Gene/Protein Disease Symptom Drug Enzyme Compound
Pivot Concepts:   Target Concepts:
Query: EC:1.9.3.1 (cytochrome oxidase)
 8,822 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

The brindled mouse (Mobr) is a neurological mutant mouse with clinical and biochemical features closely similar to Kinky hair syndrome (KHS) in humans. Neuronal degeneration in the cerebral cortex and thalamic nuclei was the constant neuropathological lesions in the CNS of the male hemizygotes of this mutant (Yajima and Suzuki, 1978). Ultrastructurally, many cortical neurons contained enlarged mitochondria with prominent tubular or vesicular cristae, which were similar to those described in the Purkinje cells in the human KHS (Ghatak et al., 1972) and in the rat brain with copper deficiency (Prohaska and Wells, 1975). Such mitochondria were observed not only in the degenerating neurons but even in the otherwise normal-appearing cortical neurons, suggesting that the mitochondrial damage possibly related to the deficient activities of the copper containing enzymes (cytochrome oxidase, etc.) preceded the neuronal degeneration. Many mitochondria in the severely degenerated neurons contained numerous electron dense spicules of possible calcium. Although rare, similar morphological alteration of neuronal mitochondria was also noted in the female heterozygotes, indicating the presence of possible subclinical defect in copper transport in the heterozygotes as well.
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PMID:Neuronal degeneration in the brain of the brindled mouse. An ultrastructural study of the cerebral cortical neurons. 76 Mar 62

Neuronal activity has been shown to influence pattern formation in the visual system. In the present study, we determined whether or not this was also true in the somatosensory system by silencing the primary somatosensory cortex of rats with tetrodotoxin (TTX) for the first 7-11 days of life. Application of TTX during this period did not prevent the formation of the normal vibrissa-related pattern in S-I as visualized by either staining cortical sections for cytochrome oxidase, demonstration of the pattern with an antibody directed against serotonin, or labelling of thalamocortical axons with the carbocyanine dye, Di-I. These results indicate that neither peripherally evoked nor spontaneous activity are required for qualitatively normal pattern formation in the rat's primary somatosensory cortex.
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PMID:Postnatal blockade of cortical activity by tetrodotoxin does not disrupt the formation of vibrissa-related patterns in the rat's somatosensory cortex. 131

Neuronal activity and oxidative energy metabolism are tightly coupled. There is evidence that cytochrome oxidase, the terminal enzyme of the electron transport chain, can serve as a metabolic marker of neuronal activity. All the respiratory chain enzymes have iron containing prosthetic groups and therefore represent an important component of iron utilisation. Since iron entry into cells is mediated by the transferrin receptor, this receptor may also serve as marker of neuronal activity. The histochemical distribution of cytochrome oxidase has therefore been compared with the autoradiographic distribution of the transferrin receptor in the human spinal cord, brainstem and cerebellum. Cytochrome oxidase activity showed a very similar pattern of distribution to the transferrin receptor in the spinal cord, brainstem and cerebellum. The highest levels of cytochrome oxidase activity and transferrin receptor binding were associated with; in the spinal cord, the substantia gelatinosa, laminae II and III and the motor neurones; in the medulla and pons, the spinal trigeminal nucleus, hypoglossal nucleus, dorsal motor nucleus of the vagus, inferior and superior olives, nucleus praepositus, nucleus paramedianus, central grey, superior central nuclei and locus coeruleus; in the cerebellum, the molecular layer. The results suggest that the transferrin receptor may provide a useful marker of total neuronal respiratory activity.
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PMID:Distribution of transferrin receptors in relation to cytochrome oxidase activity in the human spinal cord, lower brainstem and cerebellum. 133 38

Histochemical detection of cytochrome oxidase activity has been widely used to deduce patterns of neuronal electrical activity in the CNS. Here we investigated the utility of cytochrome oxidase localization by immunohistochemistry and compared immunostaining with histochemical staining patterns in dorsal root ganglia of the rat. In addition, a limited survey of cytochrome oxidase immunostaining density within what are thought to be highly active parvalbumin-immunoreactive neurons was conducted. The immunohistochemical approach produced granular cytoplasmic immunolabelling in neuronal cell bodies and allowed identification of individual labelled cells in all brain regions including those within dense immunoreactive networks of neuropil. Neuronal somata exhibited a wide range of staining densities which were particularly evident in the hippocampus and dorsal root ganglia. The distribution of neurons intensely immunoreactive for cytochrome oxidase within various structures was consistent with previous histochemical descriptions of enzyme activity. Densitometric measurements of immunohistochemical reaction product in individual neurons of hippocampus, substantia nigra, cerebellum and dorsal root ganglia showed that the rate of product deposition was linear with time under conditions chosen for comparisons of staining density. Quantitative analysis of cytochrome oxidase immunohistochemical and histochemical staining densities within the same cells in adjacent sections of dorsal root ganglion gave a correlation coefficient of r = 0.75 (P less than 0.001). In sections processed immunohistochemically for both cytochrome oxidase and parvalbumin, most but not all parvalbumin-containing cells displayed dense cytochrome oxidase immunolabelling. Conversely, many examples were found of neurons that were densely stained for cytochrome oxidase, but lacked parvalbumin. Immunohistochemistry for cytochrome oxidase reveals the enzyme in neuronal cell bodies with a clarity not usually seen with the histochemical method. Combination of this immunohistochemical approach with simultaneous immunolabelling of other neuronal markers, as shown here in the case of parvalbumin, is expected to assist the elucidation of patterns of activity in neurochemically identified cell types and anatomically defined neural systems.
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PMID:Cytochrome oxidase immunohistochemistry in rat brain and dorsal root ganglia: visualization of enzyme in neuronal perikarya and in parvalbumin-positive neurons. 164 84

The distribution of cytochrome oxidase (C.O.) was examined in the normal adult cat lateral geniculate nucleus at the cellular and electron-microscopic levels. The darker reactivity of the X- and/or Y-receptive laminae (A, A1, magnocellular lamina C [Cm], and medial interlaminar nucleus [MIN]) compared with the lightly reactive W-receptive parvicellular lamina C (Cp) indicates that there are pathway-specific histochemical differences in the visual system of the cat. At the cellular level, darkly reactive large cells in the lateral geniculate nucleus (LGN) closely resemble class 1, Y-cells, in relative size and distribution, thus indicating that C.O. histochemistry may be used as a functional marker for these cells. Perigeniculate neurons are also darkly reactive. Neuronal classes 2, 4, and 3 (presumed X-cells, W-cells, and/or interneurons) have moderate to lightly reactive perikarya. The darkly reactive neuronal classes tend to receive relatively stronger proximal excitatory synaptic input than do the less reactive neuronal classes. Since all neuronal classes appeared to have darkly (or moderately) reactive dendrites, C.O. reactivity must differ between dendrite and soma of some neuronal classes. At the electron-microscopic level, distinct components of the neuropil tend to have specific levels of C.O. reactivity. The predominance of darkly reactive mitochondria in dendrites indicates that dendrites are metabolically very active. RLD and may F's, but few large axon terminals with round vesicles (RL) or small axon terminals with round vesicles (RS) profiles are darkly reactive, implying that specific classes of presynaptic structures are more active than others. Thus C.O. histochemistry may be useful for distinguishing not only functionally active neuronal classes such as Y-cells and perigeniculate (PG) neurons from less active neuronal classes, but also functionally more or less active parts of the same neuron including its dendrites, axons, and/or axon terminals.
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PMID:An analysis of the cellular localization of cytochrome oxidase in the lateral geniculate nucleus of the adult cat. 241 75

Neuronal cell bodies and synaptic terminals positive for glutamic acid decarboxylase, the enzyme responsible for synthesizing gamma-amino butyric acid, have been located by immunocytochemical staining in all layers of the macaque monkey cortex. In layers II and III the staining pattern of periodic dots is identical with that seen in sections stained for cytochrome oxidase. The rows of dots run parallel with the ocular dominance columns, suggesting that the labelled neurones are preferentially related to each eye.
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PMID:Immunocytochemical localization of glutamic acid decarboxylase in monkey striate cortex. 626 4

The Golgi and Nissl methods and cytochrome oxidase (CO) histochemistry were used to study the overall structure and neuronal morphology of the lateral geniculate nucleus (LGN) of the Black Sea porpoise (Phocoena phocoena). Differences were observed between dorsal and ventral portions of the nucleus in terms of cell size and CO staining. In addition to prominent fibre bundles crossing the LGN horizontally, vertically oriented variations of CO staining were apparent. Neuronal types in the LGN corresponded broadly to those observed in land mammals. The commonest were variants of multipolar cells, and may represent thalamocortical relay cells. Various other types were probably interneuronal.
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PMID:Neuronal morphology in the lateral geniculate nucleus of the porpoise (Phocoena phocoena). 839 34

The relationship between neuronal activity, intracellular oxygenation and energy metabolism in the cerebrum and the brainstem-cerebellum of the rat brain in graded hypoxia was studied. Intracellular oxygenation was monitored by near-infrared measurement of the redox state of cytochrome oxidase (cyt.ox.). Neuronal activity was assessed by EEG (electroencephalography) and the evoked potentials (VEP; visual, BSR; brainstem, C-SEP; cortical-sensory, S-SEP; spinal-sensory evoked potentials). As hypoxia progressed, neuronal activities disappeared in the order of VEP, C-SEP, EEG, BSR, S-SEP. However, intracellular oxygenation at the disappearance of each neuronal activity was significantly lower in the brainstem-cerebellum than in the cerebrum. ATP (adenosine triphasphate), glucose, and lactate were measured in the cerebral cortex, subcortex, brainstem, and cerebellum 1-2 minutes after the disappearance of neuronal activities on EEG. Hypoxia caused decreases in ATP in each brain region. Marked increases in lactate were observed in each brain region, though the degree of increment was less in the cerebral cortex than the other brain regions. A decrease in glucose was observed only in the cerebral cortex. These results suggest that by the use of the energy generated via glycolysis, the brainstem functions even after oxygen supply has been significantly reduced, while the neuronal activity in the cerebrum is suppressed at the higher oxygenation level than that in the brainstem-cerebellum. It is, thus, supposed that these differential responses of brainstem and cortical neurons to oxygen deprivation are inherent, and critical for neuronal survival in severe hypoxia.
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PMID:[Energy metabolism in the cerebrum and the brainstem-cerebellum of the rat brain under hypoxic conditions]. 1064 90

Activated microglia are implicated in the injury of neurones and macroglia both in vitro and in vivo. Here, we demonstrate that media conditioned by interferon-gamma treated microglia initially impair the metabolism of mouse cerebellar neurones grown in serum-free conditions without inducing cell death. Metabolic effects include inhibition of the ability of mitochondria to reduce 3-[4,5-dimethylthiazol-2-yl]-2,5-diphenyltetrazolium bromide (MTT) and cytochrome oxidase activity. These effects are blocked by antibodies to tumour necrosis factor-alpha (TNFalpha), a cytokine produced by microglial activation, and they are not reproduced by media conditioned by resting microglia. The metabolic effects are evident for up to 24 h in vitro. More prolonged exposure, up to 48 h, results in TNFalpha dependent neuronal death as previously observed. Between 2 and 48 h TNFalpha present in media conditioned by interferon-gamma treated but not resting microglia is associated with nuclear factor kappa B (NF-kappaB) consensus sequence binding in paired mouse cerebellar neuronal cultures without affecting activation of the signal transducer and activator of transcription (STAT) transcription factor. Neuronal death can be accelerated by peptide blockade of the nuclear transport of NF-kappaB p52 subunit during exposure of cerebellar neurones to medium from interferon-gamma treated microglia. This toxicity is blocked by anti-TNFalpha antibody. Soluble factors released by activated microglia therefore contribute to neuronal dysfunction that is initially reversible but may culminate in neurotoxicity. Characterizing and manipulating these events in vivo theoretically provides an opportunity for neuroprotection in selected diseases affecting the central nervous system.
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PMID:Inhibition of tumour necrosis factor-alpha (TNFalpha)-induced NF-kappaB p52 converts the metabolic effects of microglial-derived TNFalpha on mouse cerebellar neurones to neurotoxicity. 1123 28

Using the monkey as a model for human hemispherectomy, the effects of early removal of a whole cerebral hemisphere on the cytoarchitecture and cytochrome oxidase histochemistry of the superior colliculus (SC) were evaluated. Results show that the SC ipsilateral to the cortical lesion suffers a 29.9% average volume reduction and a 32.7% total loss of neurons compared to the contralateral SC. Neuronal densities and metabolic activity are similar in normal and hemispherectomized monkeys. Furthermore, the ipsi- and contralesional SC receive retinal inputs as revealed with intraocular injections of tritiated proline. These data suggest that the superior colliculus retains functional capabilities following hemispherectomy in monkey.
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PMID:Anatomical sparing in the superior colliculus of hemispherectomized monkeys. 1125 Dec 1


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