Analysis of cholinergic markers, biogenic amines, and amino acids in the CNS of two APP overexpression mouse models

Two transgenic mouse models expressing mutated human amyloid precursor protein and previously found to display cognitive and behavioural alterations, reminiscent of Alzheimer patients' symptomatology, were scrutinised for putative brain region-specific changes in neurochemical parameters. Brains of NSE-hAPP751m-57, APP23 and wild-type mice were microdissected to perform brain region-specific neurochemical analyses. Impairment of cholinergic transmission, the prominent neurochemical deficit in Alzheimer brain, was examined; acetylcholinesterase and choline acetyltransferase activity levels were determined as markers of the cholinergic system. Since Alzheimer neurodegeneration is not restricted to the cholinergic system, brain levels of biogenic amines and metabolites, and amino acidergic neurotransmitters and systemic amino acids were analysed as well. Cholinergic dysfunction, reflected in reduced enzymatic activity in the basal forebrain nuclei, was restricted to the APP23 model, which also exhibited more outspoken and more widespread changes in other neurotransmitter systems. Significant changes in compounds of the noradrenergic and serotonergic system were observed, as well as alterations in levels of the inhibitory neurotransmitter glycine and systemic amino acids. These observations were clearly in occurrence with the more pronounced histopathological and behavioural phenotype of the APP23 model. As transgenic models often do not represent an end-stage of the disease, some discrepancies with results from post-mortem human Alzheimer brain analyses were apparent; in particular, no significant alterations in excitatory amino acid levels were detected. Our findings of brain region-specific alterations in compound levels indicate disturbed neurotransmission pathways, and greatly add to the validity of APP23 mice as a model for Alzheimer's disease. Transgenic mouse models may be employed as a tool to study early-stage neurochemical changes, which are often not accessible in Alzheimer brain.     

Anatomical Substrates of Behavioral Impairment Induced by Developmental Lead Exposure in Monkeys: Inferences from Brain Lesions

There is a substantial literature exploring the behavioral consequencesof developmental lead exposure in the monkey; deficits havebeen observed on a number of tasks assessing learning and memoryincluding spatial delayed alternation, discrimination reversal,matching to sample, and concurrent discrimination. Differencesin performance between control and lead-exposed monkeys havealso been observed on intermittent schedules of reinforcement.Comparison of the effects of lead with the extensive literatureon the consequences of lesions in discrete areas of brain onthe same tasks may provide insight into the possible sites ofbrain damage responsible for lead-induced behavioral impairment.Available data strongly suggest that prefrontal cortical areasare damaged by lead, based on the pattern of performance deficitsacross specific tasks. In addition, a constellation of globaldeficits including perseveration, increased distractibility,inability to change response strategy, and inability to inhibitinappropriate responding are hallmarks of both prefrontal damageand developmental lead exposure. Evidence also implicates basalforebrain structures in behavior impairment produced by leadbased on the pattern of deficits across numerous tasks, althoughthe evidence is much weaker than for prefrontal cortex. In contrast,the pattern of behavioral impairment produced by limbic systemlesions is different in many respects from that produced bylead; in addition, the scant neuropathological data availablesuggest that limbic structures are not a target of lead evenat high blood lead levels in the monkey. Comparison of the patternof damage following lead exposure with the effects of lesions,presented here, provides direction for further morphologicalor neurochemical exploration of lead-induced brain damage inthe monkey.     

Dose-dependent and reversible effects of lead on rat dopaminergic system

It has been suggested that hyperactivity and mental retardation, the most serious clinical aspects observed in children during lead intoxication, may occur as consequence of specific alterations of neurotransmitter functions. In our experiments we indicate that the behavioural patterns observed in chronically lead exposed rats may be correlated with an impairment of the dopaminergic system. Performing our study at two different levels of lead exposure, we found after the last assumption of lead we observed a complete disappearance of these neurochemical variations. Our findings suggest that lead affects dopamine function in different brain areas in reversible manner, inducing effects which are dose-dependent.     

Pre- and postnatal aminopeptidase activities in the rat brain

Research concerning the functional role of brain peptides is performed, in part, by studying peptidase enzymes which might be involved in brain peptide processing or inactivation. Aminopeptidase (AP) activity has been proposed as a candidate regulator of the degradation of these peptides. In this paper, changes in Lys- and Leu-aminopeptidase activities in rat brain hemispheres, cerebellum and medulla were examined in 20 day fetuses and one day postnatal subjects. Aminopeptidase activities were studied by measuring the rate of hydrolysis of the artificial substrates Lys- and Leu-2-naphthylamides (fluorimetrically detected in triplicate). Both enzyme activities increase from the last fetal stage up to the first day of birth in all the brain areas examined except for the case of Leu-AP activity in the medulla. It is suggested that these activities play a part in the neurochemical changes that take place during rat brain maturation, possibly by regulating the activity of several neuroactive peptides.     

Effects of Postnatal Trimethyltin or Triethyltin Treatment on CNS Catecholamine,GABA, and Acetylcholine Systems in the Rat

Abstract: The effects on brain neurochemistry of two neurotoxic tin compounds, trimethyltin (TMT) hydroxide and triethyltin (TET) sulfate, were examined. Long-Evans rats were treated with TMT hydroxide (1 mg/kg, i.p.) on alternate days from day 2 to 29 of life. These treatments caused a weight deficit of 10–20% by the time the animals were killed on day 55 by head-focused microwave irradiation. These TMT treatments are known to cause severe neuronal loss in the hippocampus and lesser damage in other brain regions. Accordingly, the concentration of γ-aminobutyric acid (GABA) was decreased in the hippocampus; however, acetylcholine and choline concentrations were unaffected. These data suggest that TMT-induced effects on GABA systems are greater than that due simply to generalized neuronal loss. The TMT treatments also caused a significant decrease in dopamine concentrations in the striatum, but did not alter the concentrations of dihydroxyphenylacetic acid or homovanillic acid, the acidic metabolites of dopamine. Conversely, concentrations of dopamine and norepinephrine in the brain stem and norepinephrine in the cerebellum were not altered. Despite reports in the literature of TMT-induced neuronal damage in areas of the cortex, no effects on GABA, acetylcholine, or choline levels were found in the cortical areas examined, or in the hypothalamus. TET sulfate (0.3 mg/kg/day) was administered for 6 consecutive days of every week during days 2–29 of life. This dose is lower than that needed to cause intramyelin edema, yet it does result in long-term behavioral changes. Despite this, no changes in the concentration of any of the measured neurotransmitters or their metabolites were detected. In concert, these data demonstrate that neurochemical methods should not be used as neurological “screens,” but rather to define specific mechanisms suggested by detailed behavior, pharmacological, and/or physiological studies.     

Genomic regulation of sexual behavior

Estrogen receptors are distributed in discrete areas of the hypothalamus, preoptic area and amygdala of the rat brain, and in some of these areas estrogens induce progestin receptor sites. Estradiol (E), followed by progesterone (P), induce feminine sexual behavior in female, but not in male, rats. This induction takes time (on the order of hours, not minutes, so that the hormone may be cleared from the body) and is dependent on RNA and protein synthesis. Within the hypothalamic ventromedial nuclei (VMN), E and P induce changes in RNA and protein synthesis and also induce morphological changes indicative of cellular growth, genomic activation, and either new synapse formation or morphological rearrangement of existing synapses. Neurochemically, a number of neurotransmitter systems are implicated in the control of feminine sexual behavior, including acetylcholine, serotonin, GABA, and the neuropeptides, oxytocin and CCK. One of the means by which E and P may exert their influence on sexual behavior, aside from the morphological alterations, is by regulating levels of receptors for certain of these neurotransmitters. The critical differences which underlie the inability of male rats to display high levels of feminine sexual behavior after E plus P priming may depend on sex differences in the ability of E to induce particular neurochemical products as well as P receptors and upon differences in neural circuitry in the VMN.     

Regional distribution of neuropeptide-degrading enzyme activity in the rat brain: Effects of subacute exposure to carbon disulfide

Carbon disulfide, a volatile solvent, is widely used in industry. It has been demonstrated that it causes several neuropsychological symptoms. However, the neurochemical basis of its neurotoxic effect is relatively unknown. In this paper we have measured the effect of subacute i.p. administration on neutral and basic aminopepti-dase activities in discrete zones of the rat brain using lysine- and leucine-2-naphtylamides as substrates. Neutral aminopeptidase activity showed a significant decrease in the thalamus and cerebellum with marked (not significant) changes in the hypothalamus, hippocampus, medulla, and occipital cortex. There were no changes in basic ami-nopeptidase activity. It is suggested that amino-peptidase activity could play a role in carbon disulfide neurotoxic action in the aforementioned regions by generating changes in several neuropeptide levels.     

Effects of acute and chronic hyperglycemia on the neurochemical profiles in the rat brain with streptozotocin-induced diabetes detected using in vivo ¹H MR spectroscopy at 9.4 T

Chronic hyperglycemia could lead to cerebral metabolic alterations and CNS injury. However, findings of metabolic alterations in poorly managed diabetes in humans and animal models are rather inconsistent. We have characterized the cerebral metabolic consequences of untreated hyperglycemia from the onset to the chronic stage in a streptozotocin-induced rat model of diabetes. In vivo 1H magnetic resonance spectroscopy was used to measure over 20 neurochemicals longitudinally. Upon the onset of hyperglycemia (acute state), increases in brain glucose levels were accompanied by increases in osmolytes and ketone bodies, all of which remained consistently high through the chronic state of over 10 weeks of hyperglycemia. Only after over 4 weeks of hyperglycemia, the levels of other neurochemicals including N-acetylaspartate and glutathione were significantly reduced and these alterations persisted into the chronic stage. However, glucose transport was not altered in chronic hyperglycemia of over 10 weeks. When glucose levels were acutely restored to euglycemia, some neurochemical changes were irreversible, indicating the impact of prolonged uncontrolled hyperglycemia on the CNS. Furthermore, progressive changes in neurochemical levels from control to acute and chronic conditions demonstrated the utility of 1H magnetic resonance spectroscopy as a non-invasive tool in monitoring the disease progression in diabetes.     

Effects of lead exposure on rat brain catecholaminergic neurochemistry

1. The effects of lead on catecholaminergic neurotransmission have been investigated. 2. Using the rat as a model, animals were exposed both acutely and chronically to lead. The levels of catecholamines, noradrenaline, adrenaline, and dopamine along with the activities of tyrosine hydroxylase and phenylethanolamine-N-methyl transferase were measured in 5 brain regions--cerebral cortex, brainstem, hippocampus, anterior and posterior hypothalamus. 3. A lead related reduction in the activity of tyrosine hydroxylase was observed in association with alterations in steady-state levels of the catecholamines in the posterior and anterior hypothalamus. 4. Thus, lead exposure, known to result in behavioural changes, is associated with localised neurochemical effects on the hypothalamus.     

Levels of amino acids in 52 discrete areas of postmortem brain of adult and aged humans

Summary In a series of studies we have analyzed the regional distribution of the free amino acid pool in 52 discrete areas of postmortem brain of adult and aged humans. Here we show the distribution of eleven amino acids: alanine, methionine, valine, leucine, isoleucine, glutamine, asparagine, lysine, arginine, ornithine, and histidine. As found previously for other amino acids, the distribution of these amino acids was seen to be heterogeneous, the level of the area of highest level being 3.4 to 10.7 times that of the area of the lowest level. On average we found a five- or six-fold difference in concentration between the highest and lowest level areas in the brain samples from adult and old respectively. The distribution patterns were found to be different for each amino acid; they were not similar even in the same class (amides, branched chain, basic amino acids), and they were different from those recently found in rat brain. Only a few changes, mostly increases, were found in the aged brain, such as increases in alanine and valine levels in cortical areas. In studies of changes in cerebral amino acid levels, the great regional heterogeneity of distribution has to be taken into account since changes in whole brain values may not reflect regional changes. The functional significance and the control of this regional heterogeneity are under investigation.     

Low-Dose Sarin Exposure Produces Long Term Changes in Brain Neurochemistry of Mice

Sarin is a toxic organophosphorus (OP) nerve agent that has been reported to cause long-term alterations in behavioral and neuropsychological processes. The present study was designed to investigate the effect of low dose sarin exposure on the monoamine neurotransmitter systems in various brain regions of mice. The rationale was to expand our knowledge about the noncholinergic neurochemical alterations associated with low dose exposure to this cholinesterase inhibitor. We analyzed the levels of monoamines and their metabolites in different brain areas after exposure of male C57BL/6 mice to a subclinical dose of sarin (0.4 LD50). Mice did not show any signs of cholinergic toxicity or pathological changes in brain tissue. At 1, 4 and 8 weeks post-sarin exposure brains were collected for neurochemical analysis. A significant decrease in the dopamine (DA) turnover, as measured by the metabolite to parent ratio, was observed in the frontal cerebral cortex (FC) at all time points tested. DA turnover was significantly increased in the amygdala at 4 weeks but not at 1 or 8 weeks after exposure. The caudate nucleus displayed a decrease in DA turnover at 1 week but no significant change was observed at 4 and 8 weeks suggesting a reversible effect. In addition to this, serotonin (5-HT) levels were transiently altered at various time points in all the brain regions studied (increase in FC, caudate nucleus and decrease in amygdala). Since there were no signs of cholinergic toxicity or cell death after sarin exposure, different non-cholinergic mechanisms may be involved in regulating these effects. Our results demonstrate that non-symptomatic dose of OP nerve agent sarin has potent long-term, region-specific effects on the monoaminergic neurotransmitter systems. Data also suggests differential effects of sarin on the various DA projections. These neurochemical alterations could be associated with long term behavioral and neuropsychological changes associated with low dose OP exposure.     

In vivo monitoring of brain neurotransmitter release for the assessment of neuroendocrine interactions

Summary 1. The neurotransmitter mechanisms regulating neuroendocrine processes have been traditionally inferred from the effects of drugs purportedly acting through specific transmitter systems. The direct appraisal of changes in endogenous neuromediators had to rely initially on analyses of brain samples obtained post-morten.2. Currently, a more physiological assessment is available through the monitoring ot the extracellular levels of neurotransmitters and their metabolites in discrete brain areas of living animals. Two methodologies, namely in vivo voltammetry and microdialysis, are being increasingly used for this purpose. This article summarizes their principles, relative merits, and limitations and presents some relevant applications.3. Thus, microdialysis data show a differential response in the amphetamine-induced dopamine release in the nucleus accumbens in adult male and female rats castrated prepuberally. Given their high time-resolution, in vivo electrochemistry techniques seem especially suited for studying the fast, non-genomic effects of steroid hormones. This is illustrated by the voltammetric detection of a rapid release of dopamine in the corpus striatum induced by progesterone in males.4. These methodologies should be regarded as complementary tools for the assessment of the neurochemical correlates of neuroendocrine interactions.     

Neurochemical consequence of steroid abuse: stanozolol-induced monoaminergic changes

An extensive literature has documented adverse effects on mental health in anabolic androgenic steroids (AAS) abusers. Depression seems a common adverse reaction in AAS abusers. Recently it has been reported that in a rat model of AAS abuse stanozolol induces behavioural and biochemical changes related to the pathophysiology of major depressive disorder. In the present study, we used the model of AAS abuse to examine possible changes in the monoaminergic system, a neurobiological substrate of depression, in different brain areas of stanozolol-treated animals. Wistar rats received repeated injections of stanozolol (5mg/kg, s.c.), or vehicle (propylene glycol, 1ml/kg) once daily for 4weeks. Twenty-four hours after last injection, changes of dopamine (DA) and relative metabolite levels, homovanilic acid (HVA) and 3,4-dihydroxy phenylacetic acid (DOPAC), serotonin (5-HT) and its metabolite levels, 5-hydroxy indolacetic acid (5-HIAA), and noradrenaline (NA) amount were investigated in prefrontal cortex (PFC), nucleus accumbens (NAC), striatum (STR) and hippocampus (HIPP). The analysis of data showed that after chronic stanozolol, DA levels were increased in the HIPP and decreased in the PFC. No significant changes were observed in the STR or in the NAC. 5-HT and 5-HIAA levels were decreased in all brain areas investigated after stanozolol exposure; however, the 5-HIAA/5-HT ratio was not altered. Taken together, our data indicate that chronic use of stanozolol significantly affects brain monoamines leading to neurochemical modifications possibly involved in depression and stress-related states.     

Effects of acute and chronic administrations of phencyclidine on the levels of serotonin and 5-hydroxyindoleacetic acid in discrete brain areas of mouse

The effects of phencyclidine (PCP) on the levels of serotonin (5-HT) and 5-hydroxyindoleacetic acid (5-HIAA) in discrete brain areas of mouse were investigated. Following a single administration, PCP significantly increased at 60 min the level of 5-HT but not 5-HIAA in the cortex. However, acute administration of PCP induced no changes of 5-HT and 5-HIAA levels in other brain areas investigated. On the other hand, chronic treatment of PCP produced a significant increase the striatal 5-HT and 5-HIAA levels by about 30% and 20%, respectively. These increased levels were gradually returned to the control levels, and there was no difference of these levels between the control group and the 48 hr withdrawal group. The changes of 5-HT level in the hypothalamus were similar to those in the striatum. These results suggest that the pharmacological actions of PCP and tolerance development to PCP may be related to the functional changes of serotonergic neuronal activity.     

Up-Regulation of CCT8 Related to Neuronal Apoptosis after Traumatic Brain Injury in Adult Rats

Neurochemical Research - Traumatic brain injury (TBI) initiates a series of neurochemical and signaling changes that could eventually lead to neuronal apoptosis. Recent studies indicated that...     

Changes in dialysate concentrations of glutamate and GABA in the brain: an index of volume transmission mediated actions?

Brain microdialysis has become a frequently used method to study the extracellular concentrations of neurotransmitters in specific areas of the brain. For years, and this is still the case today, dialysate concentrations and hence extracellular concentrations of neurotransmitters have been interpreted as a direct index of the neuronal release of these specific neurotransmitter systems. Although this seems to be the case for neurotransmitters such as dopamine, serotonin and acetylcholine, the extracellular concentrations of glutamate and GABA do not provide a reliable index of their synaptic exocytotic release. However, many microdialysis studies show changes in extracellular concentrations of glutamate and GABA under specific pharmacological and behavioural stimuli that could be interpreted as a consequence of the activation of specific neurochemical circuits. Despite this, we still do not know the origin and physiological significance of these changes of glutamate and GABA in the extracellular space. Here we propose that the changes in dialysate concentrations of these two neurotransmitters found under specific treatments could be an expression of the activity of the neurone-astrocyte unit in specific circuits of the brain. It is further proposed that dialysate changes of glutamate and GABA could be used as an index of volume transmission mediated actions of these two neurotransmitters in the brain. This hypothesis is based firstly on the assumption that the activity of neurones is functionally linked to the activity of astrocytes, which can release glutamate and GABA to the extracellular space; secondly, on the existence of extrasynaptic glutamate and GABA receptors with functional properties different from those of GABA receptors located at the synapse; and thirdly, on the experimental evidence reporting specific electrophysiological and neurochemical effects of glutamate and GABA when their levels are increased in the extracellular space. According to this concept, glutamate and GABA, once released into the extracellular compartment, could diffuse and have long-lasting effects modulating glutamatergic and/or GABAergic neurone-astrocytic networks and their interactions with other neurotransmitter neurone networks in the same areas of the brain.     

Creatine-Enhanced Diet Alters Levels of Lactate and Free Fatty Acids After Experimental Brain Injury

Free fatty acids (FFA) and lactic acid are markers of secondary cellular injury following traumatic brain injury (TBI). We previously showed that animals fed a creatine (Cr)-enriched diet are afforded neuroprotection following TBI. To further characterize the neuroprotective Cr diet, we studied neurochemical changes in cortex and hippocampus following a moderate injury. Adult rats were fed either a control or Cr-supplemented diet (0.5%, 1%) for 2 weeks before TBI. At 30 min or 6 h after injury, tissue was processed for quantitative analysis of neurochemical changes. Both lactate and FFA were significantly increased in all tissues ipsilateral to the injury. Cr-fed animals had significantly lower levels, although the levels were elevated compared to sham controls. Animals fed a 1% Cr-diet were afforded greater neuroprotection than animals fed a 0.5% Cr diet. These results support the idea that a Cr-enriched diet can provide substantial neuroprotection in part by suppressing secondary brain injury.     

Simultaneous Measurement of Extracellular Morphine and Serotonin in Brain Tissue and CSF by Microdialysis in Awake Rats

In this report, we describe an HPLC with electrochemical detection assay for the simultaneous measurement of levels of morphine, serotonin, 5-hydroxyindole-3-acetic acid, and homovanillic acid in dialysates of various brain areas and CSF in the awake rat. Morphine could be detected in the dialysates after a single intraperitoneal injection, with doses as low as 1.0 mg/kg. The time course of extracellular morphine content in the lateral hypothalamus, striatum, cerebellum, periaqueductal gray, and dorsal horn of the spinal cord and in CSF, from the ventricles and cisterna magna, was similar. We detected morphine in the first 15-min sample, and levels peaked 45-60 min after injection. Maximal dialysate levels, however, varied with the type of dialysis probe used and the area sampled. The most efficient in vivo recovery was in CSF dialysates from the cisterna magna, presumably because of minimal tissue interference with the dialysis probe. For this reason, the cisterna is an ideal region for sampling CSF. Morphine had no significant effect on the extracellular concentrations of serotonin in any of the areas studied and did not modify or only slightly increased levels of tissue metabolites; however, morphine markedly increased the CSF levels of 5-hydroxyindole-3-acetic acid and homovanillic acid. Because microdialysis in freely moving animals permits assessment of the behavioral effects of morphine while continuously monitoring the drug levels in discrete brain regions, this approach will greatly facilitate future studies of the neurochemical basis of morphine's effects in the brain.     

Fluoxetine Partly Exerts its Actions Through GABA: A Neurochemical Evidence

Fluoxetine, as a serotonin re-uptake inhibitor augments serotonin concentration within the synapse by inhibiting the serotonin transporter. The contribution of amino acids has also been shown in depression. We hypothesized that fluoxetine exerts its actions at least in part by intervening brain signaling operated by amino acid transmitters. Therefore the aim of this study is to supply neurochemical evidence that fluoxetine produces changes in amino acids in cerebrospinal fluid of rats. Sprague-Dawley rats were anesthetized and concentric microdialysis probes were implanted stereotaxically into the right lateral ventricle. Intraperitoneal fluoxetine (2.5 or 5 mg/kg) or physiological saline was administered and the probes were perfused with artificial cerebrospinal fluid at a rate of 1 μl/min. In the chronic fluoxetine group, the rats were treated daily with oral fluoxetine solution or inert syrup for 3 weeks. The microdialysis probes were placed on the 21st day and perfused the next day. Fluoxetine was ineffective in changing the cerebrospinal fluid GABA levels at the dose of 2.5 mg/kg but produced a significant increase in the perfusates following injection of 5 mg/kg of fluoxetine (P < 0.05). Oral fluoxetine administration (5 mg/kg) for 21 days also elevated the CSF GABA levels by approximately 2-fold (P < 0.05). l-glutamic acid levels were not affected in all groups. These neurochemical findings show that fluoxetine, a selective serotonin re-uptake inhibitor affects brain GABA levels indirectly, and our results suggest that acute or chronic effects may be involved in beneficial and/or adverse effects of the drug.     

Correlation between carbohydrate and catecholamine level impairments in methionine sulfoximine epileptogenic rat brain

This work shows that the convulsant methionine sulfoximine induces an increase in glucose and glycogen levels and a parallel decrease in norepinephrine and dopamine levels in rat brain. Among the epileptogenic agents, methionine sulfoximine is known to have a glycogenic property in the central nervous system. The aim of this work is to look for the neurochemical mechanism underlying this property. For this, catecholamines, glucose, and glycogen were measured at the same time in different areas of the brain in rats submitted to methionine sulfoximine. The convulsant induced an increase in glucose and glycogen levels as previously described and a decrease in dopamine and norepinephrine levels in all the areas of the rat brain. These changes were roughly dose dependent. WhenL-dihydroxyphenylalanine and benserazide (a decarboxylase inhibitor) were administered with methionine sulfoximine, the latter failed to induce seizures in rat up to 8 h after dosing. Moreover, the glucose and glycogen amounts did not increase. In all these experiments, there was an obvious evidence of parallelism between seizures, increase in carbohydrate levels, and decrease in catecholamine levels. These results allow to conclude that the glycogenic property of methionine sulfoximine in the central nervous system probably results from its ability to decrease norepinephrine and dopamine levels. Because the effect of the convulsant on the catecholamine levels persisted for long, it is normal that glucose and glycogen levels increased during preconvulsive, convulsive and postconvulsive period. Methionine sulfoximine is probably glycogenic in rat brain because it decreases catecholamine levels for a long time.