Evidence for Regulatory Variants of the Dopa Decarboxylase and Alpha-Methyldopa Hypersensitive Loci in Drosophila

We have analyzed two variants of Drosophila melanogaster (RS and RE) which lead to the dual phenotype of elevated DDC activity and increased resistance to dietary alpha-methyldopa relative to Oregon-R controls. Both phenotypes show tight genetic linkage to the dopa decarboxylase, Ddc, and l(2)amd genes (i.e., less than 0.05 cM distant). We find that low (Oregon-R), medium (RS) and high (RE and Canton-S) levels of DDC activity seen at both pupariation and eclosion in these strains are completely accounted for by differences in accumulation of DDC protein as measured by immunoprecipitation. Genetic reconstruction experiments in which Ddc+ and amd+ gene doses are varied show that increasing DDC activity does not lead to a measurable increase in resistance to dietary alpha-methyldopa. This suggests that the increased resistance to dietary alpha-methyldopa is not the result of increased DDC activity but, rather, results from increased l(2)amd+ activity. Both cytogenetic and molecular analyses indicate that these overproduction variants are not the result of small duplications of the Ddc and amd genes, nor are they associated with small (greater than or equal to 100 bp) insertions or deletions. Measurements of DDC activity in wild-type strains of Drosophila reveal a unimodal distribution of activity levels with the Canton-S and RE strains at the high end of the scale, the Oregon-R control at the low end and RS near the modal value. We conclude that accumulated changes in a genetic element (or elements) in close proximity to the Ddc+ and amd+ genes lead to the coordinated changes in the expression of the Ddc and amd genes in these strains.     

Complex evolution of orthologous and paralogous decarboxylase genes

The decarboxylases are involved in neurotransmitter synthesis in animals, and in pathways of secondary metabolism in plants. Different decarboxylase proteins are characterized for their different substrate specificities, but are encoded by homologous genes. We study, within a maximum-likelihood framework, the evolutionary relationships among dopa decarboxylase (Ddc), histidine decarboxylase (Hdc) and alpha-methyldopa hypersensitive (amd) in animals, and tryptophan decarboxylase (Wdc) and tyrosine decarboxylase (Ydc) in plants. The evolutionary rates are heterogeneous. There are differences between paralogous genes in the same lineages: 4.13 x 10(-10) nucleotide substitutions per site per year in mammalian Ddc vs. 1.95 in Hdc; between orthologous genes in different lineages, 7.62 in dipteran Ddc vs. 4.13 in mammalian Ddc; and very large temporal variations in some lineages, from 3.7 up to 54.9 in the Drosophila Ddc lineage. Our results are inconsistent with the molecular clock hypothesis.     

Characterization of third chromosome dominant alpha-methyl dopa resistant mutants (Tcr) and their interactions with l(2)amd alpha-methyl dopa hypersensitive alleles in Drosophila melanogaster

In Drosophila melanogaster two alleles at the Third chromosome resistance locus (Tcr; 3-39-6) were isolated in a screen of EMS mutagenized third chromosomes for dominant resistance to dietary alpha-methyl dopa, alpha-MD, a structural analogue of DOPA. Both alleles of Tcr are recessive lethals exhibiting partial complementation. Almost half (48.3%) of the Tcr40/Tcr45 heterozygotes die as embryos but some survive past adult eclosion. Both the embryonic lethal phenotype and the adult phenotype suggest that Tcr is involved in cuticle synthesis. Tcr mutants suppress the lethality of partially complementing alleles at the alpha-MD hypersensitive locus, l(2)amd. The viability of Tcr40/Tcr45, however, is not increased by the presence of a l(2)amd allele. The possibility that the Tcr and l(2)amd mutations reveal a catecholamine metabolic pathway involved in cuticle structure is discussed.     

Decarboxylation-dependent transamination catalyzed by mammalian 3,4-dihydroxyphenylalanine decarboxylase

In addition to the usual decarboxylation, pig kidney 3,4-dihydroxyphenylalanine (dopa) decarboxylase catalyzes a decarboxylation-dependent transamination which converts dopa into 3,4-dihydroxyphenylacetaldehyde and sinultaneously converts enzyme-bound pyridoxal-P into pyridoxamine-P. Similar reactions occur when this enzyme acts on m-tyrosine, alpha-methyldopa, and alpha-methyl-m-tyrosine. The transamination occurs in about 0.02% of decarboxylations of dopa and m-tyrosine and in about 2% of decarboxylations of alpha-methyldopa and alpha-methyl-m-tyrosine. The fraction of decarboxylations proceeding by the transamination pathway is independent of pH. This reaction appears to result from a divergence in the normal mechanism of decarboxylation; the quinoid intermediate which is formed by decarboxylation of the substrate-pyridoxal-P-Schiff base ordinarily protonates on the alpha carbon of the amino acid, but protonation occasionally occurs at the benzylic carbon of the coenzyme, and this latter route leads to transamination.     

Cytological location and further characterization of the Third chromosome resistance gene in Drosophila melanogaster

Mutations in the Third chromosome resistance (Tcr; 3-39.6) gene confer dominant resistance to α-methyl dopa and suggest the gene is involved in catecholamine metabolism. Evidence for involvement in catecholamine metabolism comes from the three phenotypes associated with the mutant Tcr chromosomes dominant resistance, dominant rescue of partially complementing l(2)amd alleles, and recessive lethal phenotypes. Only dominant resistance to αs-methyl dopa, however, was mapped to the Tcr locus. Both recessive lethality and dominant rescue of l(2)amd alleles have now been mapped to the Tcr gene and, through the isolation of a new deletion in the region, we demonstrate these phenotypes are due to a loss of Tcr function. This deletion places the Tcr gene in the 69B4-5 to 69C8-11 region. Additionally, we have tested and verified three predictions of the biochemical model proposed by Bishop, Sherald, and Wright (1989) for the function of the Tcr protein. This revised version was published online in July 2006 with corrections to the Cover Date.     

Genes regulating the development and functioning of the nervous system determine life span in Drosophila melanogaster

Earlier, it has been shown that genes responsible for differences in longevity between wild-type Drosophila melanogaster lines 2b and Oregon are localized in region 7A6-B2, 36E4-37B9, 37B9-D2, and 64C-65C. Quantitative complementation tests were conducted between the gene mutations localized in these regions and involved in catecholamine biosynthesis (iav (inactive), Catsup (Catecholamines up), amd (alpha methyl dopa resistant), Dox-A2 (Diphenol oxidase A2), pie (pale)) and neuron development control (Fas3 (Fascyclin 3), tup (tail up), Lim3), on the one hand, and two different normal alleles of these genes in lines 2b and Oregon, on the other. Complementation was found for genes iav, Fas3, amd and ple. The remaining genes (Catsup, Dox-A2, tup, and Lim3) are candidate genes for controlling differences in longevity between lines 2b and Oregon.     

Temporal and spatial expression of the yellow gene in correlation with cuticle formation and dopa decarboxylase activity in Drosophila development

The yellow (y) gene of Drosophila is required for the formation of black melanin and its deposition in the cuticle. We have studied by immunohistochemical methods the temporal and spatial distribution of the protein product of the y gene during embryonic and pupal development and have correlated its expression with events of cuticle synthesis by the epidermal cells and with cuticle sclerotization. Except for expression in early embryos, the y protein is only found in the epidermal cells and may be secreted into the cuticle as it is being deposited. The amount of y protein in various regions of the embryo and pupa correlates directly with the intensity of melanization over any section of the epidermis. Expression of the y gene begins in the epidermal cells at 48 hr after pupariation and is well correlated with the beginning deposition of the adult cuticle. At this stage the adult cuticle is unsclerotized and unpigmented and dopa decarboxylase levels, a key enzyme in catecholamine metabolism which provides the crosslinking agents as well as the precursors for melanin, is low. As a separate event 26 hr after the onset of y gene expression, the first melanin deposition occurs in the head bristles and pigmentation continues in an anterior to posterior progression until eclosion. This melanization wave is correlated with elevated dopa decarboxylase activity. Crosslinking of the adult cuticle also occurs in a similar anterior to posterior progression at about the same time. We have shown by imaginal disc transplantation that timing of cuticle sclerotization depends on the position of the tissue along the anterior-posterior axis and that it is not an inherent feature of the discs themselves. We suggest that actual melanization and sclerotization of the cuticle by crosslinking are initiated at this time in pupal development by the availability of the catecholamine substrates which diffuse into the cuticle. Intensity of melanization and position of melanin pigment is determined by the presence or absence of the y protein in the cuticle, thus converting the y protein prepattern into the melanization pattern.     

Drosophila yellow-h encodes dopaminechrome tautomerase: A new enzyme in the eumelanin biosynthetic pathway

Melanin is a widely distributed phenolic pigment that is biosynthesized from tyrosine and its hydroxylated product, dopa, in all animals. However, recent studies reveal a significant deviation from this paradigm, as insects appear to use dopamine rather than dopa as the major precursor of melanin. This observation calls for a reconsideration of the insect melanogenic pathway. While phenoloxidases and laccases can oxidize dopamine for dopaminechrome production, the fate of dopaminechrome remains undetermined. Dopachrome decarboxylase/tautomerase, encoded by yellow-f/f2 of Drosophila melanogaster, can convert dopaminechrome into 5,6-dihydroxyindole, but the same enzyme from other organisms does not act on dopaminechrome, suggesting the existence of a specific dopaminechrome tautomerase (DPT). We now report the identification of this novel enzyme that biosynthesizes 5,6-dihydroxyindole from dopaminechrome in Drosophila. Dopaminechrome tautomerase acted on both dopaminechrome and N-methyl dopaminechrome but not on dopachrome or other aminochromes tested. Our biochemical and molecular studies reveal that this enzyme is encoded by the yellow-h gene, a member of the yellow gene family, and advance our understanding of the physiological functions of this gene family. Identification and characterization of DPT clarifies the precursor for melanin biosynthetic pathways and proves the existence of an independent melanogenic pathway in insects that utilizes dopamine as the primary precursor.     

The Drosophila virilis dopa decarboxylase gene is developmentally regulated when integrated into Drosophila melanogaster.

The dopa decarboxylase gene (Ddc) has been isolated from Drosophila virilis and introduced into the germ-line of Drosophila melanogaster by P-element mediated transformation. The integrated gene is induced at the correct stages during development with apparently normal tissue specificity, indicating that cis-acting elements required for regulation are functionally conserved between the two species. A comparison of the DNA sequences from the 5' flanking regions reveals a cluster of small (8-16 bp) conserved sequence elements within 150 bp upstream of the RNA startpoint, a region required for normal expression of the D. melanogaster Ddc gene.     

The genetics of dopa decarboxylase in Drosophila melanogaster

Summary Data on 46 mutations in the structural gene, Ddc. for dopa decarboxylase and 33 mutations in the methyl dopa hypersensitive gene, 1(2)amd, in Drosophila melanogaster are presented including information on their isolation, their effects on DDC activity, and their sensitivity to dietary methyl dopa. Intragenic complementation of both loci is documented, the effects of heteroallelic complementing heterozygosity on DDC activity, in vitro thermolability of DDC, and on temperature sensitive viability are presented. Data are marshalled to support rejection of the hypothesis that Ddc mutations and 1(2)amd, mutations are lesions in a single gene.     

Dopa decarboxylase from Drosophila melanogaster

Summary Dopa decarboxylase (EC 4.1.1.26) has been purified to near homogeneity from mature larvae of Drosophila melanogaster. The enzyme has a molecular weight of 113,000 measured by sucrose gradient sedimentation and 102,000 measured by variable porosity acrylamide gel electrophoresis. Electrophoresis under denaturing conditions revealed the enzyme consists of two subunits of molecular weight 54,000. The affinity of the enzyme for L-dopa is 30-fold greater than for L-tyrosine. Activity is strongly inhibited by heavy metal ions and the sulfhydryl reagent N-ethylmaleimide. N-acetyl dopamine acts as a competitive inhibitor of the enzyme.Antibodies were elicited against the purified enzyme and measurements of the amount of cross-reacting material (CRM) in two groups of mutants were made. The first group comprised the recessive lethal mutants l(2)amd. Heterozygous mutant stocks are hypersensitive to -methyl dopa, an inhibitor of dopa decarboxylase. These stocks were found to have nearly normal amounts of CRM and enzyme activity.A second group of recessive lethal mutants, characterized by lower levels of dopa decarboxylase, was also analysed. These mutants, designated l(2) Ddc, as heterozygotes exhibited CRM levels between 25 and 75% of normal. Although they are alleles at a single locus, they were classifiable into three distinct groups whose properties readily could be ascribed to a homodimeric structure of the enzyme. This structure would also account for the pattern of intracistronic complementation exhibited by the mutants. Finally, the severity of the mutant defects, as judged by our measurements of CRM and activity, closely parallels that deduced from their complementation pattern. We conclude that these mutations are lesions in the structural gene for dopa decarboxylase.