Yellow Marking and Pteridine Contents in the Integument of Albino Armadillidium vulgare

The albino mutant strain in the woodlice, Armadillidium vulgare, was investigated with respect to the yellow patterns on the dorsal integument. Pigment cells were observed with electron microscope in order to determine the cell types of yellow markings. Quantitative analyses of pteridines in the albino were carried out by HPLC. The result indicated that the albino integument contain sepiapterin, biopterin, pterin, isoxanthopterin as in the wild type and the red mutant strain. The total amount of the four pteridines in the albino was about half as much as that in the red phenotype for both males and females, respectively. Males and females showed almost the same totals and ratios of the four pteridines in the albino and red phenotypes. Therefore, pteridine contents in both phenotypes of A. vulgare may not be related to the activity of androgenic gland hormone. Yellow chromatophores of the albino and red phenotypes were morphologically identical, emitting a yellow fluorescence. These cells contained numerous electron-lucent pigment organelles which were similar to pteridine granules of the wild type.     

Regulation of pteridine biosynthesis and aromatic amino acid hydroxylation inDrosophila melanogaster

The relationship between high dietary levels of aromatic amino acid and regulation of pteridines inDrosophila eyes was examined by measuring changes in pool levels of six pterins in the wild type and mutants and amino acid pool levels in flies that carry mutations for pteridine biosynthesis. The effect upon relative viability and developmental times was also analyzed; relative viability was affected byl-phenylalanine,l-tryptophan, andl-tyrosine in decreasing order and thed-amino acids had little or no effect. The changes in concentration of biopterin, dihydrobiopterin, pterin, sepiapterin, drosopterins, and isoxanthopterin showed a characteristic pattern of increased and/or decreased amounts in response to each of the threel-amino acids. Pterin was regularly increased, and isoxanthopterin decreased.l-Tyrosine caused a 2.1-fold increase in dihydrobiopterin, the largest increase found in this study;l-tryptophan also caused dihydrobiopterin to increase butl-phenylalanine did not. Of 18 eye-color mutants examined, 2 were found to contain high levels of phenylalanine and/or tyrosine,Pu ² andHn ^r3. These two mutants, along withpr ^c4 cn/pr ^m2b cn, were shown to be very sensitive to dietaryl-phenylalanine, indicating that having low levels of certain pteridines makes them susceptible to toxic effects of these amino acids. Therefore, high levels of aromatic amino acids can perturb the balance among pteridine pools, and low levels of some pteridines in mutants are correlated with the inability to withstand the toxic effects of phenylalanine. From the patterns of change in the pteridines we suggest that tetrahydropterin may also be a cofactor for hydroxylation of phenylalanine, along with tetrahydrobiopterin.This work was sponsored in part by a grant from the U.S.-Spain Joint Committee for Scientific and Technological Cooperation.     

Multiple function of pteridines in Drosophila: The fluorescence of the ejaculatory bulb in Drosophila melanogaster

It is demonstrated that the strong fluorescence of the ejaculatory bulb of Drosophila melanogaster males is caused by the presence of pteridines. The pteridine composition in the bulb is affected by the mutations ry² and ma-l^F1 in which isoxanthopterin has also been detected. Our results show that the bulbs of wild-type and white-eyed mutant males possess the same pteridines. Some data suggest that the bulbal pteridines originate from the testis region. Partly on the basis of former histochemical findings it is suggested that in the bulbal cavity the pH is high favouring the fluorescent dihydro-states of the pteridines present. All these and additional literature data on the ejaculatory bulb are discussed in connection with various biological processes. Some internal larval structures in which pteridines play or might play a functional role were found to present autofluorescence.     

Pigment patterns in mutants affecting the biosynthesis of pteridines and xanthommatin in Drosophila melanogaster

Eye-color mutants of Drosophila melanogaster have been analyzed for their pigment content and related metabolites. Xanthommatin and dihydroxanthommatin (pigments causing brown eye color) were measured after selective extraction in acidified butanol. Pteridines (pigments causing red eye color) were quantitated after separation of 28 spots by thin-layer chromatography, most of which are pteridines and a few of which are fluorescent metabolites from the xanthommatin pathway. Pigment patterns have been studied in 45 loci. The pteridine pathway ramifies into two double branches giving rise to isoxanthopterin, drosopterins, and biopterin as final products. The regulatory relationship among the branches and the metabolic blockage of the mutants are discussed. The Hn locus is proposed to regulate pteridine synthesis in a step between pyruvoyltetrahydropterin and dihydropterin. The results also indicate that the synthesis and accumulation of xanthommatin in the eyes might be related to the synthesis of pteridines.Support for this work was provided to J.F. in part by a grant from the Ministerio de Universidades e Investigación (Spain) and to F.J.S. by a grant from the Ministerio de Educación y Ciencia (Spain).     

Body Colouration Related to the Deposition of Pteridines in the Epidermis and Other Organs of Dysdercus Species (Insecta; Heteroptera: Pyrrhocoridae)

In epidermal cells of Dysdercus species, two types of pigment granules were detected using both light and electron microscopic methods; the granules differed in colour, size, distribution and osmiophily. Red (D. intermedius) and yellow (D. nigrofasciatus) epidermal cells contained both types of granules, but in white cells only one type was present. Chromatographic analyses showed that the larger granules were more transparent to electrons, and contained uric acid, while the smaller ones contained erythropterin, became coloured later, and were osmiophilic. In accordance with these findings, in the testes of D. intermedius both granule types were present, but in the testes of D. nigrofasciatus only those containing erythropterin. The number of granules per cell varied with the species and developmental stage. Epidermal cells of D. intermedius contained more erythropterin granules than those of D. nigrofasciatus, the reverse occurring in the testes. This pattern corresponded to the visible colouration of the insects. As the development progressed, a decrease of the red and an increase of the white granules took place in the coloured epidermal cells. The main amount of pteridines, except isoxanthopterin, was accumulated in the integument of the insects studied. Chemical and histological data showed the influence of pterins on insect colouration. Orange, yellow and red colours were caused by different amounts of erythropterin containing special granules in the epidermal cells, and the white colour only by uric acid containing granules. A partial melanization of the cuticle resulted in dark spots below which pteridines were deposited additionally in the epidermal cells. Considering erythropterin, the quantitative chemical data are in accordance with the histological ones and also with the colouration externally visible. Intensively red coloured stages had a higher concentration of erythropterin and more corresponding granules than the light-red coloured ones; the lowest amount was found in yellow coloured insects. Therefore, the pigmentation effect of erythropterin, which reached from yellow to orange and red, depended on its concentration and played the most important role in the colouration of the Dysdercus species studied, uric acid was responsible for the colouration of the white parts of the integument.     

Pteridine concentrations differ between insectary-reared and field-collected Anopheles albimanus mosquitoes of the same physiological age

Biopterin, isoxanthopterin and 6-pterincarboxylic acid were identified in the head of the malaria vector mosquito Anopheles albimanus Weidemann (Diptera: Culicidae) by HPLC. Total pteridine concentrations (TPC) were estimated in heads, body parts (BP: abdomen, legs and wings) and whole bodies of insectary-reared and field-collected females, by spectrofluorometry, to investigate whether they could be used for age determination. Pteridine concentrations diminished with age in both mosquito groups. TPC correlated with chronological age in insectary-reared sugar-fed females (heads: r2 = 0.35, BP: r2 = 0.34, P < 0.001), but lower correlation occurred in blood-fed females (heads: r2 = 0.22, BP: r2 = 0.27). TPC differed among females of the same age fed with blood at different times (P < 0.05), indicating that bloodmeals modify the diminution rate of pteridines with age. Nevertheless, a polynomial significant correlation was documented for TPC and the number of ovipositions (heads: r2 = 0.24, BP: r2 = 0.27, whole body: r2 = 0.52, P < 0.001) in insectary-reared mosquitoes. This correlation was lower in field-collected mosquitoes (heads: r2 = 0.14, BP: r2 = 0.10, P < 0.05), which showed a remarkable pteridine increase in one-parous females. The correlation of TPC in whole body with physiological age was much less (r2 = 0.03). These observations indicate that TPC determination by spectrofluorometry is not a reliable method to estimate the age of An. albimanus females from the feral population.     

STUDIES ON FINE STRUCTURE AND CYTOCHEMICAL PROPERTIES OF ERYTHROPHORES IN SWORDTAIL, XIPHOPHORUS HELLERI, WITH SPECIAL REFERENCE TO THEIR PIGMENT GRANULES (PTERINOSOMES)

The fine structure and the composition of pteridine pigments of erythrophores in adults of the swordtail fish, Xiphophorus helleri, were studied by means of cytochemistry, paper chromatography, ionophoresis, centrifugal fractionation, and electron microscopy. It was found that water-soluble pigments of erythrophores consisted exclusively of pteridine derivatives including large amounts of drosopterin, isodrosopterin, neodrosopterin, and moderate amounts of sepiapterin. While these substances were responsible for red pigmentation, moderate quantities of colorless pteridines, biopterin, Rana-chrome 3, xanthopterin, isoxanthopterin, and others, were also detectable. The ultrastructure of the erythrophore is characterized by numerous pigment granules and a well developed tubular endoplasmic reticulum. The former consist of a three-layered limiting membrane and inner lamellae which appear to be whorl-like due to a concentric arrangement of parallel membranes. All of the mentioned pteridines are primarily contained in this organelle which is designated, accordingly, "pterinosome." The possible functions of erythrophores and pterinosomes are discussed in the light of their structure and pigmentary constitution.     

Genetic and biochemical analysis of brown eye mutation in Drosophila nasuta nasuta and Drosophila nasuta albomicans

By analyzing the progeny of crosses involving brown eye mutants and the wild types in two members of Drosophila nasuta subgroup namely D. n. nasuta and D. n. albomicans we could show that the mutant gene is recessive, located in the chromosome 2 and the alleles of this gene are present at different loci. A study of fitness in the eye color mutants in comparison with the wild types revealed that D. n. nasuta mutant has higher viability at both 25 ± 1°C and ambient temperatures; while D. n. albomicans mutant has faster rate of development only at 25 ± 1°C. Quantitative analysis of eye pigments in the mutants revealed that there is biosynthesis of both pteridines and xanthommatins unlike in bw/bw of D. melanogaster, where only xanthommatins are synthesized. In both the species, the pteridine quantities in mutants are similar; whereas xanthommatin quantity in is 10 times higher than that of . Further, the F₁ progeny of intraspecific crosses (wild type X mutant) are found to have high amounts of pteridine, even when compared with parental wild type. This revised version was published online in July 2006 with corrections to the Cover Date.     

Die radioaktiven strahlungsmuster der flügel von Colias myrmidons Esper,Colias australis Verity und Colias hyale Linnaeus (Lepidoptera : Pieridae) nach pupalen 35S-natriumsulfat-injektionen

The pigment areas of the wings of Colias hyale L., C. australis Verity and Colias myrmidons Esper are investigated autoradiographically by pupal injections of ³⁵S-Sodium sulphate. The red erythropterin areas radiate more than the colourless leucopterin and isoxanthopterin ones as well as the yellow sepiapterin and xanthopterin parts. The dark districts take up the isotope differently.     

Correlation of guanosine triphosphate cyclohydrolase activity and the synthesis of pterins in Drosophila melanogaster

The enzyme guanosine triphosphate cyclohydrolase (GTP cyclohydrolase), which in bacteria is known to be the first enzyme in the biosynthetic pathway for the synthesis of pteridines, has been discovered in extracts of Drosophila melanogaster. Most of the enzyme (80%) is located in the head of the adult fly. An analysis of enzyme activity during development in Drosophila has revealed the presence of a relatively small peak of activity at pupariation and a much larger peak that appears at about the time of eclosion. Enzyme activity declines rapidly as the fly ages. Analyses for the production of the typical pteridine pigments of Drosophila have indicated that the small peak of GTP cyclohydrolase activity evident at pupariation coincides with the appearance of isoxanthopterin, sepiapterin, and pterin, and the larger peak at eclosion roughly corresponds to the accumulation of drosopterin as well as to the appearance in larger amounts of pterin and sepiapterin. These observations strongly suggest that in Drosophila, like bacteria, GTP cyclohydrolase is involved in the biosynthesis of pteridines. Analyses of a variety of zeste mutants of Drosophila melanogaster have shown that these mutants all contain GTP cyclohydrolase equal approximately to the amount found in the wild-type fly. These observations do not support the suggestions made by Rasmusson et al. (1973) that zeste is the structural locus for GTP cyclohydrolase.This work was supported by research grants from the National Institutes of Health (AM03442) and the National Science Foundation (GB33929).     

Effect of Isoxanthopterin on the Activity of Transforming DNA in <Emphasis Type="Italic">Bacillus subtilis</Emphasis>

WHEN an aqueous solution of the pteridine, isoxanthopterin, is incubated with salmon sperm DNA, an unstable association of the pteridine with the DNA can be demonstrated by chromatography on “Sephadex”¹. One interesting property of the complex is that the fluorescence of isoxanthopterin is enhanced ten-fold, a phenomenon which has been ascribed, in other cases, to intercalation of a planar heterocycle between base pairs in the DNA double helix². If such an intimate positioning occurred, it might be possible to disrupt the structure of DNA by using radiant energy of a wavelength (345 nm) which would be absorbed by the pteridine but not by the DNA. In a living organism the result would be expressed as a mutational event, or in the extreme case, cell death. We have tested this hypothesis using a sensitive biological indicator—bacterial transformation—to observe effects at specific gene loci. For experimental convenience, changes in DNA were detected by changes in transforming ability of wild type DNA.     

Mechanism of suppression in Drosophila. V. Localization of the purple mutant of Drosophila melanogaster in the pteridine biosynthetic pathway

The suppressible eye color mutant purple (pr) of Drosophila melanogaster is known to be unable to synthesize a wild-type complement of pteridine eye pigments. This study measures the reduced levels of drosopterins, sepiapterin, and an unidentified presumed pteridine in pr and pr ^bw. Pteridine analyses in double mutants combining pr with one of three other eye color mutants sepia, Henna-recessive³, and prune², suggest that the metabolic block in pr occurs prior to sepiapterin biosynthesis. Measurements of GTP and GTP cyclohydrolase in pr showed wild-type levels and indicate the metabolic block in pr to be at one of the steps converting dihydroneopterin triphosphate to sepiapterin. Quantitation of pteridines in suppressed purple [su(s) ²; pr and pr; su(pr) ^e3] shows restoration of pteridines to wild-type or nearly wild-type levels.T. G. W. is a predoctoral trainee supported by Grant GM 1974 from the National Institute of General Medical Sciences, National Institutes of Health.The Oak Ridge National Laboratory is operated by Union Carbide Corporation for the U.S. Energy Research and Development Administration.     

Involvement of Pteridines in the Body Coloration of the Isopod Armadillidium vulgare

The pteridine content was measured as a function of age in Armadillidium vulgare, and the fine structure of the pteridine-containing granules in the integument was examined in relation to pteridine content. Yellow chromatophores are an essential component of the cream-markings, which are a defining feature of the female A. vulgare. Four kinds of pteridines in the integument including a yellow pigment (sepiapterin) were determined by HPLC. The body color of the red phenotype of A. vulgare varies from dark red to yellowish red and was formerly thought to be due to the quality and quantity of ommochrome pigment. Our analysis of the pteridine content in the integument of this phenotype revealed a significant change in sepiapterin content per body weight with age. Sepiapterin content per body weight decreased gradually with age, while that of biopterin tended to increase with age. Ultrastructural observations of the pigment granules in the yellow chromatophores revealed a corresponding change in the fine structure of pigment granules. In the older adults, some of the electron-dense fibrous materials in the pteridine-containing granules was concentrically arranged, and in the younger adults, most of pteridine-containing granules were electron-lucent. The role of pteridine quality in determining the structure of pteridine-containing granules is discussed.     

Pigment pattern formation in the quail mutant of the silkworm, Bombyx mori: parallel increase of pteridine biosynthesis and pigmentation of melanin and ommochromes

The larval pigment pattern in the silkworm, Bombyx mori, is formed by melanin, ommochromes and pteridines. During development all these pigments are synthesized autonomously, and possibly also with mutual interaction between them, to yield unique pigment patterns. In order to find the key trigger for such pigment pattern formation, developmental changes in pteridine biosynthesis were studied using the quail mutant (q/q), which has darker larval marks formed by melanin and an abundance of ommochromes in the integument. In the current study, emphasis has been placed on the analysis of GTP-cyclohydrolase I (GTP-CH I), which is a key enzyme for the biosynthesis of pteridines, during the development of the silkworm. Results of Northern blotting showed that in the quail mutant strong signals of GTP-CH I mRNA appeared around each period of ecdysis, while no such signals appeared in the background strain (+q/q) used. Also, both GTP-CH I activities and pteridine content were higher in the quail mutant compared with the background strain. These results strongly suggest that pteridine biosynthesis is closely linked to the formation of melanin and ommochromes. It is also suggested here that in the silkworm a recessive gene (q) may be involved in the regulation of its pigment pattern formation.     

Zur genphysiologischen Analyse der Pterine im Insektenauge (Drosophila melanogaster undCalliphora erythrocephala)

Summary The action of genew ^bl andw ^m4 on the eye-pteridines ofDrosophila melanogaster under the influence of different temperatures is studied. Whereas inw ^bl the temperature unfavorable for the synthesis of the eye-pteridines (25°C) results in a marked decrease of all pteridines, inw ^m4 the unfavorable temperature (18°C) results in a decrease of the red pteridine, but causes an accumulation of the tetrahydrobiopterin-compound and the yellow pteridine. InCalliphora erythrocephala genew causes accumulation of the yellow pteridine but a marked decrease of the tetrahydrobiopterin-compound. The relationships between the tetrahydrobiopterin-compound, the yellow pteridine (which probably is the dihydro-product) and the red colored end-product are discussed.

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Age determination in the adult screwworm (Diptera: Calliphoridae) by pteridine levels

Fluorescence spectrophotometry was used to assess the possible use of pteridines in the compound eyes to estimate the age of adult screwworms, Cochliomyia hominivorax (Coquerel). Factors affecting the quantities of pteridines include temperature and head size. No difference in pteridine levels was found among flies fed protein or carbohydrate. A regression model for estimating the age of female screwworms was constructed. The model uses head capsule size and relative pteridine quantities and assumes a constant body temperature of 30 degrees C. This regression formula has an r2 of 0.74. Our study extends the use of pteridine accumulation for age determination from obligate sanguinivorous Diptera to an autogenous species that feeds facultatively on nectar and wound exudates. The technique appears to provide a valid means to determine age of these flies.     

Environmental control of seasonal variation in the butterfly Colias eurytheme: Effects of photoperiod and temperature on pteridine pigmentation

Photoperiod and temperature were examined for their effects on the four major pteridine components of the wings of Colias eurytheme. Orange individuals show reduced pteridine pigmentation in response to short photoperiods, but make no significant adjustment of pigmentation as a result of varying temperatures. ‘Alba’ females, on the other hand, respond to temperature, but levels of the coloured pteridines are apparently insufficient for there to be an observable effect of photoperiod. Low temperature causes an increase in the concentrations of the coloured pteridines in these white females. The action of photoperiod in reducing resources committed to pigmentation in orange animals is consistent with the notion that it is advantageous to free nitrogen for other purposes under thermally stringent conditions. The response of the ‘alba’ females to temperature is more puzzling, but it may reflect the absence of selection for the canalization of this phenotype against the effects of temperature.     

MORPHOLOGICAL AND BIOCHEMICAL CHARACTERIZATION OF GOLDFISH ERYTHROPHORES AND THEIR PTERINOSOMES

The fine structure of integumental erythrophores and the intracellular location of pteridine and carotenoid pigments in adult goldfish, Carassius auratus, were studied by means of cytochemistry, paper and thin-layer chromatography, ionophoresis, density-gradient centrifugal fractionation, and electron microscopy. The ultrastructure of erythrophores is characterized by large numbers of somewhat ellipsoidal pigment granules and a well-developed system of tubules which resembles endoplasmic reticulum. The combined morphological and biochemical approaches show that pteridine pigments of erythrophores are located characteristically in pigment granules and are the primary yellow pigments of these organelles. Accordingly, this organelle is considered to be the "pterinosome" which was originally found in swordtail erythrophores. Major pteridines obtainable from goldfish pterinosomes are sepiapterin, 7-hydroxybiopterin, isoxanthopterin, and 6-carboxyisoxanthopterin. Density-gradient fractions indicate that carotenoids are mostly associated with the endoplasmic reticulum. Both tyrosinase and possibly a tyrosinase inhibitor containing sulfhydryl groups are present in the pterinosome. The possible existence of a tyrosinase inhibitor is suggested by the marked increase of tyrosinase activity upon the addition of iodoacetamide or p-chloromercuribenzoic acid. In the light of their fine structure, pigmentary composition, and enzymatic properties, the erythrophores and pterinosomes are discussed with respect to their probable functions and their relationship to melanophores.     

Insulin receptor mutation results in insulin resistance and hyperinsulinemia but does not exacerbate Alzheimer's-like phenotypes in mice

tRNA-guanine transglycosylases (TGTs) are responsible for incorporating 7-deazaguanine-modified bases into certain tRNAs in eubacteria (preQ₁), eukarya (queuine) and archaea (preQ₀). In each kingdom, the specific modified base is different. We have found that the eubacterial and eukaryal TGTs have evolved to be quite specific for their cognate heterocyclic base and that Cys145 (Escherichia coli) is important in recognizing the amino methyl side chain of preQ₁ (Chen et al., Nuc. Acids Res. 39 (2011) 2834 [15]). A series of mutants of the E. coli TGT have been constructed to probe the role of three other active site amino acids in the differential recognition of heterocyclic substrates. These mutants have also been used to probe the differential inhibition of E. coli versus human TGTs by pteridines. The results indicate that mutation of these active site amino acids can “open up” the active site, allowing for the binding of competitive pteridine inhibitors. However, even the “best” of these mutants still does not recognize queuine at concentrations up to 50 μM, suggesting that other changes are necessary to adapt the eubacterial TGT to incorporate queuine into RNA. The pteridine inhibition results are consistent with an earlier hypothesis that pteridines may regulate eukaryal TGT activity (Jacobson et al., Nuc. Acids Res. 9 (1981) 2351 [8]).