Effects of food deprivation and immobilization on tryptophan and other amino acids in rat brain

A review of effects of calorie restriction and fasting with potential relevance to depression

In recent years, there has been a great deal of interest in the effects of calorie reduction (calorie restriction) and fasting on depression. In the current paper, we have reviewed the literature in this area, with discussion of the possible neurobiological mechanisms involved in calorie restriction and intermittent fasting. Factors which may play a role in the effects of these dietary manipulations on health include changes involving free fatty acids, ketone bodies, neurotransmitters, cyclic adenosine monophosphate response element binding protein (CREB), brain-derived neurotrophic factor (BDNF), cytokines, orexin, ghrelin, leptin, reactive oxygen species and autophagy. Several of these factors are potential contributors to improving symptoms of depression. Challenges encountered in research on calorie restriction and intermittent fasting are also discussed. Although much is now known about the acute effects of calorie restriction and intermittent fasting, further long term clinical studies are warranted.

Fasting in mood disorders: neurobiology and effectiveness. A review of the literature

Clinicians have found that fasting was frequently accompanied by an increased level of vigilance and a mood improvement, a subjective feeling of well-being, and sometimes of euphoria. Therapeutic fasting, following an established protocol, is safe and well tolerated. We aim in this article to explore the biological mechanisms activated during fasting that could have an effect on brain function with particular focus on mood (we do not discuss here the mechanisms regulating eating behavior) and to provide a comprehensive review on the potential positive impact of therapeutic fasting on mood. We explored Medline, Web of Science and PsycInfo according to the PRISMA criteria (Preferred Reporting Items for Systematic reviews and Meta-Analysis). The initial research paradigm was: [(fasting OR caloric restriction) AND (mental health OR depressive disorders OR mood OR anxiety)]. Many neurobiological mechanisms have been proposed to explain fasting effects on mood, such as changes in neurotransmitters, quality of sleep, and synthesis of neurotrophic factors. Many clinical observations relate an early (between day 2 and day 7) effect of fasting on depressive symptoms with an improvement in mood, alertness and a sense of tranquility reported by patients. The persistence of mood improvement over time remains to be determined.

Identification of L-amino acid/L-lysine alpha-amino oxidase in mouse brain

Lysine, an essential amino acid is catabolized in brain through only the pipecolic acid pathway. During the formation of pipecolic acid, alpha-deamination of lysine, and the formation of the alpha-keto acid as well as its cyclized product are pre-requisites. The enzyme mediated alpha-deamination of L-lysine and the formation of the alpha-keto acid and the cyclized product are not demonstrated so far. Both lysine and pipecolic acid are known to increase in brain under the conditions of fasting, studies were therefore undertaken to identify the enzyme responsible for the alpha-deamination of L-lysine in the brain tissue of mice which were fasted. The detection of the alpha-keto acid of L-lysine -alpha-keto-epsilon-amino caproic acid and its cyclized product-delta-piperidine-2-carboxylate was facilitated by the use of L-[U-14C]-lysine as the substrate. The quantitation of the radioactivity in reaction products was done after separation by ion exchange chromatographic methods. The formation of the alpha-keto acid was enzyme mediated, the alpha-keto acid formed was established by reaction with N-methyl benzothiazolinone hydrazone hydrochloride. The cyclized product was accounted in a fraction which matched the resolution of authentic pipecolic acid on the Dowex column, and the cyclized product was confirmed by spectrophotometry. The hitherto undemonstrated alpha-amino deaminating enzyme of L-lysine in brain tissue, the alpha-keto acid of L-lysine and its cyclized product in a mammalian system could thus be demonstrated in the present study. These findings confirm the involvement of L-lysine oxidase/L-amino acid oxidase in the formation of pipecolic acid from L-lysine.

Short-term fasting alters neonatal rat striatal dopamine levels and serotonin metabolism: an in vivo microdialysis study

Although frequent feeding is necessary for neonatal brains, rat pups were usually separated from their dams throughout a microdialysis experiment. First, in 5-day-old rats, we examined the effect of probe insertion on initial fluctuation of extracellular striatal monoamines using in vivo microdialysis and subsequent HPLC. Second, fasting effect on monoamine metabolism was examined with or without fasting; the latter was regarded as controls. Extracellular striatal DA in the fasting group decreased promptly to 60% of the basal level in the first 2 h, and reached 50% by the end of the experiment. Dopamine in the fasting group decreased more markedly than in the control group (P < 0.01 by ANOVA) which also decreased to about 80% of the basal level. Extracellular 5-hydroxyindole-3-acetic acid (5-HIAA) continuously increased (P < 0.01), and the serum concentration of tryptophan also increased in the fasting group (P < 0.001). We showed that extracellular striatal monoamine levels fluctuated especially in the first 2 h and fasting altered monoamine metabolism. Therefore, it should take at least 2 h after surgery to stabilize the animals and obtain adequate basal levels. In addition, we should consider that these alterations occur when we use fasting animals as controls in microdialysis studies.

Effects of two stressors on behaviour in the elevated X-maze: preliminary investigation of their interaction with 8-OH-DPAT

Effects of water deprivation and restraint were compared in the rat elevated X-maze. Water deprivation for 12-48 h increased corticosterone and had a duration-dependent "anxiolytic" effect in the elevated X-maze, increasing the ratio of open/total arm entries (OTR) and the proportion of time spent on the open arms (% time) without affecting total entries. Brain 5HIAA/5HT was increased only after 24 or 48 h deprivation. Restraint for 15 min also increased plasma corticosterone and brain 5HIAA/5HT but had no effect on behaviour in the elevated X-maze when rats were tested immediately afterwards. However, 1 h restraint was "anxiogenic" in the elevated X-maze immediately after release, reducing OTR and % time, but with a less consistent reduction in total entries; reductions in OTR and % time were still present 24 h later. The 5HT1A agonist 8-hydroxy-2-(di-n-propylamino) tetralin (8-OH-DPAT) (0.1-0.2 mg/kg), administered 10 min before testing in the elevated X-maze, had "anxiogenic" actions in non-stressed rats. The effect of 0.1 mg/kg 8-OH-DPAT was not significantly altered by 24 or 48 h water deprivation but was abolished by restraint for 1 h immediately beforehand, despite the "anxiogenic" effect of restraint alone. Similar mutual antagonism of 8-OH-DPAT and restraint occurred when the dose of 8-OH-DPAT was increased to 0.2 mg/kg. Twenty-four hours after restraint, restrained rats which had received 8-OH-DPAT (0.1-0.2 mg/kg) still did not show any significant "anxiogenic effect" compared with non-restrained vehicle treated controls. Restraint-induced deficits in elevated X-maze exploration may prove a useful model with which to study the pharmacology of depression-related anxiety. However, the effects of the stressors examined, and their interaction with 8-OH-DPAT in the elevated X-maze, appear to depend on the nature of the stressor.

Relationship between plasma and brain large neutral amino acids in rats fed diets with different compositions at different times of the day

Large neutral amino acids (LNAAs) compete with each other for carrier-mediated transport through the blood-brain barrier into the brain. The relative plasma concentration, expressed as the ratio of each LNAA to the sum of LNAAs, is considered the main regulator of brain LNAA concentrations. In order to investigate the consistency of this assumption throughout a 24-h period, we have compared the relationship of plasma LNAAs to brain LNAAs among groups of rats fed diets containing various amounts of protein (in order to obtain a wide range of plasma LNAA levels) at two different phases of the light/dark cycle (0900 and 2100 hours). The relationship between plasma and brain LNAAs was found to be dependent on both diet and the time of day. Similar plasma amino acid concentrations in the morning and in the evening contrasted with different brain concentrations. Furthermore, previous findings that brain LNAA concentrations are influenced by plasma amino acid concentrations were confirmed.

Serotonin release varies with brain tryptophan levels

This study examines directly the effects on serotonin release of varying brain tryptophan levels within the physiologic range. It also addresses possible interactions between tryptophan availability and frequency of membrane depolarization in controlling serotonin release. We demonstrate that reducing tryptophan levels in rat hypothalamic slices (by superfusing them with medium supplemented with 100 microM leucine) decreases tissue serotonin levels as well as both spontaneous and electrically-evoked serotonin release. Conversely, elevating tissue tryptophan levels (by superfusing slices with medium supplemented with 2 microM tryptophan) increases both tissue serotonin levels and serotonin release. Serotonin release was found to be affected independently by tryptophan availability and frequency of electrical field-stimulation (1-5 Hz), since increasing both variables produced nearly additive increases in release. These observations demonstrate for the first time that both precursor-dependent elevations and reductions in brain serotonin levels produce proportionate changes in serotonin release, and that the magnitude of the tryptophan effect is unrelated to neuronal firing frequency. The data support the hypothesis that serotonin release is proportionate to intracellular serotonin levels.

Tryptophan availability modulates serotonin release from rat hypothalamic slices

Application of a novel in vitro experimental system has allowed us to describe the relationship between tryptophan availability and serotonin release from rat hypothalamic slices. Superfusing hypothalamic slices with a physiologic medium containing l-tryptophan (1, 2, 5, or 10 microM) caused dose-dependent elevations in tissue tryptophan levels; the magnitude of the elevations produced by supplementing the medium with less than 5 microM tryptophan was within the physiologic range for rat brain tryptophan levels. Slice serotonin levels rose biphasically as the tryptophan concentration in the medium was increased. Superfusing the slices with medium supplemented with a low tryptophan concentration (1 or 2 microM) caused proportionally greater incremental changes in serotonin levels than the increases caused by further elevating the tryptophan concentration (5 or 10 microM). The spontaneous release of serotonin from the slices exhibited a dose-dependent relationship with the tryptophan concentration of the superfusion medium. Electrically evoked serotonin release, which was calcium-dependent and tetrodotoxin-sensitive, also increased in proportion to the medium tryptophan concentration. These data suggest that the rate at which serotonin is released from hypothalamic nerve terminals is coupled to brain tryptophan levels. Accelerations in hypothalamic serotonin synthesis, caused by elevating brain tryptophan levels, result in proportionate increases in the rates of serotonin release during rest and with membrane depolarization.

Electrochemical analysis of hypothalamic serotonin metabolism accompanied by immobilization stress in rats

The effects of stress on serotonin metabolism in the lateral hypothalamic area (LHA) were investigated. Differential pulse voltammetry with a carbon fiber electrode was used to measure 5-hydroxyindoleacetic acid (5-HIAA), the metabolic product of the serotonin (5-HT). High-performance liquid chromatography with electrochemical detection was also used to analyze these compounds in the cerebrospinal fluid (CSF). The peak in voltammogram at an oxidation potential of +230 mV (P3) was identified as 5-HIAA by pharmacological manipulations that are known to affect 5-HT metabolism. A significant increase in 5-HIAA concentration in the LHA was detected after immobilization. An intraperitoneal injection of 5-hydroxytryptophan (5-HTP; a precursor of 5-HT) increased the height of P3, and injection of pargyline prevented the effect of 5-HTP during the course of increasing P3. These results support our previous conclusion that immobilization-induced anorexia might be mediated through activation of serotonergic mechanisms in the LHA.

Brain serotonin and catecholamine responses to repeated stress in rats

This study was designed to compare the effects of single and repeated administration of a discrete 2-min restraint stress on serotonin (5-HT) and catecholamine neuron activity in various regions of rat brain. A single 2-min restraint stress significantly increased the 5-hydroxyindoleacetic acid (5-HIAA) and 5-HT responses in hypothalamus and cerebral cortex and the 5-HIAA response in brainstem. A second 2-min restraint stress applied 90 min after the initial stress did not appreciably alter the steady-state concentrations of 5-HIAA and 5-HT nor did it produce any further changes in the 5-HIAA and 5-HT responses compared to those seen following a single stress in these 3 brain regions. In addition, the synthesis rate of 5-HT in anterior hypothalamus, posterior hypothalamus, hippocampus and brainstem was not altered by a second stress applied 90 min after the initial stress. In contrast, a second 2-min restraint stress applied 30 or 60 min after the initial stress significantly increased the 5-HIAA concentration in hypothalamus, cerebral cortex and brainstem. Also, the synthesis rate of 5-HT was greater following application of a second stress at 30 min than following either a single stress or a second stress applied at 90 min. Following application of a single 2-min restraint stress the hypothalamic concentration of norepinephrine (NE) was significantly decreased at 5 min after onset of the stress and returned to prestress levels by 15 min; the hypothalamic dopamine (DA) concentration was significantly increased at 30 min after the onset of the stress, while the hypothalamic epinephrine (EPI) concentration remained unchanged. A second 2-min restraint stress applied at 30 min markedly lowered NE concentrations in whole and mediobasal hypothalamus but not in laterobasal hypothalamus, and the NE concentrations remained decreased for a period lasting at least 60 min; there was a significant decrease in the hypothalamic EPI concentration 60 min after application of the second stress at 30 min. In addition, the synthesis rate of catecholamines was significantly greater in anterior but not in posterior hypothalamus after application of a second stress 30 min after the initial stress than following either a single stress or a second stress applied at 90 min. Negative correlations were demonstrated between increased synthesis rates of both hypothalamic 5-HT and anterior hypothalamic catecholamines and decreased corticosterone response to single and repeated stress.(ABSTRACT TRUNCATED AT 400 WORDS)

Increase in 5-HT synthesis in the dorsal part of the spinal cord, induced by a nociceptive stimulus: blockade by morphine

The effects of a nociceptive peripheral stimulus and/or morphine upon endogenous tryptophan levels (TRP), specific activity of tryptophan (S.A. of TRP) and serotonin (5-HT) synthesis in the dorsal and ventral spinal cord, the brainstem and the forebrain were investigated in anaesthetized rats. Whereas endogenous TRP and S.A. of TRP were not found to be affected by any of the manipulations described below, 5-HT synthesis was markedly altered. The application of a prolonged and intense nociceptive electrical stimulus to the tail induced a rise in 5-HT synthesis which was dependent on the part of the CNS considered, with the dorsal cord being the most sensitive (25%), the ventral cord and the brainstem being effected to a lesser extent (14% and 16% respectively), and the forebrain not being affected significantly. By contrast, the application of a prolonged and innocuous electrical stimulus on the tail was not followed by any detectable changes in 5-HT synthesis. Morphine administration (1 mg/kg; i.v.) did not significantly alter 5-HT synthesis in the four CNS regions considered. Nevertheless, the same morphine dose did induce a highly significant (P less than 0.005) reduction in the increase in 5-HT synthesis induced by the nociceptive stimulus, both in the dorsal cord and in the brainstem. Such an effect was not seen in the ventral cord. The specificity of these morphine effects was demonstrated by their naloxone reversibility; on the other hand, naloxone alone failed to modify the stimulus-induced increase in 5-HT synthesis seen in the dorsal cord and the brainstem. The results, particularly those concerning the dorsal cord, are discussed with reference to pain mechanisms and morphine analgesia. They suggest that peripheral nociceptive messages induce an increased activity in some bulbo-spinal 5-HT pathways and that a low dose of morphine can counteract such an effect. It is proposed that exogenous opiates exert a complex regulation of bulbo-spinal 5-HT pathways. Functional significances of these processes are discussed.

Effect of brain monoamine precursors on stress-induced behavioral and neurochemical changes in aged mice

Male CF-1 mice aged 22 months showed approximately the same level of motor activity and aggressive behavior as 3-month-old mice under control (no stress) conditions, or 45 min following cold swim stress. Increasing brain catecholamine activity by dietary L-tyrosine treatment had no effect on these two age groups either under control conditions or after stress. In contrast, 30-month-old mice showed lower motor activity under control conditions which was raised significantly by supplementation of the diet with L-tyrosine. However, marked reductions in activity and aggression following stress were observed in the 30-month-old animals and these deficits were not reversed by L-tyrosine treatment prior to stress. Reduction in motor activity was greatest in stressed, 30-month-old mice on L-tyrosine supplemented diets. Compared to 3-month-old mice, the 30-month-old animals had lower brain tyrosine following dietary L-tyrosine treatment, lower brain tryptophan, norepinephrine (NE), dopamine (DA) and DOPAC, but higher HVA, serotonin (5-HT) and 5-HIAA levels. Under both control (no stress) and stress conditions, L-tyrosine pretreatment decreased brain 5-HT in the young animals, but increased 5-HT in the old mice. After stress the 30-month-old animals evidenced only slight increases in levels of blood corticosterone. Brain tyrosine was reduced by stress in the young animals but increased by stress in the old animals. Stress-induced decreases in brain NE and increases in serotonin and 5-HIAA levels were observed in both age groups. These results are consistent with hypotheses concerning age-related alterations in brain monoamine functions and adrenocortical control mechanisms.

Developmental changes in brain indoles, serum tryptophan and other serum neutral amino acids in the rat

The rates at which brain neurons synthesize and release serotonin depend in part on brain tryptophan concentrations; these, in turn, vary directly with serum (or plasma) tryptophan, and inversely with the serum concentrations of other large neutral amino acids (LNAA). Concentrations of serum tryptophan, LNAA and brain indoles were examined in samples drawn at noontime from rats aged 0-59 days. Developmental changes in serum tryptophan largely paralleled those in the tryptophan/LNAA ratio, and brain tryptophan concentrations. Brain serotonin and 5-hydroxyindole acetic acid (5-HIAA) levels also increased postnatally; the changes in 5-HIAA tended to parallel those in brain tryptophan while those in serotonin did not.

Effects of dietary supplements and a tryptophan-free diet on aggressive behavior in rats

The effects of dietary excesses of tryptophan, histidine, tyrosine or choline and of a tryptophan-free diet were examined on shock-induced fighting, muricide and jump-flinch thresholds. Following the tryptophan-free diet, shock-induced fighting and pain sensitivity were specifically increased. The increased incidence of muricide was not specific to the lack of tryptophan in the diet. Groups of rats which were pair fed chow or had 0.15% L-tryptophan added to the tryptophan-free diet increased muricide as well. Brain 5-HT levels were 41% depleted following the tryptophan-free diet and reduced 13% with the 0.15% tryptophan supplement. In addition body weights were reduced in the three groups compared to control. None of the excess diets affected shock-induced fighting, muricide and jump-flinch thresholds. Body weights were decreased in the excess tryptophan, histidine, tyrosine and choline groups. These data indicate that the expression of different forms of aggression appears to be influenced by a tryptophan deficiency in the diet, but not by excesses of tryptophan, tyrosine, histidine and choline.

Ontogenesis of tryptophan transport in the rat brain

During the first three postnatal weeks, the levels of tryptophan in the brain are exceptionally high, 2--4 times those found in adult rats. This is related to two main peculiarities concerning tryptophan transport in young animals: 1. the lack of tryptophan binding onto serum albumin which makes its diffusion from plasma to tissues easier for the early life period; 2. the greater capacity of synaptosomes from neonates to accumulate tryptophan. Experiments consisting of electrolytic lesioning of the midbrain raphé or 5, 7-dihydroxytryptamine treatment clearly demonstrate that the uptake or tryptophan during postnatal development is not more active in serotoninergic than in other types of nerve terminals. In adult rats, changing the concentration of tryptophan induces parallel modifications in the rate of 5-HT synthesis in the brain since the rate limiting enzyme, tryptophan hydroxylase, is not saturated by its substrate. In contrast, neither tryptophan loading, nor parachlorophenylalanine administration (resulting in a marked decrease in brain tryptophan levels) alters the rate of 5-HT synthesis in the CNS of neonates, indicating that tryptophan hydroxylase is saturated during the early life period. These results are discussed in relation to the possible non-transmitter role of 5-HT during brain growth.

Drug-induced parkinsonism in the rat- a model for biochemical investigation of the parkinson-syndrome. III. The incorporation of D-glucose-14C(U) in amino acids of brain and liver from rats pretreated with reserpine or with phenothiazines

Following treatment with reserpine or alternatively with a combination of phenothiazines (Randolektil, Majeptil) a drug-induced parkinsonoid reaction was provoked in rats. Twenty min before decapitation, 18 muCi d-glucose-14C(U) was administered intravenously. Concentration and radioactivities of glutamic acid (glu), glutamine (gln), serine (ser), and glycine (gly) were assayed in some regions of brain and in liver. Separation was performed by a combination of paper electrophoresis and chromatography or by an automatic amino acid analyzer. 1 After reserpine, the concentrations of serine and glycine were increased ten-fold while their specific activities decreased by the same factor. The interconversion serine-glycine was not affected. The concentration of glutamic acid was reduced while its specific activity remained constant. 2. After phenothiazines, the concentrations of serine and glycine in brain were also increased but their specific activities were decreased to a different degree. This indicates an additional effect on the serine-synthesis from glucose. The interconversion serine-glycine was also altered. The concentration of glutamic acid was decreased but specific activity was constant except in the thalamus region tested. 3. The influence of both treatments on amino acid turnover in liver differed from the observed impairment of brain metabolism. 4. Possible correlations between the changes in amino acid metabolism, catecholamines, and the neurologic parkinsonian symptoms are discussed.

Amino acid precursors of monoamine neurotransmitters and some factors influencing their supply to the brain

There is evidence that changes in the concentrations of the monoamine neurotransmitters within the brain are associated with changes in mental processes, with disorders of control of movement and with certain neuropsychiatric diseases. These neurotransmitters are synthesized in the brain from aromatic amino acid precursors that have to be obtained from the circulating blood. In this study some factors which alter the rates of entry of four amino acids (the important neurotransmitter precursors L-tyrosine and L-tryptophan, as well as L-phenylalanine and L-histidine) into the brain have been studied and the findings considered in relation to conditions in which the quantities of one or more of the monoamine neurotransmitters formed within the cerebral cells may be either too large or too small. Thus too little neurotransmitter will be formed if competition between amino acids for the carriers transporting them into the cerebral cells causes the exclusion of a large proportion of any of the aromatic amino acid precursors from the brain. ,or example, L-tryptophan is partially excluded from the brain if a raised level of any one of several other amino acids is maintained in the circulation. Of these, L-phenylalanine inhibits the transport of L-tryptophan into the brain most effectively, while aromatic amino acids in general exclude L-tryptophan more effectively than do other neutral amino acids. Over-production of one or more of the monoamine neurotransmitters is likely to occur when there is too much of one of the aromatic amino acid precursors in the brain cells as a result of abnormally high uptake from the blood, or as a result of their release by an excessive breakdown of the protein within these cells. Underproduction of neurotransmitters may occur in certain disease states, such as some aminoacidurias or Parkinsonism. We have listed some conditions associated with altered mental states or motor disability in which over- or under-production of monoamine neurotransmitters may occur and have tried to relate the findings in human disease with our experimental results.

Effects on plasma and brain tryptophan in the rat of drugs and hormones that influence the concentration of unesterified fatty acid in the plasma

1 The effects on tryptophan distribution and metabolism of drugs altering plasma unesterified fatty acid (UFA) concentration were investigated in the rat.2 UFA and plasma free (i.e. ultrafilterable) tryptophan altered in the same direction.3 Catecholamines and L-DOPA increased both plasma UFA and free tryptophan. L-DOPA also increased brain tryptophan and 5-hydroxyindoleacetic acid (5-HIAA) but decreased brain 5-hydroxytryptamine (5-HT).4 Aminophylline increased plasma UFA and free tryptophan and also brain tryptophan, 5-HT and 5-HIAA. Food deprivation had qualitatively similar effects.5 Insulin decreased plasma UFA and free tryptophan in both fed and food-deprived rats. However, while in fed rats these changes were associated with small decreases of brain indoles, in food-deprived animals small increases occurred.6 Nicotinic acid had only small effects in fed rats but it opposed both the UFA and indole changes in food-deprived animals. Total plasma tryptophan increased in nicotinic acid treated, food-deprived rats.7 There was a tendency towards inverse relations between changes of plasma free and total tryptophan.8 The results suggest that drugs which influence plasma UFA through actions on cyclic AMP thereby alter the binding of tryptophan to plasma protein and that this leads to altered distribution and metabolism of tryptophan.