Masoprocol decreases serum triglyceride concentrations in rats with fructose-induced hypertriglyceridemia.

Historically, extracts of the creosote bush have been used by native healers of the Southwest region of North America to treat symptoms of type 2 diabetes. More recently, we have shown that masoprocol (nordihydroguaiaretic acid), a pure compound isolated from the creosote bush (Larrea tridentata), decreases serum glucose and triglyceride (TG) levels when administered orally in rodent models of type 2 diabetes. The present studies were undertaken to determine if masoprocol also decreases TG concentrations in rats with fructose-induced hypertriglyceridemia (HTG), a nondiabetic model of HTG associated with insulin resistance and hyperinsulinemia. Serum TG levels, which were significantly higher after rats ate a fructose-enriched (60% by weight) diet for 14 days as compared with chow-fed controls (411 v 155 mg/dL, P < .01), decreased in a stepwise fashion in fructose-fed rats treated orally with masoprocol for 4 to 8 days over a dose range of 10 to 80 mg/kg twice daily. Using the nonionic detergent Triton WR 1339 to compare TG secretion rates in masoprocol- and vehicle-treated rats, masoprocol at a dose of 40 or 80 mg/kg twice daily, significantly reduced hepatic TG secretion (P < .01) and liver TG content (P < .001), whereas lower doses of masoprocol decreased serum TG without an apparent reduction in hepatic TG secretion. Administration of Intralipid (a fat emulsion) showed that the half-time for removal of TG from serum was also shorter in masoprocol-treated rats versus vehicle-treated controls (31 v 64 minutes, P < .05). In addition adipose tissue lipoprotein lipase (LPL) activity was increased in masoprocol-treated rats and adipose tissue hormone-sensitive lipase (HSL) activity was decreased. We conclude that masoprocol administration to rats with fructose-induced HTG results in lower serum TG levels associated with reduced hepatic TG secretion and increased peripheral TG clearance.

Streptozotocin-diabetic rats exhibit facilitated adrenocorticotropin responses to acute stress, but normal sensitivity to feedback by corticosteroids.

A variety of chronic stress paradigms have been shown to increase basal activity in the hypothalamic-pituitary-adrenocortical axis, resulting in hypercorticoidism. Despite this, chronically stressed rats typically exhibit facilitated ACTH responses to acute novel stress, suggesting that the activity of some central neural component(s) in the axis is facilitated by chronic stress. We have used the chronic stress of streptozotocin (STZ)-induced diabetes in rats to determine diurnal sensitivity of basal and stimulated ACTH secretion to exogenous corticosterone (B) feedback in vivo. Control and STZ-diabetic rats were adrenalectomized or adrenalectomized and implanted with a 30% or 50% B pellet at the time of vehicle/STZ injection. Rats were killed 5 days later, under basal conditions or after 6 min of restraint, in the morning or evening. We show that basal ACTH secretion in both the morning and evening was similarly suppressed by B in STZ-diabetic and control rats. However, stress-induced ACTH secretion was significantly greater in STZ-diabetic compared to control rats throughout the range 3-7 micrograms/dl B, when tested in the morning. Suppression of evening stress-induced ACTH secretion by B was also significantly different in STZ-diabetic rats; however, the IC50 values for the inhibition of ACTH by B did not differ. This result shows that in the evening after stress and under basal conditions in both the morning and evening, sensitivity to B feedback is normal in chronically stressed, STZ-diabetic rats. Despite the observed facilitation of morning stress-induced ACTH secretion in STZ-diabetic rats, there were no differences in hypothalamic CRF content between control and STZ-diabetic tissue. We conclude that 1) the facilitatory input to the paraventricular nucleus functions primarily at the time of the circadian trough to maintain or enhance acute stress responsiveness in chronically stressed, hypercorticoid rats; and 2) the sensitivity of ACTH to inhibition by B is normal in rats chronically stressed by STZ-induced diabetes.

Feast and famine: critical role of glucocorticoids with insulin in daily energy flow.

The hypothesis proposed in this review is that normal diurnal rhythms in the hypothalamic-pituitary-adrenal (HPA) axis are highly regulated by activity in medial hypothalamic nuclei to effect an interaction between corticosteroids and insulin such that optimal metabolism results in response to changes in the fed or fasted state of the animal. There are marked diurnal rhythms in function of the HPA axis under both basal and stress conditions. The HPA axis controls corticosteroid output from the adrenal and, in turn, forward elements of this axis are inhibited by feedback from circulating plasma corticosteroid levels. Basal activity in the HPA axis of mammals fed ad lib peaks about 2 h before the peak of the diurnal feeding rhythm, and is controlled by input from the suprachiasmatic nuclei. The rhythm in stress responsiveness is lowest at the time of the basal peak and highest at the time of the basal trough in the HPA axis activity. There are also diurnal rhythms in corticosteroid feedback sensitivity of basal and stress-induced ACTH secretion which peak at the time of the basal trough. These rhythms are all overridden when feeding, and thus insulin secretion, is disrupted. Corticosteroids interact with insulin on food intake and body composition, and corticosteroids also increase insulin secretion. Corticosteroids stimulate feeding at low doses but inhibit it at high doses; however, it is the high levels of insulin, induced by high levels of corticosteroids, that may inhibit feeding. The effects of corticosteroids on liver, fat, and muscle cell metabolism, with emphasis on their interactions with insulin, are briefly reviewed. Corticosteroids both synergize with and antagonize the effects of insulin. The effects of stress hormones, and their interactions with insulin on lipid and protein metabolism, followed by some of the metabolic effects of injury stress, with or without nutritional support, are evaluated. In the presence of elevated insulin stimulated by glucocorticoids and nutrition, stress causes less severe catabolic effects. In the central nervous system, regulation of function in the HPA axis is clearly affected by the activity of medial hypothalamic nuclei that also alter feeding, metabolism, and obesity in rats. Lesions of the arcuate (ARC) and ventromedial (VMN) paraventricular (PVN) nuclei result in obesity and hyperactivity in the HPA axis. Moreover, adrenalectomy inhibits or prevents development of the lesion-induced obesity. There are interactions among these nuclei; one mode of communication is via inputs of neuropeptide Y (NPY) cells in the ARC to the VMN, dorsomedial nuclei, and PVN.(ABSTRACT TRUNCATED AT 400 WORDS)

Obese Zucker (fa/fa) rats exhibit normal target sensitivity to corticosterone and increased drive to adrenocorticotropin during the diurnal trough.

Genetically obese Zucker (fa/fa) rats exhibit numerous metabolic and endocrine disorders associated with modest hypercorticosteronemia and reported changes in peripheral target tissue sensitivity to glucocorticoids. In this study we investigated phenotypic differences in basal and stress-induced ACTH and corticosterone (B) secretion in intact and adrenalectomized lean and obese male Zucker rats. In addition, we determined whether differences in the sensitivity to B of plasma ACTH and insulin secretion as well as other peripheral B targets could be observed between the two phenotypes. There were no significant differences in basal ACTH or B in either the morning (AM) or evening (PM) in intact obese and lean rats; however, mean B was increased in the obese rats in the AM, and signs of chronically increased adrenocortical activity were observed, including increased adrenal weight and intraadrenal phenylethanolamine-N-methyl transferase activity and decreased thymus weight. In a second experiment, B was significantly elevated 3 min after either administration in obese compared to lean rats; however, there was no significant difference in B between the groups at 10 min, nor were ACTH levels at these times different. Five days after adrenalectomy with sc B replacement, ACTH was decreased as a function of B in both phenotypes under AM basal and stress conditions. The IC50 values for inhibition of basal ACTH by B were 3.16 and 4.17 micrograms/dl in lean and obese rats, respectively. Under stress conditions, the IC50 values were not different (4.39 micrograms/dl for lean and 4.24 micrograms/dl for obese rats). B dose-dependent increases in body and epididymal fat depot weights were greater in obese than in lean rats, an expected result because of elevated insulin levels in this group. Insulin exhibited only small B-dependent increases, and thymus weight decreased in a B-dependent fashion; there were no differences in the sensitivity to B of these measures between lean and obese rats. We conclude that 1) there is no evidence for altered sensitivity to B in obese rats for any of the B-sensitive end points measured; and 2) basal adrenocortical activity is slightly elevated, and the sensitivity of ACTH to B feedback is decreased in obese rats under AM conditions in the absence of external stress.(ABSTRACT TRUNCATED AT 400 WORDS)

Feedback sensitivity of the rat hypothalamo-pituitary-adrenal axis and its capacity to adjust to exogenous corticosterone.

Chronic stress causing elevated morning (AM) corticosterone (B) concentrations of 2-8 micrograms B/dl does not appear to inhibit subsequent activity in the hypothalamic-pituitary-adrenal (HPA) axis, a surprising finding in view of the known depression in AM basal ACTH by only 3 micrograms B/dl in adrenalectomized rats. To distinguish between the possibilities that either intact rats are less sensitive to B feedback than adrenalectomized rats, or that chronic stress facilitates responses in the HPA axis, we elevated basal B levels in young male rats with slow-release B pellets in the absence of stress. Between 4-6 days after implantation of B pellets at three doses that elevated basal AM (diurnal trough) plasma B to approximately 1.2, 4, and 10 micrograms/dl, we studied basal ACTH and B at trough (AM) and peak evening (PM) times of the diurnal cycle, as well as the responses to the stress of restraint and blood collection from the tail at each time of day. We also determined mean daily plasma B, insulin, and glucose from samples collected at six intervals during the day. Adrenal, thymus, and body wts were measured as were transcortin (CBG) and adrenal phenylethanolamine-N-methyl transferase activity. Compared to controls implanted with wax pellets, all doses of B inhibited adrenal wt and AM stress responses and tended to inhibit pituitary ACTH content and adrenal phenylethanolamine-N-methyl transferase activity. Inhibition with the middle dose B pellet was close to maximally effective for these endpoints. Plasma glucose and thymus wt were significantly decreased and insulin was significantly increased in the middle and highest B pellet groups, with significantly greater effects at the highest dose. The gain in body wt and transcortin concentrations were significantly decreased only in the highest dose groups, in which mean daily plasma B was approximately 10 micrograms/dl, a level that clearly overwhelmed the capacity of the adrenocortical system to respond to any stimulus tested. By contrast, rats with low and middle dose B pellets appeared to adjust HPA axis function by decreasing the peak diurnal increase in B, so that 24-h mean B levels did not differ from control, and were maintained at approximately 5 micrograms/dl. Both of these groups also had inhibited ACTH responses to stress applied during the diurnal trough (AM). By contrast, neither group had inhibited ACTH responses to stress applied during the diurnal peak (PM). We conclude that: 1) The HPA axis of intact rats is extremely sensitive to exogenous B.(ABSTRACT TRUNCATED AT 400 WORDS)

Feedback and facilitation in the adrenocortical system: unmasking facilitation by partial inhibition of the glucocorticoid response to prior stress.

Previously stressed animals remain responsive to subsequent stressors, despite secreting an adequate corticosteroid signal during the first stress which should act to damp the response to a second stress. We have previously postulated that stress acts to facilitate subsequent responses in the adrenocortical system, and that this facilitation is balanced by the corticosteroid feedback signal. To test this hypothesis directly, we treated young male rats with cyanoketone (CK) to partially block the adrenal capacity to synthesize corticosterone (B). Subsequently, groups of CK- or vehicle (VEH)-treated rats were exposed to the FIRST stress of 30-min restraint with small blood samples collected at 0, 15, and 30 min. The FIRST stress was given to subgroups of rats 12, 9, 6, or 3 h before lights off (12 h) or lights on (24 h). At 12 or 24 h, rats were again restrained with blood samples at 0 ("basal") and 30 min (SECOND stress). Control groups were stressed for the first time when the experimental groups received their SECOND stress. Plasma ACTH and B concentrations were measured. Although in the absence of stress, basal B concentrations were normal in CK-treated compared to VEH-treated rats throughout the day, the B response to the FIRST stress was reduced by 60% in the CK- compared to the VEH-treated group. When the FIRST stress was performed during the time of lights on, "basal" plasma ACTH was elevated in CK groups at 12 h (lights off) compared to levels in both previously stressed VEH groups and unstressed CK controls. There was no difference at this time of day in the magnitude of the ACTH response to the SECOND stress in CK rats compared to that in CK rats receiving their only stress (controls) or that in VEH-treated rats receiving the SECOND stress. When first stress was performed during the time of lights off, "basal" plasma ACTH at 24 h (lights on) in CK and VEH rats were not different compared to levels in their respective unstressed controls. The ACTH response to the SECOND stress at 24 h was elevated in all previously stressed CK groups compared to that in either CK control or VEH groups. At neither time of day were SECOND stress ACTH concentrations in VEH rats different from those in control VEH rats. At 12 h (lights off), but not at 24 h (lights on), "basal" ACTH was significantly elevated in VEH rats above the unstressed VEH control values.(ABSTRACT TRUNCATED AT 400 WORDS)

Chronic streptozotocin diabetes in rats facilitates the acute stress response without altering pituitary or adrenal responsiveness to secretagogues.

We have used streptozotocin (STZ)-induced diabetes in rats to determine whether this represents a sustained stimulus to the adrenocortical system and whether STZ-diabetic rats are able to mount an acute stress response. Furthermore, we compared pituitary responsiveness to CRF and/or arginine vasopressin, and adrenal responsiveness to ACTH in STZ- vs. vehicle-treated rats. We also compared the efficacy of dexamethasone inhibitory feedback in STZ-diabetic and control rats. Our results show that STZ-treated rats chronically hypersecrete corticosterone (B) as evidenced by their decreased thymus weights, their increased urinary B excretion, and their elevated mean plasma B levels during the light hours of the day. Despite the evidence for sustained hypersecretion of B, STZ-treated rats showed greater and more prolonged ACTH and B responses to the acute stress of histamine injection. However, when tested separately, neither pituitary nor adrenal responsiveness to their secretagogues were increased in STZ-diabetic compared to control rats. Dexamethasone inhibition of stress-induced B secretion was tested using two different paradigms: pentobarbital-anesthetized rats were given iv injections of acid saline, and awake rats were given ip injections of histamine. In both experiments the STZ-treated rats were relatively resistant to glucocorticoid inhibition of stress responses. This finding, taken together with the exaggerated ACTH and B responses to stress, strongly suggests that the facilitatory effects of chronic STZ-diabetes are a consequence of changes in sensitivity of central neural components of the adrenocortical system to stimulatory and/or inhibitory inputs, in conjunction with changes in glucocorticoid feedback sensitivity.

The pituitary-adrenocortical system of neonatal rats is responsive to stress throughout development in a time-dependent and stressor-specific fashion.

The responsiveness of the neonatal hypothalamus-pituitary-adrenal (HPA) axis to stress has been thought to be impaired or diminished during the first 2 weeks of life. Although we previously found full responsiveness of the hypothalamus-pituitary unit to adrenalectomy in young rats [days (d) 5-10], we failed to measure a significant increase in ACTH 10 min after ether administration until d14 of age. These studies were, therefore, designed to test the functional activation of the HPA axis after a single or repeated exposures to stress. Both qualitative (time-course, stressor-specific, circadian) and quantitative changes in the ACTH and corticosterone (B) responses to various stressors were tested during the first 10 days of life. Exposure to 3 min of ether vapor increased ACTH and B secretion (P less than 0.05-0.01) in 1-, 5-, and 10-d-old rats, with an increasing amplitude of both ACTH and B responses as a function of age. Peak secretion of ACTH occurred 5 min after the onset of stress (122 +/- 3.8 to 359 +/- 54 pg/ml on d1-10), while the time of maximal B increased as a function of age. Other stressors, such as maternal separation (12 h), cold (4 C; 60 min), or histamine injection (4 mg/kg BW, ip), provoked significant and stressor-specific ACTH and B responses in 10-d old rats. Histamine administration increased ACTH secretion above that of vehicle-injected rats, with a peak of secretion 15 min after drug injection (272 +/- 29 vs. 127 +/- 8 pg/ml; P less than 0.01). Histamine-induced B secretion peaked at 60 min (3.7 +/- 0.5 micrograms/dl). In contrast to early responses observed after ether, separation, or histamine stress, cold stress in 10-d-old pups caused a large ACTH and B release 4 h after the onset of cold compared to that in maternally deprived pups [ACTH: cold, 457 +/- 61 pg/ml; separated, 150 +/- 14 (P less than 0.01); B: cold, 3.3 +/- 0.4 micrograms/dl; separated, 1.8 +/- 0.2 (P less than 0.05)]. We did not detect morning-evening (AM-PM) differences in either the pattern or the magnitude of the ACTH or B response to maternal separation or cold stress. Suppression of cold-induced ACTH release by B injection (1 mg/kg BW) 2 h before stress was observed until 4 h after stress in the AM and PM, whereas when given after cold, B was less effective in the PM than in the AM at preventing the rise in ACTH levels observed at 4 h.(ABSTRACT TRUNCATED AT 400 WORDS)

Stress-induced adrenocorticotropin secretion: diurnal responses and decreases during stress in the evening are not dependent on corticosterone.

To test whether the diurnal rhythm in stress responsiveness is dependent on corticosterone (B)-mediated negative feedback, the responses of intact (SHAM) and adrenalectomized (ADX) rats to restraint for 3-90 minutes or ip injection with saline in the morning (AM) and the evening (PM) were compared. In both SHAM and ADX rats, ACTH responses to restraint stress were larger in the AM. In intact rats, this could have resulted from both fast negative feedback, due to the rate of rise of B during the stress in the PM, and delayed negative feedback, due to the high basal concentrations of B before the stress in the PM. However, this diurnal pattern of stress responsiveness was not dependent on B, as the same relative responses to restraint and ip injection were found in ADX rats. To determine whether the lack of response of ADX rats in the PM to stress was due to a loss of sensitivity to endogenous secretagogues, ADX rats were given CRF + arginine vasopressin (AVP) while anesthetized with ether after 30 min of restraint. In both the AM and the PM, the pituitaries were able to respond to exogenous secretagogues. A second novel finding was that in the PM, but not the AM, plasma ACTH concentrations in the ADX rats decreased substantially during the period of restraint, despite the lack of B-mediated negative feedback. In the AM and the PM, ADX rats were restrained for 30 min and then stressed with ether for 6 min. The ACTH concentrations were not different before and after ether, suggesting that, although the pituitaries of ADX rats are able to respond to exogenous CRF + AVP after stress, an additional stress of ether exposure no longer stimulates endogenous CRF and AVP release after 30 min of restraint at either time of day. After 90 min of restraint in the AM and the PM, the relationship between ACTH and B was positive, not negative, providing no evidence of ongoing B-mediated negative feedback in the SHAM rats. Therefore, the same mechanism responsible for the decrease in ACTH secretion in ADX rats may occur in SHAM rats as well. From these results, we conclude that the diurnal rhythm in stress responsiveness and, in the PM in the ADX rats, the decrease in plasma ACTH during stress, are largely independent of B.

Failure of neuropeptide Y to modulate the release of LH and prolactin by cultured bovine pituitary cells.

Possible direct effects of neuropeptide Y (NPY) on dispersed and cultured cells of the anterior lobe (AL) of the bovine pituitary were investigated. AL tissue from steers was enzymatically dissociated into individual cells, preincubated for 18 hr and then incubated in suspension cultures for 2 hr or 24 hr with either NPY, gonadotropin-releasing hormone (GnRH) or both. Release of luteinizing hormone (LH) and prolactin (PRL) into medium was quantified by radioimmunoassay and expressed as hormone released per 100,000 cells. Basal release of LH averaged 38 and 86 ng for 2 hr and 24 hr respectively while that of PRL averaged 118 and 438 ng for the same incubation periods. Addition of NPY did not alter (P greater than .05) basal release of LH or PRL for either duration of incubation. Also, NPY did not affect (P less than .05) release of of LH in response to GnRH. In summary, this study indicated that NPY, at in vitro dosages of .01 to 100 nM, does not modulate the release of LH or PRL at the pituitary level in castrate cattle.