Protective effect of hypothermia on brain neurons of rats exposed to ionizing radiation

The conditions of the protein-synthesizing system in neurons of the hippocampus (areas CA1 and C A3) and of the cortex (sensomotor region) in rats subjected to y-irradiation at a dose of 8 Gy under hypothermia (16 - 18 degrees C) and hypoxia-hypercapnia were investigated by fluorescent and electron microscopy. Under hypothermia, the protein-synthesizing system was shown to be damaged to a lesser degree and to be restored faster in comparison with similar neurons in rats irradiated at room temperature. In rats irradiated under hypothermia, the rRNA biogenesis and the protein-synthesizing activity of polyribosomes were restored in two days. The protective influence of hypothermia did not spread to changes in membrane structures (endoplasmic reticulum and Golgy apparatus); i.e., a partial loss of integrity and possible transformation of their structure caused by the irradiation and the restoration of these structures occurred at a lower rate.     

The effect of hypothermia on the rat radioresistance

The cooling of Wistar rats up to 15-19 degrees C under a condition hypoxia-hypercapnia increased the radioresistance with a dose reduction factor (DRF) of 1.4. To elucidate the mechanisms of hypothermia radioprotective effect was evaluated the functional state of rat neocortex using a electroencephalogram (EEG) as well as was studied the lipid composition of neocortex under the conditions of both normothermia and hypothermia. At 19-20 degrees C the activity within a wide range of frequencies in EEG was suppressed; the nonregular slow waves were recorded against a background of "silence". The reduction of EEG spectrum with increasing temperature began with the low frequencies. At 26-28 egresC the contribution of theta-rhythm (an indicator of brain activity level) in EEG reaches the normothermia value, from this point the rat brain starts to functionate as a whole system. At normothermia the similarity of neocortex lipid composition in nonhibernators (rats) and hibernators (ground squirrels) mammalians was noted. The difference is only in a higher content of phosphatidylinositol in rats. Rats falling into hypothermia state as well as ground squirrels into torpor is followed by a decrease of cholesterol content and the absence of significant changes of the phospholipid composition in neocortex tissues.     

The functional brain state of hibernators and nonhibernators at different animals temperatures

Literature and our own data on structural and functional state of neocortex and hippocampus during both entrance in hibernation of ground squirrel (Spermophilus undulates) and Wistar rats in hypothermia were generalized. During hibernation when body temperature is about 2-4 degrees C the suppression of both bioelectrical and protein-synthesizing activity, the decrease of neuronal cell bodies and the branching of dendrites, retraction of dendritic spines, and a decrease of postsynaptic active zones of synapses were observed. Similar changes in those parameters were triggered for rats during hypoxia-hypercapnia at body temperature 17-19 degrees C. Hypoxia-hypercapnia facilitates the entrance in torpid state for hole animals. Nonhibernating animals during cooling and hypoxia-hypercapnia trigger functioning some mechanisms similar hibernators during entrance in hibernation. Similar morphological and functional changes for both hibernators and nonhibernators at low temperature state show similarity of mechanisms which induce a low level of brain activity of different animals.     

The influence of hypothermia on the restoration of neural activity of brain slices from hibernating ground squirrels

1. 1. Neural activity was recorded in hippocampal slices from deep hibernating Yakut ground squirrels and in hippocampal and septal slices from non-hibernating animals.

2. 2. Slices were placed immediately after preparation in hypothermic conditions (3–4°C). Their activity was tested under standard conditions at 31°C in the incubation chamber. Some of the prepared slices were tested after maintenance in hypothermia for 2 or 24 h.

3. 3. In the hippocampal slices of hibernating ground squirrels, neural activity was present, irrespective of the period in hypothermia.

4. 4. Slices from guinea-pigs and hamsters did not possess neural activity after either 2 or 24 h of hypothermic treatment.

     

A comparative analysis of restoration of electroencephalographic and protein-synthesizing activities in neocortex and hippocampus in hibernating (ground squirrels) and nonhibernating (rats) animals during exit from hypothermia

A similarity in the sequence of restoration of the EEG spectrum between ground squirrels arousing from torpor and rats passing out of artificial hypothermia (17-18 degrees C) was shown. First of all, the low-frequency part of the EEG spectrum was restored. As animals warmed up, their breathing became hurried, cold shivering appeared, and the theta- and alpha-rhythms increased. During the exit from hypothermia, the activity of the protein-synthesizing system in both rats and ground squirrels was almost entirely restored when the animal body temperature achieved 21-22 degrees C. In ground squirrel, the rate of protein synthesis in the neocortex was lower than in hippocampus CA1 and CA3 areas, whereas in rats, on the contrary, it was higher in the neocortex in comparison with the CA3 area.     

Influence of ionizing radiation on the condition of the protein-synthesizing system in ground squirrel brain neurons at different functional states

It was shown by fluorescent and electron microscopy that the physiological state of ground squirrels subjected to ionizing radiation at different phases of the torpor-normothermia cycle plays a determining role in the alteration of the conditions of the protein-synthesizing system in neurons of hippocampus fields CA1 and CA3 and sensomotor area of the brain. In ground squirrels irradiated under normothermia, the neurons were less radioresistant and restored slower compared with torpor animal cells, the distinctions being most expressed in CA1 field neurons. The effect of irradiation was minimum during the entrance into torpor and maximum during arousal. It was supposed that the inhibition of protein synthesis in the latter case occurred at the elongation stage when heavy polyribosomes were formed in neuron cytoplasm.     

Comparative analysis of morphofunctional features of cortical neurons in ground squirrels and guinea pigs under hypothermia

Activity of sensorimotor cortical neurons in the ground squirrel was studied on slices under cooling the incubation medium from 32–34 to 21–26°С. Hypothermia evoked spontaneous firing activity in “silent” neurons and a slight decrease in firing in high-frequency neurons. Changes in the firing rate arose below 27°С and were accompanied by a fall in the spike amplitude. The intensity of hypothermic and post-hypothermic changes in ground squirrels was lower than in guinea pig sensorimotor cortical neurons recorded under the same conditions. In ground squirrels, most hypothermia-resistant were high-frequency (more than 8 spikes/s) neurons, which accounted for 45% of the recorded, while in guinea pigs high-frequency neurons occurred only in 15% of records. By the diameter of cell bodies, the population of sensorimotor cortical neurons was more homogeneous in ground squirrels than in guinea pigs. It is suggested that specific hypothermic changes in sensorimotor cortical neurons of ground squirrels relate to a lower density of K⁺ channels in their plasma membranes, because in the mammalian nervous system the latter open below 27°С due to thermal limitations of the M-cholinergic reaction which blocks these channels.     

The effect of hypothermia on the wavelength and vulnarability to ventricular arrhythmias in mammals

Arrhythmias developing in isolated Langendorff-perfused heart following the cooling of the perfusion solution from +37 to +3 degrees C were studied in rats and winter hibernating ground squirrels Citellus undulatus with application of no drugs. In rats, hypothermia significantly increased the probability of ventricular arrhythmias (from 22 +/- 6 % at 37 degrees C to 56 +/- 14 % at 17 degrees C). Excitation failure was observed in the rat hearts below 10 +/- 1 degrees C. The appearance of arrhythmias was closely correlated with a decrease in the wavelength which strongly suggests a reentrant mechanism of the hypothermic arrhythmias. In contrast, ground squirrels showed insensibility of the wavelength to cooling and were resistant to arrhythmias during hypothermia.     

Topochemical aspects of nucleic-acid and protein metabolism within the neuron-neuroglia unit of the hypothalamic supraoptic nucleus

The RNA and both the total and basic protein content of individual cells were determined by cytospectrophotometry in neurons and perineuronal oligodendroglia of the hypothalamic supraoptic nucleus in rats subjected to various stresses, as well as in ground squirrels during natural hibernation. Barbiturate narcosis and deep cooling, which induced a decrease in body temperature in rats and hibernation in squirrels, caused a marked decrease of all macromolecular constituents in neurons. A similar decrease was found in the perineuronal oligodendroglia in rats, but an increase was observed in ground squirrels. After cessation of cooling, while the body temperature of the animals returned to normal, the neurons, but not the oligodendroglia, of rats showed a significant accumulation of RNA, while RNA accumulated in both neurons and perineuronal oligodendroglia in ground squirrels. Milder cooling of rats, which did not lower their body temperature, induced reciprocal changes in basic-protein content in neuronal and glial cell nuclei, with the accumulation of protein occurring initially in neurons, and subsequently in glia. When cold adaptation was accomplished, the basic protein content of neurons and glial cells returned to the control level. Four days after adrenalectomy in rats, the RNA content decreased in oligodendroglia but not in neurons of the supraoptic nucleus. This effect was completely abolished by daily injections of cortisol in the adrenalectomized animals. The data obtained indicate the existence of differences in metabolic responses to stress between neurons and glial cells of the supraoptic nucleus of the hypothalamus.     

The radioprotective effect of hypothermia on the immune and hematopoietic systems in mammals

The functional activity of the synthetic apparatus (parameter alpha) in blood lymphocytes, bone marrow hemopoietic cells, and thymus cells, as well as the total number of blood and bone marrow cells in rats after y-irradiation at a dose of 8 Gy in the conditions of normothermia and hypothermia (16-18 degrees C) with hypoxia-hypercapnia were investigated after 2 h and on days 1 and 4. The recovery processes in blood in both groups of rats after acute X-irradiation at a dose of 7 Gy for 36 days were analyzed too. Under hypothermia, on days 1-4 after acute gamma-irradiation, a decrease in the synthetic activity in remaining cells and devastation in the hemopoietic system were pronounced to a lesser degree. After X-irradiation, the restoration of synthetic activity in blood lymphocytes was shown to begin earlier and to finish faster in "hypothermic" rats as compared with the animals irradiated in the state of normothermia. The survival of "hypothermic" rats was 100% as compared with 30% in "normothermic" animals. Thus, the data show that hypothermia exerts a radioprotective effect on the cells of the immune and hemopoietic systems, thus enhancing the resistance of the organism to radiation.     

Protective effect of hypothermia on brain neurons in rats exposed to ionizing radiation

The protein-synthesizing system of hippocampal (CA1, CA3) and sensorimotor cortex neurons is damaged less and recovers much quicker in rats exposed to 8 Gy of γ-radiation under hypoxia/hypercapnia (body temperature 16–18°C) than under usual conditions, as evidenced by microfluorimetry and electron microscopy. The radioprotective effect does not cover the membrane structures (endoplasmic reticulum and Golgi complex), and their restoration is not so prompt.     

Protein synthesis in cardiac cells and the ultrastructural dynamics of cardiomyocytes of hibernating animals during the hibernation cycle

A significant increase in protein synthesis correlating with ultrastructural dynamics of cardiomyocyte organelle convertions has been demonstrated in cardiomyocytes of ground squirrel during arousal from hibernation. In hibernating ground squirrels, the ultrastructure of protein-synthesizing organelles and of the cardiomyocyte nucleus points out to the readiness of cells to active synthesis of proteins. In the perinuclear area of cardiomyocytes abundant ribosomes, elements of endoplasmic reticulum and Golgi complex, mitochondria and high-energy substrates--glycogen and lipid inclusions--are seen. The cardiomyocyte nuclei are large, with highly convoluted borders and abundant pores, their nucleolar structure is granular, the chromatin is mainly diffuse. The potency of cardiomyocyte protein-synthesizing system of hibernating ground squirrels is realized every time at periodical arousals during hibernation. The role of cyclic changes of protein synthesis rate in adaptation of cells of hibernating mammals to functioning at various temperatures is discussed.     

The paradoxically high reactivity of septal neurons in hibernating ground squirrels to endogenous neuropeptides is lost after chronic deafferentation of the septum from the preopticohypothalamic areas

The effect of neuropeptides (TSKYR, TSKY and DY) and neurotransmitters (serotonin and noradrenaline) on the activity of medial septum (MS) neurons from the brain of summer wakening ground squirrels (WGS), hibernating ground squirrels (HGS), and hibernating ground squirrels with the undercut septum (UHGS) was studied. It was shown that in HGS, the neuropeptides were substantially more effective in modulating the spontaneous activity of MS neurons than in WGS. The undercutting of MS led to the disappearance of the increased responsiveness to the neuropeptides: in UHGS, neuropeptide-induced changes in the spontaneous activity became nearly identical to those in WGS. The decrease in MS responsiveness in UHGS is due mainly to pacemaker neurons, which cease to respond to the peptides. It was shown that the neuropeptides have a dual effect: they change the level of spontaneous activity through direct modulation of pacemaker potential and control responses to electrical stimulation by modulating the synaptic transmission. Contrary to neuropeptides, neurotransmitters were highly effective in neurons of all groups of animals. Presumably, the enhanced excitability of MS during hibernation, which is necessary for performing the 'sentry post' function, is formed under the influence of the preopticohypothalamic area, and this influence is mediated by peptides.     

Effect of ionizing radiation on the protein-synthesizing system of brain neurons of ground squirrels in different functional states

Using fluorescence and electron microscopy, it is shown that the physiological state of ground squirrels exposed to ionizing radiation at different stages of the torpor-awakeness (hypothermia-normothermia) cycle is the main factor responsible for changes in the protein-synthesizing system of neurons in the hippocampus (fields CA1 and CA3) and the sensomotor cortex. The neurons of animals irradiated in the state of awakeness are less radioresistant and recover more slowly than neurons of animals irradiated in torpor, with the difference being more distinct in neurons of the CA1 field. The effect of irradiation is weak in animals entering torpor and reaches a peak in awakening animals. It is proposed that the inhibition of protein synthesis in the latter case takes place at the elongation stage, with heavy polysomes formed in the cytoplasm of neurons.     

Regulation of glucokinase activity in liver of hibernating ground squirrel Spermophilus undulatus

The kinetic properties of glucokinase (GLK) from the liver of active and hibernating ground squirrels Spermophilus undulatus have been studied. Entrance of ground squirrels into hibernation from their active state is accompanied by a sharp decrease in blood glucose (Glc) level (from 14 to 2.9 mM) and with a significant (7-fold) decrease of GLK activity in the liver cytoplasm. Preparations of native GLK practically devoid of other molecular forms of hexokinase were obtained from the liver of active and hibernating ground squirrels. The dependence of GLK activity upon Glc concentration for the enzyme from active ground squirrel liver showed a pronounced sigmoid character (Hill coefficient, h = 1.70 and S _0.5 = 6.23 mM; the experiments were conducted at 25°C in the presence of enzyme stabilizers, K⁺ and DTT). The same dependence of enzyme activity on Glc concentration was found for GLK from rat liver. However, on decreasing the temperature to 2°C (simulation of hibernation conditions), this dependency became almost hyperbolic (h = 1.16) and GLK affinity for substrate was reduced (S _0.5 = 23 mM). These parameters for hibernating ground squirrels (body temperature 5°C) at 25°C were found to be practically equal to the corresponding values obtained for GLK from the liver of active animals (h = 1.60, S _0.5 = 9.0 mM, respectively); at 2°C sigmoid character was less expressed and affinity for Glc was drastically decreased (h = 1.20, S _0.5 = 45 mM). The calculations of GLK activity in the liver of hibernating ground squirrels based on enzyme kinetic characteristics and seasonal changes in blood Glc concentrations have shown that GLK activity in the liver of hibernating ground squirrels is decreased about 5500-fold.     

The effects of artificial analogue peptide TSKY isolated from the brain of hibernating ground squirrels in rats and mice

Elevation of the i.c.v. injection dose of TSKY from 4 to 8 microg increased the movement activity of rats; in EEG theta- and beta-rhythms were enhanced and alpha-rhythm was suppressed. On the contrary, after treatment of 15 microg the rats fell into sleepy-like state; theta- and beta2-rhythms suppression, delta-, alpha- and beta1-rhythms were increased. Exposure under hypoxia-hypercapnia conditions reduced body temperature of mice to 18-19 degrees C, and maintain this state about 3-4 h after transferring into conventional gas medium. Preliminary cooling mice were administrated with TSKY that at dose 100 microg intraperitonally induced a prolonged hypothermia up to 12 h. Analogous injection without cooling raised mice temperature by 1.2 degrees C during about 2 h.     

Effect of total hypothermia on the fatty acid composition of blood phospholipids of rats and ground squirrels and of the light irradiation on chemical processes in lipid extract

Effect of hypothermia on the fatty acid composition of rat and ground squirrel blood phospholipids is studied. Different reaction of these animals to cooling is revealed; in rats no changes were observed in the fatty acid composition of blood phospholipids, whereas in the winterhibernating ground squirrels there were significant changes in the content of individual fatty acids (FA). The content of monoenic acids in ground squirrels decreased almost by 50%, while the content of saturated acid (C18) and of polyenic acids C18: 2ω6 and C20: 4ω6 rose significantly. Such changes seem to be the mechanism that promotes maintenance of the organism viability under conditions of a decreased level of metabolism, heart rhythm, and body temperature and is evolutionary acquired. At the same time, the observed changes in the content of individual FA do not lead to sharp changes in such integrative parameters as the total non-saturation of phospholipids, which determines liquid properties of chylomicrons and other lipolipoprotein transport particles of the ground squirrel blood. There are studied absorption spectra of blood lipid extracts of rats and ground squirrels under effect of light as well as effect of light upon the FA composition of lipid extracts of these animals. The FA composition of lipid extracts has been established to remain practically constant, whereas the character of changes of spectra under action of light indicates the presence in the extracts of oxidation-reduction reactions. The obtained data allow suggesting that in the lipid extract there occurs cooperation of both the phospholipids molecules themselves and of them with other organic molecules, which makes it possible for fatty acids to participate in processes of transport both of electrons and of protons. This novel role of FA as a participant of the electron transfer might probably be extrapolated to chemical reactions (processes) occurring inside the membrane.     

Role of lipids in the assembly of endoplasmic reticulum and dictyosomes in neuronal cells from the cerebral cortex of Yakutian ground squirrel (Citellus undulatus) during hibernation

Phospholipids and cholesterol were assayed in homogenates and microsomal fractions from the cerebral cortex of summer-active, winter-torpid, and winter-active Yakutian ground squirrels (Citellus undulatus). Ultrastructural analysis of both microsomal fraction and intact neurons was performed by serial ultramicrotomy. The levels of sphingomyelin (SM), phosphatidylserine (PS), and phosphatidylethanolamine (PEA) were decreased in homogenates from the cerebral cortex of winter ground squirrels compared with the summer-active animals, while the levels of phosphatidylcholine (PC) and cardiolipin (CL) were increased. The level of cholesterol was decreased in the cerebral cortex of winter-torpid animals compared with both winter-active and summer-active animals, and the level of total phospholipids was decreased in comparison to the summer-active animals. Three-dimensional reconstruction of serial membrane profiles displayed the microsomal fraction to be an interconnected system of cisterns and vesicles, which corresponds to endoplasmic reticulum and dictyosomes (Golgi stacks) of intact neurons. In winter the content of PC was increased in the microsomal fraction, while the contents of lysophosphatidylcholine (LPC), PS, phosphatidylinositol (PI), and SM were decreased. In winter-torpid animals compared with the winter-active ones the contents of total phospholipids, PEA, LPC, and cholesterol were decreased. As for the winter-active ground squirrels, their lipid contents did not differ from those in the summer-active animals, but LPC content was decreased. The changes in microsomal lipid contents in intact pyramidal neurons throughout the hibernation were accompanied by disassembly of dictyosomes and endoplasmic reticulum (ER), including the decomposition of polyribosomes to monosomes. The ultrastructural analysis of nucleoli, ER, and dictyosomes of both winter-active and torpid ground squirrels showed a direct correlation between the increasing contents of both cholesterol and total phospholipids (mainly PEA and LPC) in microsomes and the structural recovery of endoplasmic reticulum, Golgi stacks, and nucleoli in intact pyramidal neurons. A role of seasonal variations in lipid contents of brain cells in their adaptation to low temperature is discussed. We also propose an involvement of cholesterol in the activation of protein-synthesizing function of endoplasmic reticulum and Golgi stacks in intact neurons.     

Relationships between the thermal environment and activity of Piute ground squirrels (Spermophilus mollis)

(1) We examined relationships between ground squirrel activity and operative temperature (T_e) in two habitats in southwestern Idaho, USA to determine how activity patterns are tied to environmental conditions and how habitat can mediate the thermal environment. (2) Midday environmental conditions were too hot throughout much of the active season for Piute ground squirrels to remain active in a grassland habitat. (3) Ground squirrels were most active in grassland at a T_e of approximately 25°C and showed a strong bimodal activity pattern during the latter half of their active season (after 15 April). (4) Suitable aboveground microclimates existed throughout most of the season in sagebrush (Artemisia tridentata) habitats and ground squirrels remained active throughout the day. (5) The availability of cooler microhabitats may make sagebrush a better habitat than grassland for Piute ground squirrels, especially during the latter portion of the active season and in hotter than normal years.     

Activity of liver and brain arginase during hypothermia

The content of urea and activity of arginase in the brain and liver have been determined in squirrels falling into hibernation and in rats with an artificial decrease of the body temperature. It is shown that the intensity of urea synthesis under hypothermia (20, 10 degrees C) in the studied organs of animals falling into hibernation remains at high level in contrast to animals without such adaptation.