In temperate zones duration of daylight, i.e. photoperiod, changes with the seasons. The changing photoperiod affects animal as well as human physiology. All mammals exhibit circadian rhythms and a circadian clock controlling the rhythms is located in the suprachiasmatic nucleus (SCN) of the hypothalamus. The SCN consists of two parts differing morphologically and functionally, namely of the ventrolateral (VL) and the dorsomedial (DM). Many aspects of SCN-driven rhythmicity are affected by the photoperiod. The aim of the present overview is to summarize data about the
effect of the photoperiod on the molecular timekeeping mechanism in the rat SCN, especially the effect on core clock genes, clock-controlled genes and clock-related genes expression. The summarized data indicate that the photoperiod affects i) clock-driven rhythm in photoinduction of c-fos gene and its protein product within the VL SCN, ii) clock-driven spontaneous rhythms in clock-controlled, i.e. arginine-vasopressin, and in clock-related, i.e. c-fos, gene expression within the DM SCN, and iii) the core clockwork mechanism within the rat SCN. Hence, the whole central timekeeping mechanism within the rat circadian clock measures not only the daytime but also the time of the year, i.e. the actual season.
The role of the striatal adenylyl cyclase (AC) and cholinergic systems in the learning and expression of new forepaw movements (reaching with prolonged pushing on a fixed piston) was studied in male Wistar rats. Motor learning processes, prenatal hypoxia, and cholinergic drugs changed the properties of the AC system in the striatum. After learning, the striatal basal AC activity was decreased compared to untrained control rats. In addition, the AC activity was more decreased in animals with a good ability to learn compared to poor learners (up to 31 % and 51 %, correspondingly; p<0.01). Rats subjected to prenatal hypoxia (13-14th days of embryogenesis) had a lower ability to learn the new movements requiring tactile control and the striatal AC activity in these rats was 1.8 times higher (p<0.001) than controls. In vitro application of the cholinergic agonist carbachol (CARB) 10-5 M (corresponding to ~ 0.3 µg), as well as the antagonist scopolomine (SCOP) 10-5 M (~ 0.3 µg) decreased AC activity in the synaptosomal fraction of the striatum. In vivo injections of CARB (0.3-3 µg/1µl) or SCOP (0.3-3 µg/1µl) into the ventral striatum (nucleus accumbens) modified the newly learned sensorimotor skill. After CARB injections the rats performed slower movements with more prolonged pushing. After SCOP the rats could not retain the learned pushing movement. These in vivo and in vitro data suggest that the cholinergic mediator system of the striatum is involved in learning sensory-controlled forepaw movements as well as the regulation of new motor skills by modulating the AC signal transduction process in the striatum. The data confirmed that modification of the striatal AC system resulted in the modulation of reaching behavior and better expression of the learned reflex., I. A. Zhuravin, N. M. Dubrovskaya, S. A. Plesneva., and Obsahuje bibliografii
The relationship between hippocampal function and aging was explored in Wistar rats using taste aversion learning by comparing the performance of adult dorsal hippocampal lesioned and fifteen-month-old intact rats with that of adult intact rats. In experiment 1 the conditioned blocking phenomenon was absent in the hippocampal and the aging rats. Unlike the adult intact rats, the hippocampal and aging rats were not impaired in acquiring a learned aversion to a cider vinegar solution (3 %) presented as a serial compound with a previously conditioned saccharin solution (0.1 %). In experiment 2 both the hippocampal and the aging rats developed reduced aversions to a saline solution (0.5 %) followed by an i.p. injection of lithium chloride (0.15 M; 2 % b.w.) if the taste solution was previously preexposed without consequences. This latent inhibition effect was similar to that seen in intact adult rats. In both experiments, the aging rats exhibited enhanced conventional learned taste aversions. It is concluded that aging is not a unitary process but induces both hippocampal dependent and hippocampal independent complex changes in the functioning of the neural circuits, implementing taste aversion learning., I. Moron, M.A. Ballesteros, A. Candido, M. Gallo., and Obsahuje bibliografii
In the present study, we investigated the effects of vagus nerve stimulation (VNS), a proposed treatment for patients with intractable epilepsy, on cardiac rhythm following seizures induced by pentylenetetrazole (PTZ) in Wistar rats. After a baselinerecording of electroencephalogram (EEG), electrocardiogram (ECG) and blood pressure (BP), rats in the first group received a single convulsive dose of PTZ (70 mg/kg) (Group 1). In the other
two groups, the Wistar rats were implanted with a cuff electrode on the left cervical vagus nerve. One day after surgery, rats in the second group were treated with VNS (Group 2), whereas rats in the third group were connected to the stimulator but did not receive VNS (Group 3). Ten minutes after VNS onset, 70 mg/kg dose of PTZ was injected. EEG, ECG and BP were continuously recorded during post-injection period. Seizure severity was scored behaviorally. Then, baseline, ictal and postictal periods were analyzed for cardiac rhythms, seizure severity and blood pressure variability. PTZ treatment induced tonic-clonic seizure activity in all animals of Group 1 and Group 3. In these groups a marked increase of mean arterial blood pressure (MABP) but a significant decrease in heart rate and PP interval fluctuations was observed at postictal period. However, in the VNS-treated group the seizure scores and cardiac parameter returned to the baseline level. Present results emphasize that VNS effectively reduces seizure severity and suppress the seizure-induced cardiac rhythm changes.