Quantification and excretion profiles of pteridines in primate urine.

Biopterin, 6-hydroxymethyl-pterin, isoxanthopterin, neopterin and, pterin were quantified in stress-free collected spontaneous morning urine samples from Callithrix jacchus, Saguinus fuscicollis, Saguinus labiatus, Saimiri sciureus, Presbytis entellus, Cercopithecus albogularis, Cercocebus torquatus, Macaca fascicularis, Hylobates concolor, Pongo pygmaeus, and Gorilla gorilla. In most species, biopterin was the most frequent urinary pteridine followed by neopterin. Sex differences in biopterin and neopterin excretion were observed in Gorilla gorilla and Pongo pygmaeus. Pterin and isoxanthopterin were only present in minor concentrations. 6-hydroxymethyl-pterin was barely detectable and not present in the urine of Saguinus labiatus, Saimiri sciureus, and both male Gorilla gorilla and Pongo pygmaeus.     

Alcohol dehydrogenase-coupled spectrophotometric assay of plasmalogenase

Plasmalogenase has been assayed by conversion of the fatty aldehydes, released by hydrolysis of the vinyl ether bond of plasmalogens, to long-chain alcohols by horse liver alcohol dehydrogenase. The reaction was followed spectrophotometrically by measuring the oxidation of NADH. The assay is sufficiently sensitive to enable plasmalogenase activity to be determined in isolated oligodendroglia and derived membranes and in brain microsomal membranes using 50-250 micrograms protein.     

Esrom, an ortholog of PAM (protein associated with c-myc), regulates pteridine synthesis in the zebrafish

Zebrafish esrom mutants have an unusual combination of phenotypes: in addition to a defect in the projection of retinal axons, they have reduced yellow pigmentation. Here, we investigate the pigment phenotype and, from this, provide evidence for an unexpected defect in retinal neurons. Esrom is not required for the differentiation of neural crest precursors into pigment cells, nor is it essential for cell migration, pigment granule biogenesis, or translocation. Instead, loss of yellow color is caused by a deficiency of sepiapterin, a yellow pteridine. The level of several other pteridines is also affected in mutants. Importantly, the cofactor tetrahydrobiopterin (BH4) is drastically reduced in esrom mutants. Mutant retinal neurons also appear deficient in this pteridine. BH4-synthesizing enzymes are active in mutants, indicating a defect in the regulation rather than production of enzymes. Esrom has recently been identified as an ortholog of PAM (protein associated with c-myc), a very large protein involved in synaptogenesis in Drosophila and C. elegans. These data thus introduce a new regulator of pteridine synthesis in a vertebrate and establish a function for the Esrom protein family outside synaptogenesis. They also raise the possibility that neuronal defects are due in part to an abnormality in pteridine synthesis.     

Neopterin and Biopterin Levels in Patients with Atypical Forms of Phenylketonuria

The pattern of unconjugated pterins in liver tissue and in urine from patients with atypical forms of phenylketonuria with hyperphenylalaninemia (HPA) has been investigated with a high performance liquid chromatographic technique. Two patients with defects in the biosynthesis of biopterin have been shown to have higher than normal levels of neopterin and lower than normal levels of biopterin. In contrast, a patient with HPA due to a deficiency of dihydropteridine reductase has the reverse urinary pattern, i.e., high biopterin, low neopterin. These results indicate that the ratio of neopterin to biopterin in urine can be of value in discriminating between HPA due to a deficiency of phenylalanine hydroxylase (classic PKU), HPA due to dihydropteridine reductase deficiency, and HPA due to a block in the biosynthesis of biopterin.     

Partial purification and some properties of biopterin synthase and dihydropterin oxidase from Drosophila melanogaster

An enzyme which has been named biopterin synthase has been discovered in Drosophila melanogaster. This enzyme, which has been purified 200-fold from extracts of Drosophila, catalyzes the conversion of sepiapterin to dihydrobiopterin, or oxidized sepiapterin to biopterin. The K _m values for the two substrates are 63 µm for sepiapterin and 10 µm for oxidized sepiapterin. NADPH is required in this enzymatic reaction. An analysis of enzyme activity during development in Drosophila indicates a correlation between enzyme activity and biopterin content at various development stages. Another enzyme, called dihydropterin oxidase, was also discovered and partially purified. This enzyme catalyzes the oxidation of dihydropterin compounds to the corresponding pterin compounds. For example, sepiapterin (a dihydropterin) is oxidized to oxidized sepiapterin in the presence of this enzyme. The only dihydropterin that has been tested that is not a substrate for this enzyme is dihydroneopterin triphosphate, the compound thought to be a precursor for all naturally occurring pterins and dihydropterins. Since the action of dihydropterin oxidase is reduced significantly when the concentration of oxygen is very low, it is likely that this enzyme uses molecular oxygen as the oxidizing agent during the oxidation of dihydropterins. Neither NAD⁺ or NADP⁺ is required. In the presence of the two enzymes dihydropterin oxidase and biopterin synthase, sepiapterin is converted to biopterin. However, in the presence of biopterin synthase alone, sepiapterin is converted to dihydrobiopterin.This work was supported by research grants from the National Institutes of Health (AMO3442) and the National Science Foundation (PCM75-19513 AO2).     

Effect of Colchicine on Cell Membrane and on Biopterin Transport in Crithidia fasciculata*

SYNOPSIS. Incorporation of ¹⁴C-labeled biopterin into Crithidia fasciculata was inhibited by 1 mM colchicine or lumicolchicine. These substances do not penetrate the cell membrane, hence they cannot interact with the subpellicular microtubules. In view of this, interference of colchicine with biopterin transport must occur on the outer surface of the cell membrane. Binding of colchicine to Crithidia was not temperature-dependent and did not exhibit saturation kinetics. These facts exclude a binding as in the case of tubulin, or similar proteins which may be present in the membrane. The results suggest an inhibition reflecting steric hindrance of the biopterin carrier system.     

Dense Crithidia Growth and Heme Sparing: Relation to Fe,Cu, Mo Chelation*

SYNOPSIS. Heme, intrinsically required by Trypanosomatidae, is unstable, especially in conventional alkaline (pH 7.2–8.0) media. Low solubility of heme in a pH 6.5 basal medium (developed to assay biopterin with Crithidia fasciculata) posed a problem: in media acidified during growth because of glycolysis, heme precipitated, perhaps contributed to acid-limited growth and interfered with densitometric estimation of growth. The remedy was to: replace glucose with less rapidly metabolized mannitol; distribute media in thin layers to promote oxidation of acetate, fumarate, and malate (presumably leaving an alkaline residue); and buffer heavily with histidine + Good zwitterionic buffers, and superimpcse physiological buffering by arginine + asparagine whose catabolism appeared to yield an excess of NH⁺₄ over acid. Thereupon, Fe and Cu deficiencies sharply limited growth in the medium whose main chelators were: (a) 2,3–dihydroxybenzoic + 5-sulfosalicylic acids (which preferentially bind transitional elements at their higher valences; (b) malic and gluconic acids; and (c) histidine. With unconventionally heightened concentrations of Fe, Cu, and Mo (the latter serving as Cu buffer as well as nutrient per se), the hemin concentration could be lowered, widening the margin of safety for heme solubility. Growth then reached 1.4 × 10⁸ cell/ml. This medium may serve to screen for ligands promoting uptake or release of Fe and Cu. The increased growth is a step towards improving the assay medium for biopterin and practical use of Crithidia to assay several B vitamins and essential amino acids for metazoa.     

Effect of aluminum exposure on pteridine metabolism

Occupational and environmental aluminum (Al) exposure cause serious health problems by interaction with biological systems. Al is one of the most documented metals because its cellular targets are unclear biochemical processes and membranes of organisms. The major aim of the present study was to investigate the alteration of serum and urine aluminum in occupational exposure and to observe whether the metal exposure could cause any changes in pteridine-pathway-related critical compounds such as urinary neopterin and biopterin and blood dihydropteridine reductase (DHPR). In this study, determination of the metal concentrations was carried out in Al-exposed workers (n=23) and healthy volunteers (n=18) by using a tomic absorption spectrometer. DHPR enzyme activity and levels of neopterin and biopterin were detected by spectrophotometric and high-performance liquid chromatographic methods, respectively. It was found that occupational exposure to the metal led to a statistically significant increase in serum Al levels compared to the controls (p<0.05). At the same time, urinary neopterin and biopterin concentrations of the exposed group were higher than nonexposed subjects (both p<0.05). The correlations among Al levels and DHPR activity, magnesium concentration in serum and urine, working years, smoking status, and age were evaluated.     

Oxidative stress in vitiligo: photo-oxidation of pterins produces H(2)O(2) and pterin-6-carboxylic acid

Patients with vitiligo accumulate millimolar levels of H(2)O(2) in their epidermis. The recycling process of (6R)-l-erythro-5,6,7,8-tetrahydrobiopterin in these patients is disrupted due to deactivation of 4a-OH-BH(4) dehydratase by H(2)O(2). The H(2)O(2) oxidation products 6- and 7-biopterin lead to the characteristic fluorescence of the affected skin upon Wood's light examination (UVA 351 nm). Here we report for the first time the presence and accumulation of pterin-6-carboxylic acid (P-6-COOH) in the epidermis of these patients. Exploring potential sources for P-6-COOH revealed that sepiapterin and 6-biopterin are readily photo-oxidised to P-6-COOH by UVA/UVB irradiation. Photolysis of sepiapterin and 6-biopterin produces stoichiometric H(2)O(2) under aerobic conditions, where O(2) is the electron acceptor, thus identifying an additional source for H(2)O(2) generation in vitiligo. A detailed analysis utilising UV/visible spectrophotometry, HPLC, TLC, and mass spectroscopy showed for sepiapterin direct oxidation to P-6-COOH, whereas 6-biopterin formed the intermediate 6-formylpterin (P-6-CHO) which is then further photo-oxidised to P-6-COOH.