Features of vertebrate brain Na,K-adenosine triphosphatase activation by detergents

Studies have been made on changes in the activity of Na,K-ATPase in brain homogenates of vertebrates (rat, hen, frog, tortoises) induced by various detergents (sodium deoxycholate, Twin-20, Twin-80, Triton X-100). After application of detergent at optimal concentrations, usually the enzymic activity increased, the increase being dependent on animal species and the brain structure. In crude homogenate of the forebrain, Na,K-ATPase activity was the highest in hen and was altogether absent in frog; detergents practically did not affect the enzymic activity in hen and sharply increased it in frogs. It is suggested that the activating effect of detergents is associated with damage of vesicular membrane structures which are formed during homogenization of the brain tissue, the degree of vesicularization being dependent on fatty acid composition of membrane phospholipids of the brain.     

An Amphiphile-Dependent Form of Human Brain Caudate Nucleus Acetylcholinesterase: Purification and Properties

Abstract: Different forms of acetylcholinesterase (AChE), EC 3.1.1.7, were demonstrated in human brain caudate nucleus. One form was solubilized at high ionic strength, the other with Triton X-100. The detergent-extractable form was purified to homogeneity by affinity chromatography. This form of AChE is amphiphile-dependent; i.e., it was active only in the presence of amphiphiles (detergents or lipids). Further, the enzyme was shown to bind detergents and to interact hydrophobically with Phenyl-Sepharose. In the presence of detergents the enzyme is a tetramer (subunit molecular weight, 78,000) which aggregates on the removal of detergents. Human brain AChE showed a reaction of identity with human erythrocyte AChE in crossed-line immunoelectrophoresis. The high-salt-soluble brain enzyme did not cross-react with the erythrocyte enzyme. The two classes of AChE seem not to be related, as they show no common antigenic determinant.     

An endogenous activator of renal glutamic acid decarboxylase effects of adenosine triphosphate, phosphate and chloride on the activity of this enzyme.

The renal glutamic acid decarboxylase (GAD) differs from the brain and pancreatic enzyme by its strong binding to membranes that is not influenced by detergents. After centrifugation of freshly prepared homogenate of the rat renal cortex, only 10-15% of GAD activity was found in supernatants and 15-30% in pellets. The majority of the GAD activity was lost. The bound GAD was found in the pellet. A thermolabile activator was present in the supernatant, which was not lost on dialysis. Approximately 55% of the total GAD activity was solubilized in homogenates stored for 24 h at 4 degrees C without detergent, whereas in homogenates stored with Triton X-100, the solubilized GAD increased to 80%. This solubilization was decreased by inhibitors of thioproteases such as leupeptin, antipain and trans-epoxysuccinyl-L-leucylamido-(4-guanidino)butane (E-64). Solubilized GAD was applied to DEAE Toyopearl resin and the GAD activator was eluted with 35 mM Pi. GAD was eluted with 250 mM Pi. The effect of ATP on the activity of renal GAD was also different to its effect on brain GAD. ATP is a strong inhibitor of the brain enzyme at physiological concentrations. ATP (and Pi), together with chlorides (another brain GAD inhibitor), stabilize the renal GAD. However, renal GAD was inhibited by ATP in the presence of leupeptin in freshly prepared homogenates. Similarly, ATP inhibits solubilized GAD from homogenates stored without Triton X-100 for 24 h at 4 degrees C, but Pi retains its stabilizing effect in this preparation. A significant finding of the work presented here is the obligatory requirement of an endogenous activator for renal GAD activity. Whether this activator is an enzyme converting the inactive GAD to active enzyme (as hypothesized for brain GAD), or whether it is a protein affecting the activity of renal GAD by binding (as observed for GAD in some plants) remains to be established.     

Alanine reverses the inhibitory effect of phenylalanine on acetylcholinesterase activity

The aim of this work was to evaluate, in vitro, the effect of L-alanine (Ala) on suckling rat brain acetylcholinesterase (AChE) and on eel Electrophorus electricus pure AChE inhibited by L-phenylalanine (Phe) as well as to investigate whether Phe or Ala is a competitive inhibitor or an effector of the enzyme. AChE activity was determined in brain homogenates and in the pure enzyme after 1 h preincubation with 1.2 mM of Phe or Ala as well as with Phe plus Ala. The activity of the pure AChE was also determined using as a substrate different amounts of acetylthiocholine. Ala reversed completely the inhibited AChE by Phe (18-20% in 500-600 microM substrate, p<0.01). Lineweaver-Burk plots showed that Vmax remained unchanged. However, Km was found increased with Phe (150%, p<0.001), decreased with Ala alone (50%, p<0.001) and unaltered with Phe plus Ala. It is suggested that: a) Phe presents a competitive inhibitory action with the substrate whereas Ala a competitive activation; b) Ala competition with Phe might unbind the latter from AChE molecule inducing the enzyme stimulation; c) Ala might reverse the inhibitory effect of Phe on brain AChE in phenylketonuric patients, if these results are extended into the in vivo reality.     

Binding of [3H]gamma-vinyl-GABA to GABA-transaminase in brain homogenates

[3H]Gamma-vinyl-GABA, an irreversible inhibitor of GABA-transaminase, was used to label the enzyme in homogenates of rat brain. The binding procedure utilized was found to be specific for GABA-transaminase and linear with tissue obtained from several regions of rat brain up to concentrations of 8 micrograms protein/microliter. The specific binding was directly proportional to the activity of the enzyme measured in vitro and was completely inhibited by the GABA-transaminase inhibitors aminooxyacetic acid (100 microM) and 3-mercaptopropionic acid (1.0mM). The binding procedure was used to estimate the amount of active enzyme present in a homogenate of striatal tissue.     

Effects of L-phenylalanine on acetylcholinesterase, (Na+,K+)-ATPase and Mg2+-ATPase activities in adult rat whole brain and frontal cortex

The effect of different L-phenylalanine (Phe) concentrations (0.12-12.1 mM) on acetylcholinesterase (AChE), (Na+,K+)-ATPase and Mg2+-ATPase activities was investigated in homogenates of adult rat whole brain and frontal cortex at 37 degrees C. AChE, (Na+,K+)-ATPase and Mg2+-ATPase activities were determined after preincubation with Phe. AChE activity in both tissues showed a decrease up to 18% (p<0.01) with Phe. Whole brain Na+,K+-ATPase was stimulated by 30-35% (p<0.01) with high Phe concentrations, while frontal cortex Na+,K+-ATPase was stimulated by 50-55% (p<0.001). Mg2+-ATPase activity was increased only in frontal cortex with high Phe concentrations. It is suggested that: a) The inhibitory effect of Phe on brain AChE is not influenced by developmental factors, while the stimulation of Phe on brain Na+,K+-ATPase is indeed affected; b) The stimulatory effect of Phe on rat whole brain Na+,K+-ATPase is decreased with age; c) Na+,K+-ATPase is selectively more stimulated by high Phe concentrations in frontal cortex than in whole brain homogenate; d) High (toxic) Phe concentrations can affect Mg2+-ATPase activity in frontal cortex, but not in whole brain, thus modulating the amount of intracellular Mg2+.     

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.     

Pyruvate dehydrogenase phosphate (PDHb) phosphatase in brain: activity, properties, and subcellular localization

The activity of pyruvate dehydrogenase phosphate (PDHb) phosphatase in rat brain mitochondria and homogenate was determined by measuring the rate of activation of purified, phosphorylated (i.e., inactive) pyruvate dehydrogenase complex (PDHC), which had been purified from bovine kidney and inactivated by phosphorylation with Mg . ATP. The PDHb phosphatase activity in purified mitochondria showed saturable kinetics with respect to its substrate, the phospho-PDHC. It had a pH optimum between 7.0 and 7.4, depended on Mg and Ca, and was inhibited by NaF and K-phosphate. These properties are consistent with those of the highly purified enzyme from beef heart. On subcellular fractionation, PDHb phosphatase copurified with mitochondrial marker enzymes (fumarase and PDHC) and separated from a cytosolic marker enzyme (lactate dehydrogenase) and a membrane marker enzyme (acetylcholinesterase), suggesting that it, like its substrate, is located in mitochondria. PDHb phosphatase had similar kinetic properties in purified mitochondria and in homogenate: dependence on Mg and Ca, independence of dichloroacetate, and inhibition by NaF and K-phosphate. These results are consistent with there being only one type of PDHb phosphatase in rat brain preparations. They support the validity of the measurements of the activity of this enzyme in brain homogenates.     

The isolation and structure of membrane lipid rafts from rat brain

The action of detergents in the isolation of detergent-resistant membrane fractions from rat brain is reported. Triton X-100 treatment of whole rat brain homogenate at 4 degrees C produced detergent-resistant membranes with a density of 1.07g/ml compared with Brij96 where the density of the membrane was only 1.05g/ml. The DRM fractions isolated using Triton X-100 are considerably heavier than those isolated from homogenates treated with Brij96. The major polar lipid composition of DRMs derived from Brij96 treated homogenates have a higher proportion of aminophospholipids compared with choline phospholipids than Triton X-100 derived DRMs; this may indicate that DRMs from Brij96 treated homogenates are more closely related to the parent membrane in lipid composition. Solubilization by Triton X-100 at higher temperatures resulted in the appearance of a second detergent-resistant membrane fraction distinctly lighter in density than the membrane recovered at density 1.07g/ml. Analysis of phospholipid composition of the brain homogenate during detergent treatment for up to 30min at 37 degrees C showed a decreasing proportion of sphingomyelin. Treatment of homogenates at 37 degrees C appears to activate phospholipases/sphingomyelinases that may alter the lipid content of isolated DRMs. The presence of K+/Mg2+ with Brij96 treatment results in DRM fractions with significantly thicker bilayers and of larger vesicle diameter than DRMs isolated from either Triton X-100 or Brij96 treated homogenates in the absence of cations.     

Environmental impact of mosquito pesticides: influence of temefos on the brain acetylcholinesterase of killifish.

Temefos and six of its metabolites were tested for their capacity to inhibit the in vitro activity of brain acetylcholinesterase (AChE) of Fundulus heteroclitus. While temefos was not inhibitory at levels up to 10.7 mM in brain homogenate samples, its metabolites were active within the range of 2 X 10(-4)mM to 1.26 mM in causing a 50% reduction in the enzyme activity. Exposure of F. heteroclitus to temefos under laboratory conditions caused a reduction in AChE activity, which was proportional to the pesticide concentration and the exposure period. Visible symptoms of organophosphate poisoning were apparent only after the AChE inhibition reached 80%. F. heteroclitus and Cyprinidon variegatus exposed to 10 biweekly applications of temefos granules in the field showed no inhibition of brain AChE. However, exposure of F. heteroclitus to biweekly applications (four) of temefos emulsion caused a reduction in the enzyme (50%), but only in the pre-third application samples. A gradual increase in brain AChE occurred both in F. heteroclitus and C. variegatus as the season progressed from April to October.     

GALACTOCEREBROSIDE SULFOTRANSFERASE: FURTHER CHARACTERIZATION OF THE ENZYME FROM RAT BRAIN

Abstract— Myelin has an unusual lipid composition, being particularly rich in sulfatide. This lipid is synthesized by the transfer of sulfate from phosphoadenosine phosphosulfate to galactocerebroside, catalyzed by galactocerebroside sulfotransferase. This paper describes a sensitive assay for the sulfotransferase (capable of measuring activity in as little as 10 μg of extracted rat brain protein) so that this enzyme can be readily investigated in isolated cells, or the small amounts of tissue available in developing animals. Both manganase (20 m m ) and thiol reagents were required for optimal activity. This assay was used to monitor the purification of the sulfotransferase from rat brain. Extraction of the enzyme from crude homogenates required the nonionic detergent, Triton X-100, at pH 7–7.5. Removal of Triton X-100 from the extracted enzyme resulted in a soluble but less active enzyme, the activity of which could then be restored with detergents. Stability of the detergent-extracted enzyme was investigated, and even at —40°C there was a 20% loss of activity over 10 days. By standard procedures 500-fold purification of the enzyme has been achieved.     

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.     

Delineation of a Particulate Thyrotropin-Releasing Hormone-Degrading Enzyme in Rat Brain by the Use of Specific Inhibitors of Prolyl Endopeptidase and Pyroglutamyl Peptide Hydrolase

The degradation of thyrotropin-releasing hormone in rat brain homogenates was studied in the presence of N-benzyloxycarbonyl-prolyl-prolinal and pyroglutamyl diazomethyl ketone, specific and potent active-site-directed inhibitors of prolyl endopeptidase and pyroglutamyl peptide hydrolase, respectively. Substantial TRH degradation was observed, suggesting the presence of another thyrotropin-releasing hormone-degrading enzyme(s). Reports of a thyrotropin-releasing hormone-degrading enzyme with narrow specificity that cleaves the pGlu-His bond of this tripeptide led us to develop a coupled assay using pGlu-His-Pro-2NA as the substrate to measure this activity. Cleavage of the pGlu-His bond of this substrate under conditions in which pyroglutamyl peptide hydrolase is not expressed occurred in the particulate fraction of a rat brain homogenate. This particulate pyroglutamyl-peptide cleaving enzyme was not inhibited by pyroglutamyl diazomethyl ketone but was inhibited by metal chelators such as EDTA and o-phenanthroline. The particulate pyroglutamyl-peptide cleaving enzyme was found predominantly in the brain. Activity in brain regions varied widely with highest levels present in cortex and hippocampus and very low levels in pituitary. The data suggest that degradation of thyrotropin-releasing hormone by the particulate fraction of a brain homogenate is catalyzed mainly by an enzyme that cleaves the pGlu-His bond of thyrotropin-releasing hormone but is distinct from pyroglutamyl peptide hydrolase.     

Proteolytic stimulation and solubilization of membrane-bound acetylcholinesterase from muscle sarcotubular system

Incubation of membranes derived from sarcotubular system of rabbit skeletal muscle with increasing concentrations of Triton X-100 produced both stimulation of the AChE activity and solubilization of this enzyme. Mild proteolytic treatment of microsomal membranes produced a several fold activation of the still membrane-bound acetylcholinesterase (AChE) activity. Attempts were made to solubilize AChE from microsomal membranes by proteolytic treatment. About 30–40% of the total enzyme activity could be solubilized by means of trypsin or papain. Short trypsin treatment of the microsomal membranes produced first an activation of the membrane-bound enzyme followed by solubilization. Incubation of muscle microsomes for a short time with papain yielded a significant portion of soluble enzyme. Membrane-bound enzyme activation was measured after a prolonged incubation period. These results are compared with those of solubilization obtained by treatment of membranes with progressive concentrations of Triton X-100. The occurrence of molecular forms in protease-solubilized AChE was investigated by means of centrifugation analysis and slab gel electrophoresis. Centrifugation on sucrose gradients revealed two main components of 4.4S and 10–11S in either trypsin or papain-solubilized AChE. These components behaved as hydrophilic species whereas the Triton solubilized AChE showed an amphipatic character. Application of slab gel electrophoresis showed the occurrence of forms with molecular weights of 350,000; 175,000; 165,000; 85,000 and 76,000. The stimulation of membrane-bound AChE by detergents or proteases would indicate that most of the enzyme molecules or their active sites are sequestered into the lipid bilayer through lipid-protein or protein-protein interactions and these are broken by proteolytic digestion of the muscle microsomes.     

Identification of prostaglandin D2 as a major prostaglandin in homogenates of rat brain

Prostaglandin (PG) E2, D2, F2alpha and thromboxane B2 (TxB2) were determined in homogenates of rat brain by gas-chromatography--mass spectrometry. The level of PGD2 was 735 +/- 19 ng/g, of PGF2alpha 150 +/- 13 ng/g, of TxB2 112 ng/g and of PGE2 86 +/- 8 ng/g. The same relative proportions of cyclooxygenase products were found in incubates of unstimulated sliced rat brain. 14C-PGH2 was converted in high yield into PGD2 by enzyme(s) present in the soluble fraction of the homogenate. These results indicate that PGD2 is the major cyclooxygenase product in the central nervous system of the rat.     

Cardiolipin-specific phospholipase D of Haemophilus parainfluenzae. II. Characteristics and possible significance

A phospholipase specific for cardiolipin (CL) was found in the membrane of Haemophilus parainfluenzae. The enzyme hydrolyzed CL to phosphatidic acid (PA) and phosphatidylglycerol (PG), indicating that it was a phospholipase D (an enzyme activity believed to be confined to higher plants). In addition to its substrate specificity, this enzyme was unusual in its requirement for Mg(2+) (K(m) of 1.3 mm) for maximal activity and its inhibition by chelating agents, heavy metals, some detergents, and organic solvents. When inhibitors of phospholipase activity were added to the growth medium, CL accumulated and PG disappeared in the membrane, suggesting that the phospholipase D was active in vivo. The activity of phospholipase D in cell-free homogenates was greater than expected from earlier studies of CL metabolism and greater than the other phospholipase activities detected in the homogenate. The high activity of the CL-specific phospholipase D suggests there might be a very active degradation of CL to PG and PA and an active resynthesis of CL from the hydrolysis products.     

Studies of Rat Brain Metabolism Using Proton Nuclear Magnetic Resonance: Spectral Assignments and Monitoring of Prolidase, Acetylcholinesterase, and Glutaminase

The first application of inversion-recovery spin-echo proton nuclear magnetic resonance spectroscopy to the monitoring of reactions in rat brain preparations is presented. The initial report of the assignment of proton spin-echo nuclear magnetic resonance spectra from rabbit brain homogenates (C. R. Middlehurst et al., J. Neurochem. 42, 878-879, 1984) was used to assist in the assignment of spectra acquired from rat brain homogenates that were obtained from animals killed by cervical fracture or focussed microwave irradiation. Microwave-irradiated brains were divided into four major anatomical regions. Differences in metabolite levels were detected when spectra from fresh tissue and from various regions were compared. The in situ steady-state kinetics of prolidase in whole brain homogenate was determined. The procedure relies on the spectral differences between enzyme substrates and reaction products. The concentration dependence of the rate of hydrolysis of glycyl-L-proline was discribable by the Michaelis-Menten expression with a Michaelis constant of 1.90 mmol L-1 and a maximal velocity of 9.30 mumol min-1 mg-1 protein. The reactions catalysed by glutaminase and acetylcholinesterase in the brain were also monitored.     

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.     

Activation and stabilization of diaphragm-associated acetylcholinesterase by monovalent (Na+, Li+) cations

Acetylcholinesterase (AChE) activity was determined at varied pH values between 6 and 11 in rat homogenated diaphragm and in eel E. electricus soluble AChE, in the presence or absence of 115 mM NaCl or LiCl. It was observed that by using homogenated diaphragm Li+ stimulated AChE at physiological pH (7-7.4). In control (no cations) a pH "optimum" of 8.6-9 was found, while in presence of NaCl or LiCl "optima" of 9.5 and 10.2 were observed respectively. At optimum pH, AChE activity was about 2 times higher with NaCl, while with LiCl 5 times higher than the control. Preincubation of the enzyme or the homogenate in cations presence at pH 5.5 or pH 12.8 had no effect on the activity, when it was measured at pH "optima". However, without cations only 76% of the activity in optimum pH after preincubation at pH 5.5 was found. These results suggest that: (a) Li+ may neutralize negative charges of AChE more successfully than Na+, resulting in better enzyme activation and stabilization; (b) a possible enzyme desensitization induced by pH changes can be avoided by increasing Na+ concentrations and especially Li+.     

Purifcation and properties of multiple forms of brain acetylcholinesterase (EC 3.1.1.7)

—Approximately 70 per cent of the total AChE of bovine brain tissue was solubilized by repeated homogenization and centrifugation in 0.32 m sucrose containing EDTA. After ammonium sulphate fractionation, application of the enzyme preparation to an agarose affinity gel column effected a 700-fold purification. Subsequent molecular filtration separated three active forms of AChE with molecular weights of 130,000, 270,000 and 390,000 with an average specific activity of 575 mmol of acetylthiocholine hydrolysed/mg of protein/h. The complete procedure represented an approximate 23,000-fold purification of the enzyme from that in the original tissue homogenate. The three forms of AChE exhibited certain differences in properties, including apparent K_m values, pH optima and sensitivity to inhibitory agents. Ancillary studies on less purified enzyme preparations by use of polyacrylamide gel electrophoresis and isoelectric focusing techniques also suggested that brain AChE exists in multiple forms.