The effects of molybate, tungstate and lxd on aldehyde oxidase and xanthine dehydrogenase in Drosophila melanogaster

The effects of dietary sodium molybdate and sodium tungstate on eye color and aldehyde oxidase and xanthine dehydrogenase activities have been determined in Drosophila melanogaster. Dietary sodium tungstate administration has been used as a screening procedure to identify two new lxd alleles. Tungstate administration results in increased frequencies of "brown-eyed" flies in lxd stocks and a coordinate decrease in AO and XDH activities in all genotypes tested. The two new lxd alleles affect AO and XDH in a qualitatively but not quantitatively similar fashion to the original lxd allele. AO and XDH activity and AO-CRM levels appear much more sensitive to mutational perturbations of this gene-enzyme than do XDH-CRM levels in the genotypes tested.     

Genetic control of aldehyde oxidase activity and cross-reacting-material in Drosophila melanogaster.

Four different genes are known to affect aldehyde oxidase activity (AO) in Drosophila melanogaster. Mutants at each of these loci eliminate AO activity and simultaneously eliminate detectable AO-crossing reacting material (AO-CRM) even though only one is the structural gene for AO (Aldoxn). The other three genes (cin1, lxd and mal) coordinately "control" the levels of activity of AO and two related enzymes, xanthine dehydrogenase (XDH) and pyridoxal oxidase (PO). Contrary to their effects on AO-CRM, neither of these three mutants eliminate XDH-CRM. A model of interaction of these enzymes and genes controlling their activities is discussed.     

Xanthine dehydrogenase (XDH) cross-reacting material in mutants of Drosophila melanogaster deficient in XDH activity

Rocket immunoelectrophoresis was used to estimate xanthine dehydrogenase cross-reacting material (XDH-CRM) in strains containing the cin ¹ and cin ⁹ mutant genes, which are deficient in XDH enzymatic activity. CRM levels were determined as percentages of CRM in the Oregon-R wild-type strain. The mutant strains contain 72 and 76% of Oregon-R CRM, respectively. CRM levels in strains containing the XDH-deficient mutant genes lxd and mal are 93 and 105%, respectively. The high levels of CRM in these four mutant strains indicate that the primary effects of the mutant genes are on the function of XDH protein rather than its accumulation.This research was supported by a grant from the Natural Sciences and Engineering Research Council of Canada to L. W. B.     

Post-Translational Modification as a Potential Explanation of High Levels of Enzyme Polymorphism: Xanthine Dehydrogenase and Aldehyde Oxidase in DROSOPHILA MELANOGASTER

Xanthine dehydrogenase (XDH) and aldehyde oxidase (AO) in Drosophila melanogaster require for their activity the action of another unlinked locus, maroon-like (mal). While the XDH and AO loci are on chromosome 3, mal maps to the X chromosome. Although functional mal gene product is required for XDH and AO activity, it is possible to examine the effects of mutant mal alleles in those cases when pairs of mutants complement to produce a partial restoration of activity. To test whether mal mediates a post-translational modification of the XDH and AO proteins, we constructed several mal heteroallelic complementing stocks of Drosophila in which the third chromosomes were co-isogenic. Since all lines were co-isogenic for the XDH and AO structural genes, any variation in these enzymes seen when comparing these stocks must have been produced by post-translational modification by mal. We examined the XDH and AO proteins in these stocks by gel-sieving electrophoresis, a procedure that permits independent characterization of a protein's charge and shape, and is capable of discriminating many variants not detected in routine electrophoresis. In every mal heteroallelic combination, there is a significant alteration in protein shape, when compared to wild type. The magnitude of differences in shape of XDH and AO is correlated both with differences in their enzyme activities and with differences in their thermal stabilities. As the body of this variation appears heritable, any functional differences resulting from these variants are of real genetic and evolutionary interest. A similar post-translational modification of XDH and AO by yet another locus, lxd, was subsequently documented in an analogous manner. The pattern of electrophoretic differences produced by mal and lxd modification is similar to that reported for electrophoretic "alleles" of XDH in natural populations. The implication is that heritable variation in electrophoretic mobility at these two enzyme loci, and potentially at other loci, is not necessarily allelic to the structural gene loci.     

Aldehyde oxidases of Drosophila: Contributions of several enzymes to observed activity patterns

At least four enzymes contribute to histochemically, electrophoretically, or spectrophotometrically detectable aldehyde oxidase (AO) activity in Drosophila melanogaster. The one we designate AO-1 contributes the majority of activity measured in extracts of whole flies. Pyridoxal oxidase (PO) is also a broad range AO. It is prominent only in midgut and Malpighian tubules, where it apparently accounts for a substantial fraction of total AO activity. The tissue distributions of these enzymes are clearly disparate despite close linkage of their structural loci and parallel dependence on the mal, lxd, and cin loci. A similarly related enzyme, xanthine dehydrogenase (XDH), is detected as an AO only in electrophoretic gels. A fourth broad range AO, not dependent on mal, lxd, and cin, is confined to the ejaculatory bulb. A similar array of AO isozymes is present in phylogenetically distant Drosophila species.This work was supported by NIH Grant 2 RO1 HD 10723.     

Molybdoenzymes in Drosophila. IV. Further characterization of the cinnamon phenotype

Summary Mutations at the cin gene display drastically lowered levels of the molybdoenzymes, xanthine dehydrogenase (XDH) and aldehyde oxidase (AO), and lack pyridoxal oxidase (PO) and sulfite oxidase (SO) activities. Certain mutations at cin also display varying degrees of female sterility, which is maternally affected. Here we characterize five new cin alleles with respect to the molybdoenzyme activities as well as the molybdenum cofactor, commonly required for molybdoenzyme activity. In complementing cin heterozygotes we find that, in addition to the previously reported unusually high levels of XDH and AO activities, there are unusually elevated levels of SO activity, as well as complementation for PO activity. The levels of immunologically crossreacting material in such heterozygotes indicate that the elevated levels of molybdoenzyme activities cannot be due to increases in the number of enzyme molecules. Measurements of the level of molybdenum cofactor activity normally present in XDH, AO, PO, and SO point to the possibility that a larger fraction of the enzyme molecules are active in these heterozygotes. The possible role of SO with respect to cinnamon's female sterility is also discussed.     

Evidence for Linkage Disequilibrium Maintained by Selection in Two Natural Populations of DROSOPHILA SUBOBSCURA

One island and one mainland population of Drosophila subobscura were found polymorphic at the XDH (xanthine dehydrogenase) and the AO (aldehyde oxidase) loci. It was observed that one allele at the XDH locus, which has a low frequency in both populations, is nonrandomly associated with the alleles at the AO locus. Two lines of evidence support the thesis that this linkage disequilibrium is due to epistasis rather than random drift: (1) D or r, measures of the disequilibrium, have the same sign and magnitude in both populations. (2) The linkage disequilibrium is not due to inversions. Inversions segregating on the chromosome carrying XDH and AO have been separated into two classes, between which exchange of alleles at the two loci is suppressed. Linkage disequilibrium for XDH and AO was observed within each class. In the absence of any exchange of alleles, these disequilibria must have arisen and been maintained independently. The suggestion is made that the epistatic disequilibrium results from the close structural and physiological relationship which exists between the two enzymes.     

A rapid selection technique for detecting meiotic X-chromosomal nondisjunction in Drosophila melanogaster

A chemical selection technique is described for the rapid and easy detection of X-chromosomal nondisjunction in females of Drosophila melanogaster. The method employs the maroon-like (ma-1) gene and depends on the known hypersensitivity of ma-1 flies lacking xanthine dehydrogenase (XDH) activity to killing by treatments with aqueous purine solutions. Parental females, heterozygous for two ma-1 alleles which produce 25% of wild-type XDH activity, are mated to males bearing a non-complementing ma-1 allele. After treatment of developing cultures with a 6-mM purine solution, only those individuals possessing 25% or greater XDH activity survive to eclosion. The present report demonstrates that this system can be used to measure accurately the spontaneous frequency of X-chromosomal nondisjunction as well as increased maternal nondisjunction produced by cold treatment, X-irradiation or meiotic mutants. The rapidity and ease of this system suggest that it can be used for the routine monitoring of environmental agents for those which produce this class of meiotic segregational anomalies.     

Allelic Variants at the Xanthine Dehydrogenase Locus Affecting Enzyme Activity in DROSOPHILA PSEUDOOBSCURA

Quantitative studies of enzyme activity on gels show about four-fold differences in enzyme activity of different xanthine dehydrogenase (XDH ) alleles. At least three different activity classes could be distinguished among the 23 strains isogenic for the XDH locus. No association of high activity with the high frequency electromorph was observed; instead, the low frequency electromorphs had 0.5 to 2 times the activity of the high frequency electromorph. The frequency of low activity, high activity and intermediate activity XDH alleles among these 23 lines is 0.13, 0.09, and 0.78, respectively.     

Molybdenum hydroxylases in Drosophila. III. Further characterization of the low xanthine dehydrogenase gene

The biochemical effects of several newly induced low xanthine dehydrogenase (lxd) mutations in Drosophila melanogaster were investigated. When homozygous, all lxd alleles simultaneously interrupt each of the molybdoenzyme activities to approximately the same levels: xanthine dehydrogenase, 25%; aldehyde oxidase, 12%; pyridoxal oxidase, 0%; and sulfite oxidase, 2% as compared to the wild type. In order to evaluate potentially small complementation or dosage effects, mutant stains were made coisogenic for 3R. These enzymes require a molybdenum cofactor, and lxd cofactor levels are also reduced to less than 10% of the wild type. These low levels of molybdoenzyme activities and cofactor activity are maintained throughout development from late larval to adult stages. The lxd alleles exhibit a dosage-dependent effect on molybdoenzyme activities, indicating that these mutants are leaky for wild-type function. In addition, cofactor activity is dependent upon the number of lxd ⁺ genes present. The lxd mutation results in the production of more thermolabile XDH and AO enzyme activities, but this thermolability is not transferred with the cofactor to a reconstituted Neurospora molybdoenzyme. The lxd gene is localized to salivary region 68 A4-9, 0.1 map unit distal to the superoxide dismutase (Sod) gene.     

Aldehyde oxidase cross-reacting material in the Aldox n,cin, mal,and lxd mutants of Drosophila melanogaster

Rocket immunoelectrophoresis was used to estimate aldehyde oxidase cross-reacting material (AO-CRM) in larval hemolymph and adult fly extracts in mutants with reduced AO enzymatic activity. Hemolymph of larvae homozygous for Aldox ⁿ, which is a mutation of the presumed structural gene for AO, contains 30% of the wild-type CRM. The demonstration of AO-CRM in Aldox ⁿ larval hemolymph is surprising since this genotype has been reported to lack CRM. By contrast, adult Aldox ⁿ flies lack detectable CRM. The other AO-deficient mutants that were examined are cin, mal, and lxd; each has appreciable levels of CRM in both larval hemolymph and adult extracts. Detection of CRM in these mutants helps to clarify conflicting reports in the literature.This research was supported by a grant from the Natural Sciences and Engineering Research Council of Canada to L.W.B.     

Dynamic Properties of Endogenous Phytochrome A in Arabidopsis Seedlings

The flacca tomato (Lycopersicon esculentum) mutant displays a wilty phenotype as a result of abscisic acid (ABA) deficiency. The Mo cofactor (MoCo)-containing aldehyde oxidases (AO; EC 1.2.3.1) are thought to play a role in the final oxidation step required for ABA biosynthesis. AO and related MoCo-containing enzymes xanthine dehydrogenase (XDH; EC 1.2.1.37) and nitrate reductase (EC 1.6.6.1) were examined in extracts of the flacca tomato genotype and of wild-type (WT) roots and shoots. The levels of MoCo were found to be similar in both genotypes. No significant XDH or AO (MoCo-containing hydroxylases) activities were detected in flacca leaves; however, the mutant exhibited considerable MoCo-containing hydroxylase activity in the roots, which contained notable amounts of ABA. Native western blots probed with an antibody to MoCo-containing hydroxylases revealed substantial, albeit reduced, levels of cross-reactive protein in the flacca mutant shoots and roots. The ABA xylem-loading rate was significantly lower than that in the WT, indicating that the flacca is also defective in ABA transport to the shoot. Significantly, in vitro sulfurylation with Na₂S reactivated preexisting XDH and AO proteins in extracts from flacca, particularly from the shoots, and superinduced the basal-level activity in the WT extracts. The results indicate that in flacca, MoCo-sulfurylase activity is impaired in a tissue-dependent manner.     

Acetaldehyde utilization and toxicity in Drosophila adults lacking alcohol dehydrogenase or aldehyde oxidase

Metabolic utilization and toxicity of acetaldehyde were studied in flies lacking alcohol dehydrogenase (ADH), aldehyde oxidase (AO), or both functions. Prior to the experiments, mutant alleles Adhn4 and mal were transferred to the same genetic background by 10 successive backcrosses. By comparison with wild-type flies, various deleterious, pleiotropic effects could be attributed to the mal allele but not to Adhn4. Of the four genotypes studied (mal, Adhn4, mal Adhn4, and wild), all were able to use acetaldehyde as a resource in a similar way. In spite of its high toxicity, acetaldehyde appeared a better resource than ethanol. Flies treated with intermediate acetaldehyde concentrations (around 0.5%) exhibited a very high interindividual heterogeneity which could reflect a physiological adaptation occurring as a consequence of the aldehyde treatment. Toxicity tests showed that ADH-negative flies were more sensitive to acetaldehyde than wild type, but this is most likely explained by the transformation of the aldehyde into alcohol. Our results show that the aldehyde metabolizing enzyme (AME) system in Drosophila is neither ADH nor AO. The existence of an aldehyde dehydrogenase is plausible.     

Gene expression in Drosophila: post-translational modification of aldehyde oxidase and xanthine dehydrogenase.

Summary Maroon-like homozygotes are completely deficient for xanthine dehydrogenase (XDH) and aldehyde oxidase (AO), however ma-l is not a structural locus for either enzyme. Quantitative immunoelectrophoresis of ma-l and wild type extracts suggests that the ma-l function must be post-translational. To determine whether the ma-l function involves some direct physical changes in XDH and/or AO the enyzmes were characterized with respect to temperature sensitivity and behavior in gel sieving electrophoresis. Since the XDH and AO from complementary ma-l heterozygotes is more thermolabile and different in shape from wild type XDH and AO, we conclude that ma-l is involved in a post-translational modification of these enzymes.     

An analysis of xanthine dehydrogenase negative mutants of the rosy locus in Drosophila melanogaster.

Eighteen alleles of the rosy locus in Drosophila melanogaster were characterized to identify putative nonsense mutants. Seven alleles exhibited no evidence of intragenic complementation, no evidence of immunological complementation, no evidence of immunological cross-reactivity to antibodies elicited by wild type xanthine dehydrogenase (XDH), and of course were completely deficient in measurable XDH activity. It is possible that one or more of these highly negative ry alleles are nonsense mutants. The remaining eleven ry alleles code for XDH molecules that retain some antigenic similarities to the wild type enzyme as assessed by immunoelectrophoresis and six of these eleven were capable of intragenic complementation.     

Characterization of acid phosphatase-1 null activity mutants of Drosophila melanogaster

A complementation analysis was performed on 15 Acph-1 ⁿ alleles. Only three of these alleles proved to be nonleaky and to exhibit no evidence of complementation. These were then tested immunologically to determine their level of antigenically cross-reacting material (CRM). Their CRM levels were virtually zero, as compared to low, but positive, levels for two other homozygous Acph-1 ⁿ mutants and considerably higher levels for heteroallelic combinations of some of the leaky alleles. Acid phosphatase-1 enzyme subunits, formed by dissociating native enzyme, have close to 100% CRM activity in tests with antibodies elicited by native enzyme.Submitted by John Bell in partial fulfillment of the requirements for a Doctor of Philosophy degree from Cornell University.     

The effect of chromosomal position on the expression of the Drosophila xanthine dehydrogenase gene

Thirty-six isogenic D. melanogaster strains that differed only in the chromosomal location of a 7.2 or an 8.1 kb DNA segment containing the (autosomal) rosy gene were constructed by P-element-mediated gene transfer. Since the flies were homozygous for a rosy- allele, rosy gene function in these indicated the influence of flanking sequences on gene expression. The tissue distribution of XDH activity in all the strains was normal. Each line exhibited a characteristic level of adult XDH-specific activity. The majority of these values were close to wild-type levels; however, the total variation in specific activity among the lines was nearly fivefold. Thus position effects influence expression of the rosy gene quantitatively but do not detectably alter tissue specificity. X-linked rosy insertions were expressed on average 1.6 times more activity in males than in females. Hence the gene acquires at least partial dosage compensation upon insertion into the X chromosome.     

The response of Mo-hydroxylases and abscisic acid to salinity in wheat genotypes with differing salt tolerances

The differential responses of the wheat cultivars Shi4185 and Yumai47 to salinity were studied. The higher sensitivity of Yumai47 to salinity was linked to a greater growth reduction under salt stress, compared to more salt-tolerant Shi4185. Salinity increased the Na⁺, proline and superoxide anion radical (O₂ ^?) contents in both cultivars. Leaf Na⁺ content increased less in the more salt-tolerant cultivar Shi4185 than salt-sensitive Yumai47. The proline content increased more significantly in Shi4185 than Yumai47; on the contrary, superoxide anion radical content increased less in Shi4185 than Yumai47. This data indicated that wheat salinity tolerance can be increased by controlling Na⁺ transport from the root to shoot, associated with higher osmotic adjustment capability and antioxidant activity. Although salinity increased aldehyde oxidase (AO) activity and abscisic acid (ABA) content in the leaves and roots of both cultivars following the addition of NaCl to the growth medium, AO and ABA increased more in the salt-sensitive cultivar Yumai47 than the more salt-tolerant cultivar Shi4185. Xanthine dehydrogenase (XDH) activity in the leaves of both cultivars increased with increasing concentrations of NaCl; however, leaf XDH activity increased more significantly in Yumai47 than Shi4185. Root XDH activity in Shi4185 decreased with increasing NaCl concentrations, whereas salinity induced an increased root XDH activity in Yumai47. The involvement of AO and XDH enzymatic activities and altered ABA content in the response mechanisms of wheat to salinity are discussed herein.     

Urine metabolomics reveals novel physiologic functions of human aldehyde oxidase and provides biomarkers for typing xanthinuria

Classical xanthinuria is a rare inherited metabolic disorder caused by either isolated xanthine dehydrogenase (XDH) deficiency (type I) or combined XDH and aldehyde oxidase (AO) deficiency (type II). XDH and AO are evolutionary related enzymes that share a sulfurated molybdopterin cofactor. While the role of XDH in purine metabolism is well established, the physiologic functions of AO are mostly unknown. XDH and AO are important drug metabolizing enzymes. Urine metabolomic analysis by high pressure liquid chromatography and mass spectrometry of xanthinuric patients was performed to unveil physiologic functions of XDH and AO and provide biomarkers for typing xanthinuria. Novel endogenous products of AO, hydantoin propionic acid, N1-methyl-8-oxoguanine and N-(3-acetamidopropyl) pyrrolidin-2-one formed in the histidine, nucleic acid and spermidine metabolic pathways, respectively, were identified as being lowered in type II xanthinuria. Also lowered were the known AO products, N1-methyl-2-pyridone-5-carboxamide and N1-methyl-4-pyridone-5-carboxamide in the nicotinamide degradation pathway. In contrast to the KEGG annotations, the results suggest minor role of human AO in the conversion of pyridoxal to pyridoxate and gentisaldehyde to gentisate in the vitamin B6 and tyrosine metabolic pathways, respectively. The perturbations in purine degradation due to XDH deficiency radiated further from the previously known metabolites, uric acid, xanthine and hypoxanthine to guanine, methyl guanine, xanthosine and inosine. Possible pathophysiological implications of the observed metabolic perturbations are discussed. The identified biomarkers have the potential to replace the allopurinol-loading test used in the past to type xanthinuria, thus facilitating appropriate pharmacogenetic counseling and gene directed search for causative mutations.