Neuroendocrine profile in a rat model of psychosocial stress: relation to oxidative stress.

AIMS: Psychosocial stress alters the hypothalamic-pituitary-adrenal axis (HPA-axis). Increasing evidence shows a link between these alterations and oxidant elevation. Oxidative stress is implicated in the stress response and in the pathogenesis of neurologic and psychiatric diseases. NADPH oxidases (NOXs) are a major source of reactive oxygen species (ROS) in the central nervous system. Here, we investigated the contributory role of NOX2-derived ROS to the development of neuroendocrine alterations in a rat model of chronic psychosocial stress, the social isolation. RESULTS: Significant elevations in the hypothalamic levels of corticotropin-releasing factor and plasmatic adrenocorticotropic hormone were observed from 4 weeks of social isolation. Increased levels of peripheral markers of the HPA-axis (plasmatic and salivary corticosterone) were observed at a later time point of social isolation (7 weeks). Alteration in the exploratory activity of isolated rats followed the same time course. Increased expression of markers of oxidative stress (8-hydroxy-2-deoxyguanosine [8OhdG] and nitrotyrosine) and NOX2 mRNA was early detectable in the hypothalamus of isolated rats (after 2 weeks), but later (after 7 weeks) in the adrenal gland. A 3-week treatment with the antioxidant/NOX inhibitor apocynin stopped the progression of isolation-induced alterations of the HPA-axis. Rats with a loss-of-function mutation in the NOX2 subunit p47(phox) were totally protected from the alterations of the neuroendocrine profile, behavior, and increased NOX2 mRNA expression induced by social isolation. INNOVATION: We demonstrate that psychosocial stress induces early elevation of NOX2-derived oxidative stress in the hypothalamus and consequent alterations of the HPA-axis, leading ultimately to an altered behavior. CONCLUSION: Pharmacological targeting of NOX2 might be of crucial importance for the treatment of psychosocial stress-induced psychosis.

Paradoxical effects of arthritis-regulating chromosome 4 regions on myelin oligodendrocyte glycoprotein-induced encephalomyelitis in congenic rats.

Immunoregulatory gene loci in different organ-specific inflammatory diseases often co-localize. We here studied myelin oligodendrocyte glycoprotein (MOG)-induced EAE in rat strains congenic for arthritis-regulating genome regions on chromosome 4. We used congenic rats with a 70-centimorgan (cM) fragment from the EAE- and arthritis-resistant PVG.1AV1 rat strain on the arthritis- and EAE-permissive Dark Agouti (DA) rat background. In addition, we evaluated three recombinant strains, C4R1-C4R3, which overlap with arthritis-linked loci. PVG.1AV1 alleles in the C4R1 recombinant did not affect arthritis, but conferred protection against MOG-EAE. PVG.1AV1 alleles in the C4R2 recombinant down-regulated arthritis but had no effect in MOG-EAE. Paradoxically, PVG.1AV1 alleles in the C4R3 recombinant down-regulated arthritis, but the same fragment increased serum levels of anti-MOG Ab and aggravated clinical MOG-EAE. Thus, we provide original evidence that the same genome regions can have opposite effects in different organ-specific inflammatory diseases. Interestingly, no apparent difference in the MOG-EAE phenotype was observed in full-length congenic rats and parental DA rats, suggesting that the disease amelioration in C4R1 and aggravation in C4R3 functionally counteract each other. The data set the stage for definition of the mechanisms and positioning of the genes regulating two organ-specific inflammatory diseases differently.