Correlation of hexokinase content and basal energy metabolism in discrete regions of rat brain

Direct neuronal glucose uptake heralds activity-dependent increases in cerebral metabolism

Metabolically, the brain is a highly active organ that relies almost exclusively on glucose as its energy source. According to the astrocyte-to-neuron lactate shuttle hypothesis, glucose is taken up by astrocytes and converted to lactate, which is then oxidized by neurons. Here we show, using 2-photon imaging of a near-infrared 2-deoxyglucose analogue (2DG-IR), that glucose is taken up preferentially by neurons in awake behaving mice. Anesthesia suppressed neuronal 2DG-IR uptake and sensory stimulation was associated with a sharp increase in neuronal, but not astrocytic, 2DG-IR uptake. Moreover, hexokinase, which catalyze the first enzymatic steps in glycolysis, was highly enriched in neurons compared with astrocytes, in mouse as well as in human cortex. These observations suggest that brain activity and neuronal glucose metabolism are directly linked, and identifies the neuron as the principal locus of glucose uptake as visualized by functional brain imaging.

Low cerebral glucose extraction rates in the human medial temporal cortex and cerebellum

Previous studies have reported that there exist different regional sensitivities to acute hypoxia. To better understand these differences, we estimated regional differences of cerebral blood flow (CBF), cerebral glucose metabolism (CMRglc) and kinetic constants (K(1), k(2), k(3)) in the human cortex under resting conditions. CBF, CMRglc, kinetic rate constants and glucose extraction rate (GER) were measured in eight normal male subjects (mean age: 26.1+/- 4.9 years) using the 15O-water autoradiographic technique and subsequently the dynamic and the static [18F]2-fluoro-2-deoxy-D-glucose technique with positron emission tomography (PET). Of all the brain structures investigated, the medial temporal lobe showed the lowest CBF (46.0 ml/100 g/min) and lowest CMRglc (3.97 mg/100 g/min). The medial temporal GER was lowest (8.9%), followed by the cerebellar GER (9.3%). While the cerebellar blood flow (64.0 ml/100 g/min) was the highest, the cerebellar metabolic rate for glucose (5.79 mg/100 g/min) was relatively low. The cerebellum showed the highest K(1) value (0.13) and k(2) value (0.16), and the lowest k(3) value (0.05). In the medial temporal cortices and cerebellum, CMRglc and GER were lower than those in the neocortices. These results indicate that there are great perfusional/metabolic differences between the medial temporal lobe, cerebellum and other brain regions in the normal human brain under resting conditions.

Compartment analysis of cerebral glucose metabolism and in vitro glucose-metabolizing enzyme activities in the rat brain

To clarify the relationship between cerebral glucose metabolic rate constants and glucose-metabolizing enzyme activities in the cerebral cortex, we evaluated the cerebral metabolic rate of glucose (CMRGlu), metabolic rate constants of [18F]-2-fluoro-2-deoxy-D-glucose (FDG) and related enzyme activities in the frontal cortex under normal and glucose metabolism-suppressed conditions. Applying a three-compartment four-parameter model, metabolic rate constants were obtained by dynamic positron emission tomography with FDG, and CMRGlu was calculated based on these rate constants. The glycolytic enzyme activities were determined by in vitro biochemical assay. Three days after ibotenic acid injection into the basal forebrain, CMRGlu was decreased in the ibotenic acid-treated frontal cortex as well as k3* (phosphorylation), while K1* (plasma to brain) showed no remarkable change. No significant reductions of the enzyme activities except for hexokinase activity were found in the frontal cortex. Regression analysis showed a significant positive correlation between k3* and the hexokinase activity. These results suggested that k3* in the compartment analysis reflects hexokinase activity.

Hexokinase levels in discrete regions of rat brain: evaluation by quantitative immunofluorescence 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.

Effects of kainate on glucose metabolising enzymes in the brain

Hexokinase and glucose-6-phosphate dehydrogenase activities were studied in brain regions after intraventricular injection of kainic acid. Hexokinase activity was decreased by 10-15% in various regions while glucose-6-phosphate dehydrogenase activity remained unaltered. Soluble hexokinase activity, which remained the smaller fraction of total hexokinase activity, showed slightly more dramatic decreases of 15-35% compared to normal activities in brain regions. This decrease of hexokinase activity in the cytosolic compartment could partly account for the kainate-induced decreases seen in glucose metabolism.

Glucose-6-phosphate dehydrogenase activity in the olfactory system of the young rat: an enzyme histochemical study using computerized image analysis

An understanding of olfactory system glucose metabolism is necessary for the interpretation of radiolabeled 2-deoxyglucose studies of odor processing since the relationship between glucose uptake and neural activity is based on assumptions regarding cellular glucose utilization. As part of an ongoing study examining divergent pathways of glucose metabolism in the olfactory system, the relative activity of glucose-6-phosphate dehydrogenase, the rate-limiting enzyme of the hexose monophosphate shunt, was examined among cells of the rat olfactory bulb and anterior olfactory nucleus, by using enzyme histochemistry on fresh frozen tissue. Optical density measurement of formazan reaction product in stained tissue were quantified by computerized image analysis. To aid in the identification of histochemically stained neurons, alternate sections were Nissl-stained. The highest olfactory bulb dehydrogenase levels were found in the olfactory nerve and glomerular layers. Individual mitral and tufted cells also showed high dehydrogenase activity. In most stained neurons, formazan reaction product filled the cytoplasm and sometimes extended into the proximal part of dendrites and axons. The external plexiform and granule cell layers had low enzyme activity. High activity also was seen in pyramidal cells of pars dorsalis and pars lateralis of the anterior olfactory nucleus, one of the first, and most rostral of the olfactory bulb projection sites. High glucose-6-phosphate dehydrogenase activity in the olfactory system indicates that a significant amount of glucose can be channeled through the hexose monophosphate shunt in these neurons, with a concomitant production of NADPH. This may reflect high activity of cellular detoxification enzymes that rely on NADPH for reducing power. Such detoxification processes may be engaged in response to the potential entry and transsynaptic movement of airborne chemicals into the brain via the olfactory system.