Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: EC:3.1.4.37 (CNPase)
 539 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Seven cell specific marker enzymes in brain and optic nerve and morphological evaluation by light microscopy were used to characterize the neurotoxicity associated with exposure of rats to hexachlorophene (HCP; 40 mg/kg/day, po, for 9 days). In vitro exposure to HCP at concentrations up to 100 microM had no direct inhibitory effect on the marker enzymes, validating their use in evaluating brain function in vivo. Rats exhibited a reduction in body weight gain, weakness, and ataxia of the hind limbs by the ninth day of HCP exposure. At 24 hr following the last day of exposure to HCP, the activities of the three neuron specific enzymes, glutamic acid decarboxylase, tyrosine hydroxylase, and choline acetyltransferase, in rat brain were unchanged from those of the vehicle-treated control group. Of the two astroglial enzyme markers measured, a small but significant increase was observed in the activity of nonneuronal enolase in the cerebellum and glutamine synthetase in the hippocampus of HCP-treated rats. The optic nerve appeared to be the most sensitive tissue in that the activity of both the astroglial marker, nonneuronal enolase, and the myelin marker, 2',3'-cyclic nucleotide phosphohydrolase, was significantly decreased following HCP exposure. This decrease in enzyme activity is consistent with the histological observations demonstrating extensive vacuolization and edema in the optic nerve after exposure to HCP.
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PMID:Effect of short-term exposure to hexachlorophene on rat brain cell specific marker enzymes. 290 23

In order to define the locus of acrylamide neurotoxicity, the effects of chronic intoxication (total dose 500 mg/kg) on cholinergic synthesis and transport, the Schwann cell-myelin complex, lysosomal activity, and several metabolic pathways were determined in rat sciatic nerve, spinal cord, and brain. No changes were found in hematological measures or in the levels of clinically important blood enzymes, indicating no major damage to other organs. The activities of choline acetyltransferase (ChAT), 2',3'-cyclic nucleotide phosphohydrolase, beta-glucuronidase, and lactate dehydrogenase were unaffected in acrylamide paralyzed animals, but creatine kinase (CK) decreased in sciatic nerve, muscle, and brain, particularly in animals dying of the intoxication. CK blood and the CK isoenzyme patterns in blood were unchanged. The synthesis of protein in brain and spinal cord (measured in vivo) were decreased in rats exposed to high-dose acrylamide. However, in brain and cord, CK decreased only after animals became systemically ill and suffered weight loss, with the lowest activities in those animals sick enough to die. The degree of stress to which the animals had been subjected was indicated by enlargement of the adrenal glands and decreased sulfolipid synthesis in the adrenals. Rats exposed to 25 mg/kg/day acrylamide to a total dose of 250 mg/kg developed leg weakness but not paralysis or weight loss and had a 25% decrease in CK only in the distal sciatic nerve. Because of the apparently stress-related or agonal loss of CK, no specific effect of acrylamide on the enzyme could be definitely demonstrated. Neither could the changes in protein synthesis be attributed solely to a direct effect of the toxin. These results illustrate the difficulties encountered in interpreting intoxication studies that produce systemic illness and support the suggestion that CK activity may be a useful marker of the severity and duration of the agonal state in studies of postmortem human brain.
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PMID:The influence of systemic factors on acrylamide-induced changes in brain, nerve, and other tissues. 608 44