A. C. Sullivan

The effect of diet and chronic obesity on brain catecholamine turnover in the rat

Male Sprague-Dawley rats were fed a high calorie, high fat diet for 3 months to produce chronic diet-induced obesity (DIO) in which they gained 70% more weight than chow-fed controls. Thirty-six percent of the rats fed the DIO diet resisted the development of obesity (DR), gaining no more weight than chow-fed controls but serving as a comparison for the effects of the diet alone on the metabolism of brain catecholamines. The major influence of dietary composition was upon norepinephrine (NE) metabolism. Both DIO and DR rats had increased turnover of NE (107-217%) and/or shorter NE half-lives (42-67%) than controls in the hypothalamic paraventricular (PVN) and dorsomedial (DMN) nuclei and the median eminence (ME); dopamine (DA) turnover was similarly accelerated in the PVN. The DR rats alone exhibited decreased NE levels with increased disappearance of NE in frontal cortex and increased disappearance of DA in the ventromedial hypothalamic nucleus (VMH). The major effect of chronic obesity alone was a 31-33% decrease in DMN DA turnover and an 80% decrement in ME DA turnover associated with a 61% decrease in DA levels as compared to chow-fed controls. Therefore, the major effect of a high calorie, high fat diet was a diffuse acceleration of brain NE and DA turnover while chronic obesity led to decreased DA turnover in the DMN and ME.

Metabolic and sympatho-adrenal abnormalities in the obese zucker rat: Effect of chronic phenoxybenzamine treatment

The obese Zucker rat manifests a number of physiologic and metabolic abnormalities which are controlled or modulated by the sympatho-adrenal system. The interrelationship of these was examined by subjecting 3-4 month old male, homozygous lean and obese Zucker rats to various stresses which are known to activate the sympatho-adrenal system, and by chronic (16-19 days) phenoxybenzamine (PBZ) treatment to block alpha-adrenergic receptors. Both obese and lean PBZ treated rats gained only 1% and 10% of the body weight of their respective control rats during the treatment period, while only the lean rats had a significant reduction (20%) in food intake. Control obese rats failed to maintain rectal temperature after 4 hr at 7 degrees C and their relative output of plasma catecholamines (CA) to cold stress, as measured from indwelling atrial cannulae, was decreased. PBZ treatment did not alter this rectal temperature response although it was associated with increased baseline norepinephrine levels (at ambient temperature 21-22 degrees C) and relative output of CA in the obese rats, suggesting tat sympathetic neural activity was increased under these circumstances. No abnormalities of sympatho-adrenal function, as reflected in plasma CA levels, were found in treated or control obese rats immobilization for 1 hr followed by decapitation. Simultaneously obtained baseline plasma glucose levels were similar in untreated lean and obese rats, but insulin and glycerol levels in the obese rat were 1350% and 213% of lean values, respectively. During sequential stresses, the obese rats became markedly hyperglycemic and hyperglycerolemic compared to the lean rats, while insulin levels were decreased more in the obese than lean rats (12-15% versus 34-35% of controls, respectively). PBZ affected insulin levels only in the obese rats, reducing their baseline levels by 4-fold and stressed induced levels to those seen in the lean control rats. These results suggest that some of the metabolic and physiologic abnormalities of the obese Zucker rat which are modulated by the sympatho-adrenal system can be normalized by procedures which increase sympatho-adrenal activity.