Chiral lumazines: Preparation,properties, enantiomeric separation

Optically active lumazines (biolumazine, dictyolumazine, monalumazine, and neolumazine) are prepared from the corresponding pterins by enzymatic reaction, using pterin deaminase excreted by Dictyostelium discoideum. The fluorescence properties, circular dichroism spectra, and chromatographic behavior of these lumazines are studied. D - and L -enantiomers of biolumazine, dictyolumazine, and monalumazine are separated using a chiral flavoprotein column. This column also separates the enantiomeric pterins of the threo form: monapterin and dictyopterin. However, the column does not separate the enantiomeric pterins of the erythro form: neopterin and biopterin. By coupling a reverse-phase column to the flavoprotein column, the separation of pterins and lumazines in function of their hydrophobicity, as well as the separation of the diastereomers, is achieved. This coupled achiral/chiral high-performance liquid chromatography method enables determination of the stereoconfiguration of natural lumazines by comparison with optically pure compounds. A lumazine derivative, present in the extracellular medium of Dictyostelium discoideum, is identified as D -dictyolumazine, i.e., 6-(D -threo-1,2-dihydroxypropyl)-lumazine. © 1994 Wiley-Liss, Inc.     

Pterin and folate salvage. Plants and Escherichia coli lack capacity to reduce oxidized pterins

Dihydropterins are intermediates of folate synthesis and products of folate breakdown that are readily oxidized to their aromatic forms. In trypanosomatid parasites, reduction of such oxidized pterins is crucial for pterin and folate salvage. We therefore sought evidence for this reaction in plants. Three lines of evidence indicated its absence. First, when pterin-6-aldehyde or 6-hydroxymethylpterin was supplied to Arabidopsis (Arabidopsis thaliana), pea (Pisum sativum), or tomato (Lycopersicon esculentum) tissues, no reduction of the pterin ring was seen after 15 h, although reduction and oxidation of the side chain of pterin-6-aldehyde were readily detected. Second, no label was incorporated into folates when 6-[(3)H]hydroxymethylpterin was fed to cultured Arabidopsis plantlets for 7 d, whereas [(3)H]folate synthesis from p-[(3)H]aminobenzoate was extensive. Third, no NAD(P)H-dependent pterin ring reduction was found in tissue extracts. Genetic evidence showed a similar situation in Escherichia coli: a GTP cyclohydrolase I (folE) mutant, deficient in pterin synthesis, was rescued by dihydropterins but not by the corresponding oxidized forms. Expression of a trypanosomatid pterin reductase (PTR1) enabled rescue of the mutant by oxidized pterins, establishing that E. coli can take up oxidized pterins but cannot reduce them. Similarly, a GTP cyclohydrolase I (fol2) mutant of yeast (Saccharomyces cerevisiae) was rescued by dihydropterins but not by most oxidized pterins, 6-hydroxymethylpterin being an exception. These results show that the capacity to reduce oxidized pterins is not ubiquitous in folate-synthesizing organisms. If it is lacking, folate precursors or breakdown products that become oxidized will permanently exit the metabolically active pterin pool.     

Inhibition of xanthine oxidase by pterins

The effect of a panel of pterins on xanthine oxidase was investigated by measuring formation of urate from xanthine as well as formazan production from nitroblue tetrazolium. The pterin derivatives, depending on their chemical structure, decreased urate as well as formazan generation: 200 μM neopterin and biopterin suppressed urate formation (90% from baseline) and formazan production (80% from baseline) as well. Their reduced forms, 7,8-dihydroneopterin and 5,6,7,8-tetrahydrobiopterin, showed a lesser but still strongly diminishing influence (40% from baseline). Another oxidized pterin namely leukopterin showed only a weak inhibitory effect. Xanthopterin, a known substrate of xanthine oxidase, had a strong effect on urate formation (80% inhibition), but a lesser effect on formazan production (30% reduction). When iron-(III)-EDTA complex was added to the reaction mixture all the effects were more pronounced. Superoxide dismutase, which removes superoxide anion by dismutation intooxygen, decreased formazan production in addition to pterin derivatives and had a small but enhancing effect on urate formation. Also the reductant N-acetylcysteine had an additive effect to pterins to diminish formazan production in a dose-dependent way. The results of our study suggest that depending on their chemical structure pterins reduce superoxide anion generation by xanthine oxidase.     

Partial purification of a plasma membrane flavoprotein and NAD(P)H-oxidoreductase activity

Plasma membrane flavins and pterins are considered to mediate important physiological functions such as blue light photoperception and redox activity. Therefore, the presence of flavins and pterins in the plasma membrane of higher plants was studied together with NAD(P)H-dependent redox activities. Plasma membranes were isolated from the apical hooks of etiolated bean seedlings (Phaseolus vulgaris L. cv. Limburgse Vroege) by aqueous two-phase partitioning. Fluorescence spectroscopy revealed the presence of two chromophores. The first showed excitation maxima at 370 and 460 nm and an emission peak at 520 nm and was identified as a flavin. The second chromophore was probably a pterin molecule with excitation peaks at 290 and 350 nm and emission at 440 nm. Both pigments are considered intrinsic to the plasma membrane since they could not be removed by treatment with hypotonic media containing high salt and low detergent concentrations. The flavin concentration was estimated at about 500 pmol mg^?1 protein. However difficulties were encountered in quantifying the pterin concentrations. Protease treatments indicated that the flavins were non-covalently bound to the proteins. Separation of the plasma membrane proteins after solubilisation by octylglucoside, on an ion exchange system (HPLC, Mono Q), resulted in a distinct protein fraction showing flavin and pterin fluorescence and NADH oxidoreductase activity. The flavin of this fraction was identified as flavin mononucleotide (FMN) by HPLC analysis. Other minor peaks of NADH:acceptor reductase activity were resolved on the column. The presence of distinct NAD(P)H oxidases at the plasma membrane was supported by nucleotide specificity and latency studies using intact vesicles. Our work demonstrates the presence of plasma membrane flavins as intrinsic chromophores, that may function in NAD(P)H-oxidoreductase activity and suggests the presence of plasma membrane bound pterins.     

Biopterin and neopterin in human saliva

Presence of biopterin and neopterin in human saliva was investigated by HPLC after iodine oxidation in acidic medium. Concentrations of biopterin and neopterin (M +/- SEM) were 1.271 +/- 0.254 and 0.358 +/- 0.075 ng per ml, respectively, in saliva of apparently healthy young male adults, ages 20 to 22 years (n = 9). Nearly identical value of the neopterin/biopterin ratio (0.29 +/- 0.07) was obtained for each of these specimens. Monapterin, the L-threo-isomer of neopterin (0.084 +/- 0.022 ng per ml saliva), and other unconjugated pterins such as xanthopterin, 6-hydroxymethylpterin and pterin were also found in the saliva. These pterins were all detectable in saliva of young female adults with similar levels to those of male saliva. Another fluorescent compound which was identical with 7-iso biopterin in retention time on HPLC was observed in all specimens of normal saliva examined.     

Pigment cell differentiation: the relationship between pterin content, allopurinol treatment, and the melanoid gene in axolotls

The effects of allopurinol (an inhibitor of the enzyme xanthine dehydrogenase (XDH] and the melanoid gene on pigment cell differentiation in the axolotl were examined by analyzing pigment components of the xanthophore (pterins). Pterin contents of skin extracts (70% ethanol) from wild type, allopurinol-treated and melanoid axolotls were determined by thin layer chromatography (TLC) and fluorometric scanning of TLC plates. Heights of peaks produced were used as a quantitative measure for pterin content. Results reveal that melanoid animals contain significantly reduced amounts of all seven pterins examined as compared with wild type animals. Allopurinol-treated animals have reduced levels of four pterins (xanthopterin, isoxanthopterin, biopterin and sepiapterin) as compared with the wild type. These findings suggest that the alterations in pterin biosynthetic pathways, either by drug-induced inhibition of XDH activity or by the melanoid gene, produce similar dramatic changes in pigment phenotype which are manifested by alterations in pigment cell differentiation.     

7-substituted pterins in humans with suspected pterin-4a-carbinolamine dehydratase deficiency. Mechanism of formation via non-enzymatic transformation from 6-substituted pterins.

A recently described new form of hyperphenylalaninemia is characterized by the excretion of 7-substituted isomers of biopterin and neopterin and 7-oxo-biopterin in the urine of patients. It has been shown that the 7-substituted isomers of biopterin and neopterin derive from L-tetrahydrobiopterin and D-tetrahydroneopterin and are formed during hydroxylation of phenylalanine to tyrosine with rat liver dehydratase-free phenylalanine hydroxylase. We have now obtained identical results using human phenylalanine hydroxylase. The identity of the pterin formed in vitro and derived from L-tetrahydrobiopterin as 7-(1',2'-dihydroxypropyl)pterin was proven by gas-chromatography mass spectrometry. Tetrahydroneopterin and 6-hydroxymethyltetrahydropterin also are converted to their corresponding 7-substituted isomers and serve as cofactors in the phenylalanine hydroxylase reaction. Dihydroneopterin is converted by dihydrofolate reductase to the tetrahydro form which is biologically active as a cofactor for the aromatic amino acid monooxygenases. The 6-substituted pterin to 7-substituted pterin conversion occurs in the absence of pterin-4a-carbinolamine dehydratase and is shown to be a nonenzymatic process. 7-Tetrahydrobiopterin is both a substrate (cofactor) and a competitive inhibitor with 6-tetrahydrobiopterin (Ki approximately 8 microM) in the phenylalanine hydroxylase reaction. For the first time, the formation of 7-substituted pterins from their 6-substituted isomers has been demonstrated with tyrosine hydroxylase, another important mammalian enzyme which functions in the hydroxylation of phenylalanine and tyrosine.     

Pterin pigment granules are responsible for both broadband light scattering and wavelength selective absorption in the wing scales of pierid butterflies

A small but growing literature indicates that many animal colours are produced by combinations of structural and pigmentary mechanisms. We investigated one such complex colour phenotype: the highly chromatic wing colours of pierid butterflies including oranges, yellows and patterns which appear white to the human eye, but strongly absorb the ultraviolet (UV) wavelengths visible to butterflies. Pierids produce these bright colours using wing scales that contain collections of minute granules. However, to date, no work has directly characterized the molecular composition or optical properties of these granules. We present results that indicate these granules contain pterin pigments. We also find that pterin granules increase light reflection from single wing scales, such that wing scales containing denser granule arrays reflect more light than those with less dense granule collections. As male wing scales contain more pterin granules than those of females, the sexual dichromatism found in many pierid species can be explained by differences in wing scale pterin deposition. Additionally, the colour pattern elements produced by these pterins are known to be important during mating interactions in a number of pierid species. Therefore, we discuss the potential relevance of our results within the framework of sexual selection and colour signal evolution.     

Pterin-based pigmentation in animals

Pterins are one of the major sources of bright coloration in animals. They are produced endogenously, participate in vital physiological processes and serve a variety of signalling functions. Despite their ubiquity in nature, pterin-based pigmentation has received little attention when compared to other major pigment classes. Here, we summarize major aspects relating to pterin pigmentation in animals, from its long history of research to recent genomic studies on the molecular mechanisms underlying its evolution. We argue that pterins have intermediate characteristics (endogenously produced, typically bright) between two well-studied pigment types, melanins (endogenously produced, typically cryptic) and carotenoids (dietary uptake, typically bright), providing unique opportunities to address general questions about the biology of coloration, from the mechanisms that determine how different types of pigmentation evolve to discussions on honest signalling hypotheses. Crucial gaps persist in our knowledge on the molecular basis underlying the production and deposition of pterins. We thus highlight the need for functional studies on systems amenable for laboratory manipulation, but also on systems that exhibit natural variation in pterin pigmentation. The wealth of potential model species, coupled with recent technological and analytical advances, make this a promising time to advance research on pterin-based pigmentation in animals.     

Distribution of charged pterins in nonmethanogenic archaebacteria

Pterin content was surveyed in nine species of nonmethanogenic archaebacteria comprised of six species of halobacteria, two species of Sulfolobus, and one specie of Thermoplasma. The results indicated the presence of the sulfate-containing dimeric pterin sulfohalopterin-2 in three species of halobacteria, Halobacterium marismortui, halobacterial strain GN-1, and Halobacterium volcanii. The phosphate-containing dimeric pterin phosphohalopterin-1 was present in three other species of halobacteria, Halobacterium salinarium, Halobacterium halobium, and Halococcus morrhuae. Evidence is presented that these halopterins exist in the halobacteria as tetrahydropterin derivatives. A positively charged monomeric pterin, solfapterin (erythro-neopterin-3-D-2-deoxy-2-aminoglucopyranoside), was found to be present in Sulfolobus solfataricus and a negatively charged pterin was induced when S. solfataricus was grown in a medium containing homogentisic acid (2,5-dihydroxyphenylacetic acid). This negatively charged pterin was not present when the cells were grown in the normal medium. Another positively charged pterin found in Thermoplasma was determined to be different from solfapterin based on its paper electrophoresis properties. Uncharged pterins were also identified in all of these bacteria, however, no attempt was made to elucidate the structure of these uncharged pterins. Pterin content was found to vary in the different bacteria and to depend on the conditions under which the cells were grown.     

Contributions of pterin and carotenoid pigments to dewlap coloration in two anole species

Animals can acquire bright coloration using a variety of pigmentary and microstructural mechanisms. Reptiles and amphibians are known to use two types of pigments - pterins and carotenoids - to generate their spectrum of colorful red, orange, and yellow hues. Because both pigment classes can confer all of these hues, the relative importance of pterins versus carotenoids in creating these different colors is not always apparent. We studied the carotenoid and pterin content of red and yellow dewlap regions in two neotropical anole species - the brown anole (Norops sagrei) and the ground anole (N. humilis). Pterins (likely drosopterins) and carotenoids (likely xanthophylls) were present in all tissues from all individuals. Pterins were more enriched in the lateral (red) region, and carotenoids more enriched in the midline (yellow) region in N. humilis, but pterins and carotenoids were found in similar concentrations among lateral and midline regions in N. sagrei. These patterns indicate that both carotenoid and pterin pigments are responsible for producing color in the dichromatic dewlaps of these two species, and that in these two species the two pigments interact differently to produce the observed colors.     

The pterin (bactopterin) of carbon monoxide dehydrogenase from Pseudomonas carboxydoflava

Radioactively labeled carbon monoxide (CO) dehydrogenase has been obtained in good yield and purity from Pseudomonas carboxydoflava grown in the presence of [32P]phosphate. One enzyme molecule contained an average of 8.32 molecules of phosphate. The entire phosphate content was confined to 2 molecules of FAD and 2 molecules of a pterin. These were noncovalently bound. Molybdoenzyme cofactors could be extracted into N-methyl formamide; pterins were isolated by thin-layer chromatography. CO dehydrogenase contained a novel pterin, different from molybdopterin, which was also resolved in other bacterial molybdoenzymes. Therefore, it was tentatively named bactopterin. The characteristic features of bactopterin were as follows. A relative molecular mass, Mr, of 730 which was much greater than that of molybdopterin (330) (Mr values refer to molybdenum-free forms of the cofactors; presumably, the latter were also devoid of the sulfhydryl groups contained in the native compounds). A content of 2 molecules of phosphate/molecule compared to only 1 phosphate in molybdopterin. Bactopterin was three times less susceptible to air oxidation than molybdopterin. Native bactopterin was cleaved by perchloric acid into two phosphorous-containing fragments with Mr of 330 and 420. The smaller one is believed to be very similar to molybdopterin, the larger one was not a pterin but probably contained an aromatic structure.     

Reduced 6,6,8-trimethylpterins. Preparation, properties and enzymic reactivities with dihydropteridine reductase, phenylalanine hydroxylase and tyrosine hydroxylase

The substrates of dihydropteridine reductase (EC 1.6.99.7), quinonoid 7,8-dihydro(6 H)pterins, are unstable and decompose in various ways. In attempting to prepare a more stable substrate, 6,6,8-trimethyl-5,6,7,8-tetrahydro(3 H)pterin was synthesised and the quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin derived from it is extremely stable with a half-life in 0.1 M Tris/HCl (pH 7.6, 25 degrees C) of 33 h. Quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin is not a substrate for dihydropteridine reductase but it is reduced non-enzymically by NADH at a significant rate and it is a weak inhibitor of the enzyme: I50 200 microM, pH 7.6, 25 degrees C when using quinonoid 6-methyl-7,8-dihydro(6 H)pterin as substrate. 6,6,8-Trimethyl-5,6,7,8-tetrahydropterin is a cofactor for phenylalanine hydroxylase (EC 1.14.16.1) with an apparent Km of 0.33 mM, but no cofactor activity could be detected with tyrosine hydroxylase (EC 1.14.16.2). Its phenylalanine hydroxylase activity, together with the enhanced stability of quinonoid 6,6,8-trimethyl-7,8-dihydro(6 H)pterin, suggest that it may have potential for the treatment of variant forms of phenylketonuria.     

Inactivation of tyrosine hydroxylase by reduced pterins

Tyrosine hydroxylase [E.C. 1.14.16.2] is inactivated by incubation with its reduced pterin cofactors L-erythro-tetrahydrobiopterin, 2-amino-4-hydroxy-6-methyl-5,6,7,8-tetrahydropterin and 2-amino-4-hydroxy-6,7-dimethyl-5,6,7,8-tetrahydropterin. Each of the two diastereoisomers of L-erythro-tetrahydrobiopterin inactivates tyrosine hydroxylase but the natural (6R) form is much more potent than the unnatural (6S) form at equimolar concentrations. The pterin analog 6-methyl-5-deazatetrahydropterin, which has no cofactor activity, also inactivates the enzyme whereas the oxidized pterins 7,8 dihydrobiopterin and biopterin do not. The inactivation process is both temperature and time dependent and results in a reduction of the Vmax for both tetrahydrobiopterin and tyrosine. Neither tyrosine nor oxygen inactivates tyrosine hydroxylase.     

Inactivation of tyrosinase photoinduced by pterin

Tyrosinase catalyzes in mammals the first and rate-limiting step in the biosynthesis of the melanin, the main pigment of the skin. Pterins, heterocyclic compounds able to photoinduce oxidation of DNA and its components, accumulate in the skin of patients suffering from vitiligo, a chronic depigmentation disorder in which the protection against UV radiation fails due to the lack of melanin. Aqueous solutions of tyrosinase were exposed to UV-A irradiation (350nm) in the presence of pterin, the parent compound of oxidized pterins, under different experimental conditions. The enzyme activity in the irradiated solutions was determined by spectrophotometry and HPLC. In this work, we present data that demonstrate unequivocally that the enzyme is photoinactivated by pterin. The mechanism of the photosensitized process involves an electron transfer from tyrosinase to the triplet excited state of pterin, formed after UV-A excitation of pterin. The biological implications of the results are discussed.     

The molybdoenzyme formylmethanofuran dehydrogenase from Methanosarcina barkeri contains a pterin cofactor

Recently formylmethanofuran dehydrogenase from the archaebacterium Methanosarcina barkeri has been shown to be a novel molybdo-iron-sulfur protein. We report here that the enzyme contains one mol of a bound pterin cofactor/mol molybdenum, similar but not identical to the molybdopterin of milk xanthine oxidase. The two pterins, after oxidation with I2 at pH 2.5, showed identical fluorescence spectra and, after oxidation with permanganate at pH 13, yielded pterin 6-carboxylic acid. They differed, however, in their apparent molecular mass: the pterin of formylmethanofuran dehydrogenase was 400 Da larger than that of milk xanthine oxidase, a property also exhibited by the pterin cofactor of eubacterial molybdoenzymes. A homogeneous formylmethanofuran dehydrogenase preparation was used for these investigations. The enzyme, with a molecular mass of 220 kDa, contained 0.5-0.8 mol molybdenum, 0.6-0.9 mol pterin, 28 +/- 2 mol non-heme iron and 28 +/- 2 mol acid-labile sulfur/mol based on a protein determination with bicinchoninic acid. The specific activity was 175 mumol.min-1.mg-1 (kcat = 640 s-1) assayed with methylviologen (app. Km = 0.02 mM) as artificial electron acceptor. The apparent Km for formylmethanofuran was 0.02 mM.     

Biosynthesis of methanopterin

The biosynthetic pathway for the generation of the methylated pterin in methanopterins was determined for the methanogenic bacteria Methanococcus volta and Methanobacterium formicicum. Extracts of M. volta were found to readily cleave L-7,8-dihydroneopterin to 7,8-dihydro-6-(hydroxymethyl)pterin, which was confirmed to be a precursor of the pterin portion of the methanopterin. [methylene-2H]-6-(Hydroxymethyl)pterin was incorporated into methanopterin by growing cells of M. volta to an extent of 30%. Both the C-11 and C-12 methyl groups of methanopterin originate from [methyl-2H3]methionine, as confirmed by the incorporation of two C2H3 groups into 6-ethyl-7-methylpterin, a pterin-containing fragment derived from methanopterin. Cells grown in the presence of [methylene-2H]-6-(hydroxymethyl)pterin, [ethyl-2H4]-6-[1 (RS)-hydroxyethyl]pterin, [methyl-2H3]-6- (hydroxymethyl)-7-methylpterin, [ethyl-2H4, methyl-2H3]-6-[1 (RS)-hydroxyethyl]-7-methylpterin, and [1-ethyl-3H]-6-[1 (RS)-hydroxyethyl]-7-methylpterin showed that only the non-7-methylated pterins were incorporated into methanopterin. Cells extracts of M. formicicum readily condensed synthetic [methylene-3H]-7,8-H2-6-(hydroxymethyl)pterin-PP with methaniline to generate demethylated methanopterin, which is then methylated to methanopterin by the cell extract in the presence of S-adenosylmethionine. These observations indicate that the pterin portion of methanopterin is biosynthetically derived from 7,8-H2-6-(hydroxymethyl)pterin, which is coupled to methaniline by a pathway analogous to the biosynthesis of folic acid. This pathway for the biosynthesis of methanopterin represents the first example of the modification of the specificity of a coenzyme through a methylation reaction.     

Energy transduction during catalysis by Escherichia coli DNA photolyase.

Native DNA photolyase from Escherichia coli contains 1,5-dihydroFAD (FADH2) plus 5,10-methenyltetrahydropteroylpolyglutamate. Quantum yield and action spectral data for thymine dimer repair were obtained by using a novel multiple turnover approach under aerobic conditions. This method assumes that catalysis proceeds via a (rapid-equilibrium) ordered mechanism with light as the second substrate, as verified in steady state kinetic studies. The action spectrum observed with native enzyme matched its absorption spectrum and an action spectrum simulated based on an energy transfer mechanism where dimer repair is initiated either by direct excitation of FADH2 or by pterin excitation followed by singlet-singlet energy transfer to FADH2. The quantum yield observed for dimer repair with native enzyme (phi Native = 0.722 +/- 0.0414) is similar to that observed with enzyme containing only FADH2 (phi EFADH2 = 0.655 +/- 0.0256), as expected owing to the high efficiency of energy transfer from the natural pterin to FADH2 [EET = 0.92]. The quantum yield observed for dimer repair decreased (2.1-fold) when the natural pterin was partially (68.8%) replaced with 5,10-CH(+)-H4folate (phi obs = 0.342 +/- 0.0149). This is consistent with the energy transfer mechanism (phi calc = 0.411 +/- 0.0118) since a 2-fold lower energy transfer efficiency is observed when the natural pterin is replaced with 5,10-CH(+)-H4folate (EET = 0.46) (Lipman & Jorns, 1992). The action spectrum observed for 5,10-CH(+)-H4folate-supplemented enzyme matched a simulated action spectrum which exhibited a small (5 nm) hypsochromic shift as compared with the absorption spectrum (lambda max = 385 nm).(ABSTRACT TRUNCATED AT 250 WORDS)     

Altered Pterin Patterns in Photoreceptor Mutants of Phycomyces blakesleeanus with Defective madl Gene

Action spectra of photogravitropic equilibrium were measured for the wild type of the lower fungus Phycomyces blakesleeanus and three photobehavioral mutants with defects in the madl gene. The action spectrum for the wild type NRRL1555 had major peaks at 383 and near 460 nm and subsidiary peaks at 365 and 422 nm. The action spectra of the mutants, L1 49 mad1712, L151 mad1714 and L153 mad1716 differed significantly from that of the wild type. One prominent feature of the three mutants was hat the near-UV peaks at 365 and 383 nm, which were not well resolved in the wild type, were of approximately equal height in the mutants and were separated by an extremely sharp valley at 378 nm. The steepness of this valley suggests interaction of multiple receptors. The second prominent feature of the mutants was their enhanced 422 nm peak. The gross changes of the photogravitropic action spectra associated with the madl genotype indicate that the respective gene product acts early in the photosensory transduction chain, very likely at the level of a complex photoreceptor system. Flavins and pterins, two pigment classes which were expected to function as chromophores of the near-UV/blue light photoreceptor system, were analyzed for stage I sporangiophores of the wild-type and the mutant strains by HPLC with fluorescence detection. In the wild-type strain NRRL1555, and also in the three madl mutants, flavins were found to be present at the following concentrations: riboflavin (2.9 × 10^?6 M), FMN (3.8 × 10^?6M) and FAD (1.3 × 10^?6 M). No significant effect of the madl mutations on the flavin content could be discerned. Among the pterins found in the wild type and the madl mutants were biopterin, 6,7-dimethylpterin, neopterin, pterin and xanthopterin. These pterins occurred in all strains in the micromolar range and none of them was significantly reduced in the mutants. However, biopterin, 6,7-dimethylpterin and xanthopterin occurred in some excess in one of the madl mutants. The most significant feature of the madl mutants was that they had almost completely lost one unidentified pterin with a retention time of 18 ? 20 min. Another two unidentified pterins were reduced about twofold in the mutants compared to the wild type. The results suggest an involvement of pterins in the photoreception of near-UV and blue light in Phycomyces.     

Reconstitution of Escherichia coli DNA photolyase with various folate derivatives

DNA photolyase from Escherichia coli contains both flavin and pterin. However, the isolated enzyme is depleted with respect to the pterin chromophore (0.5 mol of pterin/mol of flavin). The extinction coefficient of the pterin chromophore at 360 nm is underestimated by a method used in earlier studies which assumes stoichiometric amounts of pterin and flavin. The extinction coefficient of the pterin chromophore, determined on the basis of its (p-aminobenzoyl)polyglutamate content (epsilon 360 = 25.7 x 10(3) M-1 cm-1), is in good agreement with that expected for a 5,10-methenyltetrahydrofolate derivative. Also consistent with this structure, the pterin chromophore could be reversibly hydrolyzed to yield a 10-formyltetrahydrofolate derivative or reduced to yield a 5-methyltetrahydrofolate derivative. The isolated enzyme could be reconstituted with various folate derivatives to yield enzyme that contained equimolar amounts of pterin and flavin. Similar results were obtained in reconstitution studies with the natural pterin chromophore, with 5,10-methenyltetrahydrofolate, and with 10-formyltetrahydrofolate. The results show that the polyglutamate moiety, previously identified in the natural chromophore, is not critical for binding. Reconstitution with the natural pterin chromophore did not affect catalytic activity. The latter is consistent with our previous studies which show that, although the pterin chromophore acts as a sensitizer in native enzyme, it is not essential for dimer repair which can occur at the same rate under saturating light with flavin (1,5-dihydro-FAD) as the only chromophore.