Levels of cyclic nucleotides in mouse regional brain following 300 ms microwave inactivation.

Abstract— The uniformity and speed of inactivation of mouse brain adenylate cyclase, guanylate cyclase and cyclic nucleotide phosphodiesterase were measured after 6 kW microwave irradiation (MWR). Inactivation of enzymes was uniform throughout the brain during heating and 100% loss of activity was evident after 300 ms. MWR. For comparison of effects of inactivation times on levels of cyclic nucleotides measured in regional brain areas, cyclic AMP and cyclic GMP were estimated after 1.5 kW MWR requiring 4 s of heating and 6 kW MWR requiring 300 ms. Except for corpus striatum, uniformly lower levels of cyclic AMP were measured following 300 ms vs. 4s MWR . There was no change in cyclic GMP levels in regional brain areas after 4s vs. 300 ms MWR . Cyclic AMP and cyclic GMP were measured from the same regional brain tissue samples after 300 ms and ratios calculated. The finding of much lower cyclic AMP:cyclic GMP ratios than had previously been reported suggests that slow inactivation times provide for the measurement of regional brain cyclic nucleotide values which are not consistent with the in-vivo state.     

Rate of inactivation of adenyl cyclase and phosphodiesterase: determinants of brain cyclic AMP

In order to assess the effects of time requirements of different tissue inactivation methods, concentrations of cyclic adenosine monophosphate in rat brain were determined. Fixation of tissues was obtained by the following methods: decapitation with removal of brain and freezing in liquid nitrogen; decapitation into liquid nitrogen; whole animal immersion in liquid nitrogen; 1.5 kW maximal field strength microwave irradiation for 8 seconds; and, 5 kW maximal field strength microwave irradiation for 2 seconds. Results of these studies indicate that as the time is reduced for inactivation of brain adenyl cyclase and phosphodiesterase, levels of cyclic adenosine monophosphate become progressively lower. This same correlation is also evident in studies of regional brain concentrations of cyclic adenosine monophosphate after 1.5 kW and 5 kW microwave inactivation. It is concluded that 5 kW maximal field strength microwave exposure is the most rapid means of enzyme inactivation permitting a more accurate estimation of endogenous cyclic adenosine monophosphate concentrations. Its use offers rapid inactivation with minimization of trauma and facilities the study of regional metabolites through ease of dissection.     

The effects of altered endocrine states and of ether anaesthesia on mouse brain

The effects of ether anaesthesia on metabolites of mouse brain in altered endocrine states has been examined. Alloxan diabetic mice, with elevated levels of blood and brain glucose, exhibited changes in brain metabolites after ether anaesthesia that were comparable to those seen in normal animals. Sympathectomized and/or adrenalectomized mice had decreased levels of brain glucose. The percentage elevation of glucose in the brains of these animals under ether anaesthesia approximated to normal values, although the absolute cerebral levels were lower. Increases in glycogen in the brains of these animals were somewhat diminished. In none of the altered endocrine states were the changes in brain metabolites following ether anaesthesia eliminated. The activity of UDPglucose-glycogen glucosyltransferase (UDPglucose: glycogen α-4-glucosyltransferasee, EC 2.4.1.11) in the mouse brain was measured in the absence and in the presence of glucose-6-P. Neither the total activity nor the percentage of the I form (measured in the absence of glucose-6-P) was altered by anaesthesia or by the endocrine state of the animal. The Michaelis constants with UDPglucose as substrate for the total and I forms were 0·36 mM and 1·0 mM, respectively. Considerable UDPglucose-glycogen glucosyltransferase activity was observed in the absence of added glycogen primer. The observed increase in activity in the presence of added glucose-6-P was greater than would have been anticipated if the hexose phosphate were acting at only one site.     

THE USE OF MICROWAVE HEATING TO INACTIVATE CHOLINESTERASE IN THE RAT BRAIN PRIOR TO ANALYSIS FOR ACETYLCHOLINE

Abstract— Heating with 2450 MHz microwave radiation has been investigated as a means for animal sacrifice concurrent with enzyme inactivation. Uniform inactivation of cholinesterase (EC 3.1.1.8) in the entire brain can be effected in the rat within 4 s and in the mouse within 2 s without destruction of acetylcholine. The acetylcholine content in the whole brain of a rat was found to be 25.4 ± 1.5 nmol/g after irradiation, in comparison to 13.8 ± 1.7 nmol/g after standard methods of sacrifice. In the mouse whole brain, the comparable acetylcholine contents were 25.5 ± 2.6 and 13.7 ± 1.7 nmol/g, respectively. The value of this procedure for rapid inactivation of enzymes in the study of acetylcholine turnover is discussed.     

Evaluation of the necessity for rapid inactivation of brain enzymes prior to analysis of norepinephrine dopamine and serotonin in the mouse.

Norepinephrine, dopamine and serotonin concentrations were measured in mouse whole brain. Animals were killed either by decapitation or by exposure to 250 msec microwave irradiation which produces irreversible inactivation of brain enzymes. The biogenic amines were determined by mass fragmentometry, fluorometry and by a combination of high performance liquid chromatography and an electrochemical detector. No differences were found in the levels of these neurochemicals between the two methods of animal sacrifice. Therefore, rapid inactivation of brain enzymes is not necessary prior to analysis for catecholamines and serotonin in mouse whole brain.     

REGIONAL γ-AMINOBUTYRIC ACID LEVELS IN RAT BRAIN DETERMINED AFTER MICROWAVE FIXATION

—GABA levels in rat whole brain were compared following three methods of sacrifice: rapid microwave fixation, decapitation into liquid nitrogen, and decapitation at 20°C. Levels were shown to be identical in animals sacrificed by microwave fixation and decapitation into liquid nitrogen. In contrast, rats decapitated at 20°C had 18 per cent higher GABA levels when determined immediately post-mortem and 48 per cent higher levels after 30 min at 20°C. Microwave treatment prevented these post-mortem increases. The increase in GABA after decapitation at 20°C was even greater in hypothalamus than in whole brain. A comparison of 3 GABA extraction methods following microwave fixation demonstrated that sodium acetate was 88 per cent as effective as 80 per cent ethanol and more effective than 0·5 n -perchloric acid in extracting GABA. Fifteen brain regions were dissected from microwave-treated brains and the GABA levels determined.     

Cerebral perfusion of metabolic inactivators: A new method for rapid fixation of labile lipid pools in brain

This paper describes a new method for the rapid fixation of labile lipid pools in the brain. Perfusion of the brain with 0.9% saline containing esterase inhibitors (p-bromphenacyl-bromide and diisopropyl fluorophosphate), an antioxidant (nordihydroguaiaretic acid) and a Ca²⁺ chelator (EDTA) resulted in a substantial reduction in the levels of free fatty acids, a biochemical marker for the degradation of labile membrane lipids. Levels of unesterified polyunsaturated fatty acids in whole brain were decreased by 90–96% as compared to levels in brains perfused with saline alone. Levels of docosahexaenoic acid approximated levels obtained after microwave irradiation. Unlike microwave irradiation, this perfusion technique perserves the cellular structure of the brain, thereby allowing subcellular fractionation with minimal postmortem changes in lipid pools. The release of arachidonic acid during isolation of the P₂ (synaptosomal) fraction was completely inhibited by the presence of the metabolic inactivators. The results of this study demonstrate a new and useful technique for the postmortem inactivation of enzymes responsible for the degradation of labile lipids in the brain. Further, the data underscore the key role of phospholipase A₂ and Ca²⁺ in mediating the release and accumulation of free fatty acids in the ischemic brain.Abbreviations 204 arachidonic acid - 226 docosahexaenoic acid - 160 palmitic acid - 180 stearic acid - 181 oleic acid - 182 linoleic acid - NDGA nordihydroguaiaretic acid - pBPB p-bromphenacylbromide - EDTA ethylenediamine-tetraacetic acid - DFP diisopropyl fluorophosphate - FFA free fatty acids - TLC thin layer chromatography - GLC gas liquid chromatography     

微波辐射对小鼠脑内乙酰胆碱含量及胆碱乙酸转移酶活性的影响

用频率为2450MHz功率密度为10mW/Cm~2(WBASAR约11.4W/kg)的微波(连续波)对置于微波暗室内的昆明种雄性小鼠急性全身照射1小时后,立即按常规方法断头,取脑,制成样品,然后用放射免疫测定法测量小鼠脑内乙酰胆碱(ACh)含量及胆碱乙酰转移酶(ChAT)活性。结果表明:照射组的ACh含量为11.6±1.4pmol/mg(脑鲜重),ChAT活性为45.4±8.7pmolACh/min.mg(脑鲜重);而对照组的分别为16.0±2.1pmol/mg和61.0±13.8pmolACh/min.mg。证明微波照射后可引起动物脑内ACh水平和ChAT活性下降,提示微波辐射对中枢胆碱能系统确有不利影响。     

MOLECULAR PROPERTIES OF CHOLINE ACETYLTRANSFERASE FROM DIFFERENT SPECIES INVESTIGATED BY ISOELECTRIC FOCUSING AND ION EXCHANGE ADSORPTION

—The isoelectric point, surface charge and K_m for choline of choline acetyltransferase from different species were determined. Choline acetyltransferase from mouse and monkey brain was resolved into three molecular forms with isoelectric points at 7·1, 7·5, 8·4 and 7·0, 7·35, 8·35 respectively, whereas choline acetyltransferase from the electric organ of Torpedo and from rabbit brain showed a molecular form with isoelectric point 6·6 and 6·9, respectively. With the exception of rabbit brain enzyme, there was a good correlation between the isoelectric points and surface charges of the different choline acetyltransferases. The K_m's for choline were 0·66, 0·88, 0·92 and 3·5 mM for monkey, mouse, rabbit and Torpedo choline acetyltransferase respectively. The separated molecular forms of mouse and monkey enzymes did not show any significant difference in their affinity for choline.     

Measurement of Hippocampal Levels of Cellular Second Messengers Following In Situ Freezing

Abstract: The in situ freezing technique has been widely used to fix labile metabolites and cellular second messengers in cerebral cortex. In this study, we isolated specific brain regions at 0°C from coronal sections of frozen heads following in situ brain freezing and measured regional concentrations of labile metabolites and cellular messengers. These levels in the cortex were compared with those in cortical punches obtained at freezing temperature (less than −40°C) from the same in situ frozen brains and those of cortex dissected from decapitated animals. In both isoflurane- and pentobarbital-anesthetized animals, we observed that the levels of lactate, free fatty acids, inositol 1,4,5-trisphosphate, and diacylglycerol, as well as the proportion of protein kinase C associated with the membrane fraction, were similar in cortical punches taken at freezing temperature and those dissected at 0°C. However, with animals decapitated at room temperature, cortical and hippocampal levels of lactate, free fatty acids, and inositol 1,4,5-trisphosphate and the proportion of membrane protein kinase C were significantly higher than those of corresponding brain regions isolated at 0°C from in situ frozen brains ( p < 0.05). These results indicate that dissection of cortex and hippocampus at 0°C following in situ freezing will eliminate decapitation-induced production of artifacts and changes in the levels of cellular second messengers such as inositol 1,4,5-trisphosphate, diacylglycerol, and protein kinase C. The present technique, used in conjunction with in situ freezing, will fix cellular second messengers and labile metabolites in several regions of brain and may facilitate accurate characterization of molecular and cellular mechanisms underlying CNS function.     

AMP-activated protein kinase phosphorylation in brain is dependent on method of killing and tissue preparation

AMP-activated protein kinase (AMPK) is activated when the catalytic α subunit is phosphorylated on Thr172 and therefore, phosphorylation of the α subunit is used as a measure of activation. However, measurement of α subunit of AMPK (α-AMPK) phosphorylation in vivo can be technically challenging. To determine the most accurate method for measuring α-AMPK phosphorylation in the mouse brain, we compared different methods of killing and tissue preparation. We found that freeze/thawing samples after homogenization on ice dramatically increased α-AMPK phosphorylation in mice killed by cervical dislocation. Killing of mice by focused microwave irradiation, which rapidly heats the brain and causes enzymatic inactivation, prevented the freeze/thaw-induced increase in α-AMPK phosphorylation and similar levels of phosphorylation were observed compared with mice killed with cervical dislocation without freeze/thawing of samples. Sonication of samples in hot 1% sodium dodecyl sulfate blocked the freeze/thaw-induced increase in α-AMPK phosphorylation, but phosphorylation was higher in mice killed by cervical dislocation compared with mice killed by focused microwave irradiation. These results demonstrate that α-AMPK phosphorylation is dependent on method of killing and tissue preparation and that α-AMPK phosphorylation can increase in a manner that does not reflect biological alterations.     

Rapid High-Energy Microwave Fixation is Required to Determine the Anandamide (<Emphasis Type="BoldItalic">N</Emphasis>-arachidonoylethanolamine) Concentration of Rat Brain

Anandamide (N-arachidonoylethanolamine, AEA) is the putative endogenous ligand for the CB₁ receptor. Despite being regulated enzymatically, brain AEA concentrations are quite variable and have been reported to increase in response to ischemia and post-mortem delay. Because these observations are similar to the effects of decapitation on brain concentrations of unesterified arachidonic acid and several of its metabolites, we propose that brain AEA concentrations also increase with decapitation and that immediate head-focused microwave irradiation is necessary to quantify basal brain AEA levels correctly. To test this hypothesis, we measured brain AEA levels in rats that were subjected to head-focused microwave irradiation 5 min. following decapitation (5.5 kW, 3.4 s) (ischemic) and prior to decapitation (controls). Brain AEA concentrations were quantified by LC/MS/MS. AEA concentrations from ischemic animals (10.01 ± 4.41 pmol/g, mean ± SD) were significantly higher and more variable than control concentrations (2.45 ± 0.39 pmol/g). Thus, the basal concentration of AEA in the brain is lower than previously thought and future studies attempting to quantify brain AEA should consider using head-focused microwave fixation to prevent anomalous results.     

A COMPARISON OF METHODS FOR STOPPING INTERMEDIARY METABOLISM OF DEVELOPING RAT BRAIN1

Abstract— Freeze-blowing (Veech et al. 1973), focussed microwave irradiation (Stavinoha et al. 1973) and immersion in liquid nitrogen were compared as methods for stopping metabolism in order to assay in vivo levels of intermediary metabolites in developing rat brain. Freeze-blowing was superior at all ages (5. 10, 15 and 20 days post-natal). The differences between this method and immersion in liquid nitrogen were quite small in the youngest rats and increased with age. reflecting the increased time needed to freeze larger brains. Brains frozen by immersion in liquid nitrogen showed evidence of increased anaerobic metabolism, with increased fructose 1.6-diphosphate. dihydroxyacetone phosphate and lactate and decreased glucose 6-phosphate and creatine phosphate concentrations. When brain metabolism was stopped by microwave irradiation there were many differences from freeze-blown brain. Increases in fructose 1.6-diphosphate. dihydroxyacetone phosphate, ADP and AMP, and decreased in ATP and creatine phosphate were especially striking. The differences between microwave irradiation and freeze-blowing were not attributable simply to anoxia. Rather, the changes produced by this method seem to reflect the different thermal characteristics of the various enzymes which must be denatured to stop metabolism of the substrates measured. Unlike freezing in liquid nitrogen, the efficacy of microwave irradiation was not a simple function of head size, in that better results were achieved with 15- and 20-day-old than 5- or 10-day-old rats. Many glycolytic and Krebs cycle intermediates, as well as glutamate and aspartate, progressively increased over the course of development. The reasons for these increases are uncertain but are probably-related to the concomitant rises in rates of glycolysis and oxidative phosphorylation in brain.     

On the Use of Microwave Radiation Energy for Brain Tissue Fixation

Abstract: Focused microwave irradiation (MWR) is an increasingly accepted method of sacrifice of laboratory animals such as the mouse or rat. By fixing the brain within a fraction of a second with heat inactivation, the investigation of fast neurochemical events may be obtained. Even though the technique is widely utilized, its application is inconsistent. This report illustrates some of the requirements necessary for the proper application of MWR for the sacrifice of animals, particularly those related to the length of time MWR is applied and the efficiency with which generated MWR power is coupled to the brain tissue. Studies were performed on the mouse, using either a 2.5 KW or 6.3 KW generator with a focused, closed system waveguide at time intervals of 350 or 500 ms or 1.4 s. During each of these intervals MWR was varied so that core brain temperatures for all groups were held between 83 and 95°C. In contrast with reported studies that used full animal restraint, all animals were minimally restrained for less than 1 s before sacrifice. Tissue content of cyclic AMP, an index of neuronal activity grossly affected by subtle changes in the activity of adenylate cyclase and/or phosphodiesterases, was monitored. No differences in tissue cyclic AMP content in any of 12 brain regions were detected after MWR, either at 350 or 500 ms. A substantial increase in cyclic AMP content occurred in 8 of 12 brain regions examined following microwave irradiation for 1.4 s. On the basis of these experiments, accurate determination of cyclic AMP in rodent brain requires that the maximum time interval of MWR exposure should not exceed 500 ms.     

Assessment of post-mortem-induced changes to the mouse brain proteome

This study was designed to assess the influence of high-energy head-focused microwave irradiation and the post-mortem interval on measurements of the mouse brain proteome. Difference gel electrophoresis was used to compare mouse brain protein levels in animals killed by decapitation, where the tissue was held at 25°C for selected time intervals post-mortem, and by high-energy head-focused microwave irradiation followed by immediate resection. Microwave-mediated killing was used because it comprehensively snap-inactivates enzymes while largely retaining brain cytoarchitecture. Of the 912 protein spots common to at least eight of 10 gels analyzed, 35 (3.8%) showed significant differences in levels ( t -test; p  < 0.05) depending on whether animals were killed by microwave irradiation or decapitation. When animals were killed by decapitation, 43 protein spots (4.7%) showed changes in levels over the post-mortem interval ( anova ; p  < 0.05). The vast majority of the near 1000 proteins evident on a 2D gel were stable for up to 4 h. These data have important implications for studies of proteins in the brain, whether based on analysis of tissue derived from animal models or from humans.     

The quantitative histochemistry of a chemically induced ependymoblastoma. I. Enzymes

Enzymes from several metabolic pathways were studied quantitatively in homogenates and in homogeneous areas of frozen-dried cryostat sections of an experimental, mouse ependymoblastoma, mouse mammary carcinoma, and mouse melanoma, growing as transplants in mouse brain. Micro analyses were performed in fiveto sixfold replicates on portions of tumour with a dry weight of 0·03-0·2 μg. A close resemblance of the enzyme spectrum of the ependymoblastoma to that of immature brain was noted. Hexokinase and malate dehydrogenase were lower and lactate, glucose-6-phosphate, and NADP⁺-linked isocitrate dehydrogenases, and β-glucuronidase higher in the ependymoblastoma than in whole, adult mouse brain. Mouse mammary carcinoma had a higher level of hexokinase and lower levels of lactate and glucose-6-phosphate dehydrogenases and β-glucuronidase than ependymoblastoma. The concentration of malate dehydrogenase was lower and that of lactate, glucosed-6-phosphate, and NADP⁺-linked isocitric dehydrogenases was higher in the melanoma than in the ependymoblastoma. β-Glucuronidase levels were similar in these two neoplasms. It is suggested that the relatively high levels of several NADP⁺-linked enzymes in the ependymoblastoma may be related to increased capacity for lipid synthesis.     

A Comparison of the Distribution of Neurotransmitters in Brain Regions of the Rat and Guinea-Pig Using a Chemiluminescent Method and HPLC with Electrochemical Detection

Six brain areas of rats and guinea-pigs, killed by microwave irradiation, were used for the concomitant measurement of the levels and regional distribution of cholinergic, biogenic amine, and amino acid neurotransmitters and metabolites. Acetylcholine (ACh) and choline (Ch) were quantified by chemiluminescence; noradrenaline (NA), dopamine (DA), 5-hydroxytryptamine (5-HT), and their metabolites by HPLC with electrochemical detection (HPLC-EC); and six putative amino acid neurotransmitters by HPLC-EC following derivatisation. The levels and regional distribution of these transmitters and their metabolites in the rat were similar to those reported in previous studies, except that biogenic amine transmitter levels were higher and metabolite concentrations were lower. The guinea-pig showed a similar regional distribution, but the absolute levels of ACh were lower in striatum and higher in hippocampus, midbrain-hypothalamus, and medulla-pons. In all areas, the levels of Ch were higher and those of NA, 5-HT, and taurine were lower than in the rat. The most marked differences between the rat and guinea-pig were in the relative proportion of DA metabolites and 5-HT turnover, as estimated by metabolite/transmitter ratios. This study can be used as a basis for a comprehensive understanding of the central effects of drugs on the major neurotransmitter systems.     

Regional levels of cyclic AMP in rat brain: pitfalls of microwave inactivation.

Techniques of in-vivo microwave irradiation to inactivate brain enzymes in rats were varied as to exposure configuration and output power. The rate at which metabolism was stopped was studied in various regions of the rat brain, using changes in levels of cyclic AMP and phosphodiesterase activity. Exposure times required to obtain stabilized levels of cyclic AMP varied in different brain regions, i.e., hypothalamus, cortex and cerebellum. Levels of cyclic AMP in selective regions of the brain decreased as more rapid inactivation was achieved. The authors identify important sources of variability of present microwave inactivation systems and the need for improved control of signficant microwave parameters.     

Assay of norepinephrine and dopamine in the rat brain after microwave irradiation

Rapid inactivation of enzymes prior to the assay of rat brain catecholamines was evaluated. Regional levels of norepinephrine and dopamine were measured by high performance liquid chromatography with electrochemical detection after enzyme inactivation by microwave irradiation at levels of 1.3 kw and 5 kw, and compared with decapitation. The differences found in regional levels of catecholamines between the two methods of euthanasia indicate that rapid inactivation of brain enzymes is necessary for accurate analysis of catecholamines in rat brain.     

Mouse brain concentrations of 3-methoxytyramine and normetanephrine: a comparison of methods of sacrifice

The identification of sacrifice methods that produce reliable measures of baseline central nervous system neurotransmitter concentrations poses a challenge to analytical neurochemical investigation. In the present study, microwave irradiation (MWVI) was compared with in situ freezing, cervical dislocation, and simple decapitation, in an effort to examine their effects on whole mouse brain concentrations of 3-methoxytyramine (3MT) and normetanephrine (NMN), the O-methylated catecholamine metabolites believed to be sensitive indicators of release of CNS dopamine and norepinephrine, respectively. Both high-energy (6 kW, 0.3 s) and low-energy (2.5 kW, 1.5 s) MWVI produced the lowest mouse brain concentrations of 3MT and NMN when compared with other methods of sacrifice within experiments. In situ freezing resulted in values of 3MT and NMN that were slightly, yet significantly, higher than MWVI within experiments. The concentrations of 3MT and NMN obtained following either cervicle dislocation or simple decapitation were up to 9-fold greater than those produced by either of the two previous methods.