D. A. Ignat’ev

Reversible reduction in dendritic spines in CA1 of rat and ground squirrel subjected to hypothermia–normothermia in vivo: A three-dimensional electron microscope study

A study was made at electron microscope level of changes in the three-dimensional (3-D) morphology of dendritic spines and postsynaptic densities (PSDs) in CA1 of the hippocampus in ground squirrels, taken either at low temperature during hibernation (brain temperature 2-4 degrees C), or after warming and recovery to the normothermic state (34 degrees C). In addition, the morphology of PSDs and spines was measured in a non-hibernating mammal, rat, subjected to cooling at 2 degrees C at which time core rectal temperature was 15 degrees C, and then after warming to normothermic conditions. Significant differences were found in the proportion of thin and stubby spines, and shaft synapses in CA1 for rats and ground squirrels for normothermia compared with cooling or hibernation. Hypothermia induced a decrease in the proportion of thin spines, and an increase in stubby and shaft spines, but no change in the proportion of mushroom spines. The changes in redistribution of these three categories of spines in ground squirrel are more prominent than in rat. There were no significant differences in synapse density determined for ground squirrels or rats at normal compared with low temperature. Measurement of spine and PSD volume (for mushroom and thin spines) also showed no significant differences between the two functional states in either rats or ground squirrels, nor were there any differences in distances between neighboring synapses. Spinules on dendritic shafts were notable qualitatively during hibernation, but absent in normothermia. These data show that hypothermia results in morphological changes which are essentially similar in both a hibernating and a non-hibernating animal.

Effect of ionizing radiation on the synthetic activity of blood system cells in ground squirrels in different physiological states

The functional (synthetic) activity of blood lymphocytes and bone marrow hematopoietic cells in ground squirrels was studied in different seasons and at different stages of the torpor-arousal cycle. The effect of γ-irradiation on animals in different physiological states was also studied. The synthetic activity of cells was estimated from the amount of active RNA per unit DNA in the cell (parameter α). The α values in lymphocytes were minimal in hibernating animals (January–March), reached a peak upon their complete awakening (April), slightly decreased in the summer activity period, and decreased further in the prehibernation autumn period (November). During winter arousals between torpor bouts, this parameter reached the same values as in summer. The dynamics of parameter α in bone marrow hematopoietic cells were generally similar: minimal values in November and higher between torpor bouts than in summer. The peak of synthetic activity of proliferating hematopoietic cells recorded upon awakening from hibernation in April was mainly due to the accumulation of cells in the G1 and G2 phases of the cell cycle, and its decrease in summer reflected prevalent transition from G2 to mitosis and then partly to G0. In the torpor-arousal-euthermia cycle, two stages of awakening were distinguished, differing considerably in most of the test parameters. The synthetic activity and the total number of blood and bone marrow cells in ground squirrels irradiated in the state of torpor did not differ significantly from those in nonirradiated torpid animals. The adverse effect of radiation in animals irradiated at the initial stage of awakening was lesser than in animals irradiated in the active state, whereas animals at the second stage of awakening proved more vulnerable to acute irradiation. The physiological state of ground squirrels exposed to ionizing radiation at different phases of the torpor-arousal-euthermia cycle plays a key role in the dynamics of qualitative and quantitative characteristics of blood system cells. The results of this study indicate that the hypometabolic state of ground squirrels during hibernation is a factor of protection from the impact of ionizing radiation on the whole body and on the immune system in particular.

Lipids of nuclear fractions from neurons and glia of rat neocortex under conditions of artificial hypobiosis

Lipid contents were studied in tissue and nuclei isolated from neurons and glia of neocortex of rats under conditions of normothermia and in the state of artificial hypobiosis caused by hypothermia-hypoxia-hypercapnia. Compared to the neocortex tissue, both nuclear fractions were fivefold impoverished in phospholipids and cholesterol and strongly enriched with mono- and diglycerides and fatty acids. The nuclear fractions from neurons and glia contained similar amounts of phospholipids, and only the cardiolipin content in the neuronal nuclei was lower than in the glial nuclei. The state of artificial hypobiosis in rats led to an increase in the cholesterol/phospholipids ratio (mol/mol) in the nuclei from the neurons and glia; amounts of cholesterol and sphingomyelin in the nuclei from the glia were increased. The increases in the cholesterol and sphingomyelin contents and in the cholesterol/phospholipids ratio suggest an involvement of lipid-dependent signaling systems of the nuclei in the functional response of mammalian neocortex cells to artificial hypobiosis.

Cyclic structural changes of endoplasmic reticulum and Golgi complex in hippocampal neurons of ground squirrels during hibernation

Repetitive remodeling and renewal of the cytoplasmic structures realizing protein synthesis accompanies the cycling of the ground squirrels between torpor and arousal states during hibernation season. Previously, we have shown the partial loss of ribosomes and inactivation of the nucleolus in pyramidal neurons in the hippocampus CA3 area at each bout of torpor with their rapid and full recovery after warming up. In the present paper, we describe reversible structural changes of the endoplasmic reticulum (ER) and Golgi complex (GC) in these neurons. The transformation of the ER form from mainly granular stacks of flattened cisternae to smooth tubules occurs at every entrance in torpor, while the reverse change happens at arousal. The torpor state is also associated with GC fragmentation and loss of their flattened cisternae, i.e., dictiosomes. In neurons, the appearance of the autophagosomal vacuoles containing fragments of membrane structures and ribosomes in torpor state is a sign of the partial destruction of ER and GC. Granular ER restoration, perhaps through assembly from the multilamellar membrane structures, bags or whorls begins in the middle of the torpor bout, while GC dictiosomes reappear only during warming. The ER and GC completely restore their structure 2–3 h after the beginning of arousal. Thus, hibernation represents an example of the structural adaptation of the nerve cell to deep changes in functional and metabolic activity through both the active destruction and renewal of ribosomes, ER, and GC. Perhaps, namely the incomplete ER autophagosomal degradation in torpor provides its rapid renewal at arousal through the reassembly from the preserved fragments.

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.

Isoproterenol effects on the contractility of papillary muscles in the heart of ground squirrel

This paper presents a study of the influence of isoproterenol (1 μM) on the force of isometric contractions (0.1–1.0 Hz; 30 ± 1°C; 1.8 mM Ca2+) of papillary muscles of the right ventricle in the heart of a ground squirrel during summer activity (n = 5) and hibernation season (activity between hibernation bouts, n = 4; torpor, n = 4; and arousal, n = 5). It is shown that isoproterenol increases the force of contraction (a positive inotropic effect) by 20 ± 3% and 61 ± 7% at stimulation frequencies of 0.4 and 1.0 Hz, respectively. In animals of hibernating period the isoproterenol-induced increase in the force of contraction is rather brief (within 3 min after onset of the influence) and is accompanied by a 30–50% decrease in the force from the control level (a negative inotropic effect) at stimulation frequencies from 0.3 to 0.8 Hz. The positive isoproterenol inotropic effect in active summer ground squirrels is associated with a decrease in a relative value of the pause potentiating effect (a qualitative indicator of calcium content in sarcoplasmic reticulum), and the negative inotropic effect, with its increase. In all groups of animals under examination the isoproterenol inotropic effect (regardless of its direction) is accompanied by the acceleration of the temporal parameters of the contraction—relaxation cycle. The dependence of isoproterenol effects in the heart of hibernating animals on both seasonal changes in calcium homeostasis and the activity of the sympathetic nervous system is under discussion.

Ornithine Decarboxylase Activity in Rat Organs and Tissues under Artificial Hypobiosis

The influence of hypothermia-hypoxia-hypercapnia on ornithine decarboxylase (ODC, EC 4.1.1.17) activities in rat organs and tissues and also on the thymocyte distribution throughout the cell cycle stages was studied. The state of artificial hypobiosis in rats on decrease in the body temperature to 14.4–18.0°C during 3.0–3.5 h was accompanied by drops in the ODC activities in the neocortex and liver by 50–60% and in rapidly proliferating tissues (thymus, spleen, and small intestine mucosa) by 80% of the control value. In kidneys the ODC activity raised to 200% of the control level. Twenty-four hours after termination of the cooling and replacing the rats under the standard conditions, the ODC activities in the neocortex, liver, kidneys, spleen, and intestinal mucosa returned to the control values, but remained decreased in the thymus. Forty-eight hours later the ODC activities in the thymus and spleen exceeded the normal level. The distribution of thymocytes throughout the cell cycle stages did not change in rats in the state of hypothermia (hypobiosis); 24 and 48 h after termination of the cooling the fraction of thymocytes in the S stage was decreased and the fraction of the cells in the G0+G1 stage was increased. The normal distribution of thymocytes throughout the cell cycle stages recovered in 72 h. Thus, in the thymus the diminution of the ODC activity preceded the suppression of the cell proliferation rate. The tissue-specific changes in the ODC activity are suggested to reflect adaptive changes in the functional and proliferative activities of organs and tissues during the development of hypobiosis under conditions of hypothermia-hypoxia-hypercapnia.

The effect of hypothermia on membrane lipids in rat neocortex

225 It was established that the lipid composition of cell membranes changes depending on the response to different stimuli received by the cell. The change in the lipid composition depends both on the synthesis and metabolism intensity and intermembrane lipid transfer rate and on the localization of processes related to intracellular signaling [1]. To understand the role of lipids in the adaptation of mammals to low temperatures, it is of interest to study the lipid composition of functionally different cellular organelles. It is known that some mammalian species can sustain a long-term decrease in the body temperature (to –1°ë ) by entering a hypobiotic state (hibernation) with subsequent independent recovery of living activity. In this process, the main organ regulating hybernation of mammals is the brain [2]. It was shown that lipids of membranes and cellular organelles of mammalian brain are involved in the adaptation to low ambient temperatures [3, 4]. In view of this, it was important to study the effect of hypothermia on nonhibernating mammals as a model for studying the mechanisms and characteristics of hypothermia in humans [5]. In rats, a decrease in the body temperature to 14–20°ë under conditions of hypoxia/hypercapnia causes the so-called cold narcosis, which is accompanied by a dramatic suppression of mobility and metabolism intensity as well as by disappearance of energy activity in the brain. Animals can return from this state to normothermia similarly to the escape from the natural hypobiosis, hibernation [5, 6]. The effect of artificial hypothermia on the lipids in membrane and organelles of brain cortex cells of nonhibernating animals has not yet been studied. The goal of this work was to study the state of hypothermia in rats on the lipid composition of tissue, microsomal fraction, nuclear fractions of brain cortex neurons and neuroglia. Normally, the nuclear fractions of neurons and neuroglia are depleted of phospholipid and cholesterol and enriched in monoand diglycerides and fatty acids. In rats in the hypothermal state, the proportion of phosphatidylinositol in the microsomal fraction decreases. In the nuclei of glial cells, the content of cholesterol and the ratio between cholesterol and phospholipids increases. An increase in the content of cholesterol and the tendency in the sphingomyelin content in the neuroglial nuclear fraction to increase are indicative of a pronounced adaptive response of neocortical glia to hypothermia. The decrease in the content of phosphatidylinositol in the microsomal fraction is apparently determined by the involvement of inositol triphosphate cycle in responses of rat neocortex to hypothermia. Experiments were performed with male rats weighing 190–230 g. The animals were chilled using the hypoxia–hypercapnia procedure [6]. The rats were incubated in a 5-l air-proof chamber at 1–2°ë for 3.5– 4 h and then decapitated in accordance with the rules accepted at the Institute of Cell Biology, Russian Academy of Sciences [7] in the normothermal (body temperature, 37–38°ë ) and hypothermal ( 15–20°ë ) states. The nuclear fractions of neurons and neuroglial cells were isolated from the brain cortex of five rats by the method of Thomson with some modifications as described in [8]. The microsomal fraction was isolated and individual neutral lipids and phospholipids were extracted, purified, separated by TLC, and quantitated as described earlier [9]. The purity of fractions was monitored by electron microscopy. Data were statistically processed using Student’s t test.

The Dynamics of Adaptive Changes in the Spleen of the Hibernating Ground Squirrel Spermophilus undulatus

In hibernation season during torpor bouts, the spleen weight and the hemoglobin level, as well as the total and extracted protein contents in the spleen of the ground squirrel Spermophilus undulatus are increased when animals enter torpor and reach maximum values when the body temperature drops below 25°C. All these parameters return to the characteristic values of the euthermic animals during arousal, before the body temperature increases to 20°C. There were no significant differences in the numbers of splenocytes between ground squirrels in interbout euthermia and torpor. The minimum number of splenocytes was observed in animals that entered torpor when the core body temperature was approximately 18°C. The activity of ornithine decarboxylase, a key enzyme in polyamine synthesis, which is correlated with the functional and proliferative status of lymphoid tissue, was the same for the euthermic and summer ground squirrels and decreased monotonically during torpor. Upon arousal of the animals when body temperature was below 29°C, no resumption of the spleen ornithine decarboxylase activity was observed.

The effect of insulin on the heart rate and temperature of the ground squirrel Spermofilus undulatus during arousal from hibernation

The effect of insulin on the heart rate and body temperature, measured per rectum, of ground squirrels (Spermophilus undulatus) during triggered arousal from winter hibernation was studied. We found that the outcomes of insulin injection to hibernating ground squirrels varied in the course of arousal. During the first stage, while body temperatures were less than 10°C, the heart rates and rectal temperatures in both control and insulin-treated groups changed in the same manner. During the next stage of arousal, when the body temperature rose above 12°C, elevation of the heart rate and rectal temperature in the insulin-treated animals was significantly retarded and lasted 110 min compared to 80 min in the control group. Conversely, in the final stage of arousal at body temperatures above 20°C, the heart rate and body temperature increased more rapidly in the insulin-treated animals that reached normal body temperature within 40 min compared to 60 min in the control group. Suggested mechanisms of bidirectional effects of insulin on the heart rates and body temperatures in ground squirrels at the particular stages of arousal, with regard to the progression of endogenous insulin and glucose levels in the blood serum, are discussed.