Stress-induced alterations of immunity in hypophysectomized rats.

Stress-induced suppression of mitogen-induced lymphocyte proliferation was demonstrated in hypophysectomized rats. Stress effects on the numbers of peripheral blood lymphocytes and lymphocyte subsets and on splenic natural killer cell activity require the presence of pituitary. A pituitary-dependent restraining influence on stress-induced alteration of immunity is described. These results indicate that stress-induced modulation of immunity is complex and includes a range of enhancing and inhibitory mechanisms.

Food deprivation dissociates pancreatic glucagon's effects on satiety and hepatic glucose production at dark onset.

We compared the effects of different durations of pretest food deprivation on pancreatic glucagon's (PG) satiating and glycogenolytic actions in order to test the hypothesis that stimulation of hepatic glucose production causes PG's satiety effect. Rats were maintained on a 12:12 LD cycle (lights off: 1015) and deprived of food 45 min or 8, 12, 18, or 24 hr before intraperitoneal injection of 400 micrograms/kg PG. Testing began at 1015, the beginning of the dark phase. Food intake was not inhibited after 45 min of pretest food deprivation (30 min change, 2.5 +/- 4.0%, p greater than 0.05), but was inhibited after 8 or more hr food deprivation. The largest inhibitory effect, 16.2 +/- 3.8%, p less than 0.01, occurred after 8 hr food deprivation. In separate experiments, rats were food deprived 45 min or 8 hr, similarly injected, and killed 10 min after refeeding for blood and liver samples. Hepatic glycogen content at meal onset was higher in rats deprived 45 min than in rats deprived 8 hr (3.2 +/- 0.3 vs. 1.7 +/- 0.3% liver weight, p less than 0.01), and PG injection produced a higher level of hepatic vein blood glucose in the less deprived rats (196 +/- 5 vs. 168 +/- 12 mg/dl, p less than 0.05). Thus, in rats tested at the beginning of the dark phase of the LD cycle after 45 min or 8 hr food deprivation, there is an inverse relation between PG's potencies to inhibit food intake and to stimulate hepatic glucose production.(ABSTRACT TRUNCATED AT 250 WORDS)

Epinephrine inhibits feeding nonspecifically in the rat.

The hypothesis that epinephrine (EPI) and pancreatic glucagon (PG) inhibit feeding by activating a common physiological satiety mechanism was tested by comparing the two agents' behavioral effects. In several tests of specificity, EPI and PG had functionally different inhibitory actions. Intraperitoneal injection of 6.25-50 micrograms/kg EPI and 100-400 micrograms/kg PG elicited overlapping dose-related inhibitions of intake of milk diet in rats maintained ad lib on pelleted chow. Twenty-five to 50 micrograms/kg EPI also elicited anomalous behaviors that are not normally associated with feeding, including supine postures with limbs extended and crawling with trunk dorsoflexed and abdomen pressed against cage floor. EPI elicited similar anomalous behaviors in rats that either sham fed with open gastric cannulas, drank after water deprivation, or were presented neither food nor water. Fifty to 200 micrograms/kg EPI also inhibited water intake in the thirsty rats, and 25-50 micrograms/kg EPI inhibited sham feeding. PG, in contrast, neither elicited anomalous behaviors nor inhibited water intake nor inhibited sham feeding. These data demonstrate that the inhibitory actions of exogenous EPI and PG are functionally dissociable. We conclude that 25-200 micrograms/kg EPI acts nonspecifically to produce anorexia and adipsia, while PG elicits postprandial satiety.