A simple, fast and reliable method for obtaining dopamine histofluorescence from mesencephalic cultures

A modified glyoxylic acid technique for obtaining dopamine histofluorescence from cultured mesencephalic cells is described. This method requires only two solutions: one contains glyoxylic acid, sucrose and monobasic potassium phosphate and is used at room temperature, the other is a Hepes buffered solution used at 37 C. Relatively high concentrations of a monoamine oxidase inhibitor and dopamine are added to the cultures to load dopaminergic neurons; the cell bodies and their processes take up and hold dopamine quickly and evenly. The cultures are dipped in a glyoxylic acid solution, dried in air, heated for 5 min and coverslipped with mineral oil. Since the cultures remain in their culture dishes, the entire procedure takes less than 2 hr. The green histofluorescence characteristic of dopamine is seen when the cultures are viewed by standard fluorescence microscopy. Various cell body types and sizes can be distinguished, as well as the complete extent of their processes and varicosities.     

Development of dopamine-containing neurons and dopamine uptake in embryos of Hirudo medicinalis

The embryonic development of neurons which contain or take up dopamine was studied with glyoxylic acid histofluorescence in Hirudo medicinalis. Beginning at the time of the formation of the tail ganglion, one pair of dopamine-containing neurons was stained per segmental ganglion. The normal outgrowth of the cell bodies into the anterior roots was prevented in isolated and cultured chains of embryonic ganglia. Preincubation of intact embryos in dopamine led to the staining of additional neurons at certain developmental stages. These neurons presumably are the precursors of serotonin-containing cells, which have a temporary capability of taking up and storing dopamine.     

An improved histofluorescence procedure for freeze-dried paraffin-embedded tissue based on combined formaldehyde-glyoxylic acid perfusion with high magnesium content and acid pH.]

A technique is described for highly sensitive and precise visualization of central catecholamine systems in paraffin sections of freeze-dried tissue. The procedure is based on perfusion of the animal with a solution containing formaldehyde and/or glyoxylic acid, in the presence of a very high magnesium content (40 g MgSO4/150 ml solution) and acid pH. The perfused tissue is rapidly frozen, freeze-dried, treated with formaldehyde vapours (at +80 degrees C for 1 h), embedded in parffin in vacuo, and finally sectioned. The present technique has a sensitivity for the dopamine- and noradrenaline-containing systems that is comparable with that of the glyoxylic acid-Vibratome technique, which utilizes fresh, glyoxylic acid-perfused tissue. Thus, the preterminal axon pathways become fluorescent throughout their full extent and the several new terminal systems, discovered with the glyoxylic acid-Vibratome method, are well demonstrable. The method is also highly useful for the study of the cell bodies and their dendritic processes. The catacholamine fibre systems are visualized without any signs of diffusion and with a richness in detail. In animals pretreated with L-tryptophan and MAO-inhibitor the technique is also useful for studies on central indolamine-containing systems.     

A methodological approach to rapid and sensitive monoamine histofluorescence using a modified glyoxylic acid technique: The SPG method

Summary A modified approach of the glyoxylic acid (GA) condensation reaction for the visualization of biogenic amines in tissue is described.Cryostat sections are used from brain or extracerebral tissue in dog, monkey, rat and mouse and exposed for 3 s to a room temperature solution containing sucrose-potassium phosphate-glyoxylic acid (SPG). The tissues are air dried and heated in an oven for 5 min. The complete processing time from fresh tissue to microscopic examination takes 18 min. Morphologically sharp and brightly fluorescent monoamine-containing neurons, pre-and terminal axons are seen against a dark parenchymal background without drug pre-treatment. The SPG method retains the high specific sensitivity for monoamines previously described in the original technique but is, in addition, more rapid and simple and is easily accessible as a research tool to investigators inexperienced in histofluorescence techniques.     

An improved histofluorescence procedure for freeze-dried paraffin-embedded tissue based on combined formaldehyde-glyoxylic acid perfusion with high magnesium content and acid pH

Summary A technique is described for highly sensitive and precise visualization of central catecholamine systems in paraffin sections of freeze-dried tissue. The procedure is based on perfusion of the animal with a solution containing formaldehyde and/or glyoxylic acid, in the presence of a very high magnesium content (40 g MgSO₄/150 ml solution) and acid pH. The perfused tissue is rapidly frozen, freeze-dried, treated with formaldehyde vapours (at +80°C for 1h), embedded in paraffin in vacuo, and finally sectioned.The present technique has a sensitivity for the dopamine- and noradrenaline-containing systems that is comparable with that of the glyoxylic acid-Vibratome technique, which utilizes fresh, glyoxylic acid-perfused tissue. Thus, the preterminal axon pathways become fluorescent throughout their full extent and the several new terminal systems, discovered with the glyoxylic acid-Vibratome method, are well demonstrable. The method is also highly useful for the study of the cell bodies and their dendritic processes. The catacholamine fibre systems are visualized without any signs of diffusion and with a richness in detail. In animals pretreated with l-tryptophan and MAO-inhibitor the technique is also useful for studies on central indolamine-containing systems.     

The identification and localization of a catecholamine in the motor neurons of the lobster cardiac ganglion

The cardiac ganglion from Homarus americanus was investigated for the purpose of providing biochemical and histochemical information as to the identity of the neurotransmitter(s) utilized by this system. Three techniques were employed in this study: (1) the glyoxylic acid histofluorescence staining technique (GA), which showed fluorescence characteristic of catecholamines localized in the five motor neurons; (2) high-voltage electrophoresis (HVE) in one dimension followed by ascending chromatography in the second dimension, which indicated incorporation of label from tritiated tyrosine into norepinephrine (NE) and small amounts of dopamine (DA); (3) high-pressure liquid chromatography with electrochemical detection (HPLC/EC), which indicated the presence of endogenous norepinephrine.     

Glyoxylic acid promotes poly(ADP-ribosyl)ation of nuclear proteins in K562 cells cultured at limiting dilution

Addition of glyoxylic acid to the culture medium allows survival and proliferation of K562 human erythroleukemic cells cultured at low population density in the absence of serum. Concomitantly, glyoxylic acid induces a remarkable increase in nuclear poly(ADP-ribose) content, as compared to control cells cultured without addition of glyoxylate. The latter effect is reversed by addition of micromolar concentrations of benzamide to the cultures. As glyoxylic acid is metabolized through NADH-dependent reduction to glycolic acid only, the observed effects on cell growth and on nuclear poly(ADP-ribose) content seem to be mediated by an increased cellular ability to oxidize NADH.     

Catecholamine neurons in Aplysia: improved light-microscopic resolution and ultrastructural study using paraformaldehyde and glutaraldehyde (FaGlu) cytochemistry

We have modified the formaldehyde-glutaraldehyde (FaGlu) histofluorescence method of Furness, Costa, and Blessing (1977a) and Furness, Costa, and Wilson (1977b) to examine wholemounts and sections of both juvenile and adult ganglia as well as peripheral tissues of Aplysia californica. FaGlu fluorescence is the result of a reaction between formaldehyde and tissue catecholamines to produce water-insoluble (fixed) fluorophores. In serially sectioned cerebral ganglia, 70-80 positive neurons were observed (many in clusters of 10-20 cells), many more than were found using the glyoxylic acid technique. Catecholamine-containing varicosities were densely packed in localized portions of the neuropil of all central ganglia. Exclusive localization in the neuropil of presumed dopamine release sites is similar to that previously found for the neuropeptide SCP but differs from the widespread ramification of varicose neurites containing 5-HT, FMRFamide, and ELH. The FaGlu technique also enabled us to study the ultrastructure of catecholamine-containing neurons. In contrast to the larger vesicles found in serotonergic and histaminergic neurons, these dopaminergic neurons contain 70 nm dense-cored vesicles.     

Wholemount histofluorescence of catecholamine-containing neurones in a hemipteran brain

Whole brains from Rhodnius prolixus treated with glyoxylic acid display catecholamine histofluorescence in eleven bilaterally distributed clusters of neurones, and in three circumscribed neuropile regions. This simple method offers resolution of some features not detected in studies on sectioned insect tissue; cephalic neurosecretory cells in chronically starved animals are histofluorescent and diverse catecholamine-handling fibres converge within the brain of this insect.     

Glyoxylic acid prevents NAD+ and NADH depletion in K562 cells cultured at limiting dilution

K562 erythroleukemic cells cultured at low population density in the absence of serum die within 12-24 hours, unless 0.1 mM glyoxylic acid is added to the culture medium. Earlier events, preceding cell death and occurring within 2 hours culture, are: a) a marked drop of both the NAD+/NADH ratio and the NAD+ concentration, which is prevented by 10mM benzamide, b) an increased biosynthesis of NAD+, leading to extensive depletion of cellular ATP. In the presence of 0.1 mM glyoxylic acid the NAD+/NADH ratio as well as their absolute concentrations remain unchanged, while NAD+ biosynthesis is absent. A NAD+/NADH glycohydrolase activity is present in the cell extract, inhibited by 10 mM benzamide and with a higher affinity for NADH than for NAD+. Preservation of a high NAD+/NADH ratio by glyoxylic acid apparently prevents enzyme activity and the related loss of pyridine nucleotides.     

Demonstration of catecholamines in peripheral adrenergic nerves in stretch preparations with fluorescence induced by aqueous solution of glyoxylic acid.

Fluorescence induced by aqueous solution of glyoxylic acid and formaldehyde-induced fluorescence of catecholamines were compared for the demonstration of peripheral adrenergic nerves in stretch preparations. Glyoxylic acid was better than formaldehyde for the demonstration of the adrenergic nerves. On the other hand, the formaldehyde was better than glyoxylic acid for the demonstration of biogenic amines in cell bodies.     

INHIBITION OF CATALASE IN MESENCEPHALIC CULTURES BY l-DOPA AND DOPAMINE

Catalase activity in cell cultures of fetal rat mesencephalon was decreased by 42 and 50%, respectively, after exposure to l-3,4-dihydroxyphenylalanine (l-DOPA, 100 μM) or dopamine (100 μM) for 48 h. Catalase activity was also decreased 21% by 10 μM hydroquinone. Ascorbic acid (200 μM), an agent that suppresses the autoxidation of l-DOPA and dopamine, blocked the anti-catalase effect of l-DOPA, but not that of dopamine. Inhibitors of the A and B forms of monoamine oxidase (20 μM clorgyline plus 20 μM pargyline) had no effect on the anti-catalase action of either l-DOPA or dopamine. The latter results suggest that products of the oxidative deamination of dopamine by monoamine oxidase are not involved in the suppression of catalase activity. However, autoxidation reactions of l-DOPA may play a role since ascorbate suppressed the anti-catalase effect of l-DOPA. On the contrary, the basis for the failure of ascorbate to similarly block the anti-catalase effect of dopamine is uncertain. l-DOPA and dopamine (25 μM) also inhibited crystalline catalase in solution after incubation for 1 h at neutral pH (40–50% inhibition). Inhibition was blocked by 0.45 M ethanol, indicating a need for autoxidation and the formation of compound II, which is an enzymatically inactive form of catalase. The ability to model the enzyme inhibition in purely chemical experiments indicates a probable mechanism for loss of enzymatic activity in cell cultures. Inhibition of catalase may contribute to cell damage during incubation of cultures with l-DOPA, dopamine, or other autoxidizable compounds. Copyright © 1996 Elsevier Science Ltd     

The fluorimetric microdetermination of glyoxylic acid in blood, urine and bacterial extracts

1. A spectrophotofluorimetric method for the determination of glyoxylic acid in biological materials is described. 2. The method is based on the reaction between glyoxylic acid and resorcinol in acid solution, a fluorescent complex being obtained on the subsequent addition of alkali. 3. The reaction was found to be sensitive and highly specific, the minimum detectable amount of glyoxylic acid being 1·35×10⁻⁸ mole. 4. The urinary excretion of glyoxylic acid by ten normal adults ranged from 1·4 to 4·7mg./24hr. Small but measurable amounts of glyoxylic acid were found in cell-free extracts of Pseudomonas oxalaticus OX1 grown on oxalic acid as a source of carbon. No glyoxylic acid was detected in human serum.     

Autoanalytical procedure for the determination of allantoin and allantoic Acid in soybean tissue

Ureide analyses of soybean (Glycine max L.) tissues were accomplished with a modified and simplified automated analysis used to determine allantoin concentration in rat urine. The length of the circuit and flow rates of the solutions were reduced, and NaOH was used for color development at room temperature. Keto-acids did not significantly interfere with the determinations of ureides except for glyoxylic acid in extracts of fresh soybean tissue. The interference caused by glyoxylic acid was avoided by adding phenylhydrazine HCl to the solution of NaOH used for alkaline hydrolysis of allantoin.     

Application of the glyoxylic acid method to Vibratome sections for the improved visualization of central catecholamine neurons

Summary The glyoxylic acid fluorescence histochemical method for the visualization of neuronal monoamines has been applied to fresh or glyoxylic acid-perfused brain tissue, sectioned with the Vibratome intrument. This technique demonstrates the central noradrenaline and dopamine neuron systems with a sensitivity and richness in details that is superior to the standard Falck-Hillarp formaldehyde method, as observed in the following three ways: First, the entire axon, including the non-terminal portions, became fluorescent; second, more extensive terminal systems were detected in certain brain regions ; third, due to the absence of diffusion, the delicate dopamine-containing fibres in e. g. the caudate nucleus and the median eminence had a distinct fluorescence. It is concluded that the glyoxylic acid method applied to Vibratome sections should be ideal for precise and detailed neuroanatomical studies on central catecholamine neuron systems.     

Characterization of neurotransmitter phenotype during neuronal differentiation of embryonal carcinoma cells

Embryonal carcinoma cells are useful in the study of embryogenesis and development, and their differentiation into neurons serves as a model of neuronal development. Retinoic acid was used to differentiate P19S18O1A1 embryonal carcinoma cells into neuronal, glial, and fibroblast-like cells and the phenotype of the neuronal population was examined. Neuron-specific enolase was present in the neuronal cells, suggesting that these neurons had reached some degree of maturity. A population (approximately 70%) of the neurons showed positive immunocytochemistry for tyrosine hydroxylase, dopamine beta-hydroxylase and phenylethanolamine N-methyltransferase, three enzymes in the pathway of catecholamine synthesis. Therefore a population of the neurons appeared to be adrenergic. These neurons also showed a low level of histofluorescence for endogenous catecholamines and exhibited an exogenous catecholamine reuptake system. In order to determine the phenotype of other neuron-like cells found to be negative for the adrenergic properties examined, immunocytochemistry for neuropeptides and neurotransmitters known to coexist within central neurons was performed. Serotonin, vasoactive intestinal peptide, glutamic acid decarboxylase, and choline acetyltransferase were all absent from retinoic acid-treated P19S18O1A1 neuronal cultures. These studies, along with those that compare the effects of retinoic acid and other growth modulators on neuronal differentiation of embryonal carcinoma cells, should aid in the understanding of neuronal induction and development in vivo.     

Enzyme-catalysed peptide amidation. Isolation of a stable intermediate formed by reaction of the amidating enzyme with an imino acid

A series of hydrazones and semicarbazones of glyoxylic acid were shown to have a potent inhibitory effect on the enzyme-catalysed conversion of D-Tyr-Val-Gly to D-Tyr-Val-NH2. Among the derivatives tested, the inhibitory activity was increased by the presence of hydrophobic substituents and decreased by polar substituents. The inhibition produced by glyoxylic acid phenylhydrazone was shown to be competitive. No inhibition was obtained with pyruvic acid phenylhydrazone, which possesses a methyl group in place of the alpha-H of glyoxylic acid phenylhydrazone. The inhibitory potencies of these non-peptide substances are in accord with the specificity exhibited by the amidating enzyme in its reaction with peptide substrates. The inhibition produced by the glyoxylic acid derivatives was shown to be due to their ability to act as substrates for the peptide-amidating enzyme. The product formed from [14C]glyoxylic acid phenylhydrazone was identified as oxalic acid phenylhydrazide by co-chromatography in three chromatographic systems. The results demonstrate that the enzyme-catalysed oxidation of glyoxylic acid phenylhydrazone takes place by a mechanism involving hydroxylation. It is implicit that peptide amidation catalysed by the same enzyme proceeds by a similar mechanism.     

Crystal structures of Aedes aegypti alanine glyoxylate aminotransferase

Mosquitoes are unique in having evolved two alanine glyoxylate aminotransferases (AGTs). One is 3-hydroxykynurenine transaminase (HKT), which is primarily responsible for catalyzing the transamination of 3-hydroxykynurenine (3-HK) to xanthurenic acid (XA). Interestingly, XA is used by malaria parasites as a chemical trigger for their development within the mosquito. This 3-HK to XA conversion is considered the major mechanism mosquitoes use to detoxify the chemically reactive and potentially toxic 3-HK. The other AGT is a typical dipteran insect AGT and is specific for converting glyoxylic acid to glycine. Here we report the 1.75A high-resolution three-dimensional crystal structure of AGT from the mosquito Aedes aegypti (AeAGT) and structures of its complexes with reactants glyoxylic acid and alanine at 1.75 and 2.1A resolution, respectively. This is the first time that the three-dimensional crystal structures of an AGT with its amino acceptor, glyoxylic acid, and amino donor, alanine, have been determined. The protein is dimeric and adopts the type I-fold of pyridoxal 5-phosphate (PLP)-dependent aminotransferases. The PLP co-factor is covalently bound to the active site in the crystal structure, and its binding site is similar to those of other AGTs. The comparison of the AeAGT-glyoxylic acid structure with other AGT structures revealed that these glyoxylic acid binding residues are conserved in most AGTs. Comparison of the AeAGT-alanine structure with that of the Anopheles HKT-inhibitor complex suggests that a Ser-Asn-Phe motif in the latter may be responsible for the substrate specificity of HKT enzymes for 3-HK.     

Fluorescence histochemical studies of the uptake of exogenous noradrenaline and dopamine by in vitro cultured cerebrocortex explants of the rat

Cerebrocortex of the neonatal rats were cultivated (--14 days). The cultures were studied living and with histological and fluorescence histochemical methods. A differentiation of neuronal cell- and fiber elements, oligodendro glial cells and astrocytes was found. The glyoxylic acid technique to estimate biogenic monoamines (Lindvall et al. 1974) was adapted up the cultivated explants. The normal cultures have only 24 h post cultivationem a specific fluorescence granularly in small concentration of the surface of the explant and in the explant self. Incubations with noradrenaline and dopamine demonstrated a various accumulation of the exogenous transmitters in the various parts of the cultivated explants. Uptake and releasing mechanisms in the cultivated material of the cerebrocortex were discussed with respect to the results of the sympathetic ganglia in vitro.     

Chromatographic and Histochemical Identification of Dopamine Within an Identified Neuron in the Leech Nervous System

Abstract: Each segmental ganglion of the leech nervous system has two pairs of lateral roots extending to the body wall and viscera. A cluster of about eight neuron cell bodies is located proximal to the first major branch of each anterior root and is termed the anterior root ganglion (ARG). Only one of these eight cells is vitally-stained by Neutral Red dye and fluoresces an intense blue-green following the glyoxylic acid histochemical condensation. The emission spectrum of this anterior root cell (AR) is stable under continuous UV illumination and is bimodal, with peaks at about 480 and 515 nm. This spectrum is indistinguishable from that of millimolar solutions of dopamine (DA) in gelatin droplets following glyoxylic acid histochemistry. We utilized high performance liquid chromatography and an amperometric detector to measure DA within the AR neurosomata at 1.01 pmol/cell. The AR cells in this study had an average diameter of 23 μm and therefore, the minimum intrasomatal concentration of DA is 160 m M , an unusually high level for any neu-rotransmitter. We measured DA in anterior axons at 0.83 pmol, in segmental ganglia at 1.07 pmol, and in longitudinal connectives at 0.16 pmol. Control neurosomata (Retzius cells) and axonal tracts which lack blue-green fluorescence (posterior and distal anterior roots), had no detectable DA (<0.06 pmol/sample). These data establish that the catecholamine DA is responsible for the fluorescence of the AR cell.