MEASUREMENT OF THE RATE OF ACETYLCHOLINE DIFFUSION THROUGH A BRAIN SLICE AND ITS SIGNIFICANCE IN STUDIES OF THE CELLULAR DISTRIBUTION OF ACETYLCHOLINESTERASE

The rate of ACh diffusion through a 0·8 mm thick slice from the surface of the rat cerebral cortex, under aerobic conditions at 37°C, was determined by bathing the intact surface of the slice (compartment A) with ACh containing buffer and determining the concentration of ACh in buffer bathing the cut surface of the slice (compartment B). With 1 or 5 mM-ACh in compartment A no ACh was detectable in compartment B within 3 h unless at least 95 per cent of the AChE, as assessed on homogenates, was inhibited. With a given level of AChE inhibition, the rate of ACh diffusion was dependent on its concentration in compartment A. With 1 mM-ACh in compartment A the difference between the rates of hydrolysis of ACh during diffusion through slices with an AChE inhibition of 98·3 and 99·4 per cent, as assessed by AChE assays of homogenates made from the slices, was only 6 per cent of the difference between the rates of hydrolysis of 1 m-ACh by the homogenates of that part of the slices through which diffusion took place. For 5 mM-ACh and levels of 95 and 99·2 per cent inhibition the corresponding value was 10-3 per cent. Since the concentration of ACh must fall across the slice it is not possible to calculate from these figures the number of enzyme sites involved in the hydrolysis during diffusion, i.e. the concentration of extracellular AChE. The implications of these observations are discussed, particularly in relation to studies of the release of ACh from the cerebral cortex in vivo     

PROPERTIES OF THE EXTERNAL ACETYLCHOLINESTERASE IN GUINEA-PIG IRIS

Abstract— The acetylcholinesterase (AChE) of intact iris, the so-called external AChE, differs in several respects from the AChE in an homogenate of iris, called the total AChE. Maximum enzyme activities of the external and total AChE were obtained with an ACh concentration of 10 and 1.3 m m , respectively. The total AChE exhibited substrate inhibition at high substrate concentrations, whereas the external enzyme did not exhibit substrate inhibition in the range studied. The external AChE activity, when measured at 1.3 m m -ACh. accounted only for 12% of the total enzyme activity. After irreversible inhibition of AChE with diisopropylfluorophosphate (DFP) or methylisocyclopentylfluorophosphate (soman) the external AChE recovered to almost normal values after 48 h, whereas only 30% of the total AChE recovered during this period. Pupillographic studies after inhibition with DFP demonstrated that pupillary diameter had reached normal size after 24 h.
Destruction of the cholinergic input to iris reduced the total AChE activity by 40%, but did not alter the external AChE activity nor its rate of recovery after DFP inhibition. The specific activities of total AChE and total choline acetyltransferase were significantly higher in the sphincter than in the dilator muscle. After such denervation of iris the greatest reduction in total AChE and choline acetyltransferase were found in the sphincter region. After treatment with DFP the total AChE was inhibited to the same extent and recovered at the same rate in both regions.
After extraction of AChE from iris with various salt solutions and detergents, the particulate enzyme recovered faster than the soluble enzyme from DFP inhibition.     

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.     

THE EFFECTS OF SOLUBILIZATION PROCEDURES ON THE RELEASE AND MOLECULAR STATE OF ACETYLCHOLINESTERASE FROM ELECTRIC ORGAN TISSUE

Abstract— A study was made of the effect of various solubilization procedures on the release of AChE from electric organ tissue of the electric eel and on the molecular state of the enzyme. The procedures employed included homogenization in different ionic media or in the presence of detergents, etuymic treatment and chemical modification. Studies were performed on intact electroplax, tissue homogenates and membrane fractions. The apparent AChE activity of intact cells, homogenates and membrane fractions was shown to be governed by diffusion-controlled substrate and hydrogen ion gradients, generated by AChE-catalyscd hydrolysis, leading to a lower substrate concentration and a lower pH in the vicinity of the particulate enzyme.
Treatment of homogenates with NaCl solutions or with NaCl solutions containing the nonionic detergent Triton X-100 causes release of the native'molecular forms of the enzyme (primarily the 18 S species) which aggregate at low ionic strength. For optimal extraction both high ionic strength (e.g. 1 M-NaCl) and the detergent are needed AChE is also solubilized by treatment of tissue homogenates with trypsin, bacterial protease or collagenase. The first two enzymes caused its release as an 11 S non-aggregating form, while collagenase also produces a minor non-aggregating - 16 S component. Treatment of tissue homogenates with maleic anhydride causes release of AChE as a non-aggregating 18 S species. On the basis of the solubilization experiments it is concluded that the interaction of AChE with the excitable membrane is primarily electrostatic. The possible orientation of the enzyme within the synaptic gap is discussed.     

THE INFLUENCE OF IONIC STRENGTH ON THE INTERACTION OF QUATERNARY DRUGS WITH MAMMALIAN ACETYLCHOLINESTERASE IN RELATION TO POSSIBLE REGULATORY EFFECTS

Abstract— The effects of inorganic salts, gallamine triethiodide and (+)-tubocurarine chloride on mammalian acetylcholinesterase (AChE) were examined. The results were obtained mainly from soluble erythrocyte AChE; particle-bound and detergent-solubilized rat brain enzymes were also used. Three aspects of AChE were examined, namely direct effects on activity, the recovery of activity of the diethylphosphorylated enzyme and thirdly the aggregation of the enzyme at low ionic strength as shown by chromatography on columns of Sepharose 6B. The action of gallamine on AChE was controlled by the substrate concentration and the ionic strength of the medium. Both inhibition and activation by gallamine could be observed, depending on the particular conditions used. All effects of gallamine disappeared when the ionic strength was raised to 015. The action of gallamine closely resembled the result of increasing ionic strength by adding NaCl, for in both cases the apparent affinity of AChE for substrate decreased and concomitantly the maximum velocity of hydrolysis increased. The phosphorylated enzyme recovered activity more rapidly when gallamine or tubocurarine were present, or when the ionic strength was increased. Aggregation of all enzyme forms was observed at low ionic strength; an increase to I = 015 dissociated AChE to the single molecular form. It was concluded that the mammalian enzymes closely resembled electric eel AChE. The possible methods by which regulation of AChE activity could occur are discussed in relation to these results.     

HETEROGENEITY OF ACETYLCHOLINESTERASE IN NEUROBLASTOMA

Abstract– Multiple forms of acetylcholine hydrolyzing activity have been observed in Triton X-100 treated homogenates of mouse neuroblastoma cells. All these forms appear to be the true acetylcholinesterase, AChE (EC 3.1.17): they are substrate-inhibited; hydrolyze acetylcholine > acetyl-β-methylcholine ≫ butrylcholine and are preferentially inhibited by specific AChE inhibitors. Almost all of the cell AChE activity is membrane associated, but readily 'solubilized' by Triton X-100 and as such appears free of membrane contamination. With the aid of affinity chromatography the 'solubilized' neuroblastoma AChE has been partially purified (490-fold) to a specific activity of 34,300 nmol/min/mg protein.
Four active neuroblastoma AChE species appear upon acrylamide gel electrophoresis (with MWs of 64,000; 116,000; 186,000 and 284,000) while three species (4S, 6S and 9.6S) have been found upon sucrose gradient sedimentation analysis. We have determined that the 4S form migrates on acrylamide as the 116,000 MW species and the 9.6S form contains, in equal amounts, the 186,000 and 284,000 MW acrylamide species. Numerous active AChE forms are seen on Sepharose 6B chromatography. From comparing the crude, 4S, 9.6S and partially purified AChEs on acrylamide gels, sucrose gradients and Sepharose, mouse neuroblastoma appears to contain active AChE units which are capable of multiple types of dissociation and reassociation. An attempt is made to correlate all the observed AChE forms as well as relate this data to that known about AChE obtained from other sources.     

Iodide-induced inhibition of adenylate cyclase activity in horse and dog thyroid

The characteristics of the iodide-induced inhibition of cyclic AMP accumulation in dog thyroid slices have been previously described [Van Sande, J., Cochaux, P. and Dumont, J. E. (1985) Mol. Cell. Endocrinol. 40, 181-192]. In the present study we investigated the characteristics of the iodide-induced inhibition of adenylate cyclase activity in dog and horse thyroid. The inhibition of cyclic AMP accumulation by iodide in stimulated horse thyroid slices was similar to that observed in dog thyroid slices. The inhibition was observed in slices stimulated by thyroid-stimulating hormone, cholera toxin and forskolin. Increasing the concentration of the stimulators did not overcome the iodide-induced inhibition. Adenylate cyclase activity, assayed in crude homogenates or in plasma-membrane-containing particulates (100,000 x g pellets), was lower in homogenates or in particulates prepared from iodide-treated slices than from control slices. This inhibition was observed on the cyclase activity stimulated by forskolin, fluoride or guanosine 5'-[beta, gamma-imino]triphosphate, but also on the basal activity. It was relieved when the homogenate was prepared from slices incubated with iodide and methimazole. Similar results were obtained with dog thyroid. The inhibition persisted when the particulate fraction was washed three times during 1 h at 100,000 x g, in the presence of bovine serum albumin or increasing concentration of KCl. It was similar whatever the duration of the cyclase assay, in a large range of protein concentration. These results indicate that a stable modification of adenylate cyclase activity, closely related to the plasma membrane, was induced when slices were incubated with iodide. Iodide inhibition did not modify the affinity of adenylate cyclase for its substrate (MgATP), but induced a decrease of the maximal velocity of the enzyme. The percentage inhibition was slightly decreased when Mg2+ concentration increased, and markedly decreased when Mn2+ concentration increased. A detectable adenylate cyclase activity was demonstrated when intact slices were incubated in the presence of [alpha-32P]ATP, probably because of the presence of broken cells produced during the slicing. Iodide had no direct effect on this cyclase system, which confirms that iodide needs the integrity of the cell to induce the inhibition and suggests that the inhibition is not transmitted between cells.     

Effect of environment on allosteric properties of acetylcholinesterase]

In the presence of organophosphorus inhibitors (OPI) AChE inhibition is initiated at a lower concentration of ACh; the plot reaction rate versus substrate concentration shows two maxima with a distinct minimum between them. It was shown that extremely mild conditions (short-term heating up to 50 degrees C; acidic or alkaline pH shift by 0.5 units; high concentrations of bivalent cations; erythrocyte storage) which do not affect substrate inhibition, remove this effect. The data obtained suggest that OPI effect is not directed to the site of AChE responsible for enzyme inhibition by ACh excess ("substrate inhibition site"), but to some other area. This results in a change in the conformation of the substrate inhibition site and a pronounced inhibition of the AChE activity takes place at lower substrate concentration.     

SOLUBLE AND PARTICLE-BOUND ACETYLCHOLINESTERASE AND ITS ISOENZYMES IN PERIPHERAL NERVES

Abstract— The distribution of AChE (EC 3.1.1.7) in soluble and particulate fractions of the peripheral nerves of dogs, cats, rabbits and frogs was examined. About 20–30% of the total AChE activity was found in the supernatant fluid after centrifugation (100,000 g for 90 min) of iso-osmotic sucrose homogenates. The effect of different media on the extent of solubilization of the enzyme was studied and Triton X-100 (0.2%) was found to be the most effective. The electrophoretic pattern of AChE in peripheral nerves was also investigated. The 2–3 types of AChE observed previously were found in both particulate and soluble fractions, but the proportions of these forms were different. The most slowly migrating form of AChE is the most firmly bound to nerve membranes. A very small but consistent proportion (3%) of AChE escaped into the medium from surviving dog nerves kept in aerated Ringer solution. It was calculated that the possible contribution of blood AChE contained in the nerve is negligible. Electrophoretograms of AChE released during incubation into Ringer solution were similar in pattern to those found for the soluble fraction.     

ACETYLCHOLINE AND ACETYLCHOLINESTERASE ACTIVITY IN EARLY EMBRYOS OF THE MEDAKA ORYZIAS LATIPES, A TELEOST

Acetylcholinesterase (AChE) activity is present in homogenates of medaka embryos during cleavage and epiboly. The levels of AChE activity change little during this period of development and are similar in embryos grown at either 15°C or 25°C. The specific activity of AChE in cells isolated from blastulae is 0.06 mmoles substrate hydrolyzed/min/g protein, a value comparable to that of chicken myoblasts and myotubes in vitro . Acetylcholinesterase activity was detected cytochemically in all cells dissociated from blastulae and gastrulae. In deep blastomeres AChE activity is present nearly throughout the cytoplasm; it is absent from peripheral regions of the cytoplasm which are involved in circus, or limnicolor, movements. Acetylcholine-like activity in extracts of the embryos was assayed using the clam heart ventricle bioassay. The active principle, which caused a decrease in both the frequency and magnitude of ventricular contractions, was inactivated by heating at pH 10 and by incubation at pH 7.0 with commercial AChE. The effect of the active principle on the clam heart was blocked by mytolon chloride, a drug which specifically blocks the effect of acetylcholine on the clam heart. The active principle migrated on Whatman #1 chromatography paper with the same R_f as authentic acetylcholine in three solvent systems. The amount of acetylcholine in blastulae is about 4 picomoles/embryo.     

SUBCELLULAR ANALYSIS OF THE MOLECULAR FORMS OF ACETYLCHOLINESTERASE IN RAT SKELETAL MUSCLE

Acetylcholinesterase (AChE, EC 3.1.1.7) activity of rat gastrocnemius muscle homogenized in 1 M-NaCl and 0.5% Triton X-100 was separated by velocity sedimentation in sucrose gradients into three molecular forms with sedimentation coefficients of about 4S, 10S and 16S. The distribution of homogenate AChE activity among the three peaks was 53, 34 and 13% respectively. The different molecular forms were found to be heterogeneously distributed in subcellular fractions prepared from sucrose homogenates of muscle, as follows: Subfractions of the crude sarcolemmal fraction were prepared by discontinuous sucrose gradient centrifugation. AChE was recovered in the greatest yield and with the highest specific activity in a light density subfraction (0.6/0.8 M-sucrose interface). The AChE activity in this light density subfraction was mainly (81-88%) the 10S form of the enzyme. The velocity sedimentation profiles of the AChE activity in the more dense subfractions were markedly different in that 16S AChE was a major component.     

SUBSTRATE SPECIFICITY AND DEVELOPMENTAL CHANGES OF ACETYLCHOLINESTERASE IN COTTON BOLLWORM*

Abstract The substrate specificity and developmental changes of acetylcholinesterase (AChE) of cotton bollworm, Helicoverpa armigera Hübner, were investigated during 1991 to 1994. The insects were collected from Handan suburbs of Hebei Province and Guan County of Shandong Province. The results show that the specific activity and Michaelis constants (k_m) of AChE toward acetylthiocholine (ATCH) and acetyl-β-methyl-thiocholine (MeTCh) regularly varied with the developmental stage of cotton bollworm. The two peaks of the specific activity were observed respectively in the third instar and sixth instar of larvae. The specific activity of AChE in pupae was the lowest and that in heads of four-days moth was the highest in various developmental stages of cotton bollworms. The tendency of K_m and maximum velocity (V_max) was identical with the change of specific activity in the AChEs of cotton bollworm. The activation energy (Ea) of AChE toward MeTCh in pupae and adults was 3. 9–4. 3 times as much as that of, larvae in cotton bollworms from Handan of Hebei Province. It suggests that the spending energies of AChE for hydrolysing substrate are different in larva, pupa and adult. The optimum conditions of AChE reaction with ATCh in larvae were 50–100 mg of tissue weights for the amount of enzyme, 10–20 minutes for the reaction time, 35°C for the reaction temperature and 8. 0 for the reaction pH value.     

INCREASED RATE OF ACETYLCHOLINESTERASE SYNTHESIS IN DIFFERENTIATING NEUROBLASTOMA CELLS

When neuroblastoma cells (N18) in vitro are maintained in the absence of serum, the specific activity of AChE begins to rise rapidly after an initial lag period of about 2–3 days, reaching a maximum level (10–20-fold increase) by 7 days after induction. In order to clarify the mechanism of induction, it was necessary to measure the rate of AChE synthesis and its sensitivity to metabolic inhibitors. Return of enzymatic activity after irreversible inhibition of AChE in "differentiated" cells was blocked by cycloheximide, but not by cordycepin or actinomycin D, suggesting that protein but not mRNA synthesis was required for replacement. By using the initial rate of this replacement as a measure of the rate of synthesis of the enzyme, it was shown that cells which had differentiated in the absence of serum synthesized AChE 50-fold faster on a specific activity basis than their undifferentiated counterparts. In contrast, cordycepin effectively blocked the increase in the rate of AChE synthesis that occurs as a result of serum deprivation, indicating that the induction process itself requires the synthesis of new mRNA. Axonation, another index of differentiation, was not completely blocked by inhibition of RNA or protein synthesis and presumably utilizes only pools of pre-existing structural proteins.     

ACETYLCHOLINESTERASE IN THE SUBSTANTIA NIGRA AND CAUDATE-PUTAMEN OF THE RAT: PROPERTIES AND LOCALIZATION IN DOPAMINERGIC NEURONS

Abstract— In order to examine the hypothesis that acetylcholinesterase (AChE) is contained within dopaminergic neurons of the nigro-striatal projection, the effects of selective destruction of these neurons by 6-hydroxydopamine (6-OHDA) on cholinesterase, tyrosine hydroxylase, and choline acetyltransferase in substantia nigra (SN) and caudate-putamen (CP) were studied in the rat. Four to five weeks after intraventricular or intracerebral 6-OHDA injections tyrosine hydroxylase in these structures was reduced by 90% or more. Choline acetyltransferase was not affected in the SN or CP, but cholinesterase was reduced by about 40% in the SN and by 12% in the CP. To determine that the observed decreases in cholinesterase activity reflected true AChE and not butyrylcholinesterase (BChE), further experiments were conducted on tissues from animals with intracerebral 6-OHDA lesions. (1) Substrate specificity. Acetylcholine (ACh) was replaced by either acetyl-β-methyl-choline (AcβMeCh) or butyrylcholine (BCh) in the cholinesterase assay. SN and CP from 6-OHDA lesioned rats showed 54% and 92% of control tissue cholinesterase activity respectively with AcβMeCh as substrate, in good agreement with values found using ACh. No decrease in activity toward BCh was observed. (2) Kinetics. The decrease in cholinesterase activities at different concentrations of ACh was determined. Analysis of the data revealed that cholinesterase in dopaminergic neurons was inhibited by high ACh concentrations, a characteristic property of AChE but not BChE. (3) Selective inhibitors. In the SN, cholinesterase in dopaminergic neurons was inhibited by the selective AChE inhibitors BW284C51 and ambenonium with a dose-response curve similar to erythrocyte AChE but different from serum BChE. The selective BChE inhibitor, tetraisopropylpyrophosphoramide, inhibited the enzyme in dopaminergic neurons only at concentrations which inhibited erythrocyte AChE, concentrations somewhat higher than those which inhibited serum BChE. These results support recent histochemical observations indicating that AChE is contained in dopaminergic neurons of the SN. Moreover, these experiments represent the first characterization of AChE from a homogeneous population of non-cholinergic neurons in mammalian CNS.     

Effect of helium on the respiration and glycolysis of mouse liver slices

It has been shown that helium has the ability to affect variously the rates of certain metabolic reactions in vitro as compared to nitrogen. An attempt has been made to approximate the sites of action in mouse liver preparations. The following results have been obtained by the substitution of a mixture of 80 per cent helium and 20 per cent oxygen for air: (a) An increase in the rate of oxygen consumption and carbon dioxide production to the same degree, the respiratory quotient remaining unchanged. (b) A decrease in the magnitude of cyanide inhibition. The effectiveness of helium increases with the degree of the cyanide inhibition. (c) No effect on the activity of slices which have been poisoned with fluoride when either lactate or pyruvate has been added as a substrate. (d) A change in the rate, and the slope of the curve of oxygen consumption in liver homogenates which are utilizing pyruvate as a substrate. The use of helium relative to nitrogen under anaerobic conditions causes: (a) A depression of the glycolytic rates in both mouse liver slices and diaphragm. (b) An increase in the carbon dioxide evolution and lactic acid production of mouse liver homogenates oxidizing either glucose and hexose diphosphate, or hexose diphosphate alone. In neither slices nor homogenates does the addition of fluoride and the use of pyruvate as the hydrogen acceptor alter the fundamental response of the preparations. The following hypotheses have been advanced and discussed in order to explain the observed phenomena: 1. Helium does not alter the substrate utilized by the tissue. 2. The gas interferes in some way with the cyanide-cytochrome oxidase bond, but may not affect cytochrome oxidase in the absence of cyanide. 3. The citric acid cycle is not subject to the influence of helium in tissue slices, but is altered in an unexplained fashion in homogenates. It is postulated that a rearrangement of particulate surfaces may be the significant factor here. 4. The glycolytic cycle is the site of both an inhibitory and an acceleratory effect of helium. The locus of the inhibition lies above the aldolase reaction and that of the acceleration between the aldolase and enolase reactions.     

Acetylcholinesterase and butyrylcholinesterase activity in the atria of the heart of adult albino rats

In experiments on adult albino rats the authors used the substances BW 284 C51 (1.5-bis(allyldimethylammoniumphenyl)-pentane-3-one-dibromide) as a specific inhibitor of acetylcholinesterase (AChE) and ethopropazine (10-(2-diethylaminopropyl) phenothiazine hydrochloride) as a specific inhibitor of butyrylcholinesterase (BuChE) to determine the two enzyme activities in atrial homogenates and to investigate changes after AChE or BuChE inhibition of the negative chronotropic effect of acetylcholine (ACh) on atria incubated in vitro. AChE accounted for only 12% and BuChE for 88% of the total ability of atrial homogenates to hydrolyse acetylcholine. The concentration of exogenous ACh needed to reduce the spontaneous frequency of contractions of the isolated right atrium by 30, 60, or 90/min fell by 78%, 79% and 84% respectively after BW 284 C51 inhibition of AChE and by 95%, 94% and 94% after simultaneous inhibition of AChE and BuChE. The significance of AChE in control of the negative chronotropic effect of ACh is thus evidently significantly greater than would correspond to the percentual proportion of AChE in cholinesterase activities in the atria of the rat heart. In can be assumed that AChE is functionally associated with parasympathetic innervation of the heart and that it is probably present in a high concentration in the primary pacemaker region.     

The isolation of 2,3-oxidosqualene from the liver of rats treated with 1-dodecylimidazole, a novel hypocholesterolaemic agent

1. Non-saponifiable lipid from the livers of rats treated with 1-dodecylimidazole contained an unidentified compound that was not present in the livers from untreated animals. 2. Treated rats had lower serum cholesterol concentrations than control rats. 3. 1-Dodecylimidazole, when added to rat liver slices, inhibited the incorporation of [1-(14)C]acetate and [2-(14)C]mevalonate into digitonin-precipitable sterols and resulted in the accumulation of a labelled compound, which was chromatographically identical with the unknown compound described in 1 above. 4. Rats treated with 1-dodecylimidazole incorporated less [(14)C]mevalonate into liver digitonin-precipitable sterols than untreated animals and accumulated the unknown compound as a labelled intermediate. 5. The unknown intermediate had the same chromatographic properties, n.m.r. and mass spectra as authentic 2,3-oxidosqualene. 6. The identity of the intermediate as 2,3-oxidosqualene was further established by showing that it was incorporated into sterols by rat liver homogenates under anaerobic conditions. In addition, incubation of [(14)C]squalene with rat liver homogenates resulted in trapping of the radioactivity by the added intermediate. 7. It is suggested that the hypocholesterolaemic activity of 1-dodecylimidazole results in part from the inhibition of cholesterol biosynthesis at the level of 2,3-oxidosqualene sterol cyclase.     

Changes in the concentrations of some phosphorylated intermediates and stimulation of glycolysis in liver slices

1. The concentrations of some phosphorylated glycolytic intermediates and of NADH were measured in glycolysing rat liver slices. 2. In anaerobically incubated liver slices the concentration of hexose monophosphates decreases during the first 20min. of incubation, whereas the concentrations of fructose diphosphate and triose phosphates increase progressively. 3. In liver slices from fed rats, previously exposed to oxygen, the stimulated anaerobic glycolysis is accompanied by an increase in the concentration of hexose monophosphates; fructose diphosphate and triose phosphates maintain the concentrations reached at the end of the aerobic preincubation. 4. The same pattern in the concentration of glycolytic phosphorylated intermediates is seen under all conditions where aerobic preincubation brings about a stimulation of anaerobic glycolysis. A similar pattern is also found in liver slices from fed rats incubated anaerobically in the presence of fructose; these slices display a high glycolytic activity, which is not further affected by previous aerobic incubation. 5. The concentration of NADH decreases in liver slices during exposure to oxygen; during the subsequent anaerobic glycolysis the concentration increases but is always lower in preincubated than in non-preincubated liver slices. 6. The results of the present experiments suggest that the limiting step mainly affected by the preliminary exposure to oxygen might be at the level of the utilization of triose phosphates.     

ZONAL CENTRIFUGATION OF NEURONAL PERIKARYA AND ISOLATION OF NEURONAL MEMBRANES RICH IN ACETYLCHOLINESTERASE

Abstract— A method is presented that allows the isolation of neuronal perikarya of high purity and in good yield from rat brain. To this procedure is coupled a second isolation step which affords neuronal membranes in preparative quantities. The arrangement of the two isolation steps in tandem ensures that the final preparation has a high degree of purity with respect to both its neuronal origin and its membrane content. The membranes so obtained do not constitute plasma membranes but rather represent intracellular structures that are predominantly derived from endoplasmic reticulum and contain mitochondrial elements as well. During the process of membrane purification AChE is enriched four-fold while cholinesterase is concurrently eliminated. The present method supplements the procedure reported by M organ , W olfe , M andel and G ombos (1971) for the isolation of synaptosomal plasma membranes. It may also open access to a useful source of brain AChE.     

TRITON SOLUBILIZED ACETYLCHOLINESTERASE OF BRAIN

—The total AChE of brain can be readily extracted into aqueous Triton X-100. By column chromatography of these extracts a preparation was obtained at least six times as active as the original material and in yields of 60-80 per cent of the original amounts. The molecular weight of this material was estimated to be over 200,000. When brain tissue was treated with venom or bacterial protease, a water-soluble AChE was obtained with an overall purification of 150-fold. The most active preparation of AChE hydrolysed 880 μ-moles of acetylthiocholine/hr/mg of protein. The molecular weight of this preparation was estimated to be about 100,000. The enzyme which was extracted by Triton X-100 is probably the precursor of the more water-soluble enzyme that can be prepared from brain tissue by treatment with venom or protease.