Genetic Approaches to Hypothalamic-Pituitary-Adrenal Axis Regulation.

The normal function of the hypothalamic-pituitary-adrenal (HPA) axis, and resultant glucocorticoid (GC) secretion, is essential for human health. Disruption of GC regulation is associated with pathologic, psychological, and physiological disease states such as depression, post-traumatic stress disorder, hypertension, diabetes, and osteopenia, among others. As such, understanding the mechanisms by which HPA output is tightly regulated in its responses to environmental stressors and circadian cues has been an active area of investigation for decades. Over the last 20 years, however, advances in gene targeting and genome modification in rodent models have allowed the detailed dissection of roles for key molecular mediators and brain regions responsible for this control in vivo to emerge. Here, we summarize work done to elucidate the function of critical neuropeptide systems, GC-signaling targets, and inflammation-associated pathways in HPA axis regulation and behavior, and highlight areas for future investigation.

Site-specific modulation of brain glucocorticoid receptor and corticotropin-releasing hormone expression using lentiviral vectors.

The glucocorticoid receptor (GR) and corticotropin-releasing hormone (CRH) are important molecular regulators of an individual's ability to respond to stressful stimuli in an adaptive manner. Impaired signaling of both GR and CRH often leads to dysfunction of the hypothalamic-pituitary-adrenal axis, which underlies the etiology of many affective disorders such as anxiety and depression. Studies focusing on how GR and CRH influence the stress response are limited as they generalize to broad brain regions, thus hindering identification of how specific CNS nuclei contribute to maladaptive stress responses. Our objective is to distinguish the site-specific involvement of GR and CRH in limbic regions involved in the stress response. With that intent, we use lentiviral (LV) vectors in combination with transgenic mouse lines, enabling us to modify expression of GR or CRH in a very localized manner. This paper describes the generation of several distinct LV vectors and transgenic mice models that will help further elucidate the site-specific actions of GR and CRH.

Behavioral Studies and Genetic Alterations in Corticotropin-Releasing Hormone (CRH) Neurocircuitry: Insights into Human Psychiatric Disorders.

To maintain well-being, all organisms require the ability to re-establish homeostasis in the presence of adverse physiological or psychological experiences. The regulation of the hypothalamic-pituitary adrenal (HPA) axis during stress is important in preventing maladaptive responses that may increase susceptibility to affective disorders. Corticotropin-releasing hormone (CRH) is a central stress hormone in the HPA axis pathway and has been implicated in stress-induced psychiatric disorders, reproductive and cardiac function, as well as energy metabolism. In the context of psychiatric disorders, CRH dysfunction is associated with the occurrence of post-traumatic stress disorder, major depression, anorexia nervosa, and anxiety disorders. Here, we review the synthesis, molecular signaling and regulation, as well as synaptic activity of CRH. We go on to summarize studies of altered CRH signaling in mutant animal models. This assembled data demonstrate an important role for CRH in neuroendocrine, autonomic, and behavioral correlates of adaptation and maladaptation. Next, we present findings regarding human genetic polymorphisms in CRH pathway genes that are associated with stress and psychiatric disorders. Finally, we discuss a role for regulators of CRH activity as potential sites for therapeutic intervention aimed at treating maladaptive behaviors associated with stress.

Behavioral insights from mouse models of forebrain--and amygdala-specific glucocorticoid receptor genetic disruption.

Genetic modulation of glucocorticoid receptor (GR) function in the brain using transgenic and gene knockout mice has yielded important insights into many aspects of GR effects on behavior and neuroendocrine responses, but significant limitations regarding interpretation of region-specific and temporal requirements remain. Here, we summarize the behavioral phenotype associated with two knockout mouse models to define the role of GRs specifically within the forebrain and amygdala. We report that forebrain-specific GR knockout mice exhibit impaired negative feedback regulation of the hypothalamic-pituitary-adrenal (HPA) axis and increased despair- and anxiety-like behaviors. In addition, mice with a disruption of GR specifically within the central nucleus of the amygdala (CeA) are deficient in conditioned fear behavior. Overall, these models serve as beneficial tools to better understand the biology of GR signaling in the normal stress response and in mood disorders.

Pro-NGF, sortilin, and p75NTR: potential mediators of injury-induced apoptosis in the mouse dorsal root ganglion.

The nerve growth factor precursor (pro-NGF) may function as a death-inducing ligand that mediates its apoptotic effects via p75NTR. Pro-NGF-induced apoptosis is postulated to be dependent upon membrane expression of the sortilin receptor, which interacts with p75NTR to promote a high-affinity binding site for pro-NGF. Here, we explore the expression of pro-NGF, sortilin and p75NTR in the mouse lumbar dorsal root ganglion (DRG) to understand the potential for this trimeric signaling complex to function in injury-induced neuronal death of DRG neurons. Our results reveal the expression of all 3 components within the DRG and that a subpopulation of neurons coexpresses sortilin and p75NTR. Following sciatic nerve transection, the expression of these proteins appears insensitive to injury; however, the majority of small p75NTR-sortilin coexpressing neurons are lost 25 days after sciatic nerve transection. These results propose pro-NGF-induced, p75NTR-sortilin-mediated neuronal death as a critical aspect of nerve injury-induced death in the DRG.

Apoptosis: understanding the new molecular pathway.

Advances in science have increased the knowledge of how cells die in the body (apoptosis). A basic understanding of this process can improve nurses' ability to review new scientific literature and enable them to provide safer bedside care.