A kinetic analysis of Drosophila melanogaster dopa decarboxylase

The kinetic mechanism of dopa decarboxylase (3,4-dihydroxy-L-phenylalanine carboxy-lyase, EC 4.1.1.28) was investigated in Drosophila melanogaster. Based on initial velocity and product inhibition studies, an ordered reaction is proposed for dopa decarboxylase. This kinetic mechanism is interpreted in the context of measured enzyme activities and the catecholamine pools in Drosophila. The 1(2)amd gene is immediately adjacent to the gene coding for dopa decarboxylase (Ddc) and determines hypersensitivity to alpha-methyldopa in Drosophila. Dopa decarboxylase does not decarboxylate alpha-methyldopa and hence does not generate a toxic product capable of inhibiting 1(2)amd gene function. We propose that the 1(2)amd gene is involved with an unknown catecholamine pathway involving dopa but not dopamine.     

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.     

Amylase gene expression in intraspecific and interspecific somatic transformants of Drosophila.

The Amylase locus in Drosophila melanogaster normally contains two copies of the structural gene for alpha-amylase, a centromere-proximal copy, Amy-p, and a distal copy, Amy-d. Products of the two genes may display discrete electrophoretic mobilities, but many strains known to carry the Amy duplication are characterized by a single amylase electromorph, e.g., Oregon-R, which produces the mobility variant AMY-1. A transient expression assay was used in somatic transformation experiments to test the functional status of the Amy genes from an Oregon-R strain. Plasmid constructs containing either the proximal or distal copy were tested in amylase-null hosts. Both genes produced a functional AMY-1 isozyme. Constructs were tested against an AMY-3 reference activity produced by a coinjected plasmid that contains the Amy-d3 allele from a Canton-S strain. With reference to the internal control, the Amy-p and Amy-d genes from Oregon-R expressed different relative activity levels for AMY-1 in transient assays. The transient expression assay was successfully used to test the functional status of Amy-homologous sequences from strains of other species of Drosophila characterized by a single amylase elctromorph, namely, Drosophila pseudoobscura ST and Drosophila miranda S 204. The amylase-null strain of D. melanogaster provided the hosts for these interspecific somatic transformation experiments.     

Sex pheromones enable Drosophila males to discriminate between conspecific females from different laboratory stocks

Drosophila melanogaster males from Canton-S and Oregon-R stocks perform more courtship in response to virgin females from the stock other than their own. Pairs of Canton-S and Oregon-R males also court each other more in the presence of volatile compounds extracted from Oregon-R and Canton-S females, respectively. These observations suggest that D. melanogaster females are polymorphic with respect to some components of their sex pheromone system and that males are capable of distinguishing females from their own stock and females from another stock on the basis of these differences in pheromone production.     

Effects of genotype and age on mixed-function oxidase activities in adult Drosophila melanogaster

The mixed-function oxidases that metabolize dimethylnitrosamine, aminopyrine, benzphetamine, 7-ethoxycoumarin and benzo[alpha]pyrene were measured in adults of the Canton-S, Oregon-R and Hikone-R strains of Drosophila melanogaster. The expression of these activities is both genotype and age dependent.     

Life-span in generations of chronic irradiated Drosophila wild type isogenic and geterogenic strains

With the goal to study radioadaptation on life-span and observe the role in this phenomenon of genotype, we investigated the dynamics of life-span in 14 consistent generations after chronic gamma-irradiation in heterogenic (Canton-S) and isogenic (Oregon-R spa) Drosophila wild type strains. The gamma-source was 226Ra in dose 60 cGy per generation. The animals kept in standard conditions (25 degrees C and 12 h lighting). Was shown, that the dynamics of median life-span in wild type strains Canton-S and Oregon-R spa was different and the character of alterations depends on genetic heterogeneity. After chronic irradiation in generations in heterogenic line Canton-S since 5 generation cyclic life-span oscillations disappeared, values of median life-span leave on a plateau. Since the 8th generation the life-span values of irradiated populations exceeded all the control values. As a result of the irradiation practically in all generations in isogenic line Oregon-R spa occurs increasing of life-span with the comparing to non-irradiated control. This is possible due to the positive influence of radio-induced heterogeneity on the life-span of isogenic strain. Thus, chronic irradiation led to violation of natural cyclic dynamics of Drosophila life-span in heterogenic strain, discovered in the end 80-s' years by F. Lints and D. Ismaylov. Irradiation of isogenic strain led to increasing of life-span in all generations.     

Sex-linked lethal frequencies produced by 7,12-dimethylbenz[a]anthracene in five Drosophila melanogaster wild strains

7,12-Dimethylbenz[a]anthracene (DMBA) was tested for the induction of mutations in 5 strains of Drosophila melanogaster. Larvae were fed mixtures containing either 1.0 or 4.0 mM DMBA in darkness. After emergence the males were mated to Basc females to test for sex-linked lethals. Canton-S males produced the highest frequency with no significant differences in the induction of lethals by the 2 concentrations. DMBA was slightly mutagenic in Oregon-R males over controls without significant differences between the 2 concentrations. Berlin-K, Lausanne-S and Urbana-S males all produced significantly more mutations at the 4.0-mM than the 1.0-mM concentrations. DMVA produced partial sterility in Canton-S and Urbana-S males. The DMBA mutation frequencies of all 5 wild strains are interpreted as being related to the levels of activating enzymes that metabolize DMBA.     

Sex-linked lethal mutations induced in Drosophila melanogaster by 7,12-dimethylbenz[a]anthracene

One of the most potent carcinogens, 7,12-dimethylbenz[a]anthracene (DMBA), was tested for the induction of mutations in 2 strains of Drosophila melanogaster. Larvae were fed mixtures containing DMBA, peanut oil and solubilizing agents in darkness. After emergence the males were mated with Basc or FM7a females to test for sex-linked lethals. For Canton-S males, all DMBA treatments produced highly significant increases in mutation frequencies over controls. DMBA was slightly mutagenic for Oregon-R males.     

Ddcde1, a Mutant Differentially Affecting Both Stage and Tissue Specific Expression of Dopa Decarboxylase in Drosophila

The isolation and characterization of a unique Dopa decarboxylase (Ddc) mutant in Drosophila melanogaster is reported. This mutant, DdcDE1, exhibits stage- and tissue-specific altered Ddc expression. Homozygous DdcDE1 embryos, central nervous systems (CNSs) at pupariation and newly eclosed adult epidermis all have approximately 5% as much specific dopa decarboxylase (DDC) activity as the pr control stock in which DdcDE1 was induced. In contrast, the DdcDE1 epidermis at pupariation has roughly 50% as much DDC activity as controls, a 10-fold increase over the relative activity detected in other tissues and stages. Although the adult cuticle lacks proper pigmentation as expected in flies with low DDC activity (less than or equal to 5%), the bristles unexpectedly have wild-type black pigmentation. This implies that the bristle forming cells have more DDC activity than the rest of the adult epidermis. This variegated phenotype, black bristles and pale cuticle, plus the fact that DdcDE1 was originally isolated in a reciprocal translocation between proximal X heterochromatin and the euchromatic left arm of the second chromosome, 42 bands from the Ddc locus, suggested that the mutant might be an example of position-effect variegation. All tests for position-effect variegation, including persistence of the mutant phenotype when DdcDE1 was removed from the translocation, were negative. At pupariation DDC cross-reacting material (CRM) levels are similar in DdcDE1 and wild-type controls, but in newly eclosed adults CRM levels are approximately 35% of wild-type controls. This suggests that DDC produced by DdcDE1 adults has less activity per DDC molecule than the DDC produced at pupariation by DdcDE1. If the DDC enzyme produced by DdcDE1 at adult eclosion had full DDC activity (35% DDC CRM = 35% DDC activity) then no mutant phenotype would be exhibited by DdcDE1 since flies with as little as 10% activity have a wild-type phenotype. DDC thermolability assays clearly demonstrate that DDC from DdcDE1 is more thermolabile than control DDC at both pupariation and adult eclosion. Furthermore, DDC from adults in both DdcDE1 and the pr control is more thermolabile than DDC from white prepupae. Mixing experiments indicate the difference in DDC thermolability between pr white prepupae and pr adults is not due to a difference in the white prepupal and adult supernatants. This suggests that in wild-type different isoforms of DDC are produced either by differences in post-translational modification or as a result of a different primary amino acid sequence.(ABSTRACT TRUNCATED AT 400 WORDS)     

The Genetics of Dopa Decarboxylase and a-Methyl Dopa Sensitivity in Drosophila melanogaster

Dopa decarboxylase (DDC) in the Diptera is an enzyme involvedin sclerotinization of the cuticle in the epidermis and theproduction of neurogenic amines in the central nervous system.Its appearance in the epidermis at pupariation is induced bythe molting hormone ecdysone. The dietary administration ofthe analog inhibitor -methyl dopa (a MD) was used to isolateresistant and hypersensitive mutants. Two of three dominantresistant strains isolated increase DDC activity 35-70%. Forboth the increase is due to mutations between rdo (53) and pr(54.5) on the left arm of the 2nd chromosome (2L). The veryhighly resistant strain which does not affect DDC in any wayis located at 54.0 on 2L. Twelve dominant, l(2)amd^H —MD hypersensitive alleles located immediately to the right ofhk (53.9) on 2L have been recovered. All are recessive lethalsand exhibit some intracistronic complementation, and none ofthem, not even heteroallelic heterozygotes, affect DDC in anyway. The.recovery and analysis of 16 overlapping deficienciespermitted the localization of a DDC dosage effect to bands 37B10-C7on 2L; a region which includes the l(2)amd locus. Subsequentlyeight DDC deficient lethal alleles were recovered in this elevenband region which as heterozygotes reduce activities to 28–53% of controls. Some heteroallelic heterozygotes exhibit intracistroniccomplementation; most with viabilities 5% and with a mutantphenotype probably derived from inadequately sclerotinized cuticle.These Ddc alleles are within 0.004 Map Units to the right ofl(2)amd. None as Ddc/CyO heterozygotes are sensitive to -MD,and complementation occurs between the Ddc alleles and the l(2)amdalleles both on the basis of viability and DDC activity. Althoughthe protein product mutated by the l(2)amd alleles has not yetbeen identified, it seems likely that the two groups of mutantsare functionally related. Finally, the Ddc structural mutantsreduce DDC activity in the central nervous system as well asthe epidermis.     

Developmental expression and spatial distribution of dopa decarboxylase in Drosophila

Regulation of the dopa decarboxylase gene of Drosophila has been studied at the genetic and molecular levels. Here we report a direct assay for the tissue and temporal regulation of Ddc. A dopa decarboxylase (DDC) peptide was obtained by bacterial expression of a portion of the DDC gene in a pUC plasmid. Antisera raised against this biologically purified DDC peptide react specifically with Drosophila DDC in histological preparations and protein blots. The levels of DDC cross-reacting material closely parallel the levels of enzyme activity observed during development, indicating that DDC is degraded during periods of declining activity. We find that DDC is expressed in only two tissues, namely, the epidermis and the nervous system of the larva and adult. Epidermal DDC was found within the epidermal cells and was not detected in the overlying cuticle. DDC-containing neurons were observed in the central as well as in the visceral nervous system. Paired and unpaired midline neurons in the ventral ganglia are arranged in a segmental pattern. A subset of the DDC-positive neurons appears to correlate with the serotonin-positive neurons suggesting that the others are producing only dopamine. We find that the DDC activity associated with the proventriculus and ovary is due to the presence of DDC in the stomatogastric and caudal system neurons specifically associated with those structures.     

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.