Effect of chronic inhalation of toluene on behavior of rats of various age groups in multi-branched maze.

The effect of a 40-day toluene inhalation on learning of young and adult rats was examined in a multi-branched maze. Experimental rats of both age groups needed more time to pass the maze and made more errors than controls. This impairment was observed in young rats immediately after termination of toluene inhalation and in adult rats immediately and 90 days after toluene.

[Neuronal porosome in the rat and cat brain].

It is well established that during cell secretion, membrane-bound secretory vesicles dock and fuse at the base of supramolecular cup-shaped structures at the cell plasma membrane called "porosomes", to expel intra-vesicular contents to the outside. In neurons, it has been demonstrated that 12-17 nm cup-shaped lipoprotein structure possessing a central plug are present at the presynaptic membrane, where 50 nm in diameter synaptic vesicles transiently dock and fuse to release neurotransmitter. In the past decade, the neuronal porosome has been isolated and its major chemical composition determined. Additionally, the porosome has been both structurally and functionally reconstituted into artificial lipid membrane, establishing its role as the secretory portal in neurons. Studies utilizing atomic force and electron microscopy, combined with electron density and 3D contour mapping, provide at the nanoscale, the structure and assembly of proteins within the neuronal porosome. In the current study, ultrahigh resolution imaging of the presynaptic membrane of isolated brains from both rats and cats, demonstrate for the first time, the presence of neuronal porosomes in cat brain, and further confirms the presence of porosomes at the presynaptic membrane in rat brain synaptosomes. Results from the present study further confirm the cup-shaped morphology of porosomes in the rat brain, and demonstrates their similar shape and size in the cat nerve terminal. The study also demonstrates for the first time, the universal presence of similar porosomes in different species of mammals.

Effect of nadolol injected prior to CRH on stress-induced plasma corticosterone level in rat.

The proposed research is the part of our investigation of the role of catecholamines in the alterations provoked by stress. Especially, we elucidate if Nadolol injected prior to CRH ICV has some effect on plasma corticosterone level. 15 mg/kg of Nadolol (the dose sufficient to prevent CRH-induced increases in heart-rate for 2 hr), dissolved in saline was administered intraperitoneally, 30 minutes prior to CRH (The dose of interest for CRH - 1 mkg/kg - was determined earlier, as provoking the maximal increase of plasma corticosterone level after 20 minutes of its ICV injection). Whole blood was collected at 11.00 am, via indwelling jugular catheter at 0 (control) and 15 minutes after Nadolol injection, also 30 and 60 min after CRH injection. After centrifugation the plasma level of corticosterone was essayed using ELISA method. 15 minutes after Nadolol injection the level of plasma corticosterone in comparing with control wasn't changed, at subsequent time-points plasma corticosterone level was increased but significant difference was observed only after 30 minutes. Thus, according our results, 30 min after injection, the dose of Nadolol, sufficient to prevent CRH-induced increase in heart rate, doesn't preclude the CRH-induced increase of plasma corticosterone - one of key signs of the stress-axis activation. The results were discussed.

Stress-system: corticotropin-releasing hormone and catecholamines (review).

The brain's stress-handling system--the limbic-hypothalamic-pituitary-adrenal axis--is one of the most thoroughly studied circuitry of the central nervous system. As a result of stress-axis activation different behavioral and physical changes develop; these changes allow the organism to adapt. For this purpose stress-system closely "works" with other elements of central nervous system, which are involved in the regulation of emotion and structures, also with axes, responsible for reproduction, growth and immunity. Dysfunction of stress-system--it's hyper- or hypoactivity--is characteristic peculiarity of many pathological states and disorders. Various molecules (corticotropin-releasing hormone, vasopressin, glucocorticoids, mineralocorticoids, ACTH, its precursor proopiomelanocortin etc.) are engaged in the regulation of stress-axis. Among these molecules corticotropin-releasing hormone is supposed to have a key role in regulating the response to stress. Besides these molecules, the end-products of the stress-axis activation: catecholamines, different hormones and cytokines - control the activity of multiple levels of this axis. According some views catecholamines play one of the essential roles in the alterations provoked by stress-axis activation. In this review we cite some classical (Crousseau et al.) and modern data concerning corticotropin-releasing hormone and catecholamine activities during stress.