[About evolution of sleep-wakefulness cycle in vertebrates].

Data about behavioral, somato-vegetative and neurophysiological parameters of sleep and wakefulness in insects, cold- and warm-blooded vertebrates are provided. Hypotheses existing now about evolutionary formation of separate sleep phases and stages in vertebrates are considered. In the review are shown the data about correlations of quantitative characteristics of sleep and wake in some mammals with basic metabolic rate, lifestyle, environmental habits. The original experimental results at formation of neurophysiological characteristics of sleep and wake in vertebrates, phylogeny and in ontogeny of mature and immature mammals are provided in detail. On the basis of own concepts about evolutionary development of sleep-wakefulness cycle in vertebrates the interactions of telencephalic, diencephalic and rhombencepalic parts of brain in the processes of cycle wakefulness cycle integration are discussed.

[On filo- and ontogenetic development of dopaminergic regylation of wakefulness-sleep cycle in vertabrates].

The comparative immunohistochemical researches of dofamine containing neurons and fibers are carried uot in telencephalic and diencephalic departments of the brain in different vertebratts (adults rats, rats aged 14 and 30 days and frogs). For analysis of quantitative changes dynamics in thyrozinhydroxylase, D1 and D2 immunoreactive material in sleep-wakefulness cycle the model of sleepdeprivation is used. There are found the facts of morphofunctional correlations in the reactions of dophaminergic system during ontogeny and phylogeny. Besides, the pharmacological effects of dofamine agonist and antagonists on the sleep-wakefulness cycle in young rats and in frogs are shown. So, dopamine and its agonist apomorphine increase in sleep-wakefulness cycle duration of sleep-like state ofcataplexy (homolog of the sleep) in frogs, in 30-day-old rats it increase the share of wakefulness and catalepsy. D1 receptors antagonist (SCH 23390) adminisrated to frogs, caused increase of wakefulness and catatonic type states duration, where as D2 receptors antagonist (apomorphine) increased cataleptic condition. Administration of dopamine antagonist (haloperidol) to 30-day-old rats previously causes the increase of cataleptic state, after which the slow wave sleep state is enhanced. The questions of phylo-, ontogenetic formation of dopaminergic system regulating role in sleep-wakefulness cycle, when transition mainly from neurosecretory diencephalic influences of dophamine to the mainly neurotransmittory functins of telencephalic regions occured, is discussed.

[Effect of apomorphine on the wakefulness--sleep cycle of the common frog Rana temporaria].

This work considers effects of introduction into spinal lymphatic sac of dopamine agonist--apomorphine-(APO) at doses of 0.1, 1.0, 2.0 and 4.0 mg/kg body weight on the common frog wakefulness-sleep cycle (WSC). Usually the frog WSC is represented by wakefulness and three types of passive-protective behavior: by immobility states of the type of catalepsy, catatonia, and cataplexy that are characterized by high thresholds of arousal and by different (corresponding to the name) skeletal musculature tones. These immoboloty forms are considered as homologues of mammalian stress-reaction, hibernation, and sleep. Low apomorphine doses produced in WSC a marked decrease of portion of wakefulness and an increase of the immoboloty state of the catalepsy; high doses, on the contrary, initially promoted in CNS an increase of wakefulness and the state of catalepsy by demonstrating thereby its stressogenic action; after this, in WSC these increased the portion of the sleep-like immobility state of the catalepsy type that is considered as a functional homologue of sleep of homoiotherms. In spectra of electrograms of the flog telencephalon the representation of waves of the delta diapason rose. Taking into account that the states of catalepsy and cataplexy in frogs are under control of the anterior hypothalamus, it can be suggested that manifestations of cataplexy (sleep) in frog are due to the low level of dopaminergic activity, whereas manifestations of catalepsy (the homologue of stress reaction) are due to the high dopamine content in the anterioi hypothalamic structures. Comparative analysis of changes in WSC of amphibians and mammals in response to administration of dopamine and its agonists allows thinking that the role of the dopaminergic neurotransmitter system in regulation of the vertebrate WSC is unanimous: the low level of activity of this system facilitates development of sleep (catalepsy), whereas the high level provides reaction of arousal and is actively included in the system providing stress-reaction.

[Participation of vertebrate forebrain activating systems in organization of the wakefulness--sleep cycle].

The article considers mechanisms of diencephalic-telencephlic interactions in regulation of the wakefulness-sleep cycle in various classes of vertebrates. In such interactions a special role is played by the dopaminergic systems that perform neurosecretory function at the level of diencephalon and neurotransmitter function at the level of telencephalon. Concepts of A. I. Karamyan and A. L. Polenov about the stage pattern of development of CNS and neurosecretory systems are presented as well as the interconnection of dopaminergic and glutamatergic neurotransmitter system in the mammalian neostriatum in the wakefulness-sleep cycle is considered. Comparison of dynamics of expression of the dopamine metabotropic receptors and of the glutamate ionotropic receptors in neostriatum showed unidirectional changes of D1 and AMPA on the background of the 6-h sleep deprivation as well as of D2 and NMDA on the background of postdeprivative sleep. The corticofugal direction of glutamate impulsation and its relatively fast actions allow admitting its triggering action on generation of the sleep-inducing processes in the underlying brain parts.

[Functional role of hypothalamic D1 and D2 receptors in organization of some forms of behavior of the common frog].

Dopamine is one of the most ancient, widely spread neurotransmitters that performs a great number of neuromodulator effects in the vertebrate CNS. For the last few years there considerably increases an interest in study of functional role of this neurotransmitter in regulation of various forms of behavior of poikilothermal vertebrates. The present work deals with study of the role of the dopaminergic system, specifically of the hypothalamic dophaminergic system in providing some behavioral frog reactions. We studies behavior of the animals in the "open field" before and after administration to them of antagonists of D1 (SCH 23390) and D2 (haloperidol) receptors as well as of animals with destructed anterior and posterior parts of hypothalamis. Administration of SCH 23390 to intact frogs caused a statistically significant decrease of the number of exploratory reactions and goal-oriented jumps, whereas haloperidol only moderately increased the number of the above reactions. Destruction of the posterior part of hypothalamus inhibited essentially all kinds of activity, while destruction of the anterior part suppressed them completely. Antagonists of D1 and D2 receptors of dopamin little changed the initial motor and emotional activity of the operated animals. The obtained data are discussed in the light of evolutionary origin of D1 and D2 receptors in the vertebrate subphylum and allow concluding that D1 and D2 receptors of hypothalamic dophamin of the common frog are located predominantly in the anterior hypothalamic areas and that their effect on behavior can be mediated and is associated with other brain neurotransmitter systems in such brain structures as lateral hypothalamus, locus coereleus, and striatum that provide different aspects of wakefulness.

[Evolutionary aspects of sleep and stress interaction: phylo-, ontogenetic approach].

This work deals the comparative behavioral, somatosensor and neurophysiological characteristics of these forms of passive defensive behavior included in amphibian's sleep-wakefulness cycle and their developmental dynamics in the ascending vertebrates secale. Sleep formation in early postnatal ontogenesis of mature- and immature-born mammals - from undifferent sleep to the mature sleep divided into two phases as well as stress formation are considered in parallel. Comparative phylo-, and ontogenetic analysis of several aspects of stress-reactions, sleep, and immobility phenomenon of cataleptic type allows concluding that amphibians and reptilians catalepsy can be interpreted as preadaptive from of behavior underlying in the stress of homoeothermic animals. Another word, the cataleptic state can be considered as the homologic state of stress-reaction. Catalepsy is the genetically programmed state of poykilothermic animals characterized by comparatively high alertness of animal, its freezing in immobile but active posture with a possibility of fast exit into waking state and alongside with other somatosensor and neurophysiological characteristics determines the entire subsequent complex of evolutionary morphofunctional, neurophysiological and hormonal changes in nomoyptherms. This in many aspects unspecific behavioral adaptive reaction in poykilotherms is realized on the corresponding hormonal and neurophysiological levels of development and promotes to fast mobilization and stabilization their homeostasis. At the higher evolutionary scale after development of most brain neurotransmitter and hypothalamo-pituitary-adrenal systems the leading role in stress regulation begins to be predominent the hormonal reaction. Only in the alertness phase of stress-reaction the elements of activation of extrapyramidal regulatory system of locomotion are observed. This is manifested by the cateleptic immobility. Thus the stress as the general adaptational syndrome reflects the evolutionary regularities of development of specific functions supporting the total homeostasis. The scheme of evolution of sleep-wakefulness cycle in vertebrates is presented; according to it, the immobility state of cataleptic type on one hand may to considered as a part of wakefulness providing mainly specific elements of stress-reaction, while on other hand it is a certain step of inhibitory processes in CNS for subsequent involvement of sleep-regulatory systems for the compensation and maintenance of recovery reactions.

[Dopaminergic system in the telencephalic and diencephalic brain regions in vertebrates in the sleep-wakefulness cycle organisation].

The aim of our study was to investigate the role of dopaminergic system in telencephalic and diencephalic brain regions of vertebrates in sleep-wakefulness cycle. The level of thyrosine-hydroxylase--the main enzyme in dopamine synthesis--was measured in striatum, zona inserta supraoptic and arcuate nuclea of hypothalamus in fish (Acipenceridae) and in mammals (rats) in ontogenesis (14-, 30-day old rats and adult animals) under tactile and sleep deprivation stresses. The thyrosine-hydroxylase-immunoreactive cells were revealed in all brain regions of fishes after a short-term stress. In the group after longtime stress, the thyrosine-hydroxylase-immunoreactive cells and fibers were almost absent in anterior brain but were found in hypothalamic nuclea. At 14-day old rats, 2-hour sleep deprivation caused increasing of thyrosine-hydroxylase-immunoreactivity both in fibers of caudate nucleus as well as in cells of the zona inserta. A 6-hour deprivation caused increasing of thyrosine-hydroxylase-immunoreactive material level in cells of zona inserta and decreasing it in fibers of 30-day old rats. In adult rats, the level of thyrosine-hydroxylase-immunoreactive material decreased in nucleus arcuatus and zona inserta after sleep deprivation and increased after sleep. Data obtained are discussed in terms ofphylo- and ontogenetic development of neurosecretory and neurotransmitter functions of dopaminergic system in evolutionary old diencephalic and evolutionary young telencephalic brain regions of vertebrates, which are the important systems of starting and maintenance of some functional conditions of the organism in sleep-wakefulness cycle.

[Diencephalo-telencephalic changes of tyrosine hydroxylase in rats and common frogs (Rana temporaria) after sleep deprivation].

Based on sleep deprivation-produced changes of electrographic parameters of the wakefulness--sleep cycle (WSC) in rats and common frogs, dynamics of activity of tyrosine hydroxylase, the key enzyme of dopamine synthesis, was studied immunohistochemically in substantia nigra and nigrostriatal pathway in rats and in striatum, paraventricular organ, and extrahypothalamic pathways in frogs. There are revealed changes in dynamics of tyrosine hydroxylase in rats and in common frogs after the 6-h sleep deprivation and after 2 h of postdeprivation sleep. This allows determining the degree of participation of corticostriatal neuroregulatory and hypothalamo-pituitary neurosecretory systems and their role in regulation of WSC. Possible evolutionary peculiarities of morphofunctional differences in homoiothermal and poikilothermal animals are discussed.

[Effect of swinging on EEG of rats of juvenile age in the wakefulness state].

Simultaneous recording of the EEG activity of superficial cortical and deep (caudate nucleus, dorsal hippocampus, anterior hypothalamus) brain parts has been performed for the first time after a 2-h swinging of frequency of 0.2 Hz in Wistar rats of juvenile age. Swinging was produced on a 4-bar parallel swing. Using a Neuron-Spectr electroencephalograph and a Diana program, normalized power spectra of wave EEG components, synchronization coefficients, and coefficients of cross-correlation between bioelectrical potentials of various brain structures were determined. After a 2-h swinging, the mean value of normalized power of slow waves of delta-diapason in hypothalamus and hippocampus was found to increase statistically significantly, while normalized power of fast waves of alpha- and beta1-diapasons in hippocampus decreased (p < 0.05). A statistically significant increase of synchronization coefficient was observed in hypothalamus and hippocampus. Changes of coefficients of cross-correlation between hypothalamus and hippocampus and other brain strictures were of the oppositely directed, individual character. In the parietal occipital brain cortex and in caudate nucleus, the changes of the EEG spectral composition also were of individual character. The obtained results on the whole correspond to data about an enhancement of the EEG low-frequency rhythms at swinging and agree with the resonance hypothesis of motion sickness.

[Effect of photostimulation on the wakefulness-sleep cycle in the common frog Rana temporaria].

Effect of daily 30-min photostimulation in the 10 s light: 10 s pause (the total of 5 days) on the time structure of the wakefulness--protosleep cycle (WPC) was studied in the common frog Rana temporaria. Changes were analyzed of EEG wave components in three immobility forms of the type of catalepsy (P-1), catatonia (P-2), and cataplexy (P-3) that form protosleep. The first three photostimulations promoted a gradual increase of the P-1 state to 84.16 +/- 11.6% [the initial value (IV) 22.9 +/- 9.1%] and a decrease of representation of wakefulness to 4.86 +/- 2/1% (IV 13.8 +/- 7.8%), of P-2 to 11.1 +/- 5.3 (IV 53.3 +/- 13.3%), and of P-3 to 2.21 +/- 1.0% (IV 11.1 +/- 5.6%). After 4-5 photostimulations and especially after their complete cessation the percentage of P-1 in the WPC was restored to initial values, whereas the percentage of the frog WPC P-3 considered to be a precursor of the homoiothermal sleep rose to 20 +/- 8.3% after 5 photostimulations and to 38.5 +/- 6.7% the next day. Changes in the frog EEG spectra appeared only after one photostimulation and were characterized by a brief increase of power of alpha-like waves and by inhibition of slow 6-waves. In P-2 the power of the slow delta-waves gradually rose. In P-3 the EEG parameters did not change. In all experimental animals a decrease of the relative thymus and adrenal masses was revealed, which indicates the photostimulation regime used in the work induces stress. The obtained data allow thinking that a certain neurohormonal response to stress has already been formed at the amphibian level and that an important role in this response realization is played by a coordinated interaction of the hypothalamic sleep-regulating system providing protosleep manifestations and of the hypothalamic neurosecretory system triggering the stress-reaction hormonal cascade.

[The effect of dopaminergic nigrostriatal system on sleep deprivation in rats].

The analysis of the electrophysiological features of sleep-wakefulness cycle in Wistar rats for 9h after a 6h sleep deprivation was carried out. The delay of sleep rebound (since 2.5-3 h after deprivation) was found in the form of moderate increasing of slow-wave sleep and fast-wave sleep phases. According to these sleep-wakefulness cycle changes, a quantitative immunohistochemical study of tyrosine hydroxylase: a key enzyme of dopamine synthesis--and D1 and D2 receptors in nigro-striatal projections has been performed. After sleep, an elevation of D1 receptors immunoreactivity in caudate nucleus and reduction of tyrosine hydroxylase immunoreactivity in compact part of substancia nigra was found. After postdeprivation sleep, a decrease of D1 receptors immunoreactivity and increase of D2 receptors immunoreactivity in caudate nucleus together some increase of tyrosine hydroxilase immunoreactivity in substancia nigra compacta has been observed. These data can testify about active role of dopaminergic nigrostriatal system which provide at the same time with another neurotransmitters of the central nervous system the telencephalo-diencephalic interaction in sleep-wakefulness-sleep cycle.