Brain Amino Acids Measured by Intracerebral Dialysis in Portacaval Shunted Rats

Changes in brain amino acid uptake and metabolism have been proposed as a possible etiological factor in hepatic encephalopathy. By use of a brain dialysis technique (a thin tube implanted in the brain of the living animal), the extracellular amino acid concentrations in the striatum of portacaval (PC)-shunted and sham-operated rats were measured. Leucine, phenylalanine, methionine, and glutamine were increased two- to sixfold in the PC-shunted rats, whilst no changes were seen for GABA, valine, glutamate, or isoleucine, confirming previous reports. Aspartate levels were 350% higher in the PC-shunted rats, and this rise, as well as that of phenylalanine, was significantly correlated with the lower motor activity observed in the PC-shunted rats, suggesting a possible importance of these amino acids in the etiology of hepatic encephalopathy. The amino acid concentrations measured in whole blood demonstrated the well-known pattern of low levels of branched-chain amino acids and increased concentrations of phenylalanine, glutamine, and histidine.     

Alanine Prevents the Reduction of Pyruvate Kinase Activity in Brain Cortex of Rats Subjected to Chemically Induced Hyperphenylalaninemia

The mechanisms by which phenylalanine is toxic to the brain in phenylketonuria are not fully understood. Considering that brain glucose metabolism is reduced in these patients, our main objective was to determine pyruvate kinase activity in brain cortex of rats subjected to acute and chronic chemically induced hyperphenylalaninemia. The effect of alanine administration on the enzyme activity in the treated rats was also investigated. We also studied the in vitro effect of the two amino acids on pyruvate kinase activity in brain cortex of nontreated rats. The results indicated that phenylalanine inhibits pyruvate kinase in vitro and in vivo and that alanine prevents the inhibitory effect of phenylalanine on the enzyme activity. Considering the crucial role pyruvate kinase plays in glucose metabolism in brain, it is possible that inhibition of this enzyme activity may contribute to the brain damage characteristic of this disease.     

Rabbit model simulating transient hyperglycinemia following transurethral prostatectomy

Summary Glycine was intravenously injected in rabbits and resulted in a dose dependent hyperglycinemia. A dose of 10mmol/kg was sufficient to achieve plasma levels of 10 to 16mM comparable to serum levels in patients at the end of a transurethral prostatectomy. The experiments documented that hyperglycinemia is associated with a significant increase of this substance in tissues outside the plasma compartment. Glycine loading resulted in a tenfold elevation of this amino acid in cerebrospinal fluid 10 minutes after injection. In retina and vitreous humor a five- to tenfold increase in glycine content was observed at 10 minutes post injection while in the anterior chamber fluid the maximum increase appeared at 30 minutes.Significant increases of the glycine content were found in different cerebral structures at 30 minutes post administration.The significant elevations of this neurotransmitter within the central nervous system are prerequisites for possible toxic side effects in the course of transurethral prostatectomy (TURP). Hyperglycinemia might be involved in the pathogenesis of visual disturbances following transurethral prostatectomy and the other neurological complications of TURP syndrome. Our observations add more evidence to this hypothesis.     

Uptake of Amino Acids by Brain Micro vessels Isolated from Rats with Experimental Chronic Renal Failure

The neurological disorders seen in patients with chronic renal failure and liver cirrhosis are analogous. Previous in vivo studies have shown that the impaired blood-brain amino acid transport seen in rats with chronic renal failure is similar to that of rats with portocaval anastomosis. To elucidate whether a comparable underlying pathogenic mechanism plays a role in both pathological conditions, blood and brain amino acid levels together with amino acid transport by isolated brain microvessels have been studied in rats with chronic renal failure and in sham-operated rats. Brain microvessels isolated from rats with experimental chronic renal failure showed that the uptake of labeled large neutral amino acid, i.e., leucine or phenylalanine, but not of lysine or alpha-methylaminoisobutyric acid, was significantly increased with respect to sham-operated rats; conversely, the uptake of glutamic acid in rats with chronic renal failure was significantly lower compared with values in controls. Kinetic analysis indicated that this was mainly due to increased exchange transport activity (Vmax) of the L-system, rather than to changes in the affinity (Km) of the carrier system for the relative substrate. These data, together with the significant rise of brain glutamine levels and an increased brain-to-plasma ratio of the sum of large neutral amino acids, are analogous to what was previously observed in rats with portocaval anastomosis.(ABSTRACT TRUNCATED AT 250 WORDS)     

Synaptic Proteins After Electroconvulsive Seizures in Immature Rats

The forebrain content of several rat brain synaptic proteins (synaptin, D1, D2, and D3) was reduced in rats receiving electroconvulsive seizures on days 2–11, 9–18, or 19–28 and sacrificed at the age of 30 days. Forebrain weight, total protein, and the glial enzyme glutamine synthetase were also decreased, whereas the neuronal enolase 14–3–2 was unchanged. The findings suggest that seizures in the immature rat brain resulted in a parallel reduction of synaptic material and of the amount of glial cells. The increased concentration of the enolase 14–3–2 found in rats seizured on days 19–28 may reflect the high demands on the glycolytic system during the seizures.     

Immobilization Decreases Amino Acid Concentrations in Plasma but Maintains or Increases Them in Brain

Immobilization for 2 h significantly decreased plasma concentrations of 13 of 16 amino acids assayed, including the transmitter amine precursors tyrosine and total tryptophan. The level of plasma free tryptophan, however, was increased. Despite the reduced plasma levels, corresponding brain concentrations of many large neutral amino acids (LNAAs) were increased (tryptophan, phenylalanine, valine, leucine, and isoleucine). Brain concentrations of tyrosine and the other amino acids measured were unaltered. The results for the LNAAs were not explained by calculated brain influx rates. Therefore, altered influx kinetics or perhaps altered brain protein metabolism or efflux may be responsible. Comparison of calculated brain influxes and brain concentrations of LNAAs suggests that the rise in level of plasma free tryptophan during immobilization is not responsible for the increase in level of brain tryptophan and that the mechanism responsible for the maintenance of or increase in brain concentrations of the other LNAAs is probably involved. Maintenance of brain concentrations of basic amino acids is explicable by reduced competition for brain uptake.     

Dialytrode Technology and Local Profiles of Amino Acids in the Awake Cat Brain

Methods to investigate the in vivo effects and release of neuroactive substances include cortical cups, push-pull cannulae, chemitrodes, and dialytrodes. Critical evaluation of these procedures is necessary in order to interpret related results and to select the most suitable devices for further studies. Recent improvements in the dialytrode include structural modifications and the use of a small, permeable membrane constructed of thin polyester. The dialytrode system and its diffusion rates have been characterized with in vitro studies. In vivo long-term experiments in awake cats have been conducted to test injection rates, diffusion of [14C]urea, temporal variability, pressure factors, and other experimental variables. Using dialytrodes we have measured the normal profile of amino acids present in different cerebral structures and their possible correlations.     

The effect of ovariectomy on phenylalanine and tyrosine metabolism

Summary Although the regulatory activity of steroid hormones on amino acid metabolism has been described, no information is published on the effect of ovariectomy. We studied the influence of ovariectomy in Wistar rats determining the amino acids phenylalanine and tyrosine in liver, kidney, plasma and urine. 32 animals were used in the study, 12 animals were sham operated, 9 animals were ovariectomized and 11 rats were ovariectomized and supplemented with estradiol. No quantitative changes were detected comparing liver and kidney phenylalanine and tyrosine between the groups (sham operated rats liver phenylalanine 2,53nM/mg ± 1,07; liver tyrosine 1.95nM/mg ± 0.92; kidney phenylalanine 2.16nM/mg ± 0.53; kidney tyrosine 1.80nM/mg ± 0.39. Ovariectomized rats showed liver phenylalanine 3.07nM/mg ± 1.14; liver tyrosine 2.63nM/mg ± 1.01; kidney phenylalanine 2.30 nM/mg ± 0.74; kidney tyrosine 1.93nM/mg ± 0.63. Ovariectomized and estradiol supplemented rats presented with liver phenylalanine 2.84nM/mg ± 1.40; liver tyrosine 2.35nM/mg ± 1.28; kidney phenylalanine 1.91nM/mg ± 0.26, kidney tyrosine 1.67nM/mg ± 0.23.). When, however, the phenylalanine/tyrosine ratio in the liver was evaluated, ovariectomized rats showed a significant decrease of the quotient (p = 0.001). The phenylalanine/tyrosine ratio was restored by estradiol replacement. Our findings show that phenylalanine and tyrosine metabolism is under estradiol control. The effect on the metabolic changes could be mediated by enzyme systems as phenylalanine hydroxylase, tyrosine hydroxylase and tyrosine aminotransferase. Our results would be compatible with previous reports on the stimulatory effect of estradiol on these enzymes. The kidney phenylalanine/tyrosine ratio was unaffected by ovariectomy and/or estradiol replacement which can be easily explained by different pools, enzyme activities, filtration/reabsorption effects, etc.The urinary P/T ratio was decreased by ovariectomy and restored by estradiol replacement indicating endocrine control of renal reabsorption and secretion mechanisms.     

Activity of Lactate Dehydrogenase in Serum and Cerebral Cortex of Immature and Mature Rats after Hypobaric Hypoxia

In our previous studies we have found both an increase of lipid peroxidation damage (expressed as levels of thiobarbituric acid-reactive substances) in brain and plasma lactate concentration in 21-day-old rats after a 30-min exposure to hypobaric hypoxia. Pretreatment of rats with l-carnitine decreased both parameters. The aim of our present study was to determine if the l-carnitine-dependent decrease of plasma lactate could be due to a modification of lactate dehydrogenase (LDH) activity. We followed brain and blood serum LDH activity of 14-, 21- and 90-day-old Wistar rats. We found an increase of brain LDH activity with age. However, we did not observe any significant differences in LDH activity after exposure to hypobaric hypoxia or l-carnitine pretreatment. In contrast to brain, serum LDH activity did not show any clear age-dependence. The hypoxia exposure increased LDH activity of 21-day-old rats only. Pretreatment of rats with l-carnitine decreased serum LDH activity of 21- and 90-day-old rats probably due to membrane stabilizing role of l-carnitine. In conclusions, acute hypobaric hypoxia and/or l-carnitine pretreatment modified serum but not brain LDH activity.     

Determination of Regional Rates of Cerebral Protein Synthesis Adjusted for Regional Differences in Recycling of Leucine Derived from Protein Degradation into the Precursor Pool in Conscious Adult Rats

The quantitative autoradiographic L-[1-14C]leucine method for the determination of regional rates of cerebral protein synthesis in vivo takes into account recycling of unlabeled leucine derived from protein degradation into the precursor pool for protein synthesis. We have evaluated the degree of recycling by measuring the ratio of the apparent steady-state leucine specific activity in the precursor amino acid pool (tRNA-bound leucine) to that in the arterial plasma. In the whole brain of the conscious rat this ratio (lambda WB) equals 0.58. The equivalent ratio for leucine in the acid-soluble pool in whole brain (psi WB) is 0.49. A first-degree polynomial equation for lambda WB as a function of psi WB was fitted from paired determinations. To determine the degree of recycling in local regions of the brain, we have measured in individual brain regions (i) psi i and calculated lambda i assuming that the fitted equation also applies to these localized regions. Our results indicate that the degree of recycling into the precursor pool does vary regionally; lambda i in the individual regions varies from 0.62 in the hypoglossal nucleus to 0.50 in the globus pallidus. Local rates of protein synthesis were then determined by the autoradiographic technique with regional corrections for recycling of unlabeled leucine. Rates of leucine incorporation into protein averaged 6.1 nmol/g of tissue/min in the brain as a whole, with the rates in gray matter about twice those in white matter.     

Amino acids and the kidney

Summary The kidney has an important role in the metabolism of amino acids and control of plasma concentrations. Reabsorption by the tubules recovers about 70g/day of amino acids, derived from both the diet and metabolism in other tissues. Amino acids regulate haemodynamics and proteolysis and maintain integrity of the kidney. Abnormal plasma and muscle amino acid profiles in chronic renal failure (i.e. low essentials and tyrosine with high nonessentials) first indicated malnutrition, which can be partially corrected by supplementation. The loss of effective kidney tissue and uraemia, in addition to nutrition, have been considered in studies of phenylalanine hydroxylation used to investigate low tyrosine. Investigations in normal kidney have shown that glutamine uptake maintains acid-base homeostasis, glycine and citrulline are removed, and serine and arginine are released into the circulation. These metabolic processes are impaired in chronic renal failure. Uraemia affects most tissues and causes malnutrition, whilst acidosis activates catabolism of amino acids and proteins in muscle. Hyperinsulinaemia probably depresses plasma branchedchain amino acids and particularly valine. These abnormalities are less likely to respond to dietary supplementation.     

高苯丙氨酸血症大鼠脑内单胺类递质的研究

以3d龄Sprague-Dawley大鼠腹腔注射苯丙氨酸(Phe)诱导高苯丙氨酸血症,荧光法测定大脑皮层及其突触体中去甲肾上腺素(NE)、多巴胺(DA)和5-羟色胺(5-HT)含量;Y型电迷宫法测其学习记忆能力.结果显示:高苯丙氨酸血症大鼠大脑皮层NE、DA及5-HT含量降低38.6%～67.4%,突触体中NE、DA和5-HT含量降低51.9%～70.2%,学习记忆能力明显低于对照组.结果提示,苯酮尿症智力障碍可能与大脑皮层及其突触体中某些单胺类递质含量降低相关.     

Reduced Cortical Glutamine Concentrations in Electrically Kindled Rats

The effect of kindling rats (with an electrical stimulus applied daily to the frontal cortex) on the concentrations of taurine, aspartate, glutamate, glutamine, and gamma-aminobutyric acid has been investigated. When compared with control groups, cortical glutamine concentrations were significantly decreased in kindled rats by approximately 20%. This decrease in glutamine directly correlated with the after-discharge duration (r = 0.84, p = 0.005). The significance of this in relation to glutamate metabolism and kindling is discussed here.     

Mass Fragmentographic Method for the Determination of Trace Amounts of Putative Amino Acid Neurotransmitters and Related Compounds from Brain Perfusates Collected In Vivo

Abstract: A mass fragmentographic method for the determination of trace amounts of amino acid neurotransmitter candidates from brain perfusates is described. The analytical procedure includes the measurements of glycine, β-alanine, γ-aminobutyric acid, proline, aspartic acid, and glutamic acid; αalanine, leucine, and sarcosine, undergoing gas chromatographic coelution, are detected simultaneously. Amino acids extracted from dried perfusate residues are converted to the corresponding N -pentafluoropropionyl hexafluoroisopropyl esters by a single-step procedure. Gas chromatographic separation of the amino acid derivatives is achieved on a packed glass column filled with trifluoropropylsilicone as stationary phase. The limit of detection for the different derivatives (signal-to-noise, 3:1) ranges from 50 femtomol to 1 picomol. Deuterium-labeled amino acid analogues are used as internal standards for quantitative measurements. The mass spectral characteristics of the derivatives are compared and discussed. The technique has been applied to the assay of amino acids released in vivo within the pigeon optic tectum, demonstrating the capabilities of the present analytical approach.     

Tenoxicam Exerts a Neuroprotective Action after Cerebral Ischemia in Rats

In this study we investigated the effects of Tenoxicam, a type 2 cyclooxygenase (COX-2) inhibitor, on brain damage induced by ischemia-reperfusion. Male Wistar rats (18-month old average) were anesthetized and submitted to ischemia occlusion of both common carotid arteries (BCAO) for 45 min. After 24 h of reperfusion, rats were decapitated and hippocampi removed for further assays. Animals were divided into sham-operated, ischemia, ischemia + Tenoxicam 2.5 mg/kg, and ischemia + Tenoxicam 10 mg/kg groups. Tenoxicam was administered intraperitoneally immediately after BCAO. Histological analyses show that ischemia produced significant striatal as well as hippocampal lesions which were reversed by the Tenoxicam treatment. Tenoxicam also significantly reduced, to control levels, the increased myeloperoxidase activity in hippocampus homogenates observed after ischemia. However, nitrite concentrations showed only a tendency to decrease in the ischemia + Tenoxicam groups, as compared to that of ischemia alone. On the other hand, hippocampal glutamate and aspartate levels were not altered by Tenoxicam. In conclusion, we showed that ischemia is certainly related to inflammation and to increased free radical production, and selective COX-2 inhibitors might be neuroprotective agents of potential benefit in the treatment of cerebral brain ischemia.     

Uptake of Amino Acids by Brain Microvessels Isolated from Rats after Portacaval Anastomosis

Abstract: The uptake of amino acids by microvessels isolated from brains of rats was studied. Previous studies have demonstrated alterations in blood-brain amino acid transport after portacaval shunt in rats. In order to elucidate whether such changes in the blood-brain barrier were located in the microvessels, brain microvessels were isolated from both rats with portacaval shunt and controls. Brain microvessels from rats 2 weeks after shunt operations took up significantly greater amounts of ¹⁴C-labeled neutral amino acids, but not of glutamic acid. lysine, or α-methylaminoisobutyric acid than microvessels from sham-operated controls. Measurement of uptake kinetics showed a higher V _max for phenylalanine and leucine uptake and a lower V _max for lysine uptake in microvessels from shunted rats compared with control, whereas the respective K _m's of uptake were similar in both preparations. The results suggest that changes in brain microvessel transport activity account for altered brain neutral amino acid concentrations after portacaval shunt and that such changes can be studied in vitro in isolated microvessels.     

L-Tyrosine-3-hydroxylase regulation in the brain: genetic aspects

Summary L-tyrosine-3-hydroxylase (TH) is the first and rate limiting enzyme in the biosynthetic pathway of catecholamine neurotransmitters (dopamine, noradrenaline, adrenaline). Implication of dopamine (DA) in various psychopathological phenomena, such as schizophrenia, has considerably contributed to the intensity of investigation of basic biochemical regulation of TH by activation and induction. Here we consider a third, constitutional (genotypic) aspect of regulation and present evidence that differences in mesencephalic (TH/SN), striatal (TH/CS), and hypothalamic (TH/HT) TH activity between virtually isogeneic strains of mice can be explained by segregating genetic factors. Biometrical genetic analysis of progenitor strains and their crosses indicated significant additive gene effects for TH/SN, TH/CS, and TH/HT, whereas dominance effects were statistically non-significant. A monogenic model of inheritance for TH/SN and TH/CS could not be rejected, while more than one gene was indicated for TH/HT. Significant positive phenotypic correlations were found in genetically segregating populations among mesencephalic, striatal and hypothalamic TH activities. This would suggest that some common genetic factors (or linked genes) are involved in the genetic variation of all three traits. A genetic selection experiment to elucidate the cellular and biochemical mechanisms underlying these variations is in progress.     

Free Fatty Acid Content and Release Kinetics as Manifestations of Cerebral Lateralization in Mouse Brain

Free fatty acid (FFA) content was analyzed in mouse cerebral hemispheres and cerebellum under basal and postdecapitative ischemic conditions. Total FFA content immediately after decapitation (2 s) was about two-fold higher in the left hemisphere than in the right. Marked dissimilarities between hemispheres were also apparent when FFA levels were measured during short periods of ischemia. Whereas in the right side a significant FFA release took place as early as 10 s, no accumulation was detected in the left in the 2-20 s interval. The highest rates of total fatty acid release occurred in the 20-30 s interval in both hemispheres and decreased afterwards (3 min). Individual FFA, especially stearate and arachidonate, differed in their rates of production, the right cerebral hemisphere being more active in releasing arachidonic acid. In cerebellum, FFA levels were lower and accumulation was slower than in cerebrum in both intervals. When subjected to 3 min ischemia, the same difference in FFA levels between right and left hemispheres (50%) was observed in heads kept at 20 or 30 degrees C. The differences between hemispheres are interpreted as manifestations of an inherent lateralization in the regulation of acylation-deacylation reactions of complex lipids.     

Production of tyrosine and other aromatic compounds from phenylalanine by rumen microorganisms

Summary Rumen contents from three fistulated Japanese native goats fed Lucerne hay cubes (Medicago sativa) and concentrate mixture were collected to prepare the suspensions of mixed rumen bacteria (B), mixed protozoa (P) and a combination of the two (BP). Microbial suspensions were anaerobically incubated at 39°C for 12h with or without 1 MM ofl-phenylalanine (Phe). Phe, tyrosine (Tyr) and other related compounds in both supernatant and microbial hydrolysates of the incubations were analyzed by HPLC. Tyr can be produced from Phe not only by rumen bacteria but also by rumen protozoa. The production of Tyr during 12h incubation in B (183.6 mol/g MN) was 4.3 times higher than that in P. One of the intermediate products between Phe and Tyr seems to bep-hydroxyphenylacetic acid. The rate of the net degradation of Phe incubation in B (76.O mol/g MN/h) was 2.4 times higher than in P. In the case of all rumen microorganisms, degraded Phe was mainly (>53%) converted into phenylacetic acid. The production of benzoic acid was higher in P than in B suspensions. Small amount of phenylpyruvic acid was produced from Phe by both rumen bacteria and protozoa, but phenylpropionic acid and phenyllactic acid were produced only by rumen bacteria.