Regional and Subcellular Distribution in Mammalian Brain of the Enzymes Producing Adenosine

The activities of 5'-nucleotidase, 2'-nucleotidase, alkaline phosphatase, and acid phosphatase were measured in rat and autopsied human brains. The four phosphatases in the rat brain showed little change in activity after death. The activities of adenosine-producing enzymes were compared in various parts of rat and human brains. When phosphatase activity was measured at pH 7.5, 5'-nucleotidase showed the highest activity in the most parts of the brain. The activity of 2'-nucleotidase and that of nonspecific phosphatase were almost the same at pH 7.5. However, higher phosphatase activity was observed in all parts of the brain when nonspecific phosphatase activity was measured at pH 10.0 or 5.5. High specific activity of 5'-nucleotidase in the brain was detected in the membranous components, especially in the synaptic membranes. The activity of 2'-nucleotidase was distributed in the soluble and synaptosomal fractions. The highest activity of both alkaline and acid phosphatases was recovered in the crude mitochondrial fraction, with the highest specific activity in the microsomal fraction. Phosphatase activity was distributed widely in the rat brain. The activity of 5'-nucleotidase was high in the medulla oblongata, thalamus, and hippocampus, but low in the peripheral nerve, spinal cord, and occipital lobe. The activity of 2'-nucleotidase was high in the vermis and frontal lobe. The highest acid and alkaline phosphatase activities were detected in the frontal lobe and in the olfactory bulb, respectively. The distribution of the four phosphatases in the autopsied human brain was similar to that in the rat brain. The highest 5'-nucleotidase activity was observed in the temporal lobe and thalamus.(ABSTRACT TRUNCATED AT 250 WORDS)     

FREE AMINO ACIDS AND RELATED COMPOUNDS IN BIOPSIES OF HUMAN BRAIN

Abstract— Contents (μmol/g wet wt.) of 35 free amino acids and related compounds were measured in biopsies of human brain from ten patients. Brain specimens were frozen in liquid nitrogen within 10 sec of their removal at neurosurgery; thus, the values found should approximate those which occur in living brain.
Levels in free pools of biopsied cerebral cortex of most of the amino acids that are constituents of proteins were only 20-50 per cent of those found in autopsied cortex. The content of cystine and ethanolamine was much lower in biopsied than in autopsied cortex. Concentrations of GABA in biopsied cortex were only 20 per cent as high as those found in autopsied cortex, and levels of γ-aminobutyryl dipeptides were also significantly lower in biopsied cortex. Amounts of cystathionine in biopsied cortex varied markedly, but averaged much higher than in autopsied cortex; a single biopsy specimen of cerebellar grey matter had a cystathionine content 36-fold greater than the mean found in autopsied cerebellum.
Appreciable variability in contents among cortical biopsies was found for glycerophosphoethanolamine, phosphoethanolamine, ethanolamine, taurine, aspartic acid, glutamic acid, glutamine, and GABA, as well as for cystathionine. Whether this variability occurred between different subjects, or between different cortical areas, was not clear, although the former possibility was suggested by findings in multiple cortical biopsies from one patient.     

Activation and partial purification of the ATPase of clathrin-coated vesicles and reconstitution of the proton pump

A N-ethylmaleimide-sensitive ATPase was extracted and partially purified from clathrin-coated vesicles of bovine brain. During purification the enzyme lost activity which was restored by a purified phospholipid fraction from brain. Phosphatidylserine, but no other commercial phospholipids tested, replaced the brain lipid fraction as activator. Particles depleted of the ATPase exhibited no H+ pump activity when reconstituted with brain phospholipids by the cholate dilution procedure. H+ pump activity was restored by incubating the reconstituted vesicles with the partially purified ATPase.     

Rapid Preparation of a Distinct Lysosomal Population from Myelinating Mouse Brain Using Percoll Gradients

To study the vesicular lysosome-associated transport and the metabolism of some brain macromolecules (in particular, sialoglycoconjugates), we developed a rapid procedure to obtain a distinct lysosomal population starting from myelinating mouse brain. This procedure is based on an initial differential centrifugation step producing a 1,000-17,500-g fraction (P2), followed by isopycnic centrifugation of fraction P2 on a self-generated colloidal silica gel (Percoll) gradient. The heaviest subfraction thus obtained is very rich in acid hydrolase activities like beta-galactosidase, arylsulfatase A, and acid phosphatase. The enrichment of these enzymes is approximately 100-fold as compared with the starting homogenate, whereas the markers of other subcellular organelles, such as mitochondria, plasma membranes, or the Golgi apparatus, are virtually absent. The lysosomal preparation contains approximately 12-14% of the total acid hydrolase activities, with a protein yield of approximately 0.12%. Electron microscopy shows that the lysosomal fraction is composed of an approximately 90% pure population of lysosomes. Therefore, the procedure described here is suitable for obtaining a highly purified lysosome preparation from myelinating mouse brain.     

REGIONAL DISTRIBUTION OF HOMOCARNOSINE, HOMOCARNOSINE-CARNOSINE SYNTHETASE AND HOMOCARNOSINASE IN HUMAN BRAIN

Homocarnosine (HCarn) content varied over a 6-fold range in different regions of autopsied human brain, being highest in the dentate nucleus and the inferior olive, and lowest in the caudate nucleus and mesolimbic system. HCarn content was similar in biopsied and autopsied frontal cortex. Very little if any carnosine (Carn) was present in human brain, except for the olfactory bulb, where Carn may have comprised 20% of the imidazole dipeptides present. Only HCarn was present in human CSF. HCarn-Carn synthetase enzyme activity in biopsy specimens of human frontal and temporal cortex was approx 10 times greater than has been reported for rat cerebral cortex. The enzyme synthesized Carn 3–5 times as rapidly as HCarn, when β-alanine (β-Ala) or GABA substrate concentrations were 10 MM. The synthetase was found to have an apparent K_m of 1.8 mM for β-Ala, and 8.8 mM for GABA. HCarn-Carn synthetase activity decreases rapidly after brain death, and was not detectable in autopsied brain specimens frozen more than 6 h after patients’deaths. Homocarnosinase activity was determined in brain, using L-[γaminobutyryl-1-¹⁴C]HCarn as substrate, and measuring radioactive GABA produced by hydrolysis of HCarn at pH 7.2 in the presence of Co²⁺ ions. Homocarnosinase activity was similar in biopsied and autopsied human cerebral cortex, and appeared to be stable for at least 10 h after death in unfrozen brain. Differences in the regional distribution of HCarn-Carn synthetase and homocarnosinase activities, as well as regional differences in GABA content in human brain, do not readily account for regional differences in HCarn content, nor do they suggest a physiological role for HCarn.     

Isoprostanes, a novel markers of oxidative stress in schizophrenic disorders

It is a well known fact that 3H-panthenol (PL) has a high bioavailability, so we studied its biotransformation and its protective action against lipoperoxide activation in homogenates and mitochondrial-synaptosomal fraction (11 000 g) of rat brain. The lipoperoxidation was initialized by Fe²⁺-ascorbate complex (Fe²⁺-Asc). In experiments in vivo , after 30 min, we demonstrated accumulation of intermediate products of CoA biosynthesis – pantothenic acid (PA), phospho-PA, and phosphopantetheine – in postmitochondrial fraction of brain, by using a HPLC technique. Addition of the PL (10 m m ) to brain hemispheres homogenates or mitochondrial-synaptosomal fraction caused a remarkable reduction of malondialdehyde production. However, 30 min preincubation with the PL, but not with PA, was ineffective. The data obtained may be a reason for a high neuroprotective activity of PL in curing brain diseases with vessel or alcohol-induced damages.     

PURIFICATION AND SOME PROPERTIES OF S-100 PROTEIN FRACTIONS FROM SHEEP AND PIG BRAINS

Abstract— The S-100 protein fraction of pig and sheep brain was purified in 40 per cent yield by a modification of the procedure of M oore (1965), which avoided selective loss of S-100 components. The S-100 fraction of both pig and sheep is a mixture of proteins as indicated by acrylamide gel electrophoresis and N -terminal amino acid analysis. Differences in amino acid composition, electrophoretic heterogenity and N -terminal analysis were found.
One fraction (fraction A) was isolated by DEAE-Sephadex chromatography from pig brain S-100 protein fraction. It was considered to be a single protein since it migrated as a single band on acrylamide gel electrophoresis and showed a single symmetrical peak during ultracentrifugal analysis. Only one N -terminal amino acid was detected in fraction A. The amino acid composition of this fraction showed minor but significant differences from that of the complete S-100 protein fraction from pig brain. The S-100 protein fraction of both species, as well as fraction A, had similar s _{20, w} values and similar molecular weights (about 20,000) as indicated by gel filtration. These results, together with the immunological data obtained by other authors, suggest that the proteins of the S-100 fraction are closely related; the heterogeneity of the S-100 protein fraction may be of the same type as the lactate dehydrogenase isoenzymes.     

Postmortem Changes of Amino Compounds in Human and Rat Brain

Abstract: Contents of 35 amino acids and related compounds were measured in whole rat brain, and in superficial areas of biopsied and autopsied human brain, after incubation for various intervals at temperatures simulating those likely to occur in cadavers under mortuary conditions. These data should aid interpretation of values for amino compounds determined in autopsied brain from patients with neurological or psychiatric disorders. The contents of glutamic acid, glutamine, taurine, phosphoethanolamine, cystathionine, and homocarnosine remain unchanged for long periods in human brain. Aspartic acid content is stable for 4 h after death, but thereafter rises rapidly. Glycine content rises rapidly, as do the contents of most amino acid components of proteins. Glutathione content drops rapidly in human brain after death. GABA content is stable for about 30 min, and rises to a maximum 2 to 3 h after death, after which it remains unchanged for at least 24 h. In rat brain, GABA content rises more rapidly, aspartate content rises more slowly, homocarnosine content decreases progressively, and glycerophosphoethanolamine content decreases more rapidly than in human brain.     

Biotransformation of D‐panthenol and its action in protection of activation of oxidizing processes in brain

It is a well known fact that 3H‐panthenol (PL) has a high bioavailability, so we studied its biotransformation and its protective action against lipoperoxide activation in homogenates and mitochondrial‐synaptosomal fraction (11 000 g) of rat brain. The lipoperoxidation was initialized by Fe²⁺‐ascorbate complex (Fe²⁺‐Asc). In experiments in vivo, after 30 min, we demonstrated accumulation of intermediate products of CoA biosynthesis – pantothenic acid (PA), phospho‐PA, and phosphopantetheine – in postmitochondrial fraction of brain, by using a HPLC technique. Addition of the PL (10 mm ) to brain hemispheres homogenates or mitochondrial‐synaptosomal fraction caused a remarkable reduction of malondialdehyde production. However, 30 min preincubation with the PL, but not with PA, was ineffective. The data obtained may be a reason for a high neuroprotective activity of PL in curing brain diseases with vessel or alcohol‐induced damages.     

Isolation of synaptic plasma membrane from brain by combined flotation-sedimentation density gradient centrifugation

A method is described for the subcellular fractionation of brain to obtain a preparation highly enriched in synaptic plasma membranes. The enriched fraction is recovered from the interface of a two-step sucrose density gradient on which a hypotonically lysed crude mitochondrial fraction from brain has been separated by simultaneous sedimentation and flotation centrifugation. Enzyme marker activities associated with the neuronal plasma membrane are enriched in the synaptic plasma membrane-containing fraction while less than 10% of enzyme markers associated with the major probable contaminants, myelin and mitochondria, are found in the same fraction. Morphological examination of the enriched fraction suggests that about 80% of the profiles are recognisably synaptic in origin. Compared to previously described methods for obtaining synaptic plasma-enriched fractions of equivalent purity, the procedure reported here is simpler, shorter, and of greater capacity.     

Oxygen transport in the cerebral cortex of rats breathing a hyperoxic gas mixture]

Oxygen dissolved in the arterial blood plasma at a high pressure was shown to pass into the brain tissue from the finest arterioles. Therefore only a thin layer of the tissue immediately adjacent to these vessels is affected by the increased oxygen tension pO2. Permeability of the arteriole walls for oxygen protects the neurones against the high pO2. A special physiological feature of the oxygen transport during normobaric hyperoxia in the brain tissue involves very "steep" gradients of the pO2 in tissues and of the transferring the oxygen fraction from arterioles to venules through the tissues. The findings allow to compare distribution of the pO2 over the whole brain vessel network with that during inhalation of air or pure oxygen.     

GABA content and glutamic acid decarboxylase activity in brain of Huntington's chorea patients and control subjects.

—GABA contents are significantly decreased in the caudate nucleus, putamen-globus pallidus, substantia nigra, and occipital cortex in autopsied brain from Huntington's chorea patients, as compared to values in the same regions from control subjects who have died without neurological disease. Homocarnosine levels are lower in choreic than in control brain, but only in the putamen-globus pallidus and the cerebellar cortex are the differences significant. Activity of the enzyme which synthesizes GABA, glutamic acid decarboxylase, is reduced in the brains of some choreic patients, but may be equally low in brain of control subjects, even though the latter exhibit normal brain GABA content. Low glutamic acid decarboxylase activity in autopsied human brain is not uniquely characteristic of Huntington's chorea. No evidence was found in this study for an inhibitor of glutamic acid decarboxylase in choreic brain, nor for the presence of an isoenzyme with decreased affinity for glutamate. GABA aminotransferase, the enzyme which degrades GABA, was equally active in control and choreic brain; therefore, increased activity of this enzyme cannot account for the low brain GABA levels in Huntington's chorea.     

Partial Purification and Properties of Human Brain Aldehyde Dehydrogenases

Acetaldehyde and biogenic aldehydes were used as substrates to investigate the subcellular distribution of aldehyde dehydrogenase activity in autopsied human brain. With 10 microM acetaldehyde as substrate, over 50% of the total activity was found in the mitochondrial fraction and 38% was associated with the cytosol. However, with 4 microM 3,4-dihydroxyphenylacetaldehyde and 10 microM indoleacetaldehyde as substrates, 40-50% of the total activity was found in the soluble fraction, the mitochondrial fraction accounting for only 15-30% of the total activity. These data suggested the presence of distinct aldehyde dehydrogenase isozymes in the different compartments. The mitochondrial and cytosolic fractions were, therefore, subjected to salt fractionation and ion-exchange chromatography to purify further the isozymes present in both fractions. The kinetic data on the partially purified isozymes revealed the presence of a low Km isozyme in both the mitochondria and the cytosol, with Km values for acetaldehyde of 1.7 microM and 10.2 microM, respectively. However, the cytosolic isozyme exhibited lower Km values for the biogenic aldehydes. Both isozymes were activated by Mg2+ and Ca2+ in phosphate buffers (pH 7.4). Also, high Km isozymes were found in the mitochondria and in the microsomes.     

Effect of Hypothyroidism on Different Forms of Actin in Rat Cerebral Neuronal Cultures Studied by an Improved DNase I Inhibition Assay

An improved DNase I inhibition assay for the filamentous actin (F-actin) and monomeric actin (G-actin) in brain cells has been developed. Unlike other methods, the cell lysis conditions and postlysis treatments, established by us, inhibited the temporal inactivation of actin in the cell lysate and maintained a stable F-actin/G-actin ratio for at least 4-5 h after lysis. The new procedure allowed separate quantitation of the noncytoskeletal F-actin in the Triton-soluble fraction (12,000 g, 10 min supernatant) that did not readily sediment with the Triton-insoluble cytoskeletal F-actin (12,000 g, 10 min pellet). We have applied this modified assay system to study the effect of hypothyroidism on different forms of actin using primary cultures of neurons derived from cerebra of neonatal normal and hypothyroid rats. Our results showed a 20% increase in the Triton-insoluble cytoskeletal F-actin in cultures from hypothyroid brain relative to normal controls. In the Triton-soluble fraction, containing the G-actin and the noncytoskeletal F-actin, cultures from hypothyroid brain showed a 15% increase in G-actin, whereas the F-actin remained unaltered. The 10% increase in total actin observed in this fraction from hypothyroid brain could be totally accounted for by the enhancement of G-actin. The mean F-actin/G-actin ratio in this fraction was about 30% higher in the cultures from normal brain compared to that of the hypothyroid system, which indicates that hypothyroidism tends to decrease the proportion of noncytoskeletal F-actin relative to G-actin.     

Regional and Subcellular Distribution of Cyanide Metabolizing Enzymes in the Central Nervous System

Activities of cyanide metabolizing enzymes were measured in various subcellular fractions and regions in the central nervous system. Brain rhodanese and liver beta-mercaptopyruvate sulfurtransferase showed a slight decrease in activity after death. The activity of beta-mercaptopyruvate sulfurtransferase was negligible in the rat brain, compared with that of rhodanese. A small amount of thiocyanate was produced from cyanide and beta-mercaptopyruvate in the human brain, probably due to contamination with red blood cells. Rhodanese activity was widely distributed in all the areas of nervous tissue examined. In the rat the olfactory bulb showed the highest rhodanese activity, and high activity was also observed served in the thalamus, septum, hippocampus, and dorsal part of the midbrain. Rhodanese activity was low in various parts of the cerebral cortex. The distribution pattern of rhodanese in post-mortem human brain was essentially similar to that in rat brain. The thalamus, amygdala, centrum semiovale, colliculus superior, and cerebellar cortex showed high rhodanese activity in the human brain. Rhodanese activity was detected in the spinal cord. Anterior horn showed the highest rhodanese activity in the cervical, thoracic, and lumbar cord. Most rhodanese activity in the rat brain was recovered in the mitochondrial fraction with the highest specific activity. Rhodanese activity was lower in spinal cords obtained from autopsied cases with amyotrophic lateral sclerosis than in those of control subjects. A significant decrease in rhodanese was observed in the posterior column of the cervical or thoracic cord, but the activity in the anterior horn did not differ significantly between the two groups.     

Isolation from bovine brain of a fraction containing capillaries and a fraction containing membrane fragments of the choroid plexus.

Combined differential and density gradient centrifugation was used for the isolation of a capillary-rich fraction from the cerebral cortex and a brush border containing fraction from the bovine choroid plexus. The activities of gamma-glutamyl transpeptidase and several other marker enzymes were monitored during the fractionation procedure. Electron microscopic examination showed a membrane-rich fraction in the choroid plexus high in the gamma-glutamyl transpeptidase and 5'-nucleotidase activities. From the brain cortex, a capillary-rich fraction was obtained which was high in gamma-glutamyl transpeptidase and alkaline phosphatase activities. A histochemical examination showed gamma-glutamyl transpeptidase activity localized in the capillary walls.     

Astroglial and axonal proteins in isolated brain filaments. I. Isolation of the glial fibrillary acidic protein and of an immunologically active cyanogen bromide peptide from brain filament preparations of bovine white matter.

The glial fibrillary acidic protein and an immunologically active cyanogen bromide peptide were purified by immunoaffinity chromatography from 8 M urea extracts of brain filament preparations isolated from bovine white matter according to Norton's procedure. The protein accounted for approximately 30% of the total protein in this preparation and for the largest fraction in the 50 000 molecular weight range. The fraction not absorbed to the immuno-Sepharose column reacted with neurofilament antisera by double immunodiffusion. On sodium dodecyl sulfate gel electrophoresis the main bands in the non-adsorbed fraction were at 74 000 daltons and above 100 000. Several bands were seen in the 50 000 molecular weight range. It is concluded that glio- and neurofilaments co-purify together in Norton's procedure and that neurofilaments are probably heterogeneous in polypeptide composition.     

QUANTITATION OF ACTIN IN DEVELOPING BRAIN1

Actin levels in the soluble fraction of chick embryo brain sonicates have been quantitated by polyacrylamide gel electrophoresis. Brain actin concentrations remained constant at 8.10 ± 0.9% in developing cnibryos but dropped to 6.0 ± 0.9% in adult brain. Over 80% of the total brain protein was solubilized by the sonication procedure and actin was not detected in the remaining insoluble fraction.     

Glutathione peroxidase activity in surgical and autopsied human brains

Glutathione peroxidase (GSHPx) activity was assayed in normal cerebral gray and white matter samples obtained from frontal, temporal, occipital and parietal lobes during surgical approach to an underlying lesion, and also in normal autopsied human frontal gray and white matter. GSHPx was assayed by a 2 step enzyme reaction which was monitored by following the oxidation of NADPH at 340 nm. It was found that all the brain samples studied contained GSHPx activity. Parietal lobe appeared to have the lowest GSHPx activity compared to temporal, occipital or frontal lobes. Mean enzyme activity in autopsied samples was comparable to that in surgical material. However, considerable loss of activity was observed after 10 years of tissue storage at –80°C.This investigation was supported by the Verterans Administration.     

Neurochemical Abnormalities in Brains of Renal Failure Patients Treated by Repeated Hemodialysis

We examined autopsied brain from 10 patients with end-stage renal failure who had undergone repeated hemodialysis. Eight had classic symptoms, and two had suggestive symptoms of dialysis encephalopathy. Findings were compared with those in autopsied brain from control adults who had never been hemodialyzed. Mean gamma-aminobutyric acid (GABA) contents were significantly reduced in frontal and occipital cortex, cerebellar cortex, dentate nucleus, caudate nucleus, and medial-dorsal thalamus of the hemodialyzed patients, the reduction being greater than 40% in cerebral cortex and thalamus. Choline acetyltransferase activity was reduced by 25-35% in three cortical regions in the hemodialyzed patients. These two abnormalities were observed in the brain of each hemodialyzed patient, regardless of whether or not the patient died with unequivocal dialysis encephalopathy. Pyridoxal phosphate contents were substantially reduced in brains of the hemodialyzed patients, but metabolites of noradrenaline, 3,4-dihydroxyphenylethylamine (dopamine), and 5-hydroxytryptamine (serotonin) were present in normal amounts. Aluminum levels were abnormally high in frontal cortical gray matter in the hemodialyzed patients. Although this study does not clarify the role played by aluminum toxicity in the pathogenesis of dialysis encephalopathy, the abnormalities we found suggest the need for further neurochemical investigations in this disorder.