Barbora Filová

The anxiolytic effect of testosterone in the rat is mediated via the androgen receptor.

Endogenous and exogenous testosterone affects several behavioural traits as shown in human and animal studies. The effects of testosterone can be mediated via androgen or oestrogen receptors, but also via rapid non-genomic effects. The aim of this study was to evaluate whether a single testosterone injection has effects, mediated via the androgen receptor, on anxiety in intact male rats. We hypothesised that administration of testosterone will have an anxiolytic effect, mediated by the androgen receptor. Intact adult male Wistar rats were divided into groups: control, flutamide, testosterone and testosterone with flutamide. Testosterone and flutamide (as an androgen receptor blocker) were applied once, intramuscularly, at a dose of 5mg/kg. Twenty four hours later, rats underwent the following behavioural tests to analyse anxiety: open field test, elevated plus maze and light-dark box. Testosterone was measured in plasma to confirm elevated levels in groups that received testosterone. The levels of testosterone were 2.5-3 fold higher amongst rats administered with testosterone compared to controls. Flutamide did not affect plasma testosterone concentrations. Testosterone administration had no effect on anxiety in the open field and elevated plus maze. In the light-dark transition task, testosterone increased the time spent in the light part of the maze by 80%, an effect which was blocked by flutamide, and which was in support of our hypothesis. Flutamide-treated rats spent more time in the central square of the open field. Using the light-dark box we have shown that a single injection of testosterone decreases anxiety in adult male rats. This effect of increased testosterone was mediated via the androgen receptor as flutamide blocked the anxiolytic effect of exogenous testosterone. Treatment with flutamide blocked the effects of endogenous testosterone and had anxiolytic effects in the open field, suggesting a non-linear relationship between genomic effects of T and anxiety.

The Effect of Testosterone on the Formation of Brain Structures

It has been confirmed in several studies that testosterone can significantly affect brain development. Following metabolism of this hormone by 5α-reductase to dihydrotestosterone, testosterone may act via androgen receptors, or after conversion by aromatase to estradiol, it may act via estrogen receptors. The parts of the brain which are changed under the influence of sex hormones are known as sexually dimorphic nuclei, especially in the preoptic area of the hypothalamus. Nevertheless, evidence suggests that testosterone also influences the structure of the hippocampus, specifically CA1 and CA3 areas of the hippocampus, as well as the amygdala. These brain areas are designed to convert information from short-term into long-term memory. In this review, we summarize the effects of testosterone on the organization of brain structures with respect to spatial cognitive abilities in small rodents.

Effects of testosterone and estradiol on anxiety and depressive-like behavior via a non-genomic pathway

Besides their known slow genomic effects, testosterone and estradiol have rapid effects in the brain. However, their impact on mood-related behavior is not clear. The aim of this study was to investigate the non-genomic pathway of testosterone and estradiol in the amygdala in relation to anxiety and depressive-like behavior. Sham-operated and gonadectomized male rats (GDX) supplemented with testosterone propionate, estradiol, or olive oil were used. Five minutes after administration, anxiety and depression-like behavior were tested. Estradiol increased anxiolytic behavior in the open-field test compared to the GDX group, but administration of testosterone had no significant effect. Besides, c-Fos expression in the medial nucleus of the amygdala significantly increased after testosterone treatment compared to the GDX group, while no significant difference was observed in the central and the basolateral nuclei of the amygdala in the testosterone-treated group compared to the GDX group. In conclusion, estradiol had an anxiolytic effect via a rapid pathway, but no rapid effect of testosterone on anxiety was found. Further studies elucidating whether the rapid effect is mediated by a non-genomic pathway are needed.

Chronic renal insufficiency does not induce behavioral and cognitive alteration in rats.

In humans, chronic kidney disease (CKD) is associated with cognitive decline, increase in anxiety, or depression. The underlying mechanisms of these changes remain unclear. The aim of this study was to elucidate whether and how experimentally induced long-term CKD affects cognitive functions in rats. Thirty male Wistar rats underwent 5/6 nephrectomy (5/6 Nx), an established model of CKD, or sham surgery. Development of CKD was monitored using biochemical analyses and confirmed by renal histology. Behavioral tests of anxiety, depression and spatial behavior were performed before, and at 3 and 9 months after the surgery. CKD in 5/6 Nx rats was characterized by significant decrease of renal function, e.g., glomerular filtration rate, and progressive glomerulosclerosis, tubular atrophy, and interstitial fibrosis; and increased plasma uremic toxins. Mortality was higher in 5/6 Nx rats in comparison with controls. Compared to control group, the surviving 5/6 Nx rats presented similar general locomotor activity, depression traits, and spatial abilities (p=0.43, p=0.84, p=0.71, respectively). At 9 months, lower anxiety in the light-dark box test was observed in 5/6 Nx rats if compared with the control group (p=0.02). Despite the development of progressive CKD in 5/6 Nx rats, no expected behavioral changes were observed. Further experimental studies associating behavioral responses to severity of CKD are definitely needed to confirm the solely psychosocial aspect background of CKD-associated cognitive impairment in humans.

Effects of fractionated whole-brain irradiation on cellular composition and cognitive function in the rat brain

Abstract Purpose: The aim of this study was investigate whether histopathological changes in the neurogenic region correlate with appropriate cognitive impairment in the experimental model of radiation-induced brain injury. Materials and methods: Adult male Wistar rats randomized into sham (0 Gy) and two experimental groups (survived 30 and 100 days after treatment) received fractionated whole-brain irradiation (one 5 Gy fraction/week for four weeks) with a total dose of 20 Gy of gamma rays. Morris water maze cognitive testing, histochemistry, immunohistochemistry and confocal microscopy were used to determine whether the cognitive changes are associated with the alteration of neurogenesis, astrocytic response and activation of microglia along and/or adjacent to well-defined pathway, subventricular zone-olfactory bulb axis (SVZ-OB axis). Results: Irradiation revealed altered cognitive functions usually at 100 days after treatment. Neurodegenerative changes were characterized by a significant increase of Fluoro-Jade-positive cells 30 days after irradiation accompanied by a steep decline of neurogenesis 100 days after treatment. A strong astrocytic response and upregulation of the activated microglia were seen in both of experimental groups. Conclusions: Results shows that fractionated irradiation led to cognitive impairment closely associated with accerelation of neuronal cell death, inhibition of neurogenesis, activation of astrocytes and microglia indicate early delayed radiation-induced changes.

Merkel-like cell distribution in the epithelium of the human vagina. An immunohistochemical and TEM study

Human Merkel cells (MCs) were first described by Friedrich S. Merkel in 1875 and named “Tastzellen” (touch cells). Merkel cells are primarily localized in the basal layer of the epidermis and concentrated in touch-sensitive areas. In our previous work, we reported on the distribution of MCs in the human esophagus, so therefore we chose other parts of the human body to study them. We selected the human vagina, because it has a similar epithelium as the esophagus and plays very important roles in reproduction and sexual pleasure. Due to the fact that there are very few research studies focusing on the innervation of this region, we decided to investigate the occurrence of MCs in the anterior wall of the vagina. The aim of our research was to identify MCs in the stratified squamous non-keratinized epithelium of the human vagina in 20 patients. For the identification of Merkel cells by light microscopy, we used antibodies against simple-epithelial cytokeratins (especially anti-cytokeratin 20). We also tried to identify them using transmission electron microscopy. Our investigation confirmed that 10 (50 %) of 20 patients had increased number of predominantly intraepithelial CK20 positive “Merkel-like” cells (MLCs) in the human vaginal epithelium. Subepithelial CK20 positive MLCs were observed in only one patient (5%). We tried to identify them also using transmission electron microscopy. Our investigation detected some unique cells that may be MCs. The purpose of vaginal innervation is still unclear. There are no data available concerning the distribution of MCs in the human vagina, so it would be interesting to study the role of MCs in the vaginal epithelium, in the context of innervation and epithelial biology.