Effect of isoproterenol on contractility of the heart papillary muscles of a ground squirrel

The effect of isoproterenol (1 microM) on the force of isometric contractions (0.1-1.0 Hz, 30 +/- 1 degree C, 1.8 mM Ca2+) of papillary muscles of the right ventricle of the heart of the ground squirrel during summer activity (n = 5) and hibernation (activity between hibernation bouts, n = 4; torpor, n = 4; and arousal, n = 5) has been studied. It was shown that isoproterenol increases the force of contraction (positive inotropic effect) in active summer ground squirrels by 20 +/- 3 and 61 +/- 7% at stimulation frequencies of 0.4 and 1.0 Hz, respectively. The isoproterenol-induced increase in the force of contraction in animals during hibernation is brief (within 3 min after the onset of treatment) and this parameter decreases by 30-50% of the control level (negative inotropic effect) at stimulation frequencies from 0.3 and 0.8 Hz. The positive inotropic effect of isoproterenol in active summer ground squirrels is associated with a decrease in the relative value of the potentiating effect of the pause (qualitative indicator of calcium content in the sarcoplasmic reticulum), and the negative inotropic effect, with its increase. It was found that the inotropic effect of isoproterenol in all groups of animals examined (irrespective of its direction) is accompanied by an acceleration of the velocity of the contraction-relaxation cycle. The dependence of the effect of isoproterenol in the heart of hibernating animals on seasonal changes in the calcium homeostasis and the activity of the sympathetic nervous system is discussed.     

The effects of KB-R7943, an inhibitor of reverse Na<Superscript>+</Superscript>/Ca<Superscript>2+</Superscript> exchange,on the force of contraction of papillary muscles in the heart of the ground squirrel <Emphasis Type="Italic">Spermophilus undulatus</Emphasis>

We investigated the effect of KB-R7943, an inhibitor of the reverse mode of Na⁺/Ca²⁺ exchanger, on the force of isometric contractions, the contractile force–frequency relationship and post-rest potentiation (a qualitative parameter of Ca²⁺ levels in sarcoplasmic reticulum) in the right ventricle papillary muscles isolated from ground squirrel hearts during summer (June, n = 4) and autumn (October, n = 4) activities. In the presence of 1.8 mM Ca2+at 36°C, 1–1.5 hours-long treatment of the summer papillary muscles with KB-R7943 produced no significant effects on the contractile indices at the majority of stimulation frequencies. In the autumn papillary muscles KB-R7943 induced a 40–50% decrease in the force of contraction (negative inotropic effect) at low stimulation frequencies (0.1–0.3 Hz) without any significant effect at higher stimulation frequencies (0.4–3.0 Hz). Furthermore, in this group, KB-R7943 suppressed the post-rest potentiation of contractility by 50 ± 21% at pause durations exceeding 120 s. These observations indicate that KB-R7943 can affect Ca²⁺ levels in sarcoplasmic reticulum and that Na⁺/Ca2⁺ exchange may contribute to the physiological remodeling of intracellular Ca²⁺ homeostasis in myocardium of hibernating animals prior their transition to a hypometabolic torpid state.     

Effect of insulin on the myocardium of the active, hibernating and wakening ground squirrel Citellus undulatus

The effect of insulin (0.1-100 nM) on isometric force of contraction in isolated ground squirrel papillary muscle was investigated. In summer, autumn and winter active animals, insulin had a negative inotropic effect on papillary muscles, decreasing the amplitude of contraction by about 30% of the control value. In some cases, predominantly in the summer group of animals, insulin produced different effects on contractility: low doses (0.1-0.5 nM) caused a transient activation of isometric contraction by about 10-15% of control, whereas high doses produced a negative inotropic effect by about 30% of the control level. During deep hibernation (at 5-6 degrees C of heart temperature) and during arousal from hibernation (from 3 to 20 degrees C), insulin had no significant effect on contractility. Opposite inotropic effects of insulin at concentrations of 0.1-50 nM were found during arousal: from 26 to 31 degrees C of heart temperature--a positive inotropic effect by about 20-25% of control, and from 32 to 36 degrees C--a negative one by about 30-40% of the control value.     

Possible reasons for the variability of the inotropic insulin effect in papillary muscles of ground squirrel myocardium

The effects of insulin (0.1–50 nM) on isometric twitch force (0.1 to 1.0 Hz; 30 ± 1°C; 1.8 mM Ca²⁺) were studied in right ventricular papillary muscles from active ground squirrels of different seasons (summer, n = 14; autumn, n = 16 and winter interbout, n = 16) in control conditions and after one-hour pretreatment of PM with 2 μM nifedipine (an L-type Ca²⁺-channel inhibitor) and 1.0 mM orthovanadate (a tyrosine phosphatase inhibitor). In active animals of different seasonal periods insulin causes both positive and negative inotropic effects. At low frequencies (0.1–0.5 Hz), insulin of low concentrations (0.1–1.0 nM) induces a transient (within the first 20 min after application) positive effect (about 15–25%). Application of high hormone concentration (10 nM) in a low range of stimulation frequencies causes a biphasic effect (a small initial positive inotropic effect followed by a marked negative one). At frequencies above 0.5-Hz stimulation, insulin of 10 nM concentration causes presumably a negative inotropic effect. It was proposed that ICaL is possibly involved in the insulin-induced negative inotropy in ground squirrels hearts. Alteration of protein phosphorylation in tyrosine residues is known to be a major link in the mechanism of insulin action. We performed a study on sodium orthovanadate action (a known inhibitor of tyrosine phosphatase) on the inotropic insulin effect. In the group of summer animals the pretreatment of papillary muscles with sodium orthovanadate (100 μM) does not change the negative inotropic effect of insulin in a low range of stimulation frequencies but almost completely removes this effect at stimulation frequencies above 0.3 Hz (n = 4). Nifedipine (1–1.5 h pretreatment), a blocker of L-type calcium channel, reduces the inhibitory effect of insulin in autumn and winter animals, and on the contrary intensifies it in summer animals. This fact indicates that different mechanisms must be involved in insulin actions in animals of summer and winter periods. The main findings of the present study are that insulin induces positive, negative or no inotropic effects in papillary muscles of ground squirrels myocardium. The character of the effects of insulin depends on the physiological state of animals; time and concentrations of the hormone applied; affected by conditions that alter cellular Ca²⁺ loading and the ratio of protein-tyrosine kinases/phosphatases activity.     

Production of tumor necrosis factor in cells of hibernating ground squirrels Citellus undulatus during annual cycle

TNF production has been studied in peritoneal macrophages and splenic T cells of Arctic Yakutian ground squirrel (Citellus Undulatus Pallas) in hibernating and awake animals in winter and in prehibernating autumn as well as in active euthermic spring-summer animals. A high level of TNF production in macrophages of ground squirrel is observed over the active period and during arousals in winter. There are no significant season variations in TNF production in splenic T lymphocytes of ground squirrels. This suggests the major role of activated macrophages in the arousals of hibernating animals. T lymphocyte proliferation in ground squirrels in the active period is higher than in winter, and the most significant seasonal variations are found in T cell mitogenic response, which increases in spring-summer period. Evidence is presented that functional activity of macrophages of squirrel in autumn has much in common with that in winter rather than in spring-summer period.     

Membrane lipids and morphology of brain cortex synaptosomes isolated from hibernating Yakutian ground squirrel

Synaptosomes were isolated from Yakutian ground squirrel brain cortex of summer and winter hibernating animals in active and torpor states. Synaptosomal membrane cholesterol and phospholipids were determined. The seasonal changes of synaptosomal lipid composition were found. Synaptosomes isolated from hibernating Yakutian ground squirrel brain cortex maintained the cholesterol sphingomyelin, phosphatidylethanolamine, lysophosphatidylcholine, cardiolipin, phosphatidylinositol and phosphatidylserine contents 2.5, 1.8, 2.6, 1.8, 1.6, and 1.3 times less, respectively, and the content of phosphatidylcholine twice as much as the one in summer season. The synaptosomal membrane lipid composition of summer animals was shown to be markedly different from that as hibernating ground squirrels and non-hibernating rodents. It is believed that phenotypic changes of synaptosomal membrane lipid composition in summer Yakutian ground squirrel are the important preparation step for hibernation. The phosphatidylethanolamine content was increased in torpor state compared with winter-active state and the molar ratio of cholesterol/phospholipids in synaptosomal membrane of winter torpor ground squirrels was lower than that in active winter and summer animals. These events were supposed to lead to increase of the synaptosomal membrane fluidity during torpor. Synaptosomes isolated from torpor animals have larger sizes and contain a greater number of synaptic vesicles on the synaptosomal profile area. The synaptosomal membrane lipid composition and synaptosome morphology were involved in phenotypic adaptation of Yakutian ground squirrel to hibernation.     

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.     

The effect of hibernation on lipids of the liver mitochondrial fraction in the Yakut ground squirrel <Emphasis Type="Italic">Spermophilus undulatus</Emphasis>

We demonstrated that the level of phospholipids in the liver mitochondrial fraction is increased by 60% during the winter hibernation season in the Yakut ground squirrel S. undulatus; the phospholipid composition in sleeping animals is characterized by an increase in phosphatidylethanolamine compared with summer animals. A sharp increase in the level of cholesterol, as well as fatty acid, monoglycerides, and diglycerides was found in the mitochondrial fraction of hibernating ground squirrels in relation to summer ground squirrels. Functional changes during hibernation concern the level of phosphatidylserine (the growth in sleeping animals compared with active animals). Seasonal modification of the lipid composition of the liver mitochondria (particularly, an increase in the level of cholesterol) can play a role in the resistance of mitochondria to the seasonal increase in the level of fatty acids in the liver. Lipids of the liver mitochondrial fraction are involved in the ground squirrel adaptation to the hibernation season.     

Ca-ATPase activity and protein composition of sarcoplasmic reticulum membranes isolated from skeletal muscles of typical hibernator,the ground squirrel Spermophilus undulatus

Ca-ATPase activity in sarcoplasmic reticulum (SR) membranes isolated from skeletal muscles of the typical hibernator, the ground squirrel Spermophilus undulatus, is about 2-fold lower than that in SR membranes of rats and rabbits and is further decreased 2-fold during hibernation. The use of carbocyanine anionic dye Stains-All has revealed that Ca-binding proteins of SR membranes, histidine-rich Ca-binding protein and sarcalumenin, in ground squirrel, rat, and rabbit SR have different electrophoretic mobility corresponding to apparent molecular masses 165, 155, and 170 kDa and 130, 145, and 160 kDa, respectively; the electrophoretic mobility of calsequestrin (63 kDa) is the same in all preparations. The content of these Ca-binding proteins in SR membranes of the ground squirrels is decreased 3–4 fold and the content of 55, 30, and 22 kDa proteins is significantly increased during hibernation.     

Comparative characteristics of sarcoplasmic reticulum preparations from skeletal muscles of the ground squirrel Spermophilus undulatus, rats, and rabbits

A comparison of sarcoplasmic reticulum (SR) preparations from skeletal muscles of ground squirrels Spermophilus undulatus, rats, and rabbits established that on the basis of protein yield and phospholipid/protein ratio these preparations are practically the same. Nevertheless, the specific activity of Ca-ATPase, the main protein component of SR membranes, in SR preparations of the ground squirrel skeletal muscles is only about half of the activity in SR preparations of rats and rabbits. Significant differences in protein composition of the preparations were detected: ground squirrel SR differed by an unusually high content of a 205 kD protein (probably myosin) and a number of low-molecular-weight SR protein components, and the SR preparations of rabbits are characterized by a high content of the Ca-binding proteins calsequestrin and sarcalumenin. Use of the anionic carbocyanine dye Stains-All established that all preparations contained only three proteins which are stained dark blue by this dye: calsequestrin, sarcalumenin, and a histidine-rich Ca-binding protein. The electrophoretic mobility of calsequestrin was identical in all preparations (molecular mass 63 kD), whereas sarcalumenin and histidine-rich Ca-binding protein are probably present in different isoforms with molecular masses of 130, 145, and 160 and 165, 155, and 170 kD, respectively, in SR preparations of ground squirrels, rats, and rabbits. Analysis of the fluorescence parameters of the fluorescent probes 8-anilino-1-naphthalene sulfonic acid and pyrene bound to SR membranes showed that the properties of the lipid bilayer in the SR membranes of the preparations differed considerably. It is suggested that the differences in protein composition and/or structural state of the ground squirrel SR membrane lipid bilayer could be the reason for the low Ca-ATPase activity in these preparations.     

Induction of summer hibernation in the 13-lined ground squirrel shown by comparative serum transfusions from arctic mammals.

A “trigger” substance was again indicated to be present in sera of hibernating animals. Sera from the hibernating 13-lined ground squirrel, hibernating woodchuck, hibernating Arctic ground squirrel, and hibernating Arctic marmot were all capable of inducing the 13-lined ground squirrel to hibernate in the summer, a season when that species would normally be active. The hibernation trigger is thus not species specific. It is effective whether drawn from these two Arctic species of hibernators or drawn from these two species of hibernators from the midwestern states. The normothermic Arctic marmot appears to have an “anti-trigger” substance in its serum in the summer, which impedes fall hibernation in the transfused 13-lined ground squirrel. This is similar to the anti-trigger observed in the summer serum of active 13-lined ground squirrels and active woodchucks. With respect to hypothermia, it was induced in Artic marmots and in Arctic foxes at Point Barrow, Alaska, in summer. Though in such cases body temperatures fell significantly (as in hibernation), no trigger was recovered from their hypothermic sera that could be shown to be capable of inducing summer hibernation in the ground squirrel. Neither was anti-trigger found in the serum of hypothermic experimentals. These latter experiments thus suggest that the release of trigger into the blood during hibernation is dependent on a mechanism more complex than simply lowering body temperature.     

The "hibernation induction trigger": specificity and validity of bioassay using the 13-lined ground squirrel

Even though the existence of the blood-borne "hibernation induction trigger" has been reported in the 13-lined ground squirrel, transfusion of plasma from hibernating rodents with other hibernating species as the recipients failed to induce the occurrence of summer hibernation. In order to verify whether the response to the "trigger" substance is species specific, the present study was carried out to compare the effect of plasma from hibernating Richardson's ground squirrels on the incidence of summer hibernation in both juvenile Richardson's and adult 13-lined ground squirrels. In two series of experiments, 13-lined ground squirrels entered hibernation quite readily independent of the treatment. The rate of occurrence of hibernation ranged from 78% after sham injection to 86% after warm saline, fresh summer active plasma, and fresh hibernating plasma, respectively. There were no differences in the number of hibernation bouts and the number of days in hibernation after each treatment. In contrast, none of the juvenile Richardson's ground squirrels entered hibernation after any of the treatments up to the end of the 8-week observation period. These results not only argue against the existence of blood-borne "trigger" substance, at least in the Richardson's ground squirrel, but also caution against the use of the 13-lined ground squirrel as a standard test animal for the bioassay of the "trigger" substance.     

Effects of Season and Host Physiological State on the Diversity,Density, and Activity of the Arctic Ground Squirrel Cecal Microbiota

We examined the seasonal changes of the cecal microbiota of captive arctic ground squirrels (Urocitellus parryii) by measuring microbial diversity and composition, total bacterial density and viability, and short-chain fatty acid concentrations at four sample periods (summer, torpor, interbout arousal, and posthibernation). Abundance of Firmicutes was lower, whereas abundances of Bacteroidetes, Verrucomicrobia, and Proteobacteria were higher during torpor and interbout arousal than in summer. Bacterial densities and percentages of live bacteria were significantly higher in summer than during torpor and interbout arousal. Likewise, total short-chain fatty acid concentrations were significantly greater during summer than during torpor and interbout arousal. Concentrations of individual short-chain fatty acids varied across sample periods, with butyrate concentrations higher and acetate concentrations lower during summer than at all other sample periods. Characteristics of the gut community posthibernation were more similar to those during torpor and interbout arousal than to those during summer. However, higher abundances of the genera Bacteroides and Akkermansia occurred during posthibernation than during interbout arousal and torpor. Collectively, our results clearly demonstrate that seasonal changes in physiology associated with hibernation and activity affect the gut microbial community in the arctic ground squirrel. Importantly, similarities between the gut microbiota of arctic ground squirrels and thirteen-lined ground squirrels suggest the potential for a core microbiota during hibernation.     

Seasonal changes in the composition of titin isoforms in muscles of hibernating ground squirrels

An electophoretic study of changes in the content of intact titin isoforms, N2B-, N2BA-, N2A-titins and T2 in skeletal and cardiac muscles of ground squirrel (Spermophillus undulatus) is made in different periods: summer activity, autumnal activity, hibernation, arousal, and winter activity. In atria and ventricles of ground squirrels in the period of autumnal activity an increase (by ～1.5 times) in the N2BA to N2B ratio was observed, in comparison with that in cardiac muscle in summer activity. During hibernation, the decrease in the relative content of N2B-, N2BA-titins and T2 in cardiac muscle as well as of N2A-titin and T2 in skeletal muscles was determined against the background of preservation of the relative amount of intact titin isoforms. At waking of ground squirrels and in a short period of winter activity, a rapid restoration of the content of N2B-, N2BA-, N2A-titisns and T2 in muscles was observed. In the myocardium of hibernating, waking ground squirrels and of those during winter activity the increased N2BA to N2B ratio was retained. The changes in the titin content are discussed in the aspect of adaptation of ground squirrels to hibernation.     

The seasonal peculiarities of force-frequency relationships in active ground squirrel Spermophilus undulatus ventricle

The plasticity of calcium homeostasis is of crucial importance for the unique ability of the hibernators’ heart to function under conditions of body temperature changing from 37 °C to near freezing point. However, the precise mechanism of calcium homeostasis regulation in these animals is largely unknown. Force–frequency relationship, as an indicator of participation of various sources of calcium (external and intracellular) in the activation of contraction, and post-rest potentiation as an index of the capacity of sarcoplasmic reticulum (intracellular calcium source) to store and release Ca²⁺, were studied to analyse the role of different calcium-transporting systems in seasonal and temperature-induced changes in isometric twitch force of ground squirrel papillary muscles. The obtained results revealed significant functional differences during the annual cycle, which are indicative of an increased role of the sarcoplasmic reticulum in regulation of contractility in animals in transition to the hibernation period. Also, how myocardium during the hibernation period copes functionally with acute decreases in temperature was investigated.     

Myoglobin content in skeletal muscles of hibernating ground squirrels rises in autumn and winter

The content of myoglobin (Mb) in skeletal muscles of Arctic Yakutian ground squirrel (Citellus undulatus Pallas) was measured in the active euthermic summer and prehibernating autumn animals as well as in hibernating and awake animals in winter. The myoglobin content in winter, irrespective of the state of the animal, was found to be about three times higher than in summer. The content of myoglobin in autumn was also two-fold increased compared to summer, suggesting that high myoglobin level is necessary for hibernation. Analysis of biochemical data available suggests that the increase in myoglobin content in winter is probably related to a high oxygen demand of muscles at the first stage of arousal (non-shivering thermogenesis) when rectal temperature rises from 0 to 10-12 degrees C. At this stage, the oxygen-dependent processes in muscles proceed under the conditions when peripheral blood flow is blocked and anaerobic glycolysis is switched off.     

Characteristics of the frequency dependence of the contraction force in the hyperthyroid rat myocardium

We have studied the effect of increased contraction frequency (from 0.2 to 1.5 Hz) on developed tension (delta T) in thin papillary muscles of eu- and hyperthyroid rats. The results show that while increasing the contraction frequency, the delta T of euthyroid papillary muscles decreased at lower frequencies than in hyperthyroid group. Also, at the contraction frequencies above 1.0 Hz the absolute and relative levels of delta T of hyperthyroid myocardium were less decreased than in euthyroid preparations. In conclusion, the myocardium of hyperthyroid rat is characterized by a decreased sensitivity to negative inotropic effect of enhanced contraction frequency. In is probably due to the acceleration of the processes of intracellular Ca2+ recycling during diastole under the influence of hyperthyroidism.     

The cardiotropic, hypometabolic and hypothermic activity of peptide fractions from the tissues of hibernating cold-adapted animals

From tissues of hibernating and active long-tailed ground squirrels and from the brain of cold-adapted Yakut horses, low molecular peptide fractions were obtained which, after injection to albino mice, decreased oxygen consumption and rectal temperature in them. The same fractions exhibited negative chrono- and inotropic effects on isolated hearts of ectothermic and endothermic animals. Fractions from the brain of ground squirrels and the brain of horse exhibited similar pattern of the activity. The activity of fractions was subjected to seasonal changes and depended on the degree of their purification. Provisional intracellular microelectrophysiological analysis of the effect of these fractions on the frequency and strength of contractions in isolated heart was made.     

Seasonal changes in the isoform composition of the myosin heavy chains in skeletal muscles of hibernating ground squirrels Spermophilus undulatus

Seasonal changes of the isoform composition of myosin heavy chains in skeletal muscles (m. triceps, m. longissimus dorsi, m. soleus, m. gastrocnemius, m. vastus lateralis) of hibernating ground squirrels Spermophilus undulatus were studied. Functional properties of myosin (the actin-activated ATPase activity and its Ca²⁺-sensitivity in vitro) were also examined. It was observed that the content of slow myosin heavy chain I isoform increased and the content of fast IIx/d isoform decreased in muscles of torpid ground squirrels and animals which are active in autumn and winter. In muscles of these animals the content of N2A-titin isoform decreased although the relative content of NT-titin isoform, observed in striated muscles of mammals in our previous experimental works, increased. Actin-activated ATPase activity and Ca²⁺-sensitivity of myosin isolated from skeletal muscles of torpid and interbout ground squirrels were found to reduce. The changes observed are discussed in the context of adaptation of skeletal muscles of ground squirrels to hibernation conditions.     

Myosin light chains of skeletal and cardiac muscles of ground squirrel Citillus undulatus in different periods of hibernation

The isoform composition of myosin light chains and the extent of their phosphorylation in skeletal and cardiac muscles of ground squirrel Citellus undulatus in different periods of hibernation were studied. Regulatory myosin light chains of skeletal muscles of hibernating ground squirrels were completely dephosphorylated, while 25% of these light chains in active animals were phosphorylated. During hibernation, a shift of isoform composition of essential and regulatory skeletal muscle myosin light chains toward slower isoforms was observed, which is evidenced by the data obtained on m. psoas and on the totality of all skeletal muscles. In the atrial myocardium of hibernating ground squirrels, ventricular myosin light chains 1 (up to 60%) were registered. In contrast, during arousal of ground squirrels, in ventricular myocardium the appearance of atrial myosin light chains 1 (up to 30%) was revealed. A possible role of posttranslation changes in myosin light chains and their isoform shifts in the hibernation scenario is discussed.