The role of the cholinergic system in the central control of thermoregulation in rats

Systemic and central administration of methacholine (a synthetic choline derivative) both produced dose-dependent decreases in rectal temperature in rats at all the ambient temperatures studied. Both at room temperature (22 degrees C) and in the cold (8 degrees C), the hypothermia in response to methacholine application was brought about by both a decrease in metabolic heat production and an increase in cutaneous circulation. In the heat (29 degrees C), the hypothermia was due solely to an increase in respiratory evaporative heat loss. Furthermore, the methacholine-induced hypothermia was antagonized by central pretreatment of atropine (a selective blocker of cholinergic receptors), but not by the central administration of either 6-hydroxydopamine (a relative depletor of catecholaminergic nerve fibers) or 5,6-dihydroxytryptamine (predominately a serotonin depletor). The data indicate that activation of the cholinergic receptors within brain with methacholine decreases heat production and (or) increases heat loss which leads to hypothermia in rats.     

Decrease of core body temperature in mice by dehydroepiandrosterone

Dietary dehydroepiandrosterone (DHEA) reduces food intake in mice, and this response is under genetic control. Moreover, both food restriction and DHEA can prevent or ameliorate certain diseases and mediate other biological effects. Mice fed DHEA (0.45% w/w of food) and mice pair-fed to these mice (food restricted) for 8 weeks were tested for changes in body temperature. DHEA was more efficient than food restriction alone in causing hypothermia. DHEA injected intraperitoneally also induced hypothermia that reached a nadir at 1 to 2 hr, and slowly recovered by 20 to 24 hr. This effect was dose dependent (0.5-50 mg). Each mouse strain tested (four) was susceptible to this effect, suggesting that the genetics differ for induction of hypophagia and induction of hypothermia. Because serotonin and dopamine can regulate (decrease) body temperature, we treated mice with haloperidol (dopamine receptor antagonist), 5,7-dihydroxytryptamine (serotonin production inhibitor), or ritanserin (serotonin receptor antagonist) prior to injection of DHEA. All of these agents increased rather than decreased the hypothermic effects of DHEA. DHEA metabolites that are proximate (5-androstene-3beta, 17beta-diol and androstenedione) or further downstream (estradiol-17beta) were much less effective than DHEA in inducing hypothermia. However, the DHEA analog, 16alpha-chloroepiandrosterone, was as active as DHEA. Thus, DHEA administered parentally seems to act directly on temperature-regulating sites in the body. These results suggest that DHEA induces hypothermia independent of its ability to cause food restriction, to affect serotonin or dopamine functions, or to act via its downstream steroid metabolites.     

Induction of VMAT-1 and TPH-1 expression induces vesicular accumulation of serotonin and protects cells and tissue from cooling/rewarming injury

DDT₁ MF-2 hamster ductus deferens cells are resistant to hypothermia due to serotonin secretion from secretory vesicles and subsequent cystathionine beta synthase (CBS) mediated formation of H₂S. We investigated whether the mechanism promoting resistance to hypothermia may be translationally induced in cells vulnerable to cold storage. Thus, VMAT-1 (vesicular monoamino transferase) and TPH-1 (tryptophan hydroxylase) were co-transfected in rat aortic smooth muscle cells (SMAC) and kidney tissue to create a serotonin-vesicular phenotype (named VTSMAC and VTkidney, respectively). Effects on hypothermic damage were assessed. VTSMAC showed a vesicular phenotype and an 8-fold increase in serotonin content and 5-fold increase in its release upon cooling. Cooled VTSMAC produced up to 10 fold higher concentrations of H₂S, and were protected from hypothermia, as shown by a 50% reduction of caspase 3/7 activity and 4 times higher survival compared to SMAC. Hypothermic resistance was abolished by the inhibition of CBS activity or blockade of serotonin re-uptake. In VTkidney slices, expression of CBS was 3 fold increased in cold preserved kidney tissue, with two-fold increase in H₂S concentration. While cooling induced substantial damage to empty vector transfected kidney as shown by caspase 3/7 activity and loss of FABP1, VTkidney was fully protected and comparable to non-cooled control. Thus, transfection of VMAT-1 and TPH-1 induced vesicular storage of serotonin which is triggered release upon cooling and has protective effects against hypothermia. The vesicular serotonergic phenotype protects against hypothermic damage through re-uptake of serotonin inducing CBS mediated H₂S production both in cells and kidney slices.     

Effect of tryptophan and selected analogues on body temperatur of endotoxin-poisoned mice

The effect of endotoxin on the body temperature of mice was studied in animals housed without bedding at an environmental temperature of 15 C. Rectal temperatures were measured during the initial 3 to 5 hr of exposure. Doses of endotoxin ranging from 0.01 to 1 ld(50), as determined for mice maintained at 25 C, produce a hypothermia in proportion to dose. Concurrent injection of tryptophan magnified this response in a dose-dependent manner. Cyproheptadine, an antiserotonin drug, antagonized both the hypothermia produced by serotonin alone, and the augmentation of hypothermia produced by tryptophan in endotoxin-poisoned mice. alpha-Methyltryptophan, an analogue of the amino acid that is known to induce tryptophan pyrrolase, also antagonized the increased hypothermia produced by tryptophan. These data support a previous suggestion that inhibition of tryptophan pyrrolase in endotoxin-poisoned mice has the effect of funneling injected tryptophan into the serotonin pathway.     

一种硬膜外局部低温方法的降温效能和安全性研究

目的应用自制降温线圈发展一种硬膜外局部低温治疗方法,对其降温效能和安全性进行评估。方法SD大鼠随机分为常温对照组（Nor组）、硬膜外局部低温组（LH组）和全身低温组（SH组）,对LH组和SH组分别实施硬膜外局部降温和全身降温,观察降温前后同侧脑温、对侧脑温、肛温以及呼吸、心率、血压变化,降温后24h对各组大鼠进行神经功能评测,取脑组织标本行光镜、电镜检查,并检测脑组织水、钠、钾离子含量和血脑屏障通透性。结果降温后,LH组大鼠的降温侧脑温在数分钟内从（36．5±0．3）℃下降到（31．4±0．4）℃并维持稳定,其对侧脑温和肛温无明显下降,R、HR和MABP无明显变化;SH组降温后双侧脑温、肛温均出现降低,降温后HR下降。降温后,LH组和SH组大鼠神经功能评分正常,光镜和电镜下脑组织无损伤表现,其脑组织水、钠、钾离子含量和血脑屏障通透性与常温对照组比较无统计学差异。结论应用这种硬膜外局部低温方法可以达到与全身降温一样的效果,且不会引起生命体征波动及对脑组织产生急性损害。     

Brain Serotonin2 and Serotonin1A Receptors Are Altered in the Congenitally Hyperammonemic Sparse Fur Mouse

In previous studies we documented an increase in the levels of the serotonin metabolite, 5-hydroxyindoleacetic acid, in the congenitally hyperammonemic sparse fur mouse. To extend these findings, brain serotonin receptors were studied in these animals. Radioligand binding assays were performed using [3H]ketanserin to label serotonin2 sites and 8-[3H]hydroxy(di-n-propylamino)tetralin to label serotonin1A sites in cortical membrane homogenates. The capacity (Bmax) for [3H]ketanserin binding was significantly lower (-21%; p less than 0.05) in sparse fur animals than in control animals; there was no change in affinity (KD). In contrast, the capacity for 8-[3H]hydroxy(di-n-propylamino)tetralin binding was significantly greater (26%; p less than 0.05) in sparse fur compared with control animals. No difference in affinity was observed. Using two behavioral assays, the functional responsiveness of these serotonin receptors was compared in sparse fur and control animals. Head twitch activity elicited by administration of the serotonin agonist quipazine was studied as a behavior mediated by serotonin2 receptors. Compared with controls, sparse fur mice demonstrated a significantly decreased head twitch response (p less than 0.005). Hypothermia elicited by administration of 8-hydroxy(di-n-propylamino)tetralin was studied as a physiologic response mediated by serotonin1A receptors. Although there were not overall group differences in the dose-response data, there was a significant increase in the hypothermia induced by 8-hydroxy(di-n-propylamino)tetralin in sparse fur compared with control mice (p less than 0.02) at the highest dose. These data provide further support for a link between hyperammonemia and alterations in the serotonin system.     

Polymorphism in 5-HT receptors as the background of serotonin functional diversity

The review concentrates on the role of different types and subtypes of 5-HT receptors in physiological and behavioural effects of the brain neurotransmitter serotonin. Specifically it describes: 1) the effects of 5-HT1A and 5-HT1B receptors on aggressive behavior, sexual arousal, food and water consumption; 2) the data showing reciprocal effect of 5-HT2A, 5-HT2C receptor agonists; 3) interaction of 5-HT3 and 5-HT1A-receptors in 5-HT3-induced hypothermia. The review provides converging lines of evidence that: different types and subtypes of 5-HT receptors are involved in the regulation of various kinds of behavior as additive as well as opposite factors providing neuroplasticity, compensatory and adaptive mechanism.     

Therapeutic hypothermia in the management of acute liver failure

A large body of experimental data and preliminary clinical studies point to the induction of mild hypothermia (32-35 °C) as a valuable approach to control the development of brain edema and intracranial hypertension in acute liver failure (ALF). The ability of hypothermia to affect multiple processes probably explains its efficacy to prevent these cerebral complications. Remarkably, mild hypothermia has been shown to prevent or attenuate most of the major alterations involved in the pathogenesis of the cerebral complications of ALF, including the accumulation of ammonia in the brain and the circulation, the alterations of brain glucose metabolism, the brain osmotic disturbances, the accumulation of glutamate and lactate in brain extracellular space, the development of inflammation and oxidative/nitrosative stress, and others. Limited information suggests that the systemic effects of hypothermia may also be beneficial for some peripheral complications of ALF. Translation of the beneficial effects of therapeutic hypothermia into standard clinical practice, however, needs to be confirmed in adequately designed clinical trials. Such trials will be important to determine the safety of therapeutic hypothermia, to identify which patients might benefit from it, and to provide the optimal guidelines for its use in patients with ALF.     

Effects of dopaminergic and serotonergic drugs on ethanol-induced hypothermia

The effects of dopaminergic and serotonergic drugs on ethanol-induced hypothermia were studied in the rat. Pretreatment with haloperidol attenuated the hypothermia in a dose-dependent manner. Apomorphine produced a dose-dependent effect on the hypothermia. At a dose of 2.0 mg/kg, apomorphine potentiated ethanol-induced hypothermia, whereas at 0.1 mg/kg, it produced a delayed attenuation effect between 30 min and 45 min after its injection. The former effect was blocked by haloperidol, whereas the latter was not affected by haloperidol, but blocked by pretreatment with parachlorophenylalanine. It is concluded that both dopamine and serotonin exert modulatory effects on ethanol-induced hypothermia.     

Serotonin and dopamine protect from hypothermia/rewarming damage through the CBS/H2S pathway

Biogenic amines have been demonstrated to protect cells from apoptotic cell death. Herein we show for the first time that serotonin and dopamine increase H(2)S production by the endogenous enzyme cystathionine-β-synthase (CBS) and protect cells against hypothermia/rewarming induced reactive oxygen species (ROS) formation and apoptosis. Treatment with both compounds doubled CBS expression through mammalian target of rapamycin (mTOR) and increased H(2)S production in cultured rat smooth muscle cells. In addition, serotonin and dopamine treatment significantly reduced ROS formation. The beneficial effect of both compounds was minimized by inhibition of their re-uptake and by pharmacological inhibition of CBS or its down-regulation by siRNA. Exogenous administration of H(2)S and activation of CBS by Prydoxal 5'-phosphate also protected cells from hypothermic damage. Finally, serotonin and dopamine pretreatment of rat lung, kidney, liver and heart prior to 24 h of hypothermia at 3°C followed by 30 min of rewarming at 37°C upregulated the expression of CBS, strongly reduced caspase activity and maintained the physiological pH compared to untreated tissues. Thus, dopamine and serotonin protect cells against hypothermia/rewarming induced damage by increasing H(2)S production mediated through CBS. Our data identify a novel molecular link between biogenic amines and the H(2)S pathway, which may profoundly affect our understanding of the biological effects of monoamine neurotransmitters.     

Involvement of histamine H1 and H2 receptors in hypothermia induced by ionizing radiation in guinea pigs

Radiation-induced hypothermia was examined in guinea pigs. Exposure to the head alone or whole-body irradiation induced hypothermia, whereas exposure of the body alone produced a small insignificant response. Systemic injection of disodium cromoglycate (a mast cell stabilizer) and cimetidine (H2-receptor antagonist) had no effect on radiation-induced hypothermia, whereas systemic and central administration of mepyramine (H1-receptor antagonist) or central administration of disodium cromoglycate or cimetidine attenuated it, indicating the involvement of central histamine through both H1 and H2 receptors in this response. Serotonin is not involved, since the serotonin antagonist methysergide had no effect on radiation-induced hypothermia. These results indicate that central histaminergic systems may be involved in radiation-induced hypothermia.     

Effects of regional body temperature variation during asphyxial cardiac arrest on mortality and brain damage in a rat model

To date, hypothermia has focused on improving rates of resuscitation to increase survival in patients sustaining cardiac arrest (CA). Towards this end, the role of body temperature in neuronal damage or death during CA needs to be determined. However, few studies have investigated the effect of regional temperature variation on survival rate and neurological outcomes. In this study, adult male rats (12 week-old) were used under the following four conditions: (i) whole-body normothermia (37 ± 0.5 °C) plus (+) no asphyxial CA, (ii) whole-body normothermia + CA, (iii) whole-body hypothermia (33 ± 0.5 °C)+CA, (iv) body hypothermia/brain normothermia + CA, and (v) brain hypothermia/body normothermia + CA. The survival rate after resuscitation was significantly elevated in groups exposed to whole-body hypothermia plus CA and body hypothermia/brain normothermia plus CA, but not in groups exposed to whole-body normothermia combined with CA and brain hypothermia/body normothermia plus CA. However, the group exposed to hypothermia/brain normothermia combined with CA exhibited higher neuroprotective effects against asphyxial CA injury, i.e. improved neurological deficit and neuronal death in the hippocampus compared with those involving whole-body normothermia combined with CA. In addition, neurological deficit and neuronal death in the group of rat exposed to brain hypothermia/body normothermia and CA were similar to those in the rats subjected to whole-body normothermia and CA. In brief, only brain hypothermia during CA was not associated with effective survival rate, neurological function or neuronal protection compared with those under body (but not brain) hypothermia during CA. Our present study suggests that regional temperature in patients during CA significantly affects the outcomes associated with survival rate and neurological recovery.     

Effect of hypothermia on brain multi-parametric activities in normoxic and partially ischemic rats

Hypothermia, as well as anesthesia, are known to protect the brain against ischemia, hypoxia and other pathological damages. One of the mechanisms of this improvement could be by lowering brain function, and thereby lowering oxygen demand. We examined the effect of hypothermia on brain function and blood supply in awake and anesthetized rats and studied the interaction between partial ischemia and the responses to hypothermia. The brain function multiprobe (BFM) used enabled simultaneous measurements of cerebral blood flow (CBF), mitochondrial NADH redox state, extracellular K(+) concentration, DC potential and ECoG from the cerebral cortex in rats whose brain temperature was lowered by 5 degrees C. Hypothermia was induced in awake, anesthetized and brain ischemic-anesthetized rats. In anesthetized and ischemic-anesthetized rats, the time required for lowering the brain temperature by 5 degrees C was five times less than in the normal awake animals. No significant changes in CBF and NADH levels were found in response to hypothermia in the awake animals. In contrast, a significant decrease in extracellular K(+) concentration was recorded under hypothermia, probably due to the lower rate of depolarization. Hypothermia in anesthetized and in ischemic-anesthetized rats did not significantly affect the levels of mitochondrial NADH, CBF and extracellular K(+). Hypothermia under ischemia was expected to be more effective.     

Mechanisms of Cyclic AMP Regulation in Cerebral Anoxia and Their Relationship to Glycogenolysis

Abstract: Anoxia elevates levels of cyclic AMP and depresses levels of cyclic GMP in cerebral cortex of mice. Similar effects are also observed in other regions of the brain. Aminophylline inhibits accumulation of cyclic AMP about 50% in hippocampus and cerebellum, but not in cerebral cortex and striaturn; however, this effect requires high doses (²⁵⁰ mgikg). Pretreatment of animals with reserpine, which depletes brain stores of norepinephrine, dopamine, and serotonin, and also produces sedation and mild hypothermia, markedly inhibits accumulation of cyclic AMP in all regions of anoxic brain. Destruction of norepinephrine terminals by treatment of neonatal animals with ⁶-OH- dopamine, which does not sedate or produce hypothermia, has an effect on cyclic AMP levels similar to that of reserpine. None of the above treatments modifies the effect of anoxia on cyclic GMP levels. These data indicate that norepinephrine is a major regulator of cyclic AMP levels in anoxic brain and that adenosine and, perhaps, other unidentified substances have lesser roles in this process. In contrast, biogenic amines and adenosine appear to have no effect on cyclic GMP regulation in anoxic brain. Reserpine slows the activation of phosphorylase and the utilization of ATP, and slightly attenuates the breakdown of glycogen caused by anoxia, but has no effect on the changes in glucose, lactate, or phosphocreatine. In contrast, ⁶-OH-dopamine has no effect on any of these anoxiainduced changes. It is concluded that the effect of reserpine on phosphorylase, glycogen, and ATP is most likely related to the hypothermic and sedative effect of the drug, and that either cyclic AMP is not responsible for initiating glycogenolysis in anoxic brain or only a small rise in cyclic AMP levels is necessary for this process.     

Effects ofp-chloroamphetamine on brain serotonin neurons

p-Chloroamphetamine (PCA) is a useful pharmacologic tool for selectively increasing brain serotonin function acutely by release of serotonin into the synaptic cleft. PCA produces behavioral, neurochemical and neuroendocrine effects believed due to serotonin release after doses in the range of 0.5–5 mg/kg. At higher doses and at longer times, PCA causes depletion of brain serotonin. The mechanisms of this depletion are not well understood but require the serotonin uptake carrier. Antagonism of PCA-induced depletion of brain serotonin is a useful means of assessing the ability of a compound to block the serotonin uptake carrier on brain serotonin neurons. PCA can also be used as a neurotoxic agent to deplete brain serotonin in functional studies, apparently by destroying some serotonergic nerve terminals. Used in this way, PCA has an advantage over 5,6- and 5,7-dihydroxytryptamines in being effective by systemic injection, and it affects brain serotonergic projections with a different neuroanatomic specificity than the dihydroxytryptamines.Special issue dedicated to Dr. Morris H. Aprison.     

Improved Production of Human Immunoglobulin γ1 Chain Fc Polypeptides in Escherichia coli and Their Properties

Exposure to some xenobiotics (pentobarbital, 3-terf-butyl-4-methoxyphenol (BHA), chloretone (acetone chloroform), 1, l-bis-(p-chlorophenyl)-2,2,2-trichloroethane (DDT) and polychlorinated biphenyls (PCB)) for a 5 hr period increased the concentrations of brain serotonin and 5-hydroxyindole acetic acid (5HIAA). The decrease in the brain serotonin level elicited by /7-chlorophenylalanine (PCPA), an inhibitor of serotonin synthesis, was prevented by the concomitant administration of chloretone. The administration of both chloretone and pargyline (an inhibitor of monoamine oxidase) caused significant elevation of the brain 5HIAA level as compared with that in a pargyline control, however, the concentration of brain serotonin was not different between pargyline alone and chloretone plus pargyline. These results show that the increase in the brain serotonin level caused by chloretone is not due to acceleration of brain serotonin synthesis, but to retardation of the degradation of brain serotonin, and the increase in brain 5HIAA caused by chloretone may be due to the reduced removal of 5HIAA from the brain. Chloretone plus pargyline caused significant elevation of hypothalamus catecholamines, as compared to in the pargyline control, so the catecholamine turnover rates may be accelerated by the administration of chloretone.     

BRAIN SEROTONIN CHANGES IN PHENYLALANINE-FED RATS: SYNTHESIS STORAGE AND DEGRADATION1

The brain serotonin levels of rats maintained on a 5 % phenylalanine diet rose more slowly (0.18 μ g/g brain/hr) after administration of a monoamine oxidase inhibitor than did serotonin levels of controls (0.41 μ g/g brain/hr). The rate of brain serotonin decline following reserpine or dimethylaminobenzoyl methyl reserpate was the same for both groups as was basal monoamine oxidase activity. Brain uptake of monoamine oxidase inhibitor was also the same for both groups. It was concluded that the decrease in brain serotonin levels in phenylalanine-fed animals was due to decreased serotonin formation rather than enhanced degradation. On the basis of available data it was concluded that both hydroxylase inhibition and inhibited precursor transport were involved.     

Relationship between serotonergic measures in periphery and the brain of mouse.

Circadian rhythm and the relationship between the concentration of serotonin (5HT) and related substances (5-hydroxyindoleacetic acid; 5HIAA and tryptophan; Trp) in mouse brain, stomach and blood have been studied. All factors underwent circadian changes in the brain and blood. 5HT and 5HIAA levels in the stomach showed no circadian fluctuation. The concentrations of 5HT in the brain and blood did not correlate. Significant correlations were found between other serotonergic parameters analyzed in brain, stomach and blood. A significant negative correlation was observed between brain 5HIAA and blood 5HIAA. The concentration of tryptophan in the brain was correlated with the plasma total tryptophan level. There was fairly significant correlation (p less than 0.06) between brain serotonin and plasma tryptophan levels. The brain serotonin and tryptophan levels were strongly correlated (R = 0.410, p less than 0.03). Significant negative correlation was found between serotonin in the blood and serotonin in the stomach as well as between its level in the brain and in the stomach. The significance of these findings and their relationship to the use of peripheral serotonergic system as a model of neurons are discussed.     

The hypothermic hamster brain: Its water and electrolyte content and perfusion

The data suggest that cold swelling of the brain does not occur in hypothermic hamsters for up to 48 hr or in the hypothermic rat for 2 hr. It may be possible that the adaptation of the Na⁺,K⁺-activated ATPase system as well as lipid changes occurs during the 6- to 8-hr induction period of hypothermia in the hamster. The absence of swelling in the rat, a species which does not hibernate, may be due to both the lack of hypercapnia and the brevity of the hypothermic period. It is noteworthy that in the hamster the distribution of cardiac output to the brain and the respiratory centers of the brain system is unaffected by hypothermia of up to 18 hr. Actual perfusion is, however, dramatically reduced. The data suggest that the helium-cold hypothermic hamster retains the ability to maintain solute gradients in hypothermia, and that hypothermic death is not due to an increase in cerebral water content or in the percentage of cardiac output received by the brain.     

Participation of the brain serotoninergic system in creating the stress reactivity of the hypophyseal-adrenal axis

The concentration of corticosteroids in the blood of rats was shown to increase in response to the immobilization stress at an earlier age than the brain serotonin metabolism changes. The level of corticosteroids in blood increased in response to the intraperitoneal serotonin injection also earlier than the reaction to the serotonin injection in the brain lateral ventricle sets up. The increase of the reaction of hypophysial-suprarenal system to stress during the period from the 12th till the 16th day of postnatal development coincided with the changes in serotonin metabolism in the brain stem and the reaction to serotonin injection in the brain lateral ventricle. It is suggested that the system of serotonin brain neurons connected with the hypophysial-suprarenal complex matures later tran the serotonin receptors in the periphery; the reaction to immobilization may be realized at the early developmental stages without the participation of brain serotonin.