-month old rats were sc injected with sublethal doses of DFP (first dose 1.6, subsequent doses 1.1 mg/kg on alternate days) for 2 weeks and killed 48 hrs after the last treatment. In the cerebral cortex, hippocampus and striatum of control rats a significant age-related reduction of ChE and of maximum number of 3H-QNB binding sites (Bmax) was observed. The administration of DFP to senescent rats resulted in more pronounced and longer lasting syndrome of cholinergic stimulation, with marked body weight loss and 60% mortality. The percentage inhibition of brain ChE induced by DFP (over 80% in all regions) did not differ between young and senescent rats. As expected, in young rats DFP caused a significant decrease of Bmax (without apparent changes in affinity), which in the cerebral cortex reached about 40%. In the surviving senescent rats, the percentage decrease of Bmax due to DFP with respect to age-matched controls was very similar to that of young animals, especially in the cerebral cortex. Thus, there is great variability in the response of aged rats to DFP treatment, from total failure of adaptive mechanisms resulting in death to considerable muscarinic receptor plasticity. The data support the view that the ability of central neurotransmitter systems to compensate for pathological or xenobiotic induced insult is an essential part of the aging process.     

Differential effects of paraoxon on the M3 muscarinic receptor and its effector system in rat submaxillary gland cells

The effects of the organophosphorus anticholinesterase paraoxon on the binding of radioactive ligands to the M₃ subtype of the muscarinic receptor and receptor-coupled synthesis of second messengers in intact rat submaxillary gland (SMG) cells were investigated. The binding of [³H]quinuclidinyl benzilate ([³H]QNB) was most sensitive to atropine and the M₃-specific antagonist 4-DAMP followed by pirenzepine and least sensitive to the cardioselective M₂ antagonist AFDX116. This, and the binding characteristics of [³H]4-DAMP, confirmed that the muscarinic receptors in this preparation are of the M₃ subtype. Activation of these muscarinic receptors by carbamylcholine (CBC) produced both stimulation of phosphoinositide (PI) hydrolysis and inhibition of cAMP synthesis, suggesting that this receptor subtype couples to both effector systems. Paraoxon (100 μM) reduced B_max of [³H]4-DAMP binding from 27 ± 4 to 13 ± 3 fmol/mg protein with nonsignificant change in affinity, suggesting noncompetitive inhibition of binding by paraoxon. Like the agonist CBC, paraoxon inhibited the forskolininduced cAMP formation in SMG cells with an EC₅₀ of 200 nM, but paraoxon was > 500 fold more potent than CBC. However, while the inhibition by CBC was counteracted by 2 μM atropine, that by paraoxon was unaffected by up to 100 μM atropine. It suggested that this effect of paraoxon was not via binding to the muscarinic receptor. Paraoxon did not affect β-adrenoreceptor function in the preparation, since it did not affect the 10 μM isoproterenol-induced cAMP synthesis, which was inhibited totally by 10 μM propranolol and partially by CBC. Paraoxon had a small but significant effect on CBC-stimulated PI metabolism in the SMG cells. It is suggested that paraoxon binds to two different sites in these SMG cells. One is an allosteric site on the M₃ muscarinic receptor which affects ligand binding and may modulate receptor function. The other site may be on the G_i proteinadenylyl cyclase system, and produces CBC-like action, that is, inhibition of the forskolin-stimulated [³H]cAMP synthesis, and is unaffected by atropine inhibition of the muscarinic receptor. This adds to the complexity of paraoxon actions on muscarinic receptors and their effector systems.     

Choline derivatives and sodium fluoride protect acetylcholinesterase against irreversible inhibition and aging by DFP and paraoxon

A light addressable potentiometric sensor was used to measure acetylcholinesterase (AChE) activity in order to evaluate the protective effects of quaternary compounds and NaF against enzyme phosphorylation and aging by two organophosphates. The use of the immobilized AChE made possible the quick removal of reagents (i.e., organophosphate, 2-pralidoxime, and protectant), thereby permitting accurate determination of AChE activity before and after phosphorylation and aging. Paraoxon was 15-fold more potent in inhibiting AChE than DFP, while the percent aging following phosphorylation by diiso-propylfluorophosphate (DFP) was much higher. Sodium fluoride (NaF), the most effective protectant against phosphorylation and aging, and the quaternary ammonium compounds reduced significantly AChE inhibition by DFP and paraoxon, to similar degrees. Even though the percent AChE activity that was lost to aging was reduced by these agents, aging as a percent of phosphorylated AChE was not reduced. Thus, their major effect was in reducing the percent AChE phosphorylation, which consequently resulted in reduction of total aged AChE. The finding that quaternary ammonium compounds protect against phosphorylation is consonant with the proposed presence of the active site of AChE in an aromatic gorge.     

INHIBITION OF ACETYLCHOLINESTERASE IN THE BRAIN AND DIAPHRAGM OF RATS BY A TERTIARY ORGANOPHOSPHOROUS ANTICHOLINESTERASE AND ITS QUATERNARY ANALOGUE; IN VIVO AND IN VITRO STUDIES

Abstract— Pinacolyl S -(2-dimethylaminoethyl)methylphosphonothioate (compound I) and its quaternary analogue (compound II), are potent anticholinesterases, that form a very stable phosphonylated AChE and differ in their in vitro anticholinesterase potency by a factor of two, but have widely differing lipid solubilities.
In vitro , compound I diffused through a cerebral cortex slice when applied to the intact surface at twelve times the rate of compound II and through a diaphragm segment at four times the rate. When applied to the intact surface of a cerebral cortex slice or a diaphragm segment for 10 min, compound I gained access to AChE sites more readily than compound II but the difference was much less than the difference in their lipid solubilities. There was no discontinuity in the percentage AChE inhibition versus logarithm of the concentration of compound II, indicating that there was no clear separation of AChE into two fractions which differed greatly in their accessibility to quaternary compounds. Both compounds gained access to AChE sites in cerebral cortex slices more readily than in diaphragm segments.
In vivo , the peak plasma levels and the rates of removal from the plasma of free inhibitor were similar for both compounds, given subcutaneously in equimolar amounts. Compound I in high doses inhibited over 90 per cent of the AChE in the cerebral cortex and the diaphragm; compound II even in lethal doses produced only marginal inhibition of AChE in the cerebral cortex and only 50–60 per cent inhibition of AChE in the diaphragm.
These results indicate that the in vivo distribution of quaternary compounds is different from that observed in vitro . The implications of this are discussed.     

Two types of asymmetric acetylcholinesterase in chick hindlimb muscle: Developmental profiles,in Vivo and in cell culture,and recovery after inactivation

1. We have analyzed the behavior of two types of asymmetric molecular forms (A forms) of acetylcholinesterase (AChE) during development of chick hindlimb muscle, in vivo and in cell culture, and upon irreversible inactivation of peroneal muscle AChE with diisopropylfluorophosphate (DFP) in vivo. 2. In agreement with previous developmental studies on chick muscle, globular forms of AChE (G forms) are predominant in chick hindlimb at early embryonic ages, being gradually replaced by A forms as hatching (and, therefore, onset of locomotion) approaches. Of the two A-form types, AI appears and accumulates significantly earlier than AII, so that A/G and II/I ratios higher than 1 are attained only at about hatching time. 3. Cultures prepared from 11-day chick embryo hindlimb myoblasts express both types of A forms, with a combined activity of 27% of total AChE after 12 days in culture. AI forms appear again earlier and are much more abundant than type II asymmetric species through the life span of cultures. 4. All AChE activity in the peroneal muscle is irreversibly inactivated by injection of DFP in vivo. The recovery of A forms follows the same sequence described for normal development, with a delayed and slower recovery of AII forms as compared with AI. 5. Several hypotheses involving tail polypeptides or tissue target molecules, or posttranslational interconversion, are proposed to help explain the earlier appearance and accumulation of AI forms in chick muscle.     

Role of liver and brain lysosomal and mitochondrial enzymes in development of delayed neuropathy in hens by 0,0-diisopropyl phosphorofluoridate

Subacute dose of 0,0-diisopropyl phosphorofluoridate (DFP), a potent organophosphorus ester capable of producing delayed neurotoxicity (OPIDN), did not produce any significant change in the levels of lysosomal and mitochondrial marker enzymes of brain, liver and serum at any time after treatment in hens protected with atropine. The results suggest the absence of any involvement of mitochondrial and lysosomal enzymes at any stage in the development of OPIDN in susceptible species by treating with DFP.