Corticosterone modulation of ACTH secretogogue gene expression in the paraventricular nucleus.

This review will describe effects of corticosterone on the temporal dynamics of components within the hypothalamo-pituitary-adrenal (HPA) axis in response to sustained hypovolemia. The characterization of the synthetic and secretory profiles of HPA elements in these rat models reveals the complexities of steroid-mediated regulation of neuroendocrine and corticotrope function during a sustained stress event. Collectively, our data suggest activation of gene transcription and secretion are independently controlled, and that corticosterone affects adrenocorticotropin hormone (ACTH) gene expression in the parvicellular neuroendocrine part of the hypothalamic paraventricular nucleus using two mechanisms: first, an inhibition which contributes to classic negative feedback, and second, a facilitation, which is seen at low plasma concentrations.

Adrenalectomy dramatically modifies the dynamics of neuropeptide and c-fos gene responses to stress in the hypothalamic paraventricular nucleus.

We have used in situ hybridization and radio-immunoassay to compare temporal dynamics of components in the hypothalamo-pituitary limb of the hypothalamo-pituitary-adrenal axis during sustained hypovolemic stress in adrenalectomized (ADX) rats to those previously reported in intact animals. We asked three questions: first, does corticotropin-releasing hormone (CRH) gene transcription occur in neuroendocrine neurones of the hypothalamic paraventricular nucleus (PVH) of ADX rats, and if so, how is it temporally organized; second, what is the expression pattern of the vasopressin and other genes known to be colocalized in these neuroendocrine neurones; third, if adrenocorticotropin hormone (ACTH) secretion occurs, what is its temporal profile? We found that sustained hypovolemia evoked a brief episode of CRH gene transcription in ADX rats that occurred earlier than in intact rats. However, in contrast to saline-injected controls, this activation was not maintained because declines in CRH hnRNA and mRNA were seen as the stress continued. Although increased vasopressin gene transcription was not seen in intact hypovolemic rats, robust increases were measured throughout in ADX rats, suggesting that in the absence of corticosterone the vasopressin gene is transcribed preferentially to the CRH gene during sustained hypovolemia. c-fos and preproenkephalin mRNA profiles also exhibited earlier onsets compared to intact rats. Finally, the onset and duration of ACTH secretion was the same in ADX rats as previously reported in intact rats. Collectively, these data support two hypotheses regarding the actions of corticosterone. First, that it provides some form of facilitatory signal allowing neuroendocrine CRH transcriptional mechanisms to remain active during sustained hypovolemia. Second, that it strongly inhibits the response of the vasopressin gene to hypovolemic stress.

Peptide gene activation, secretion, and steroid feedback during stimulation of rat neuroendocrine corticotropin-releasing hormone neurons.

We have used colloid-induced hypovolemia to investigate mechanisms operating in CRH neuroendocrine neurons of the hypothalamic paraventricular nucleus during a sustained stress. Specifically, three questions have been addressed using in situ hybridization and RIA. 1) Do neuropeptide secretion and gene activation share the same stimulus threshold? 2) Does corticosterone modulate mechanisms regulating CRH gene expression during sustained stress? 3) How are neuropeptides commonly colocalized with CRH affected? Our results show that the secretion of ACTH and activation of the CRH gene have distinct and separate stimulus thresholds. The threshold is higher for CRH gene activation than for ACTH secretion, suggesting some degree of mechanistic separation. In addition, corticosterone secreted during the first 3 h of sustained hypovolemia does not inhibit CRH gene expression. However, feedback inhibition may occur in the delayed time domain. Finally, neuropeptides colocalized with CRH are differentially regulated by sustained hypovolemia. Proenkephalin messenger RNA levels show a slower temporal response than those of CRH, while the vasopressin gene is not activated at any time in parvicellular neuroendocrine neurons. Our results emphasize that CRH neuroendocrine neurons respond to a stress event in a stimulus-specific manner in terms of both the profiles of secretion and gene expression, and the structure of glucocorticoid feedback.

Corticosterone can facilitate as well as inhibit corticotropin-releasing hormone gene expression in the rat hypothalamic paraventricular nucleus.

We have used in situ hybridization to investigate how basal levels of circulating corticosterone modulate CRH gene transcription in the neuroendocrine parvicellular part of the hypothalamic paraventricular nucleus (PVHmpd) during sustained hypovolemia. In the absence of the stressor, the accumulation rate of the CRH primary transcript exhibited a dose dependency on low maintained levels of plasma corticosterone similar to that previously reported for the mature messenger RNA (mRNA); levels declined as plasma corticosterone increased. In response to hypovolemia, the absence of corticosterone compromised CRH gene transcription mechanisms to mount the activated response seen in intact animals. However, adrenalectomized rats with low doses of corticosterone (insufficient to normalize thymus weights) showed an augmented mRNA response compared with that in intact animals. When replaced corticosterone normalized thymus weights, the magnitude of the mRNA response was reduced to that seen in intact animals. In contrast to CRH gene regulation, PVHmpd proenkephalin mRNA levels were unaffected by corticosterone concentrations. These results suggest that corticosterone affects CRH gene transcription in the PVHmpd using two mechanisms: first, inhibition, which probably uses type II glucocorticoid receptor-dependent mechanisms and contributes to classic negative feedback; and second, facilitation, which is seen at low plasma concentrations and maintains gene transcription in the presence of sustained stress, possibly using type I mechanisms. This suggests that one reason why adrenal insufficiency severely compromises survival of sustained stress is that CRH gene transcription cannot be maintained without previous exposure to low levels of plasma corticosterone.