Effects of Single Administration of Bupropion on Carboxypeptidase E Activity in Structures of Rat Brain.

Depression is associated with changes in the levels of some neurotransmitters in various brain structures. Being the key enzyme of peptide processing, carboxypeptidase E regulates their levels in various structures of the nervous system. Single injection of bupropion induced long-lasting changes in carboxypeptidase E activity in all brain structures. The decrease in enzyme activity observed in 12 and 24 h after bupropion injection confirmed the inhibiting effect of the drug on the hypothalamic-pituitary-adrenal axis. Activation of the enzyme in the medulla oblongata, hypothalamus, and hippocampus observed in 72 h after bupropion administration probably leads to enhanced synthesis and secretion of regulatory peptides (reduced during stress and depression) and stimulation of neurogenesis. Changes in enzyme activity can be a mechanism regulating the level of bioactive peptides involved in the pathogenesis of depression.

[Effect of reboxetine on activity of carboxypeptidase E in the nerve tissue of rats].

Depression is one of the most common mental disorders, but its etiology is not completely understood. It is assumed that peptidergic system components are involved in the formation of this pathology. Neuropeptides play an important role in the regulation of mental and emotional states. Сarboxypeptidase E is a key enzyme of peptide processing; it regulates neuropeptide levels in the various structures of the nervous system. We have studied effects of a single dose of reboxetine on the activity of carboxypeptidase E in various brain regions and the adrenal glands of rats. The reboxetine injection decreased carboxypeptidase E activity in the pituitary gland (12 h after injection), in the pituitary gland, the quadrigeminal bodies, the medulla oblongata, the hypothalamus, the hippocampus and the amygdala (24 h after injection), in the pituitary gland and striatum (72 h after injection). The enzyme activity in adrenal glands remained basically unchanged. Apparently, the decrease of carboxypeptidase E activity may influence the level of regulatory peptides involved in the pathogenesis of depression.

The obesity susceptibility gene Cpe links FoxO1 signaling in hypothalamic pro-opiomelanocortin neurons with regulation of food intake.

Reduced food intake brings about an adaptive decrease in energy expenditure that contributes to the recidivism of obesity after weight loss. Insulin and leptin inhibit food intake through actions in the central nervous system that are partly mediated by the transcription factor FoxO1. We show that FoxO1 ablation in pro-opiomelanocortin (Pomc)-expressing neurons in mice (here called Pomc-Foxo1(-/-) mice) increases Carboxypeptidase E (Cpe) expression, resulting in selective increases of alpha-melanocyte-stimulating hormone (alpha-Msh) and carboxy-cleaved beta-endorphin, the products of Cpe-dependent processing of Pomc. This neuropeptide profile is associated with decreased food intake and normal energy expenditure in Pomc-Foxo1(-/-) mice. We show that Cpe expression is downregulated by diet-induced obesity and that FoxO1 deletion offsets the decrease, protecting against weight gain. Moreover, moderate Cpe overexpression in the arcuate nucleus phenocopies features of the FoxO1 mutation. The dissociation of food intake from energy expenditure in Pomc-Foxo1(-/-) mice represents a model for therapeutic intervention in obesity and raises the possibility of targeting Cpe to develop weight loss medications.

Peptidomics of Cpe fat/fat mouse hypothalamus: effect of food deprivation and exercise on peptide levels.

Carboxypeptidase E is a major enzyme in the biosynthesis of numerous neuroendocrine peptides. Previously, we developed a technique for the isolation of neuropeptide-processing intermediates from mice that lack carboxypeptidase E activity (Cpe fat/fat mice) due to a naturally occurring point mutation. In the present study, we used a differential labeling procedure with stable isotopic tags and mass spectrometry to quantitate the relative changes in a number of hypothalamic peptides in Cpe fat/fat mice in two different paradigms that each cause an approximately 10% decrease in body mass. One paradigm involved a 2-day fast under normal sedentary conditions (i.e. standard mouse cages); the other involved giving mice access to an exercise wheel for 4 weeks with free access to food. Approximately 50 peptides were detected in both studies, and over 80 peptides were detected in at least one of the two studies. Twenty-eight peptides were increased >50% by food deprivation, and some of these were increased by 2- to 3-fold. In contrast, only three peptides were increased >50% in the group with exercise wheels, and many peptides showed a slight 15-30% decrease upon exercise. Approximately one-half of the peptides detected in both studies were identified by tandem mass spectrometry. Peptides found to be elevated by food deprivation but not exercise included a number of fragments of proenkephalin, prothyrotropin-releasing hormone, secretogranin II, chromogranin B, and pro-SAAS. Taken together, the differential regulation of these peptides in the two paradigms suggests that the regulation is not due to the lower body weight but to the manner in which the paradigms achieved this lower body weight.