Predominance of the Cytoplasmic Form of Brain Hexokinase in Cultured Astrocytes

Abstract: Astrocytes have been cultured from neonatal rat brain according to the flask culture procedure of Booher and Sensenbrenner. Approximately 80% of the hexokinase (ATP: d -hexose 6-phosphotransferase, EC 2.7.1.1) activity is found in the soluble fraction in homogenates of these cells, in contrast to only 20% of the total activity in the soluble fraction of whole brain homogenates. The hexokinase from the cultured astrocytes has been compared with the cytoplasmic and glucose-6-P-solubilized mitochondrial enzymes from whole brain. In kinetic properties and pH-activity relationships, the glial hexokinase was similar to the cytoplasmic enzyme but different from the mitochondrial enzyme of whole brain. Using immunohistochemical methods for detecting hexokinase localization at the electron microscopic level, most of the cells showed prominent staining of cytoplasmic areas. If the cultured astrocytes are accepted as valid models for astrocytes in situ , these results support the suggestion of Bigl and co-workers that the predominant form of hexokinase in glial cells is the cytoplasmic enzyme.     

Sulphatide synthesis in isolated oligodendroglial and neuronal cells

—Cerebroside sulphotransferase activity in oligodendroglia from calf brain is 8-fold greater per cell than in calf neurons isolated at the same time under similar conditions. However, neuronal cell fractions from calf or rat brain have significant sulphotransferase activity, and in neurons isolated from rat brain at various ages, the capacity to synthesize sulphatide increases during myelination. The neuronal and oligodendroglial enzymes have similar substrate specificities and pH optima. Less of the enzyme could be extracted with Triton X-100 from the isolated cells than from microsomes prepared from whole brain.     

Neurotransmitter enzyme activities in neurons purified by bulk-isolation

Neurons, purified by bulk-isolation procedures from 10 day-old rat brain, are 80–90% homogeneous. Contaminants are primarily blood vessels and occasional oligodendroglia. All sizes and shapes of neurons are obtained, as they are isolated from all areas of the brain, except the cerebellum. Neurotransmitter enzyme activities involved in the metabolism of catecholamines, acetylcholine, and GABA are found at twice the level in these purified neurons when compared to that found in whole brain tissue. However, acetycholinesterase is found at a similar activity as in whole brain tissue, suggesting its localization in other cell types as well. Thus purified rat neurons are a good model system for studying neuronal function.     

ON THE MECHANISM OF STIMULATION OF AMP-AMINOHYDROLASE ACTIVITY BY HEXOKINASE IN BRAIN TISSUE

—A hexokinase has been isolated from brain tissue on Sephadex G-100 and DEAE cellulose which is similar to yeast enzyme in stimulating the AMP-aminohydrolase activity of rat brain soluble fractions. This effect of hexokinase is influenced neither by N-acetyl-glucosamine nor noradrenaline. An isoenzyme of hexokinase isolated from brain tissue on DEAE cellulose, having properties similar to that of the muscle enzyme, has no effect on AMP-aminohydrolase activity. The activating effect of yeast hexokinase is not due to its oligomeric structure. Enzyme subunits obtained by the treatment of native yeast enzyme by urea also activate AMP-aminohydrolase of rat brain soluble fractions.     

UDP-Galactose:Ceramide Galactosyl Transferase of Isolated Oligodendroglia

Abstract: The activity of UDP-galactose:ceramide galactosyl transferase (CGalT) has been studied in isolated oligodendroglia from bovine brain white matter and myelinating rat brain. The specific activity and activity per mg DNA are 4- and 10-fold higher in rat oligodendroglia compared with neuronal perikarya from rat brain, and is higher in oligodendroglia from myelinating rat brain compared with bovine oligodendroglia. In membranes isolated from oligodendroglia, the specific activity decreased in the order endoplasmic reticulum > plasma membrane > myelin.     

Hexokinase Levels in Discrete Regions of Rat Brain: Evaluation by Quantitative Immuno fluoresence Using Interactive Laser Cytometry and Comparison with Basal Rates of Glucose Utilization

Relative levels of hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) have been determined in 16 discrete regions of adult rat brain by a quantitative immunofluorescence method. The distribution of immunofluorescence in brain sections was determined by interactive laser cytometry and related to hexokinase content by comparison with standard sections containing known amounts of the enzyme. In many of these regions, referred to here as group I regions, hexokinase content was correlated with previously reported basal rates of glucose utilization. However, several regions (group II regions) in which hexokinase content exceeded that expected from basal rates of glucose utilization were also detected. Compared with the corresponding regions from albino rat brain, higher hexokinase levels were found in the dorsal and ventral lateral geniculate (group I regions) of pigmented Norway rats, a result reflecting previously reported increased glucose utilization by these regions in pigmented rats. There was no difference in hexokinase levels in the superior colliculus, a group II structure, from albino and pigmented rats, a finding implying that a reported increase in rate of glucose utilization in the superior colliculus of pigmented rats is effected without an increase in hexokinase content. It is suggested that group II regions may be adapted to sustain increases in rates of glucose utilization that are, relative to basal rates, considerably greater than those experienced by group I regions.     

Comparative studies on glucose phosphorylating isoenzymes from vertebrates--VIII. Immunochemical studies on mammalian hexokinases A

An immune serum elicited in a rabbit by injection of homogeneous brain hexokinase A was shown to be specific for the antigen. Other rat hexokinase isoenzymes (hexokinases B, C or D) did not present cross-reaction when tested by immunoinhibition of enzyme activity, double immunodiffusion and immunoadsorbent columns. The enzyme activity of hexokinase A from several mammals (rodents, lagomorphs, artiodactyls) was partially inhibited by the immune serum. In the case of mouse enzyme, the amount of serum required to inhibit 50% of the activity was five-fold higher than in the case of the rat enzyme. Enzymes from cow or sheep brain were only marginally affected. Hexokinases A isolated from various mammals, tested against the rat enzyme, showed faint lines of precipitation and marked spurs in double immunodiffusion plates even when enzymes from closely related rodents were analyzed. Immunoadsorbent columns, on the other hand, were able to retain most of the activity of hexokinases A from the mammals studied. Micro-complement fixation tests showed that hexokinases A from mammals outside the Order Rodentia were only partially recognized by the anti-hexokinase Arat serum. The results suggest that amino acid substitutions on the hexokinase A molecule have occurred at a rather fast rate.     

Isolation and some chemical properties of oligodendroglia from calf brain

Abstract— The method of Norton and Poduslo (1970) for isolating brain cells has been adapted for the isolation of oligodendroglia from the white matter of calf brain. The cells were obtained in greater than 90 per cent purity, and in a yield of 11 × 10⁶ cells/g of white matter. This number of cells represented a recovery of 11 per cent of the total cells in the tissue and therefore a considerably higher recovery of the original number of oligodendroglia. The average cell contained 5, 2 pg of DNA, 2–0 pg of RNA and 6, 7 pg of lipid. The lipid comprised cholesterol, galactolipid (both cerebroside and sulphatide) and phospholipid in the molar ratio of 1:0, 45:2, 3. Gangliosides were present in a concentration similar to that found in isolated rat neurons, The myelin-specific enzyme, 2′, 3′-cyclic nucleotide 3′-phosphohydrolase, was present at a level nearly equal to that in myelin, and eight-fold higher than the levels in rat neurons or astrocytes. The isolated oligodendroglia differed considerably from isolated astrocytes in size, morphology and chemical composition.     

Mitochondrial boundary membrane contact sites in brain: points of hexokinase and creatine kinase location, and control of Ca2+ transport

The location of hexokinase at the surface of brain mitochondria was investigated by electron microscopy using immuno-gold labelling techniques. The enzyme was located where the two mitochondrial limiting membranes were opposed and contact sites were possible. Disruption of the outer membrane by digitonin did not remove bound hexokinase and creatine kinase from brain mitochondria, although the activity of outer membrane markers and adenylate kinase decreased, suggesting a preferential location of both enzymes in the contact sites. In agreement with that, a membrane fraction was isolated from osmotically lysed rat brain mitochondria in which hexokinase and creatine kinase were concentrated. The density of this kinase-rich fraction was specifically increased by immuno-gold labelling of hexokinase, allowing a further purification by density gradient centrifugation. The fraction was composed of inner and outer limiting membrane components as shown by the specific marker enzymes, succinate dehydrogenase and NADH-cytochrome-c-oxidase (rotenone insensitive). As reported earlier for the enriched contact site fraction of liver mitochondria the fraction from brain mitochondria contained a high activity of glutathione transferase and a low cholesterol concentration. Moreover, the contacts showed a higher Ca2+ binding capacity in comparison to outer and inner membrane fractions. This finding may have regulatory implications because glucose phosphorylation via hexokinase activated the active Ca2+ uptake system and inhibited the passive efflux, resulting in an increase of intramitochondrial Ca2+.     

Glucose phosphorylation in tumor cells. Cloning, sequencing, and overexpression in active form of a full-length cDNA encoding a mitochondrial bindable form of hexokinase

In rapidly growing tumor cells exhibiting high glucose catabolic rates, the enzyme hexokinase is markedly elevated and bound in large amounts (50-80% of the total cell activity) to the outer mitochondrial membrane (Arora, K.K., and Pedersen, P.L. (1988) J. Biol. Chem. 263, 17422-17428; Parry, D.M., and Pedersen, P.L. (1983) J. Biol. Chem. 258, 10904-10912). In extending these studies, we have isolated a cDNA clone of hexokinase from a lambda gt11 library of the highly glycolytic, c37 mouse hepatoma cell line. This clone, comprising 4,198 base pairs, contains a single open reading frame of 2,754 nucleotides which encode a 918-amino acid hexokinase with a mass of 102,272 daltons. This enzyme exhibits, respectively, 68 and 32 amino acid differences, including several charge differences, from the recently sequenced human kidney and rat brain enzymes. The putative glucose and ATP binding domains present in the latter two enzymes and in rat liver glucokinase are conserved in the tumor enzyme. At its N-terminal region, tumor hexokinase has a 12-amino acid hydrophobic stretch which is present in the rat brain enzyme but absent in the rat liver glucokinase, a cytoplasmic enzyme. The mature tumor hexokinase protein has been overexpressed in active form in Escherichia coli and purified 9-fold. The overexpressed enzyme binds to rat liver mitochondria in the presence of MgCl2. This is the first report describing the cloning and sequencing of a tumor hexokinase, and the first report documenting the overexpression of any hexokinase type in E. coli. Questions pertinent to the enzyme's mechanism, regulation, binding to mitochondria, and its marked elevation in tumor cells can now be addressed.     

In vitro synthesis of rat brain hexokinase

Hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) has been synthesized in the rabbit reticulocyte lysate system directed by poly(A)+ mRNA isolated from rat brain. Identification of the in vitro synthesis product as hexokinase was based on its immunoprecipitation with anti-hexokinase serum as well as the generation of identical peptide maps after partial cleavage of the in vitro product and authentic hexokinase with Staphylococcus aureus V8 proteinase or chymotrypsin. The in vitro product and authentic hexokinase were indistinguishable in molecular weight (SDS-gel electrophoresis); thus, despite the fact that, in situ, much of the hexokinase in brain is found in association with mitochondria, it is not synthesized in the form of a higher molecular weight precursor as is characteristic of other mitochondrial proteins. This is in accord with the view that hexokinase is best considered as a classical 'soluble' enzyme which is capable of exhibiting reversible association with mitochondria. The in vitro product cochromatographs (during anion-exchange HPLC) with authentic hexokinase previously shown to have a blocked (presumably acetylated) N-terminus; this procedure is capable of resolving the N-terminally blocked form of the enzyme from a partially proteolyzed form having a free N-terminal amino group. Thus the in vitro product is apparently N-acetylated by an enzyme system previously shown to be present in reticulocyte lysates. A significant fraction of the in vitro synthesized hexokinase attained a conformation characteristic of the native enzyme as judged by the observations that it could be immunoprecipitated by monoclonal antibodies recognizing the native enzyme but not by antibodies recognizing denatured hexokinase, and limited tryptic cleavage of the in vitro product gave fragments identical to those seen with the native enzyme and thought to reflect the organization of structural domains in that enzyme. However, based on these same criteria, the majority of the hexokinase synthesized in vitro appears to exist in a folding state that is not identical to that of either the fully denatured or native enzyme.     

The complete amino acid sequence of the catalytic domain of rat brain hexokinase, deduced from the cloned cDNA

The complete amino acid sequence of the catalytic domain of rat brain hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) has been deduced from the nucleotide sequence of cloned cDNA. Extensive similarity in sequence, taken to indicate similarity in secondary and tertiary structure, is seen between the mammalian enzyme and yeast hexokinase isozymes A and B. All residues critical for binding glucose to the yeast enzyme are conserved in brain hexokinase. A location for the substrate ATP binding site is proposed based on relation of structural features in the yeast enzyme to characteristics commonly observed in other nucleotide binding enzymes; sequences in regions proposed to be important for binding of ATP to the yeast enzyme are highly conserved in brain hexokinase.     

Some observations on mitochondrial-bound hexokinase and creatine kinase of the heart

A large part of the hexokinase activity of the rat brain 20,000g supernatant became mitochondrial bound when incubated with rat heart mitochondria which had been pretreated with glucose-6-phosphate. This binding was dependent on small-molecular compounds (as yet unidentified) of the brain supernatant. Divalent cations, spermine, and pentalysine strongly stimulated the binding of brain supernatant hexokinase to heart mitochondria. Inorganic phosphate, alpha-glycerophosphate, and fructose-1,6-diphosphate showed some stimulatory effect. No effect was observed with insulin or glucose. Mitochondria isolated from hearts of fasted rats had less specific hexokinase activity than mitochondria from fasted and then carbohydrate refed rats. This dietary treatment had no significant effect on the total heart hexokinase activity. Oligomycin did not inhibit the formation of creatine phosphate or glucose-6-phosphate by isolated rabbit heart mitochondria incubated in the presence of phosphoenolpyruvate and pyruvate kinase. However, the presence of creatine inhibited the formation of glucose-6-phosphate when the ATP/ADP ratio was low, indicating that creatine kinase has a greater access to ATP/ADP translocation than has hexokinase.     

In vitro synthesis of rat brain hexokinase

Hexokinase (ATP: D-hexose 6-phosphotransferase, EC 2.7.1.1) has been synthesized in the rabbit reticulocyte lysate system directed by poly(A)⁺ mRNA isolated from rat brain. Identification of the in vitro synthesis product as hexokinase was based on its immunoprecipatation with anti-hexokinase serum as well as the generation of identical peptide maps after partial cleavage of the in vitro product and authentic hexokinase with Staphylococcus aureus V8 proteinase or chymotrypsin. The in vitro product and authentic hexokinase were indistinguishable in molecular weight (SDS-gel electrophoresis); thus, despite the fact that, in situ, much of the hexokinase in brain is found in association with mitochondria, it is not synthesized in the form of a higher molecular weight precursor as is characteristic of other mitochondrial proteins. This is in accord with the view that hexokinase is best considered as a classical ‘soluble’ enzyme which is capable of exhibiting reversible association with mitochondria. The in vitro product cochromatographs (during anion-exchange HPLC) with authentic hexokinase previously shown to have a blocked (presumably acetylated) N-terminus; this procedure is capable of resolving the N-terminally blocked form of the enzyme from a partially proteolyzed form having a free N-terminal amino group. Thus the in vitro product is apparently N-acetylated by an enzyme system previously shown to be present in reticulocyte lysates. A significant fraction of the in vitro synthesized hexokinase attained a conformation characteristic of the native enzyme as judged by the observations that (1) it could be immunoprecipitated by monoclonal antibodies recognizing the native enzyme but not by antibodies recognizing denatured hexokinase, and (2) limited tryptic cleavage of the in vitro product gave fragments identical to those seen with the native enzyme and thought to reflect the organization of structural domains in that enzyme. However, based on these same criteria, the majority of the hexokinase synthesized in vitro appears to exist in a folding state that is not identical to that of either the fully denatured or native enzyme.     

Studies on the Linkage of Energy Metabolism and Neuronal Activity in the Isolated Perfused Rat Brain

An isolated rat brain preparation was perfused using glucose-free (=aglycemic) media. The high-energy phosphates, substrates of the glycolytic pathway, free atnino acids, acetylcholine as well as the intracellular distribution of hexokinase activity were determined in brain tissues. The EEG was evaluated visually. The levels of glycolytic substrates, glutamate, and glutamine in cortical tissue decreased after aglycemic perfusion, whereas the aspartate level increased and the GABA level remained unchanged. The high-energy phosphate content seemed to be unaffected for about 15 min of aglycemic perfusion and fell significantly after 20 min. The EEG of the isolated brain changed rapidly after starting aglycemic perfusion and became isoelectric after 12–15 min. Hyperglycemic perfusion (35 mmol glucose per liter perfusion medium) did not alter the energy metabolism of the isolated brain. The breakdown of cerebral energy metabolism and of EEG activity was postponed when thiopental was added to the perfusion medium. The soluble hexokinase activity measured in cortical tissue was reduced after aglycemic perfusion and was enhanced after thiopental. Hyperglycemic perfusion did not influence the intracellular hexokinase distribution. The acetylcholine level in the striatum of the isolated rat brain was significantly decreased by aglycemia and was increased in hypothalamus by thiopental. It was suggested that hexokinase bound to the mitochondrial membrane may play an important role in the relationship of energy metabolism and neuronal activity.     

Hexokinase of rat brain mitochondria: relative importance of adenylate kinase and oxidative phosphorylation as sources of substrate ATP, and interaction with intramitochondrial compartments of ATP and ADP

Interactions between intramitochondrial ATP-generating, ADP-requiring processes and ATP-requiring, ADP-generating phosphorylation of glucose by mitochondrially bound hexokinase (ATP:D-hexose 6-phosphotransferase, EC 2.7.1.1) have been investigated using well-coupled mitochondria isolated from rat brain. ADP generated by mitochondrially bound hexokinase was more effective at stimulating respiration than was ADP generated by hexokinase dissociated from the mitochondria, and pyruvate kinase was less effective as a scavenger of ADP generated by the mitochondrially bound hexokinase than was the case with ADP generated by the dissociated enzyme. These results indicate that ADP generated by the mitochondrially bound enzyme is at least partially sequestered and directed toward the mitochondrial oxidative phosphorylation apparatus. Under the conditions of these experiments, the maximum rate of ATP production by oxidative phosphorylation was approximately 10-fold greater than the maximum rate of ATP generation by the adenylate kinase reaction. Moreover, during periods of active oxidative phosphorylation, adenylate kinase made no detectable contribution to ATP production. Thus, adenylate kinase does not represent a major source of ATP for hexokinase bound to actively phosphorylating brain mitochondria. With adenylate kinase as the sole source of ATP, a steady state was attained in which ATP formation was balanced by utilization in the hexokinase reaction. In contrast, when oxidative phosphorylation was the source of ATP, a steady state rate of Glc phosphorylation was attained, but it was equivalent to only about 40-50% of the rate of ATP production and thus there was a continued net increase in ATP concentration in the system. Rates of Glc phosphorylation with ATP generated by oxidative phosphorylation exceeded those seen with equivalent levels of exogenously added ATP. Moreover, at total ATP concentrations greater than approximately 0.2 mM, hexokinase bound to actively phosphorylating mitochondria was unresponsive to continued slow increases in ATP levels; acute increase in ATP (by addition of exogenous nucleotide) did, however, result in increased hexokinase activity. The relative insensitivity of mitochondrially bound hexokinase to extramitochondrial ATP suggested dependence on an intramitochondrial pool (or pools) of ATP during active oxidative phosphorylation. Two intramitochondrial compartments of ATP were identified based on their selective release by inhibitors of electron transport or oxidative phosphorylation. These compartments were distinguished by their sensitivity to inhibitors and the kinetics with which they were filled with ATP generated by oxidative phosphorylation. Exogenous glycerol kinase competed effectively with mitochondrially bound hexokinase for extramitochondrial ATP, with relatively low levels of glycerol kinase completely inhibiting phosphorylation of Glc.(ABSTRACT TRUNCATED AT 400 WORDS)     

Some properties of soluble and solubilized particle-bound hexokinase

Abstract— Particle-bound hexokinase of rat brain homogenates was solubilized by successive treatment with 0-9 M-NaCl or 003 M-ATP (pH 8.0) and 0-5% (w/v) Triton X-100. This solubilized hexokinase and the soluble hexokinase present in cytoplasm of rat brain homogenates were chromatographed on DEAE-cellulose and some kinetic properties of the isolated hexokinase peaks were studied. The chromatographic separation was greatly influenced by the EDTA-concentration of the buffer used. No significant differences were observed in the chromatographic pattern and in the apparent K_m-values for ATP and glucose and the apparent K_t for glucose-6-phosphate (versus ATP) between the soluble and particulate hexokinase solubilized by different reagents. On agarose-electrophoresis the solubilized particulate enzyme migrates as one single band, the soluble hexokinase separates into one major and two minor bands.     

EFFECT OF FATTY ACIDS ON RAT BRAIN PARTICULATE HEXOKINASE

Abstract— The effect of free fatty acids on rat brain particulate hexokinase was studied in vitro. Hexokinase bound with brain mitochondrial fraction was found to be sensitive to the action of free fatty acids, resulting in the solubilization of at least part of bound enzyme activity into the supernatant. The decrease of total enzyme activity observed at the highest free fatty acid concentration was probably due to the inhibition of hexokinase. The physiological consequence of hexokinase solubilization by low concentrations of free fatty acids, similar to that observed in vivo , is discussed in relation to activity changes of soluble and particulate enzyme forms demonstrated previously under hypoxic conditions.     

Discrimination of antigenic site and thiol-inhibitor-sensitive site of hexokinase isoenzymes.

Rabbit antiserum was prepared against hexokinase isoenzyme type I which was purified from rat brain mitochondria. The antiserum inhibited the activity of the mitochondrial hexokinase type I as well as that of the cytosolic type I enzyme prepared from rat brain, kidney and spleen. It did not, however, inhibit the activity of type II hexokinase from muscle and spleen or that of the type III enzyme from spleen. The results suggest that all hexokinase type I isoenzymes may have a common antigenic site irrespective of their sources, though their responses to a thiol inhibitor are different.     

STALOSYLGALACTOSYL CERAMTDE AS A SPECIFIC MARKER FOR HUMAN MYELIN AND OLIGODENDROGLIAL PERIKARYA: GANGLIOSIDES OF HUMAN MYELIN, OLIGODENDROGLIA AND NEURONS

Gangliosides were isolated from human brain myelin, oligodendroglia, and neurons. Quantitative analysis revealed the following ganglioside contents: myelin, 2.0; neurons, 1.3; and oligodendroglia, 0.35 μg ganglioside sialic acid per mg protein. Myclin had a relatively simple ganglioside pattern with G_M4 and G_M1 as the predominant ganglioside species. The ganglioside pattern of oligodendroglia was quite complex and it resembled that of whole white matter rather than that of myelin. A high concentration of G_M4 was found in oligodendroglial fractions in addition to G_M1, G_D1a, G_D1b, and G_T1b. The usually- minor brain gangliosides G_M3, G_M2, and G_M3 were also enriched in oligodendroglia. The neuronal ganglioside pattern was generally similar to the pattern of whole gray matter. Both neurons and whole gray matter contained very low amounts of G_M4. These results indicate that G_M4 is specifically localized in myelin and oligodendroglia of the CNS. Evidence is also presented that myelin, but not oligodendroglia, is the major reservoir of human white matter G_M1 and G_M4.