Effect of Oxotremorine on Ornithine Decarboxylase Activity of the Adrenal Gland in Rat

Abstract: In this work we have studied the mechanism for the increase of adrenal ODC (ornithine decarboxylase, EC 4.1.1.17) activity provoked by oxotremorine, a muscarinic agonist. 1. Oxotremorine increased medullary ODC activity maximally at 2 h. Cortical enzyme responded much more slowly. 2. Blockade of peripheral muscarinic receptors with methylatropine partially reduced the response to oxotremorine in the medulla, but not cortex. 3. Hy-pophysectomy abolished the cortical, but not the medullary, responses to oxotremorine. Methylatropine reduced the effect of oxotremorine on medullary ODC in hypophysectomized rats. 4. In unilaterally splanchnicotomized rats oxotremorine caused an increase of ODC activity of the denervated adrenal gland relative to control value; activities in both medulla and cortex were significantly lower than those observed in the innervated gland. Evidence was obtained for a compensatory increase of ODC activity of the adrenal cortex (but not medulla) on the intact side of unilaterally operated rats. 5. Surgical intervention, in the form of a sham operation for transection of the spinal cord, leads to an increase of ODC activity in both parts of the adrenal gland. Transection of the cord attenuates these increases. 6. The additional increase of medullary ODC activity owing to the administration of oxotremorine to sham-operated rats is partially reduced in the adrenal medulla by muscarinic blockade, and completely in the cortex. This effect of methylatropine in regard to cortical ODC activity was not apparent in the other experiments with intact or unilaterally splanchnicotomized (unoperated side) rats. The results with unilaterally splanchnicotomized rats and those with transected spinal cord suggest that oxotremorine-induced modifications of adrenal ODC activity are centrally mediated, above the level of origin of the splanchnic nerves in the spinal cord (T_8–10). Experiments with hypophysectomized rats show that the response of the adrenal cortex to oxotremorine is entirely mediated by the hypophysis.     

Monoamine oxidase of rat skeletal muscle: substrate specificity and half-life

The substrate specificity of rat skeletal muscle MAO has been studied. By the use of clorgyline as a MAO A inhibitor, it is found that 5-hydroxytryptamine, tryptamine, and kynuramine are deaminated by MAO A whereas benzylamine is a substrate for both forms of MAO. Phenethylamine displays a concentration-dependent preference for the two forms of MAO. These substrate specificies of the two forms of MAO in skeletal muscle are different from those observed in liver and brain but resemble closely that seen with heart. The half-lives of MAO A and MAO B in muscle estimated by rate of recovery from pargyline inhibition are 6.9 and 6.4 days, respectively.     

ACTIVITY OF ALDEHYDE DEHYDROGENASE, ALDEHYDE REDUCTASE, AND ACETYLCHOLINE ESTERASE IN STRITATUM OF RATS BEARING ELECTROLYTIC LESIONS OF THE MEDIAL FOREBRAIN BUNDLE

A number of enzymes have been measured in the striatum of rats in which the dopamine-containing nerve terminals had been unilaterally destroyed by means of unipolar electrolytic lesions of the medial fore-brain bundle. Fourteen and 28 days after such lesions the tyrosine hydroxylase activity of the striatum was reduced to immeasurably low values, but neither aldehyde dehydrogenase, aldehyde reductase, nor acetylcholine esterase was affected when compared with the striatum from the intact side of the same rat or with those from control rats. These results indicate that in the rat the 3 enzymes are not localized with tyrosine hydroxylase, in the dopaminergic nerve terminals of the striatum. This conclusion is supported by a study of the subcellular localization of aldehyde dehydrogenase in rat brain. This enzyme is distributed between the cytosol and the particulate fraction of brain homogenates separated by centrifugal techniques. with no exceptionally high concentration of the enzyme in the synaptosomal fraction. Because neither of the enzymes of post-deaminative catabolism of dopamine is concentrated in the dopaminergic nerve terminals of the striatum of the rat, it is proposed that in this species the amine is not necessarily taken up by the nerve terminals prior to catabolism.     

SOME ENZYMIC ASPECTS OF THE PRODUCTION OF OXIDIZED OR REDUCED METABOLITES OF CATECHOLAMINES AND 5-HYDROXYTRYPTAMINE BY BRAIN TISSUES

The Michaelis constants of purified aldehyde dehydrogenase (aldehyde: NAD oxidoreductase, EC 1.2.1.3) and aldehyde reductases (alcohol: NADP oxidoreductase, EC 1.1.1.2) from pig brain have been obtained for a number of biologically important aldehydes. The aldehydes include 3,4-dihydroxyphenylacetaldehyde, D-3,4-dihydroxyphenylglycolaldehyde, and 5-hydroxyindoleacetaldehyde. The relative activities of the aldehyde-catabolizing enzymes in the soluble fractions of the cerebral cortex and caudate nucleus of pig brain have also been obtained. The values are used to show that the metabolic fates of the various aldehydes—and hence of the parent amines—may be explained in terms of the simple kinetics of these enzymes. It is also shown that the metabolic fates of the aldehydes may be influenced by their rates of synthesis. As the rate of aldehyde production increases the proportion of aldehyde reduced may be expected to increase at the expense of the proportion of aldehyde oxidized. It is further concluded from the kinetic constants that selective inhibition of aldehyde dehydrogenase may greatly affect the catabolism of dopamine and 5-hydroxytryptamine by altering the relevant aldehyde concentrations, while the catabolism of norepinephrine is little affected under these circumstances. Conversely, it is concluded that selective inhibition of the aldehyde reductases should scarcely affect the catabolism of dopamine and 5-hydroxytryptamine, but that the catabolism of norepinephrine should be markedly affected. The results also indicate that the concentrations of the various deaminated metabolites of the biogenic amines could be selectively controlled by modulation of the activity of the enzymes of aldehyde catabolism in brain.