Alpha-endorphin, gamma-endorphin and their des-tyrosine fragments in rat pituitary and brain tissue

Enkephalins, endorphins and related peptides were determined in pituitary and brain tissue of rats which were killed by decapitation or microwave irradiation. The tissues were heated in 1M acetic acid prior to homogenization and the levels of the various peptides were measured by means of a combination of HPLC and radioimmunoassays. Enkephalin levels in pituitary and brain of irradiation-killed rats were much higher as compared to those in tissue of rats sacrificed by decapitation. Similar data were obtained with respect to pituitary levels of γ-endorphin, des-Tyr-γ-endorphin and des- Tyr-α-endorphin. However, brain levels of α- and γ-endorphin and their respective des-Tyr-fragments were not different with the two methods of sacrifice used. The concentrations of β-endorphin in the pituitary gland were similar in rats killed by microwave irradiation and decapitation, but irradiation showed higher β-endorphin levels in the brain than decapitation. These results suggest that β-endorphin fragments like α- and γ-endorphin and des-Tyr-α- and des-Tyr-γ-endorphin are endogenous peptides in the rat pituitary gland and the brain.     

Ischemia-induced brain iron delocalization: Effect of iron chelators

Tissue damage in cerebral ischemia may be produced by acidosis-induced delocalization of intracellular iron which acts as a catalyst in oxidative reactions. Acidosis was induced either by homogenization and incubation of rat cortical homogenates in acidified buffers or by submitting hyperglycemic rats to complete ischemia, a procedure that leads to intracellular lactic acidosis. The level of low molecular weight species (LMWS) iron was measured after filtration of tissue homogenates through a 10,000 Mr ultrafiltration membrane. When cortical tissue was homogenized in buffer pH 7, the level of LMWS iron was equal to 0.21 μg/g. It was significantly enhanced by acidification of the homogenization medium, reaching 0.34 μg/g at pH 6 and 0.75 μg/g at pH 5. When the tissue was homogenized in water, the LMWS iron level reached 0.17 μg/g in normoglycemic rats and 0.38 μg/g (p < 0.5) in hyperglycemic rats. Both aerobic incubation of homogenates for 1 h at 37°C and inclusion of EDTA in the homogenization medium led to further increases in the iron level. In order to demonstrate the deleterious role of iron in brain ischemia, the effect of treatment with bipyridyl, an iron-chelating agent, was assessed by measuring regional brain edema by the specific gravity method, 24 h following induction of thrombotic brain infarction. The treatment significantly attenuated the development of brain edema, reducing the water content of the infarcted area by about 2.5%. Taken together, these results support the hypothesis that a significant component of brain ischemic injury involves an iron-dependent mechanism.     

Radioimmunoassay of met-enkephalin in microdissected areas of paraformaldehyde-fixed rat brain

We studied the effect of various sample preparation procedures on rat brain met-enkephalin content, measured by radioimmunoassay. Whole brain met-enkephalin content of rats killed by decapitation followed by immediate tissue freezing was similar to that of rats killed by microwave irradiation and to those of rats anesthetized with pentobarbital or halothane before killing, whether previously perfused with paraformaldehyde or not. In contrast, a decrease (up to 80%) in met-enkephalin concentrations was observed when brain samples were frozen and thawed to mimic the procedure utilized in the “punch” technique for analysis of discrete brain nuclei. This decrease was totally prevented by paraformaldehyde perfusion of the brain prior to sacrifice. Brain perfusion did not alter the amount of immunoassayable met-enkephalin extracted from tissue or its profile after Sephadex chromatography. Paraformaldehyde perfusion results in better morphological tissue preservation and facilitates the “punch” dissecting technique. Paraformaldehyde perfusion may be the procedure of choice for the measurement of neuropeptides in specific brain nuclei dissected by the “punch” technique.     

Effect of food restriction on serotonin metabolism in rat brain

The brain concentration of 5-hydroxytryptamine (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) increased in rats maintained on restricted volume of low-protein or normal-protein diet, whereas these two agents decreased in rats fed low-protein diet ad libitum. In these two food-restricted groups brain 5-HT and 5-HIAA concentrations were not correlated with brain tryptophan hydroxylase activity, but the concentrations correlated closely with cerebral tryptophan concentrations. The cerebral tryptophan concentration in the two food-restricted groups was not consistent with the total or free tryptophan concentration in plasma. In these restricted rats cerebral tryptophan concentration was elevated, and, unlike the plasma tryptophan, it showed no diurnal variation. These results suggested that tryptophan uptake into the brain from plasma was enhanced by limiting food volume intake. Tryptophan uptake was increased by glucagon injection without changing the plasma tryptophan level, but injection of hydrocortisone or insulin had little or no effect on tryptophan concentration in either the plasma or brain.d-Glucose injection elevated plasma tryptophan concentration but decreased brain tryptophan concentration.     

Chronopharmacokinetics of Imipramine and Desipramine in Rat Forebrain and Plasma After Single and Chronic Treatment with Imipramine

Daily variations in the pharmacokinetics of imipramine (IMI) could contribute to circadian phase-dependent effects of the drug. Therefore, the chronopharmacokinetics of IMI and its metabolite, desipramine (DMI), were studied after single and chronic application. Male rats were synchronized to a 12:12 hour lightdark (L:D) regimen with lights on from 07:00 to 19:00 (dark, 19:00-07:00). In single-dose experiments rats were injected with IMI (10 mg/kg) i.p. or i.v. at 07:30 or 19:30 and groups of rats were killed 0-22 hours thereafter. After chronic application of IMI in drinking water (≈ 15 mg/kg/d) groups of rats were killed during the 14th day of treatment at 02:00, 08:00, 14:00, and 20:00, respectively. Brain and plasma concentrations of IMI and DMI were determined by reversed-phase high-performance liquid chromatography with ultraviolet detection. After single i.p. application of IMI, maximal brain concentrations (C_max) of IMI and DMI were nearly twofold higher in darkness (IMI, 4.8 μg/g; DMI, 1.8 μg/g) than in light (IMI, 2.85 Mg/g; DMI, 0.85 Mg/g). Also, the area under the curve (AUC) (0-22 hours) was about 1.6-fold greater in darkness than in light for IMI and DMI; half-lives were not circadian phase dependent. After i.v. injection of IMI, the AUC in brain was also about 30% greater in darkness than in light. After chronic application of IMI in drinking water, brain concentrations of IMI and DMI varied more than threefold within 24 hours. The data demonstrate that the pharmacokinetics of IMI and DMI are circadian phase dependent. It is assumed that circadian variations in drug distribution are more likely to contribute to the drug's chronopharmacokinetics than variations in the drug's metabolism. The 24-hour variations in the drug's concentrations after chronic IMI application in drinking water can be explained by the drinking behavior of the rats, which by itself is altered by IMI.     

Chronopharmacokinetics of imipramine and desipramine in rat forebrain and plasma after single and chronic treatment with imipramine.

Daily variations in the pharmacokinetics of imipramine (IMI) could contribute to circadian phase-dependent effects of the drug. Therefore, the chronopharmacokinetics of IMI and its metabolite, desipramine (DMI), were studied after single and chronic application. Male rats were synchronized to a 12:12 hour light:dark (L:D) regimen with lights on from 07:00 to 19:00 (dark, 19:00-07:00). In single-dose experiments rats were injected with IMI (10 mg/kg) i.p. or i.v. at 07:30 or 19:30 and groups of rats were killed 0-22 hours thereafter. After chronic application of IMI in drinking water (approximately 15 mg/kg/d) groups of rats were killed during the 14th day of treatment at 02:00, 08:00, 14:00, and 20:00, respectively. Brain and plasma concentrations of IMI and DMI were determined by reversed-phase high-performance liquid chromatography with ultraviolet detection. After single i.p. application of IMI, maximal brain concentrations (Cmax) of IMI and DMI were nearly twofold higher in darkness (IMI, 4.8 micrograms/g; DMI, 1.8 micrograms/g) than in light (IMI, 2.85 micrograms/g; DMI, 0.85 microgram/g). Also, the area under the curve (AUC) (0-22 hours) was about 1.6-fold greater in darkness than in light for IMI and DMI; half-lives were not circadian phase dependent. After i.v. injection of IMI, the AUC in brain was also about 30% greater in darkness than in light. After chronic application of IMI in drinking water, brain concentrations of IMI and DMI varied more than threefold within 24 hours. The data demonstrate that the pharmacokinetics of IMI and DMI are circadian phase dependent. It is assumed that circadian variations in drug distribution are more likely to contribute to the drug's chronopharmacokinetics than variations in the drug's metabolism. The 24-hour variations in the drug's concentrations after chronic IMI application in drinking water can be explained by the drinking behavior of the rats, which by itself is altered by IMI.     

Rats retain chromium in tissues following chronic ingestion of drinking water containing hexavalent chromium

Humans have sometimes been exposed to as much as 10 ppm Cr(VI) in drinking water from contaminated wells. The risks to these individuals are not well understood because the digestive tract reduces some of the Cr(VI) to the less bioavailable Cr(III) prior to absorption, and the disposition of the remaining Cr(VI) has not been well studied. We determined tissue Cr concentrations in rats after chronic ingestion of Cr(VI) in drinking water at concentrations relevant to human exposure levels. Adult male and female Fischer 344 rats consumed ad libitum 0, 0.5, 3, or 10 ppm Cr(VI) as K₂CrO₄ in drinking water for 44 wk. Rats then were given deionized water 4–6 d prior to sample collection. Females given 3 or 10 ppm Cr(VI) consumed more Cr(VI) per unit of body weight than did males. Bone Cr concentrations were significantly elevated in rats that drink 10 ppm Cr(VI). Renal Cr concentrations were significantly elevated in male rats that drink 3 or 10 ppm Cr(VI) and in female rats dosed with 10 ppm Cr(VI). Female rats had elevated liver Cr concentrations after drinking 3 or 10 ppm Cr(VI). Testicular Cr concentrations were slightly elevated in rats that drank 10 ppm Cr(VI). Brain, ovarian, and whole-blood Cr concentrations were below detection limits in all exposure groups. Although tissue Cr accumulation may have resulted from absorption of Cr(III), it is poorly absorbed. Therefore, the increased tissue retention may also have resulted, in part, from increased absorption of Cr(VI) and its subsequent uptake from the systemic circulation.     

A rapid and potent natriuretic response to intravenous injection of atrial myocardial extract in rats

Supernatants of atrial or ventricular myocardial homogenates were injected intravenously into anaesthetized non-diuretic rats. Extract derived from atrial muscle caused a rapid, more than 30-fold increase of sodium and chloride excretions, while urine volume rose 10-fold, and potassium excretion doubled. No such changes were observed after injection of ventricular tissue extract obtained from the same rat hearts, or after injection of the homogenization medium. There was no significant difference in glomerular filtration rates between the two groups. We conclude that the atrial extract contained an extremely powerful inhibitor of renal tubular NaCl reabsorption.     

Adaptation of BHK-21 Cells to Growth in Shaker Culture and Subsequent Challenge by Japanese Encephalitis Virus

Baby hamster kidney (BHK-21) cells were adapted to grow in shaker culture using Waymouth medium 752/1 containing 20 mM N-2-hydroxyethyl-piperazine-N'-2'-ethanesulfonic acid buffer and supplemented with 2.5% (vol/vol) calf serum, 0.002% (wt/vol) sodium oleate, and 0.2% fatty acid-free bovine serum albumin (WO2.5). Infectivity of Japanese encephalitis virus grown in the cells adapted to WO2.5 approached 2 x 10(8) plaque-forming units per ml. The culture volume of infected cells was reduced fivefold 12 h after infection. This step resulted in a 10-fold increase in infectivity over that obtained from infected cultures not subjected to volume reduction.     

Highly sensitive method for quantitative determination of bilirubin in biological fluids and tissues

Unconjugated bilirubin (UCB) exhibits potent antioxidant and cytoprotective properties, but causes apoptosis and cytotoxicity at pathologically elevated concentrations. Accurate measurement of UCB concentrations in cells, fluids and tissues is needed to evaluate its role in redox regulation, prevention of atherosclerotic and malignant diseases, and bilirubin encephalopathy. In the present study, we developed and validated a highly sensitive method for tissue UCB determinations. UCB was extracted from rat organs with chloroform/methanol/hexane at pH 6.2 and then partitioned into a minute volume of alkaline buffer that was subjected to HPLC using an octyl reverse phase (RP) column. Addition of mesobilirubin as an internal standard corrected for losses of UCB during extraction. Recoveries averaged 75+/-5%. The detection limit was 10pmol UCB/g wet tissue. Variance was +/-2.5%. When used to measure UCB concentrations in tissues of jaundiced Gunn rats, this procedure yielded UCB levels directly comparable to published methods, and accurately determined very low tissue bilirubin concentrations (相似文献   

Insulin receptors prepared with iodoacetamide show enhanced autophosphorylation and receptor kinase activity.

In this study, we found that adding iodoacetamide to the homogenization buffer used in the preparation of mouse or rat liver plasma membranes resulted in an increase of insulin receptor autophosphorylation by 4-5-fold and receptor kinase activity by about 2-fold. Similar effects were obtained with iodoacetate and p-chloromercuriphenyl sulfonate. The effect of iodoacetamide was minimal when it was added to membranes prepared without the thiol reagent. The enhancing effect of iodoacetamide on insulin receptor autophosphorylation was the result of a more than 2-fold decrease in the Km and a more than 3-fold increase in Vmax for ATP. The presence of iodoacetamide in the preparation of plasma membranes also greatly increased the solubilization of the insulin receptor from the plasma membrane by Triton X-100. We propose that iodoacetamide acts to alkylate some unknown thiols released during tissue homogenization and that in its absence these thiols formed mixed disulfides with the insulin receptor, thus adversely affecting the process of receptor activation by insulin.     

Hyperammonemia in anorectic tumor-bearing rats

Plasma ammonia concentrations were significantly elevated by 150% in anorectic rats bearing methylcholanthrene sarcomas. Assessment of ammonia levels in blood draining these sarcomas indicated nearly a 20-fold increase as compared with venous blood in control rats, suggesting the tumor mass as the source of this increase in ammonia. Infusing increasing concentrations of ammonium salts produced anorexia and alterations in brain amino acids in normal rats that were similar to those observed in anorectic tumor-bearing rats. Therefore, these results suggest that ammonia released by tumor tissue may be an important factor in the etiology of cancer anorexia.     

Adding protein to a carbohydrate supplement provided after endurance exercise enhances 4E-BP1 and RPS6 signaling in skeletal muscle.

To examine the role of both endurance exercise and nutrient supplementation on the activation of mRNA translation signaling pathways postexercise, rats were subjected to a 3-h swimming protocol. Immediately following exercise, the rats were provided with a solution containing either 23.7% wt/vol carbohydrates (CHO), 7.9% wt/vol protein (Pro), 31.6% wt/vol (23.7% wt/vol CHO + 7.9% wt/vol Pro) carbohydrates and Pro (CP), or a placebo (EX). The rats were then killed at 0, 30, and 90 min postexercise, and phosphorylation states of mammalian target of rapamycin (mTOR), ribosomal S6 kinase (p70(S6K)), ribosomal protein S6 (rpS6), and 4E-binding protein 1 (4E-BP1), were analyzed by immunoblot analysis in the red and white quadriceps muscle. Results demonstrated that rat groups provided with any of the three nutritional supplements (CHO, Pro, CP) transiently increased the phosphorylation states of mTOR, 4E-BP1, rpS6, and p70(S6K) compared with EX rats. Although CHO, Pro, and CP supplements phosphorylated mTOR and p70(S6K) after exercise, only CP elevated the phosphorylation of rpS6 above all other supplements 30 min postexercise and 4E-BP1 30 and 90 min postexercise. Furthermore, the phosphorylation states of 4E-BP1 (r(2) = 0.7942) and rpS6 (r(2) = 0.760) were highly correlated to insulin concentrations in each group. These results suggest that CP supplementation may be most effective in activating the mTOR-dependent signaling pathway in the postprandial state postexercise, and that there is a strong relationship between the insulin concentration and the activation of enzymes critical for mRNA translation.     

Utilization of membranous lipid substrates by membranous enzymes: activation of the latent sphingomyelinase of hen erythrocyte membrane

Previous studies demonstrated that hen erythrocytes have an inoperative, latent sphingomyelinase which is activated when the cells are hemolyzed in a hypotonic medium. Within minutes after hemolysis about 60-80% of the sphingomyelin (SPM) of the RBC "ghost" membrane was hydrolyzed. In this paper, expression of sphingomyelinase activity was further investigated. The percentage of total SPM hydrolyzed depended on the volume of the hypotonic hemolyzing buffer. Thus, suspending the erythrocytes in 4 vol of the buffer resulted in clumping of the hemolyzed "ghosts" and no hydrolysis of SPM. In comparison, suspension in 19 vol of the hypotonic buffer showed no clumping and sphingomyelinase activity was fully expressed. But centrifugation of the latter or, alternatively, addition of concanavalin A induced clumping and elimination of sphingomyelinase activity. Hen RBC could also be hemolyzed in an isotonic medium in the presence of Triton X-100, mellitin, halothane, and phospholipase C. Activation of the latent sphingomyelinase occurred at concentrations of these reagents which caused cell lysis. Hen RBC were dispersed in an isotonic medium containing glutaraldehyde (0.1%) or formaldehyde (10%). This rendered the cells resistant to hemolysis, even when subsequently dispersed in a hypotonic medium or water. But incubation of the "fixed" cells in a hypotonic or isotonic medium activated the enzyme, resulting in hydrolysis of 60% of the cellular SPM. In contrast, when glutaraldehyde was included in the hypotonic buffer, hemolysis occurred but sphingomyelinase activity was eliminated.     

Electrolyte- and fluid-spaces of rat brain in situ after infusion with dinitrophenol.

Chemical distribution measurements of radioactive sodium-thiosulfate (35S) and of the brain water indicate that infusion of 2.4-dinitrophenol into a carotid artery of rats caused a water uptake and fluid shifts from the extra- into the intracellular compartments in the central nervous system. The extracellular marker compound was administered to the brain via ventriculo-cisternal perfusion and intravenous injection yielding almost equal concentrations in plasma-water and perfusate. In order to prevent an active efflux of the label from the tissue, high concentrations were utilized in the perfusate to saturate potential outward transport mechanisms. The indicator space (based on total brain water) was 16% in controls and 12% in experimental animals when marker equilibrium had been attained, which is equivalent in reduction of the extracellular space of about 1/4. Intracellular water and Na+ rose after DNP, while K+ remained all but unchanged. The fluid shift into the intracellular compartment was found to relate closely with a cellular uptake of Na+. The Na+ concentration both in plasma and in the perfusion fluid leaving the ventricular system was consistently reduced in experimental animals. The K+ concentration was significantly elevated in the plasma of experimental animals but virtually unchanged in the cisternal effluate.     

Tissue accumulation of cadmium as a function of blood concentration

We have provided data relating Cd concentration in tissue to about a 40-fold range in blood Cd concentration. Osmotic pumps containing cadmium chloride were subcutaneously implanted in male New Zealand white rabbits. The pumps continuously delivered either 0.15 or 1.5 mg Cd/d. Blood and plasma levels of Cd were measured weekly throughout the study. After 28 d, the rabbits were killed and tissue concentrations of Cd determined by atomic absorption spectrophotometry. Less than 10% of the total Cd in the blood was carried in the plasma, the remainder was associated with the blood cells, where it was bound mainly to metallothionein. We found the blood and tissue levels of Cd were correlated for each tissue we investigated. There was a wide range in affinity of the tissues for Cd; liver and kidney had the highest Cd uptake, whereas brain affinity was about 500 times less than liver.     

Effects of water dilution, housing, and food on rat urine collected from the metabolism cage

The objective of the study reported here was to investigate three factors that may affect the amounts of water consumed and urine excreted by a rat in the metabolism cage: water dilution, housing, and food. Young F344/N rats (eight per group) were used for all experiments. Food was withheld from rats before each 16-h urine collection, then rats were transferred into a metabolism cage. For trial A (water dilution), urine was collected from rats supplied with dyed water (0.05%, vol/vol). This was repeated three times over a 2-week period. Dye in water or urine was quantified, using a spectrophotometer. For trial B (housing), rats were individually housed in wire cages for 3 weeks before the first urine collection. Then they were group housed in the solid-bottom cage (four per cage). After 2 weeks of acclimation, urine collection was repeated. For trial C (food), one group of rats was provided with food, the other was not, during urine collection. About 8% of urine samples of small volume (< or = 3 ml) from trial A were contaminated with drinking water up to 13% of volume. The average urine volume associated with individual housing was approximately twice as large as that associated with group housing. When food was provided during urine collection, rats consumed similar amounts of water but excreted significantly smaller amounts of urine than did rats without food. It was concluded that water dilution of a urine sample from a sipper bottle is relatively small; rats individually housed in wire caging before urine collection can consume and excrete a larger quantity of water, compared with rats group housed in solid-bottom cages; and highly variable urine volumes are, in part, associated with lack of access to food during urine collection.     

On the loss of gangliosides by dialysis

The Gangliosides represent a family of sialic acidcontaining sphingoglycolipids which have ceramide (N-acyl-sphingosine) as the basic hydrophobic portion (Svennerholm , 1972). A heteropolysaccharide is glycosidically linked through the primary hydroxyl group of ceramide and the aldehyde of glucose. There are usually three or four different carbohydrates and up to a total of seven in the chain. The isolated gangliosides are soluble both in organic and aqueous solvents presumably because of their content of both hydrophobic and hydrophilic groups. The most commonly employed extraction procedure is based upon their solubility in chloroform-methanol (2: 1, v/v) and subsequent partitioning into an aqueous methanol phase (FOLCH, LEES and SLOANE-STANLEY, 1957). This methanolic solution is then dialysed against water to remove small molecular-weight contaminants. This paper reports the loss of gangliosides upon dialysis when they are present at low concentrations. Gangliosides were prepared from fresh calf brain as previously described (Kanfer , 1969) and contained 25-25% GMl, as judged by quantitative thin-layer chromatography (Suzuki , 1964). GM2 was prepared from this material by treatment with neuraminidase as previously described (Kolodny , Brady , Quirk and Kanfer , 1970) and purified by the procedure of Winterbourne (1971). GM2 was isolated from brain tissue of a Tay-Sachs child provided by Dr. B. Volk. Thin-layer chromatography was carried out on Analtech Silica Gel G plates (Analtech Co., Wilmington, Del.) with chloroformmethanol-2.5 N NH₄OH (60 : 30 : 8, by vol.) as developing solvent. Total sialic acid was quantified by the resorcinol procedure according to Suzuki (1964). Duplicate known quantities of gangliosides were dissolved in 2 ml of methanol 41 M KCI(1 : 1, v/v) and dialysed overnight in untreated Visking tubing (0.22-in. dia.; Fisher Scientific Co., Pittsburgh, Pa.; Cat. No. 1000) against a 500-fold vol. of distilled water at 4°C. The contents of the sacs were removed and the total volume was measured; a 10-1 5 per cent increase in volume was usually observed. Portions were analysed in duplicate for total sialic acid content, and the remainder was lyophilized for examination by TLC.     

Taurine supplementation improves the utilization of sulfur-containing amino acids in rats continually administrated alcohol

The main purpose of this study was to evaluate changes in brain sulfur-containing amino acid (SCAA) metabolism to determine whether taurine intervened under continuous alcohol intake. We fed 80 male Sprague-Dawley rats 30% alcohol-containing water for 4 weeks. Eighty animals were divided into two groups (with or without 2 g/kg body weight taurine supplementation), and five were killed every week in each group for monitoring SCAA changes in the brain, liver, kidneys and heart. Results indicated that the plasma alcohol concentration increased from Weeks 1-4; however, animals with taurine supplementation showed a lower plasma concentration of ethanol in Week 2. As to SCAA concentrations, cysteine and taurine were both lower after a week of alcohol ingestion in the brain and plasma; the same declining trend was shown in the liver in Week 2. In contrast, plasma and hepatic concentrations of homocysteine were elevated in Week 2, and the plasma S-adenosylmethionine (SAM)/S-adenosylhomocysteine (SAH) ratio also decreased in Week 1. Furthermore, the key cofactor of transsulfuration, pyridoxal-5'-phosphate, significantly declined in the plasma after a week of the ethanol intervention, whereas an increase was observed in brain tissue. Under taurine supplementation, some recoveries were shown by delaying taurine depletion to Week 2, increasing the SAM/SAH ratio and elevating plasma and brain levels of vitamin B6 in Week 2. In conclusion, daily consumption of 30% alcohol interfered with SCAA metabolism, thus decreasing taurine's role in neurotransmission. The possible mechanism involved might be that ethanol interrupts the production of cysteine, which is the upstream SCAA of taurine, thus decreasing the homocysteine level. Additionally, taurine supplementation delayed this process.     

Acetate supplementation attenuates lipopolysaccharide-induced neuroinflammation

Glyceryl triacetate (GTA), a compound effective at increasing circulating and tissue levels of acetate was used to treat rats subjected to a continual 28 day intra-ventricular infusion of bacterial lipopolysaccharide (LPS). This model produces a neuroinflammatory injury characterized by global neuroglial activation and a decrease in choline acetyltransferase immunoreactivity in the basal forebrain. During the LPS infusion, rats were given a daily treatment of either water or GTA at a dose of 6 g/kg by oral gavage. In parallel experiments, free-CoA and acetyl-CoA levels were measured in microwave fixed brains and flash frozen heart, liver, kidney and muscle following a single oral dose of GTA. We found that a single oral dose of GTA significantly increased plasma acetate levels by 15 min and remained elevated for up to 4 h. At 30 min the acetyl-CoA levels in microwave-fixed brain and flash frozen heart and liver were increased at least 2.2-fold. The concentrations of brain acetyl-CoA was significantly increased between 30 and 45 min following treatment and remained elevated for up to 4 h. The concentration of free-CoA in brain was significantly decreased compared to controls at 240 min. Immunohistochemical and morphological analysis demonstrated that a daily treatment with GTA significantly reduced the percentage of reactive glial fibrillary acidic protein-positive astrocytes and activated CD11b-positive microglia by 40-50% in rats subjected to LPS-induced neuroinflammation. Further, in rats subjected to neuroinflammation, GTA significantly increased the number of choline acetyltransferase (ChAT)-positive cells by 40% in the basal forebrain compared to untreated controls. These data suggest that acetate supplementation increases intermediary short chain acetyl-CoA metabolism and that treatment is potentially anti-inflammatory and neuroprotective with regards to attenuating neuroglial activation and increasing ChAT immunoreactivity in this model.