Chronic stress and Rosiglitazone increase indices of vascular stiffness in male rats.

Prolonged and/or frequent exposure to psychological stress responses may lead to deterioration of organs and tissues, predisposing to disease. In agreement with this, chronic psychosocial stress is linked to greater cardiovascular risk, including increased incidence of atherosclerosis, myocardial ischemia, coronary heart disease, and death. Thus the association between stress and cardiovascular dysfunction represents an important node for therapeutic intervention in cardiovascular disease. Here we report that 2weeks of chronic variable stress (CVS) increased indices of vascular stiffness, including increased collagen deposition in the aortic adventitia and increased resting pulse pressure, in male rats. Thus CVS may represent a useful rodent model for stress-associated CVD, especially for aging populations for which widening pulse pressure is a well-known risk factor. Additionally, we report that the thiazolidinedione Rosiglitazone (RSG) blunts chronic stress-associated increases in circulating corticosterone. Despite this, RSG was not protective against adverse cardiovascular outcomes associated with chronic stress. Rather RSG itself is associated with increased pulse pressure, and this is exacerbated by chronic stress-highlighting that chronic stress may represent an additional contributor to RSG-associated cardiovascular risk.

Regulatory interactions of stress and reward on rat forebrain opioidergic and GABAergic circuitry.

Palatable food intake reduces stress responses, suggesting that individuals may consume such ?comfort? food as self-medication for stress relief. The mechanism by which palatable foods provide stress relief is not known, but likely lies at the intersection of forebrain reward and stress regulatory circuits. Forebrain opioidergic and gamma-aminobutyric acid ergic signaling is critical for both reward and stress regulation, suggesting that these systems are prime candidates for mediating stress relief by palatable foods. Thus, the present study (1) determines how palatable ?comfort? food alters stress-induced changes in the mRNA expression of inhibitory neurotransmitters in reward and stress neurocircuitry and (2) identifies candidate brain regions that may underlie comfort food-mediated stress reduction. We used a model of palatable ?snacking? in combination with a model of chronic variable stress followed by in situ hybridization to determine forebrain levels of pro-opioid and glutamic acid decarboxylase (GAD) mRNA. The data identify regions within the extended amygdala, striatum, and hypothalamus as potential regions for mediating hypothalamic-pituitary-adrenal axis buffering following palatable snacking. Specifically, palatable snacking alone decreased pro-enkephalin-A (ENK) mRNA expression in the anterior bed nucleus of the stria terminalis (BST) and the nucleus accumbens, and decreased GAD65 mRNA in the posterior BST. Chronic stress alone increased ENK mRNA in the hypothalamus, nucleus accumbens, amygdala, and hippocampus; increased dynorphin mRNA in the nucleus accumbens; increased GAD65 mRNA in the anterior hypothalamus and BST; and decreased GAD65 mRNA in the dorsal hypothalamus. Importantly, palatable food intake prevented stress-induced gene expression changes in subregions of the hypothalamus, BST, and nucleus accumbens. Overall, these data suggest that complex interactions exist between brain reward and stress pathways and that palatable snacking can mitigate many of the neurochemical alterations induced by chronic stress.

"Snacking" causes long term attenuation of HPA axis stress responses and enhancement of brain FosB/deltaFosB expression in rats.

A history of limited, intermittent intake of palatable food (sucrose drink) attenuates hypothalamic-pituitary-adrenal (HPA) axis stress responses and induces markers of neuronal plasticity in stress- and reward-regulatory brain regions. Synaptic plasticity could provide a mechanism for long-term changes in neuronal function, implying that sucrose stress-dampening may endure over long periods of time. The present study tests the persistence of HPA axis dampening and plasticity after cessation of palatable drinking. Adult, male Long-Evans rats (n=10-13) with free access to water and chow were given additional twice-daily access to 4ml sucrose (30%) or water for 14days. Rats were subsequently tested for HPA responsiveness to an acute (20min) restraint stress at 1, 6 and 21days after the cessation of sucrose. Brains were collected for immunohistochemical analysis of FosB/deltaFosB, a marker of long-term neuronal plasticity, in the basolateral amygdala (BLA) and nucleus accumbens (NuAc). Prior sucrose consumption significantly decreased the plasma corticosterone response to restraint at 1day after the last palatable drink presentation, and also increased FosB/deltaFosB-positive cells in the BLA and in the NuAc core. This HPA-dampening persisted through 21days after the termination of the palatable drink, as did the increased FosB/deltaFosB immunoreactivity in both the BLA and the NuAc core. These data suggest that chronic palatable food intake causes lasting changes in stress/reward-modulatory circuitry and that the suppressed hormonal response to stress that can persist well beyond periods of palatable drink exposure.

Chronic stress produces enduring decreases in novel stress-evoked c-fos mRNA expression in discrete brain regions of the rat.

Chronic stress produces numerous adaptations within the hypothalamic-pituitary-adrenal (HPA) axis that persist well after cessation of chronic stress. We previously demonstrated profound attenuation of HPA axis responses to novel environment 4-7 days following chronic stress. The present study tests the hypothesis that this HPA axis hyporesponsivity is associated with reductions in stress-evoked c-fos mRNA expression, a marker of neuronal activation, in discrete brain regions. Adult male Sprague-Dawley rats underwent 1 week of chronic variable stress (CVS), with unhandled rats serving as controls. Independent groups of control and CVS rats were exposed to novel environment at 16 h, 4 days, 7 days, or 30 days after CVS. Marked reductions of c-fos mRNA expression in the CVS group persisted for at least 30 days within the paraventricular nucleus of the hypothalamus, and for at least 1 week in rostroventrolateral septum and lateral hypothalamus. Lower levels of c-fos mRNA expression were observed at 16 h recovery in the ventrolateral medial preoptic area, basolateral amygdala, anterior cingulate cortex, and prelimbic cortex. The results demonstrate long-term alterations in neuronal activation within neurocircuits critical for regulation of physiological and psychological responses to stressors.

SF-1, DAX-1, and acd: molecular determinants of adrenocortical growth and steroidogenesis.

The formation of the adrenal cortex in humans is notable for the presence of two discrete zones, the fetal zone (FZ) which regresses soon after birth and the definitive zone (DZ) which gives rise to the classic steroidogenic zones of the adult cortex. Mice possess an analogous structure to the FZ referred to as the X-zone (XZ) which regresses at puberty in the male and during the first pregnancy in the female. Similar to the human FZ in X-linked Congenital Adrenal Hypoplasia caused by loss of function mutations in DAX-1 (Dosage-sensitive sex reversal-Adrenal hypoplasia congenita critical region on the X chromosome), the mouse XZ does not regress when DAX-1 is mutated. Only in humans with DAX-1 mutations, however, is the DZ small and hypofunctional. Patients and mice with SF-1 mutations have complete adrenal aplasia with absence of both the DZ and FZ/XZ. Lastly, the phenotype of the Autosomal Recessive Adrenocortical Dysplasia (acd) mouse is strikingly similar to human Miniature Adult Congenital Adrenal Hypoplasia, lacking an XZ/FZ and possessing a dysfunctional DZ. Current work has addressed the regulation of SF-1 and DAX-1 dependent adrenocortical growth and steroidogenesis in vivo utilizing mouse models of simple and combined SF-1 and DAX-1 deficiency. In addition, the model of compensatory adrenal growth in SF-1 haplo-insufficient mice has been applied to evaluate the potential role of SF-1 in adrenocortical proliferation. Additional efforts aim to positionally clone the acd gene, predicated on the hypothesis that it is a critical component of the adrenal developmental cascade.

ACTH inhibits the capsaicin-evoked release of CGRP from rat adrenal afferent nerves.

The adrenal cortex is innervated by afferent fibers that have been implicated in affecting cortical steroidogenesis. Modulation of neurotransmitter release from afferents may represent a regulatory system for the control of adrenal cortical function. The present studies validate an in vitro superfusion technique for adrenal capsules employing the drug capsaicin, which activates a subset of afferent fibers and induces the release of calcitonin gene-related peptide (CGRP). Capsaicin-evoked CGRP release from adrenal afferents was blocked by capsazepine, a competitive antagonist for the capsaicin receptor, or by removal of extracellular calcium. Exogenous ACTH prevented capsaicin-evoked CGRP release, elevated basal aldosterone release, and prevented capsaicin-induced reduction in aldosterone release. Immunolabeling for the recently cloned capsaicin vanilloid receptor 1 demonstrated its presence in adrenal nerves. These results show that in vitro superfusion of adrenal capsules can be used to characterize factors that modulate neurotransmitter release from adrenal afferents. Furthermore, the results suggest that activation of adrenal afferents in vivo may attenuate aldosterone steroidogenesis and that high levels of ACTH may prevent this phenomenon.

Rat adrenal transplants are reinnervated: an invalid model of denervated adrenal cortical tissue.

Adrenal autotransplantation is a widely used approach to investigate the potential for neural modulation of adrenal cortical function. It is believed that regenerating adrenal transplants are not reinnervated, thereby providing a model to investigate adrenal function in the absence of neural modulation. However, the hypothesis that adrenal transplants become reinnervated has not been directly tested. The purpose of the present study was to characterize the time course, extent, and nature of the reinnervation of the regenerating adrenal transplant and to assess whether the recovery of steroidogenic function and enzyme expression correlates temporally with the presence of innervation. Using immunohistofluorescent detection of tyrosine hydroxylase (TH), neuropeptide Y (NPY), calcitonin gene-related peptide (CGRP), and vasoactive intestinal peptide (VIP), the innervation of regenerating adrenals was assessed 14-30 days after transplantation of adrenal capsules beneath the kidney capsule in rats. Extensive reinnervation by TH-, NPY-, and VIP-positive fibres was present by 14 days after transplantation including regions of the adrenal capsule and cortex, with only minimal reinnervation by CGRP-positive fibres up to 30 days. TH- and NPY-positive chromaffin cells were also observed in the regenerating transplants. In addition, there was marked recovery of steroidogenic function and steroidogenic enzyme expression up to 30 days. The finding that nerve fibres are present in the transplants during the re-establishment of steroidogenic function and enzyme expression suggests that innervation may modulate the regeneration and functional recovery of adrenal transplants. In an attempt to prevent reinnervation of transplants, adrenal capsules were autotransplanted to denervated kidneys. Immunohistochemical analysis showed that, despite extensive denervation of the kidney tissue, the reinnervation and regeneration of the adrenal transplants still occurred. These data demonstrate the marked capacity of the regenerating adrenal to become reinnervated and reinforces the conclusion that adrenal transplants are an invalid model of denervated adrenal cortical tissue.

Hyperinnervation during adrenal regeneration influences the rate of functional recovery.

The rat adrenal cortex has the uncommon ability to demonstrate morphological and functional regeneration after injury-induced loss of cortical tissue. Peripheral nerves are involved in tissue regeneration and healing after injury, implying that nerves may also be involved in modulating the regeneration of the adrenal cortex. Studies were initiated to assess changes in adrenal innervation during cortical tissue regeneration subsequent to adrenal enucleation. Innervation of regenerating adrenals was assessed from 3 to 62 days postenucleation by immunohistofluorescent detection of neuronal markers for primary afferent, preganglionic sympathetic, and postganglionic sympathetic fibers. The regenerating adrenal contained few nerves at 3 days postenucleation, but became differentially innervated, with extensive innervation by nerve fibers positive for calcitonin gene-related peptide (CGRP), tyrosine hydroxylase (TH), neuropeptide Y (NPY), and neuronal nitric oxide synthase (nNOS). In contrast, there was only minimal innervation by nerve fibers positive for vasoactive intestinal peptide. By 14 days postenucleation, the CGRP-, TH-, and NPY-positive innervation included areas of hyperinnervation in the capsule, cortex, and central inflammatory site of the regenerating gland. In addition, many chromaffin cells were present at all time points postenucleation. Quantification of the regenerating gland content of CGRP, norepinephrine, epinephrine, and nNOS verified the immunohistofluorescent observations. The period of extensive innervation correlated temporally with the time (3-30 days) during which the regenerating glands recovered steroidogenic function. Moreover, splanchnic nerve transection at the time of adrenal enucleation decreased the innervation by CGRP-positive and vesicular acetylcholine transporter-positive fibers and delayed regeneration. These results support the hypothesis that adrenal innervation modulates tissue regeneration and functional recovery of the enucleated adrenal gland.