Vol 52, No 1 (2016)

The review presents data on functional changes in fish, amphibians and birds associated with otolith organ activity after exposure to weightlessness during spaceflight. These data are of importance both for solving some fundamental problems of vestibulology and for practice. In the latter case, lower vertebrates are considered as a convenient and, most importantly, adequate model to unravel the mechanisms of vestibular disorders in humans. Analysis of the experimental results shows that weightlessness exerts no substantial effect on the formation and functional state of the otolith system in embryos of fish, amphibians and birds developing during spaceflight. Moreover, they even promote faster embryonic development of fish and amphibians as shown for mammalian fetuses. The experiments show that both in lower and higher vertebrates weightlessness brings about similar functional and behavioral changes. For example, in fish hatchlings and amphibian tadpoles (without lordosis) the vestibulo-ocular reflex was more pronounced immediately after orbital spaceflight than in control. An analogous alteration in the otolith reflex was observed in most cosmonauts after short-time space missions. In adult terrestrial vertebrates, as well as in humans, immediately after landing there was found a drop in the level of activity and deterioration of the equilibrium function and motor coordination. Another interesting finding was an unusual looping behavior when fish and tadpoles swam in loops post landing. Presumably, unusual motor activity of animals, as well as illusions arising in cosmonauts and astronauts during the transition from 1 to 0 g, have the same background being associated with changes in the stimulation pattern of the otolith organs. Considering the similarity of vestibular responses, the use of animal models seems very promising as allowing different invasive techniques.

Sex steroid and cortisol levels were compared in Leibovitz’s L-15 cultural medium after incubation of tissue samples from the intact female and male sterlet (Acipenser rhutenus L.) and from the fishes exposed to hormonal stimulation of sexual maturation by a superactive analog of mammalian gonadotropin-releasing hormone (LH-RH-A). A higher level of 17,20β,21-trihydroxy-4-pregnen-3-one (20βS) was revealed in the cultural medium following incubation of ovarian follicles isolated from females 5 h after LH-RH-A stimulation, as compared to the data obtained for intact females. The addition of 1 μM progesterone (P₄) to the cultural medium before incubation of ovarian follicles also led to an increase in the 20βS level in the incubates by the end of the experiment. Cortisol and testosterone levels in the incubates exhibited the same tendency. The blood cortisol level significantly increased in females 5 h after their hormonal stimulation. In males, showing high levels of androgens (testosterone and 11-ketotestosterone) in the blood serum before hormonal stimulation, high levels of these hormones were also detected in the cultural medium after incubation of testicular and liver tissue samples. The addition of P₄ to the medium before incubation stimulated the production of sex steroids and cortisol by the gonadal fragments. Upon addition of P₄ to the incubation mixture, containing liver tissue samples, the 20βS level increased.

A set of normal biochemical indices of the hemolymph plasma in the gastropod pulmonate mollusc Achatina fulica was described in this study. A comparative analysis of the whole plasma and its subfractions enriched with and depleted of the oxygen-carrying protein hemocyanin was carried out using spectrophotometry and spectrofluorimetry. Individual features of the absorption spectra were analyzed using fourth derivatives. An optimal method to estimate the protein concentration was identified. The buffer capacity, equivalence points and pK values of the dominant buffer groups were calculated to characterize the acid-base properties of hemolymph plasma and its subfractions. A major role in maintaining the hemolymph buffer capacity was shown to belong to the bicarbonate buffering system. The results of this study are compared with the data for Helix pomatia available in literature. In the future, the tested indices will be used to devise ecotoxicological criteria for environmental assessment.

Using a computer graphics approach, the last contractile responses (LCR_N, where N is a number of elementary contractile responses in tetanus) were separated from integral tetanic responses of rat fast muscles, m. Eхtensor digitorum longus (m. EDL), and slow muscles, m. Soleus, evoked by trains of 5, 10 and 50 stimuli. In m. Soleus, at a stimulation frequency of 20 Hz, the LCR₅ average amplitude decreased to 64 ± 9% compared to the single contraction amplitude. As N increased, LCR_N recovered and then rose to the values exceeding almost twofold initial elementary contractile responses (up to 211 ± 10% for LCR₅₀). Simultaneously, against the background of rising elementary contractile responses, a significant shortening of their half-decay time (∼by 50%) and the formation of a stationary plateau within LCR_N was observed. In m. EDL, at a stimulation frequency of 50 Hz, there was only a single-phase LCR_N rise (up to 165 ± 18% for LCR₅₀) without changes in half-decay time and plateau formation. In skeletal muscles of both types, the prolonged (up to 30 s) ‘hyper-relaxation effect’ was found to develop after the end of tetanic responses manifested as a reduction of muscle tension followed by its recovery to the initial level. Possible mechanisms of these events are discussed. It is hypothesized that transformation of elementary contractile responses in skeletal muscles can be fulfilled due to the existence of specialized microdomains in muscle fibers which regulate accumulation and extrusion of Ca²⁺ ions during tetanic activity. The possibility that the basic, depolarization-induced, Ca²⁺ release (DICR) is complemented by an additional, Ca²⁺-induced, Ca²⁺release (CIRC) is analyzed.

Neurodegenerative changes and neuronal death underlie ageing of the nervous system. We investigated the mechanisms of apoptosis in sensorimotor cortical neurons of HER2/neu transgenic mice during ageing, as well as the functional changes in the cortex and the involvement of exogenous neurometabolites (cytoflavin, piracetam) in the regulation of neuronal death and locomotor and psycho-emotional status in mice. The level of apoptosis and expression of the apoptotic protein markers (TUNEL, immunohistochemistry, Western blotting) were detected in HER2/neu transgenic mice versus wild type mice (FBV strain). In ageing wild type mice, the basal activity decreases while the anxiety level increases correlating with the high level of neuronal apoptosis. We revealed specific behavioral features of HER2/neu transgenic mice—their low basal activity which remains intact during ageing. Previously, we have shown that in this mouse strain the level of apoptosis is low, with no age-related dynamics, due to the suppression primarily of the p53-dependent pathway by HER2 (tyrosine kinase receptor) overexpression. Here we show that cytoflavin and piracetam have a pronounced neuroprotective effect, preserving and restoring the nervous system functions (improving locomotion and psychological status) in both mouse strains. The effect of the tested neurometabolites on neuronal apoptosis is ambiguous. In case of low-level apoptosis, there occurs its moderate stimulation in HER2/neu transgenic mice that are characterized by a high level of carcinogenesis (via the extrinsic and p53-dependent pathways with caspase-3 activation) which probably prevents tumor development. By contrast, in aged wild-type mice there is a marked decrease in the level of age-related apoptosis (via the stimulation of antiapoptotic protein Mcl-1 expression) supposed to prevent neurodegeneration.

Since long ago, one of the most vital issues mankind is concerned about is why spending almost one-third of human lives for sleep. This review addresses the major function of slow-wave sleep (SWS) and molecular mechanisms of its regulation. The main conclusions are presented below as the following generalizations and hypotheses. 1. SWS performs an energy-conserving function which developed parallel to the evolution of tachimetabolism and endothermy/homoiothermy. 2. Most significant reduction in the brain energy demands during deep SWS, characterized by increased EEG delta power, creates optimal conditions for the enhancement of anabolic processes and actualization of the major biological function of sleep—accelerating protein synthesis in the brain. 3. Conditions of paradoxical sleep (PS) as an “archeowakefulness”, containing the elements of endogenous stress, seem acceptable for chaperone expression required to fix misfolded proteins synthesized de novo during deep SWS. 4. Close integration of the HSP70 and HSP40 molecular systems, contained in the sleep center of the preoptic area of the hypothalamus, and their compensatory interrelationship contribute significantly to the maintenance of sleep homeostasis and implementation of its functions under non-stress conditions and during a long-term chaperone deficiency intrinsic to ageing and varied neuropathologies. 5. Cyclic changes in the protein synthesis rate (during deep SWS) and HSP70 chaperone expression (during wakefulness and, probably, PS), which occur on a daily basis throughout the entire lifetime, are critical for all vital functions of homeothermic organisms, including recovery of the nervous system structure and functions.