Reduction in Brain Glucose Utilization Rate after Tryptophol (3-Indole Ethanol) Treatment

Abstract: 3-Indole ethanol has been recently identified as the hypnotic agent in trypanosomal sleeping sickness, and because it is formed in vivo after ethanol or disulfiram treatment, it is also associated with the study of alcoholism. When administered intraperitoneally to rats (250 mg/kg) tryptophol induced a sleep-like state that lasted less than an hour (no righting reflex was apparent 2 min after injection, but it returned at 11 min in bovine serum albumin solution, and 47 min in 40% ethanol solution). In ethanol solutions, tryptophol reduced brain cortical glucose utilization by 55% to the basal brain metabolic rate, and this effect lasted less than 1 h. Synergistic effects of tryptophol and ethanol were suggested by the observation that in albumin solution, tryptophol reduced brain glucose utilization by 35%, but a normal rate was not observed until 2 h postinjection.     

EFFECTS OF ETHANOL ON SEROTONIN METABOLISM IN BRAIN

The effect of ethanol on serotonin metabolism in brains of mice was determined both after a single injection and ‘chronic’ administration of ethanol. Behavioral effects were also monitored.‘Chronic’ administration of ethanol by inhalation to mice resulted in an increased susceptibility to Metrazole induced seizures. This susceptibility was evident for 48 h after ‘withdrawal’ of mice from ethanol chambers. No differences in brain 5-HT levels between control and ethanol treated mice were evident during withdrawal. However, a significant elevation in brain 5-HIAA levels was noted during this period. Short lived increases in brain 5-HIAA levels were also noted after a single injection of ethanol. Ethanol treatment produced no significant changes in the activity of brain MAO, aldehyde dehydrogenase, or aldehyde reductase. Other mechanisms for ethanol induced increases in brain 5-HIAA are discussed.     

Enhancement of pentobarbital effect by continuous administration of morphine in the mouse

These studies demonstrated that continuous morphine treatment from implantation of a 75 mg morphine pellet for 3 days potentiated pentobarbital narcosis and enhanced pentobarbital hypothermia. In the morphine implant mice, sleeping time after two different doses of pentobarbital was greater than 2.5 × the sleeping time in placebo pellet implant animals and also greater than sleeping time in animals treated acutely with morphine prior to pentobarbital. Moreover, in the morphine implant mice both the degree and duration of pentobarbital induced hypothermia were enhanced. The above findings were due to slower rate of metabolism of pentobarbital as evidenced by inhibition of hepatic N-demethylation, and higher levels of brain and serum pentobarbital in the morphine implant mice compared to both placebo and acute morphine mice.     

Increased ethanol intake and preference in cyclin D2 knockout mice

Inhibitory effects of passive ethanol exposure on brain neurogenesis have been extensively documented in animal models. In contrast, a role of brain neurogenesis in ethanol self-administration has not been addressed, as yet. The aim of this study was to assess intake of, and preference for, ethanol solutions [2-16% (v/v)] in a mouse model of adult neurogenesis deficiency based on permanent knockout (KO) of cyclin D2 (Ccnd2). Wild type (WT) and Ccnd2 KO mice did not differ in 2% and 4% ethanol intake. The KO group consumed significantly more ethanol in g/kg when offered with 8% or 16% ethanol as compared with the WT controls. The WT and KO mice did not differ in 2% ethanol preference, but the KO group showed a significantly higher preference for 4-16% ethanol. Animal and human studies have suggested that the low level of response to the sedative/hypnotic effects of alcohol is genetically associated with enhanced alcohol consumption. However, in this study, there were no between-genotype differences in ethanol-induced loss of righting reflex. Previous reports have also suggested that high ethanol intake is genetically associated with the avidity for sweets and better acceptance of bitter solutions. However, the KO and WT mice consumed similar amounts of saccharin solutions and the KOs consumed less quinine (i.e. bitter) solutions as compared with the WTs. In conclusion, these results may indicate that Ccnd2 and, possibly, brain neurogenesis are involved in central regulation of ethanol intake in mice.     

The effects of swimming in mice on pain perception and sleeping time in response to hypnotic drugs

In mice, the stress of swimming induces analgesia and prolongs the pentobarbitone sleeping time. Both these effects are abolished by naloxone. Morphine in sub-analgesic doses also prolongs pentobarbitone sleeping time in these stressed mice. Niether swimming nor morphine has any effect on ethanol sleeping time. This form of stress is considered to release an opioid (or opioids) within the brain with some specificity of interaction with other drugs.     

Potentiation of pentobarbital hypnosis by Rosa damascena in mice

Rosa damascena has been found to act on central nervous system including brain. It inhibits the reactivity of the hypothalamous and pituitary systems in rat. In traditional medicine hypnotic effect of Rose is also suggested. In the present study hypnotic effect of ethanolic, aqueous and chloroformic extracts of R. damascena was investigated in mice. Hypnotic method was based on potentiation of pentobarbital induced sleeping time by extracts. Three doses of extracts (100, 500 and 1000 mg/kg) were injected i.p. in comparison with diazepam (3mg/kg) as positive control and saline as negative control. After 30 min of injection of extracts, pentobarbital (30mg/kg) was injected and increase in sleeping time by extracts was recorded. The results showed that the ethanolic and aqueous extracts in 500 and 1000 mg/kg doses significantly increased pentobarbital induced sleeping time which was comparable to diazepam. The chloroformic extract had no hypnotic effect.     

Effects of ginseng on ethanol induced sedation in mice

The effects of ginseng, ginsenosides, coffee, and caffeine on 75% ethanol induced sleeping in mice were examined. Mice treated with ethanol lost their righting reflex within 30 min and this lasted for about 4 h. The onset time of lose of righting reflex (LR) in mice pre-treated with ginseng, ginsenosides, coffee or caffeine 10 min before ethanol was significantly delayed; whereas the duration of sleep was not affected by all treatments. Administration of these agents 10 min after ethanol was ineffective in counteracting the LR effect of ethanol. Coffee and caffeine produced central stimulation and increased locomotor activity. Ginseng and ginsenosides were found to enhance exercise endurance and reduced the plasma level of ethanol. Gastric emptying was slowed by ginseng, ginsenosides or ethanol administration. An additive effect was observed when the mice were pre-treated with ginseng or ginsenosides 10 min before ethanol administration. It is suggested that ginseng decreased plasma ethanol concentration by delaying gastric emptying and this may be partly due to the effect of the ginsenosides.     

大鼠侧脑室注射精氨酸加压素对针刺镇痛的影响

以钾离子透入法引起大鼠甩尾反应为指标,测定动物的痛阈。由侧脑室注射精氮酸加压素(AVP)后,大鼠痛阈升高33.6％～68.5％,针刺镇痛效应明显加强,痛阈提高202.4％～302.7％。脑室注射抗精氨酸加压素血清,动物痛阈虽无明显变化,但针刺镇痛效应明显削弱,痛阈仅增加41.6％～71.0％。注射抗β-内啡肽血清和抗强啡肽A血清并不阻断AVP增强针刺镇痛效应。本工作的结果提示,脑内AVP参与针刺镇痛,这种作用与脑内内源性β-内啡肽和强啡肽的关系不甚密切。     

Involvement of diazepam binding inhibitor and its fragment octadecaneuropeptide in social isolation stress-induced decrease in pentobarbital sleep in mice.

Diazepam binding inhibitor (DBI) and its fragment, octadecaneuropeptide (ODN), are putative endogenous ligands for benzodiazepine (BZD) receptors and have been shown to act as an inverse BZD receptor agonist in the brain. A previous study suggested that the social isolation stress-induced decrease in pentobarbital sleep in mice was partly due to endogenous substances with an inverse BZD receptor agonist-like property. In this study, we examined the effects of DBI and ODN on pentobarbital sleep in group-housed and socially isolated mice to test the possible involvement of DBI and ODN in a social isolation-induced decrease in pentobarbital sleep. The socially isolated mice showed significantly shorter durations of pentobarbital (50 mg/kg, intraperitoneally, i. p.) sleep compared to the group-housed animals. When injected intracerebroventricularly (i.c.v.), DBI and ODN (3 and 10 nmol) dose-dependently shortened the pentobarbital-induced sleeping time in group-housed mice at the same dose range, but these peptides had no effect on the sleeping time in socially isolated animals. In contrast, flumazenil (16.5-33 nmol, i.c.v.), a BZD receptor antagonist, reversed the pentobarbital sleeping time in socially isolated mice to the level of group-housed animals without affecting the sleeping time in group-housed animals. The effects of DBI and ODN in group-housed mice were significantly blocked by flumazenil (33 nmol, i.c.v.). Moreover, the effect of flumazenil in socially isolated mice was significantly attenuated by DBI and ODN (10 nmol, i.c.v.). These results suggest that the changes in the activity of DBI and/or ODN are partly involved in the social isolation-induced decrease in the hypnotic action of pentobarbital in mice.     

Effect of Diabetes Mellitus on the Permeability of the Blood–Brain Barrier to Insulin

Banks, W. A., J. B. Jaspan and A. J. Kastin. Effect of diabetes mellitus on the permeability of the blood–brain barrier to insulin. Peptides 18(10) 1577–1584, 1997.—Insulin derived from the peripheral circulation has been shown to exert various effects on the brain due to its ability to cross the blood–brain barrier (BBB). The relation between diabetes mellitus and insulin has been extensively studied for peripheral tissues but not for central nervous system tissues. We examined the effects that streptozotocin- or alloxan-induced diabetes have on the transport of insulin across the murine BBB. We used multiple-time regression analysis to measure the unidirectional influx rate constant (K_i) and vascular association (V_i) of intravenously injected, radioactively labeled human insulin (I-Ins). Treatment with streptozotocin induced an enhancement of both the K_i and V_i of I-Ins that correlated with the onset of diabetes. Brain perfusion showed that the enhanced uptake was not due to altered vascular space or levels of insulin in the serum. Alloxan enhanced K_i and V_i after 5 days but the early phase of diabetes was associated with a decreased K_i. Hyperglycemia induced by the intraperitoneal injection of glucose elevated the V_i but abolished the K_i. Furthermore, altered I-Ins uptake by brain was not associated with changes in brain or body weight. These results show that there is an increased uptake of I-Ins by the brain in the diabetic state that is not due to acute changes in the serum levels of glucose or insulin, altered vascular space, or catabolic events. Chronic changes in levels of glucose, insulin or other hormone or neuroendocrine agents are likely to underlie the altered rate of transport of insulin across the BBB of diabetic mice.     

Interaction between high-fat diet and alcohol dehydrogenase on ethanol-elicited cardiac depression in murine myocytes

Objective: Consumption of high‐fat diet and alcohol is associated with obesity, leading to enhanced morbidity and mortality. This study was designed to examine the interaction between high‐fat diet and the alcohol metabolizing enzyme alcohol dehydrogenase (ADH) on ethanol‐induced cardiac depression. Research Methods and Procedures: Mechanical and intracellular Ca²⁺ properties were measured in cardiomyocytes from ADH transgenic and Friend Virus‐B type (FVB) mice fed a low‐ or high‐fat diet for 16 weeks. Expression of protein kinase B (Akt) and Foxo3a, two proteins essential for cardiac survival, was evaluated by Western blot. Cardiac damage was determined by carbonyl formation. Results: High fat but not ADH induced obesity without hyperglycemia or hypertension, prolonged time‐to‐90% relengthening (TR₉₀), and depressed peak shortening (PS) and maximal velocity of shortening/relengthening (± dL/dt) without affecting intracellular Ca²⁺ properties. Ethanol suppressed PS and intracellular Ca²⁺ rise in low‐fat‐fed FVB mouse cardiomyocytes. ADH but not high‐fat diet shifted the threshold of ethanol‐induced inhibition of PS and ± dL/dt to lower levels. The amplitude of ethanol‐induced cardiac depression was greater in the high‐fat but not the ADH group without additive effects. Ethanol down‐ and up‐regulated Akt and Foxo3a expression, respectively, and depressed intracellular Ca²⁺ rise, the effects of which were exaggerated by ADH, high‐fat, or both. High‐fat diet, but not ADH, enhanced Foxo3a expression and carbonyl content in non‐ethanol‐treated mice. Ethanol challenge significantly enhanced protein carbonyl formation, with the response being augmented by ADH, high‐fat, or both. Discussion: Our data suggest that high‐fat diet and ADH transgene may exaggerate ethanol‐induced cardiac depression and protein damage in response to ethanol.     

Kososan,a standardized traditional Japanese herbal medicine,reverses sleep disturbance in socially isolated mice via GABAA-benzodiazepine receptor complex activation

PurposeKososan (KSS), a traditional Japanese medicine with a distinct aroma, is clinically used to treat affective disorders but its antidepressant-like effect has not been thoroughly investigated. In this study, we investigated the effects of inhaled and orally administered KSS on sleep disturbances in socially isolated mice.MethodsFour-weeks-old male ddy mice were housed either in social isolation or in groups for 4–6 weeks before the experiment. KSS was orally administered (0.5 or 1.0 g/kg) or inhaled (0.5, 1.0, or 2.5 g/0.125 m³) 60 min before pentobarbital administration. Stress levels in mice were evaluated by the duration of pentobarbital-induced sleeping time.ResultsSleeping time was shorter in socially-isolated mice than in group-housed mice. Oral and inhaled KSS prolonged sleeping time in stressed mice, but had no effect on sleeping time of group-housed mice. Prolonged sleeping time after oral KSS was significantly inhibited (p < 0.05) by bicuculline (3 mg/kg, i.p.), a GABA_A antagonist, but not by flumazenil (3 mg/kg, i.p.), a selective benzodiazepine antagonist. Prolonged sleeping time after KSS inhalation was significantly inhibited (p < 0.05) by flumazenil but not by bicuculline.ConclusionsOur findings suggest that KSS activates GABA_A-benzodiazepine receptor complex and reverses shortened pentobarbital-induced sleep caused by social isolation.     

Adenyl cyclase in the human placenta

This study demonstrated that the human placenta possesses an adenyl cyclase system responsive to catecholamines and sodium flouride (NaF). 2.5 gm human term placentas were homogenized, centrifuged, washed, resuspended, and used as the enzyme system when placed with various agents. Incubations and the determination of adenosine 3', 5' monophosphate (cyclic AMP) formed were performed. Samples stimulated by .0001 M catecholamines (L-epinephrine or L-norepinephrine) or .01 M NaF had higher levels of cyclic AMP than the controls (p. 005 for catecholamine-treated samples and p. 001 for NaF-treated samples). A concentration of .0001 M L-epinephrine or L-norepinephrine appeared to be a maximum effective dose and .0000001 M a minimum. L=epinephrine was 10 times as effective in the stimulation as L-norepinephrine. With .0001 M, 499 and 439 pmoles/10 minutes per 25 mg of tissue was formed, whereas in the control (no added hormones) 256 pmoles/10 minutes were formed. 3.2% ethanol activated the system by a small amount (p.02). Propranolol alone did not appear to have any effect; however, the effect of .0001 M L-epinephrine was reduced by 95% in the presence of .00001 M propranolol. Propranolol had no effect on NaF-stimulated activity.     

A possible interaction between CCKergic and GABAergic systems in the rat brain

Cholecystokinin sulfated octapeptide (CCK-8S) was given to rats i.p. at single doses of 10 and 100 nmol/kg, respectively. It produced a modification in GABA levels in several areas of the rat brain. After 30 min of injection, the lower dose (10 nmol/kg) increased GABA levels in striatum by 31% (P<0.05). The higher dose (100 nmol/kg) enhanced GABA levels either in hippocampus by 78% (P<0.05) or in frontal cerebral cortex by 81% (P<0.05) and decreased in olfactory bulbs by 57% (P<0.01). Thus, these results show that systemic injection of CCK-8S, produced regional specific changes on GABA levels in brain, and these effects were dose-dependent. Systemic pretreatment with the CCK(B) receptor antagonist, PD 135,158, 1 mg/kg i.p., on the endogenous levels of GABA in certain regions was also studied. The selective CCK(B) receptor antagonist, PD 135,158, did not have an effect per se on the endogenous levels of GABA but prevents the action induced by the neuropeptide. We suggest that the action of CCK may be mediated via a selective action on the CCK(B) receptor subtypes.     

Enhancement of hexobarbital-induced sleep by lysine and its metabolites

Lysine has been shown to be metabolized in the rat brain to pipecolic acid which is a precursor of piperidine. Lysine and its proposed metabolites in this pathway were studied for the first time for their effect on the sleeping time induced by hexobarbital in the rat. Only $\text{L}$-lysine and $\text{D}$-lysine were found to prolong sleeping time significantly without toxic effect. A 3-day pretreatment with $\text{L}$-lysine produced an even more profound sleep prolongation. In most cases sleep enhancement was accompanied by a significant shortening of the time of sleep onset. Quantification of brain hexobarbital levels in the control and treated rats indicates that prolongation of sleeping time was not produced by inhibition of hexobarbital metabolism. The sleep prolonging effect of lysine, therefore, may be a direct action of lysine, or the metabolite(s) derived $\text{in}$$\text{vivo}$ from lysine, on the central nervous system.     

Brain γ-Aminobutyric Acid Turnover Rates After Spontaneous Chronic Ethanol Intake and Withdrawal in Discrete Brain Areas of C57 Mice

The effect of 4 weeks of spontaneous chronic ethanol intake in drinking water and then ethanol withdrawal on the gamma-aminobutyric acid (GABA) steady-state levels and turnover rates was investigated in 15 brain areas of C57 Bl/6J alcohol-preferring mice. These mice did not display typical ethanol withdrawal convulsions. There was no statistically significant difference in the brain GABA steady-state levels among the control group, chronic ethanol-treated mice, and mice after ethanol withdrawal. In contrast, chronic ethanol treatment induced significant variations in GABA turnover rate, as measured by gabaculine-induced accumulation of GABA, in eight of 15 areas examined versus a decrease in seven brain areas [cerebellum (-29%), amygdala (-28%), olfactory tubercles (-24%), septum (-24%), striatum (-53%), frontal cortex (-21%), and hippocampus (-24%)]; an increase in turnover rate in the posterior colliculus (100%) was observed. At 26 h after ethanol withdrawal, in the seven areas in which GABA turnover rate decreased after spontaneous chronic ethanol intake, a return to the initial control value was observed; in the posterior colliculus, the turnover rate did not change, remaining higher than the control value. This persisting alteration of GABA turnover rate may be related to the absence of the ethanol withdrawal syndrome in the C57 mouse strain.     

N,N'-diallylpentobarbital: antagonism of barbital in mice and rats

N,N'-Diallylpentobarbital (DAPB) antagonized barbital (B)-induced sleep in mice and rats. DAPB [80 mg/kg, intraperitoneal (i.p.)] reduced the barbital (350 mg/kg, i.p.)-induced sleeping time to 40% of the control in mice. Twenty, 40 and 80 mg/kg, i.p. of DAPB reduced barbital-induced sleeping time when administered 60 min prior to injection of barbital. DAPB (80 mg/kg, i.p.) also shortened barbital (250 mg/kg, i.p.)-induced sleeping time to about 70% of the control in rats. The result indicates that DAPB is an antagonist against hypnotic activity of barbital.     

Inhibtion of the transport of 5-hydroxyindoleacetic acid from brain by ethanol.

—The injection of ethanol in mice produced a transient rise in 5-hydroxyindoleacetic acid (5-HIAA) levels in brain. However, no concomitant changes in serotonin (5-HT) levels were noted. In an attempt to explain the biochemical mechanism by which ethanol produced this effect, uptake of tryptophan by brain, serotonin turnover in brain, and transport of 5-HIAA from brain were investigated. No changes in tryptophan levels or uptake into brain of ethanol-treated mice were noted. Ethanol 3 g/kg was found to decrease serotonin turnover. Ethanol was also demonstrated to inhibit the removal of 5-HIAA from the central nervous system, and was found to be an inhibitor of 5-HIAA uptake by isolated choroid plexus. The inhibition of biogenic acid transport was noted even at sub-hypnotic levels of ethanol.     

Protective effect of ethanol on acute ammonia intoxication in mice

A single i.p injection of 12 mmoles ammonium acetate/kg produced 100% mortality in mice. Ethanol in doses of 11 to 75 mmoles/kg administered along with the ammonium acetate decreased dramatically the mortality, the maximum protective effect being at 75 mmoles/kg. Blood and brain ammonia levels were also significantly reduced, while blood ethanol was higher in animals injected with ammonia and ethanol. Methanol and butanol also had some protective effect.     

Free radical mediated oxidative stress and toxic side effects in brain induced by the anti cancer drug adriamycin: insight into chemobrain

Adriamycin (ADR) is a chemotherapeutic agent useful in treating various cancers. ADR is a quinone-containing anthracycline chemotherapeutic and is known to produce reactive oxygen species (ROS) in heart. Application of this drug can have serious side effects in various tissues, including brain, apart from the known cardiotoxic side effects, which limit the successful use of this drug in treatment of cancer. Neurons treated with ADR demonstrate significant protein oxidation and lipid peroxidation. Patients under treatment with this drug often complain of forgetfulness, lack of concentration, dizziness (collectively called somnolence or sometimes called chemobrain). In this study, we tested the hypothesis that ADR induces oxidative stress in brain. Accordingly, we examined the in vivo levels of brain protein oxidation and lipid peroxidation induced by i.p. injection of ADR. We also measured levels of the multidrug resistance-associated protein (MRP1) in brain isolated from ADR- or saline-injected mice. MRP1 mediates ATP-dependent export of cytotoxic organic anions, glutathione S-conjugates and sulphates. The current results demonstrated a significant increase in levels of protein oxidation and lipid peroxidation and increased expression of MRP1 in brain isolated from mice, 72 h post i.p injection of ADR. These results are discussed with reference to potential use of this redox cycling chemotheraputic agent in the treatement of cancer and its chemobrain side effect in brain.