A Diphenol Oxidase Gene Is Part of a Cluster of Genes Involved in Catecholamine Metabolism and Sclerotization in Drosophila. I. Identification of the Biochemical Defect in Dox-A2 [l(2)37Bf] Mutants

Phenol oxidase, a complex enzyme, plays a major role in the processes of sclerotization and melanization of cuticle in insects. Several loci have been reported to affect levels of phenol oxidase activity, but to date only one structural locus has been identified [Dox-3F (2-53.1+)]. Recently isolated Dox-A2 mutations (2-53.9) are recessive, early larval lethals, which as heterozygotes reduce phenol oxidase activity. A homozygous mutant escaper had weak, completely unpigmented cuticle and unpigmented bristles. Enzyme assays show that Dox-A2 heterozygotes have diphenol oxidase activity reduced to 47-79% of wild type, whereas monophenol oxidase activity, at 94-106% of wild type, is normal. Elevated pool sizes of the diphenol oxidase substrates DOPA, dopamine, and N-acetyldopamine are observed in the mutant, confirming the enzyme assay results. Separation of the three phenol oxidase A component activities on polyacrylamide gels shows that Dox-A2 mutations reduce the activity of only the A2 component. Dox-A2 may identify a structural locus for the A2 component of the diphenol oxidase enzyme system. The Dox-A2 locus is one of 18 loci in the dopa decarboxylase, Df (2L)TW130 region of the second chromosome, at least 14 of which affect the formation, melanization or sclerotization of cuticle in some way. These loci form an apparent cluster of functionally related genes.     

Mapping candidate genes for Drosophila melanogaster resistance to the parasitoid wasp Leptopilina boulardi

Drosophila melanogaster resistance against the parasitoid wasp Leptopilina boulardi is under the control of a single gene (Rlb), with two alleles, the resistant one being dominant. Using strains bearing deletions, we previously demonstrated that the 55E2-E6; 55F3 region on chromosome 2R is involved in the resistance phenomenon. In this paper, we first restricted the Rlb containing region by mapping at the molecular level the breakpoints of the Df(2R)Pc66, Df(2R)P34 and Df(2R)Pc4 deficiencies, using both chromosomal in situ hybridization and Southern analyses. The resistance gene was localized in a 100 kb fragment, predicted to contain about 10 different genes. Male recombination genetic experiments were then performed, leading to identification of two possible candidates for the Rlb gene. Potential involvement of one of this genes, edl/mae, is discussed.     

Cytogenetic analysis of region 2B3-4-2B11 of the X-chromosome of Drosophila melanogaster

About 160 kb of DNA were cloned from the 2B region of the X chromosome, where the early ecdysone puff develops and the ecs locus is located. On the physical map of this sequence the positions of 13 chromosome rearrangement breakpoints interfering with both puff development and the ecs locus proximally and distally, were plotted by means of in situ hybridization. The maximal size of the ecs locus is about 100 kb (between the breakpoint of In(1)Hw ^49c and the proximal end of Df(1)St472) The DNA sequences essential for normal puffing are located within the ecs locus between the In(1)br ^lt103 and Df(1)St472 breakpoints and comprise about 65 kb. Thus the puff develops as a result of ecs activation. Since Df(1)P154, which reduces the puff size and removes the proximal part of the ecs locus, does not prevent puff induction by ecdysone, while removing the distal part of the locus by Df(1)St469 completely stops development of the puff, we conclude that the regulatory zone of the locus, which reacts to hormone is located in the distal parts of both the puff and the locus, proximal to the breakpoint of In(1)br ^lt103 .Since In(1)br ^lt103 , Df(1)pn7b and Df(1)br ^R1 damage ecs but do not prevent puffing it is proposed that there is a second regulatory zone for this locus with a minimal size of 15–20 kb (between the breakpoints of Df(1)br ^R1 and In(1)br ^lt103). After cytogenetic and electron microscopic analysis of 2B puff formation it seems very likely that the site of puff formation is situated in the proximal part of 2B3-4 and after enhancement of ecs expression by hormone it spreads proximally to the 2B6 band which does not puff. When the puff regresses at puff stages (PS)10-11 its material does not condense completely and a zone of residual puffing joins the condensed material located distal to it. This material can give the impression of a separate band, designated 2B5 in Bridges' map. For convenience we propose to call the site giving rise to the puff as 2B3-5.     

Cytogenetics of Notch Mutations Arising in the Unstable X Chromosome Uc of Drosophila melanogaster

A derivative of the unstable X chromosome, Uc, isolated in 1978 is still unstable and exhibits most of the genetic properties characteristic of the original Uc. This derivative, Df(1)cm-In, contains an inversion of the genes between bands 6F1-2 and 3D3-5 and a lethal deficiency between 6D5-7 and 6F1-2. This chromosome generated Notch mutations at a rate of 3.47 +/- 0.32% during seven consecutive generations. Cytological analysis of 50 Notch mutations of independent origin in the Df(1)cm-In chromosome showed that all of the 50 had an apparently identical deletion involving the region between 3D3-5 and 3C7-8 of the X chromosome. The results of in situ hybridization indicated that the extent of deletion in all of the 20 Notch deficiencies sampled from the 50 mentioned above involves about 10 kb of the sequences from the 3' end of the Notch locus. In addition to hypermutability and the accumulation of site-specific chromosome breaks, the Df(1)cm-In chromosome reinverts its inversion to the normal sequence and exhibits use of the existing chromosome breakpoints to generate new rearrangements.     

Functional genomic analysis of the 61D-61F region of the third chromosome of Drosophila melanogaster.

Assigning functional significance to completed genome sequences is one of the next challenges in biological science. Conventional genetic tools such as deficiency chromosomes help assign essential complementation groups to their corresponding genes. We describe an F2 genetic screen to identify lethal mutations within cytogenetic region 61D-61F of the third chromosome of Drosophila melanogaster. One hundred sixteen mutations were identified by their failure to complement both Df(3L)bab-PG and Df(3L)3C7. These alleles were assigned to 14 complementation groups and 9 deficiency intervals. Complementation groups were ordered using existing deficiencies, as well as new deficiencies generated in this study. With the aid of the genomic sequence, genetic and physical maps in the region were correlated by use of PCR to localize the breakpoints of deficiencies within a 268-kb genomic contig (GenBank accession No. AC005847). Six essential complementation groups were assigned to specific genes, including genes encoding a porphobilinogen deaminase and a Sac1-like protein.     

Studies of the Genetic Organization of the Vestigial Microregion of Drosophila Melanogaster

The region of the second chromosome of Drosophila melanogaster defined by Df(2R)vgB was screened for recessive lethal and visible mutations. Fifty-eight new recessive alleles fall into 17 complementation groups. Many new vg alleles were also isolated in a screen for new vg deficiencies. The breakpoints of the new vg deficiencies were nonrandomly distributed. The distal breakpoints of twelve of 20 deficiencies overlapping Df(2R)vgB are genetically identical to that of Df(2R)vgD, coinciding with the position of a complex, pleiotropic locus, l(2)49Ea-Psc-Su(z)2.     

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.     

Variant (6;15) translocations in murine plasmacytomas involve a chromosome 15 locus at least 72 kb from the c-myc oncogene.

The variant (6;15) translocations in murine plasmacytomas join the myc oncogene-bearing band of chromosome 15 and the immunoglobulin kappa band of chromosome 6. We recently cloned a region from chromosome 15 linked to C kappa and have now used probes from that region to define the major locus of plasmacytoma variant translocations, which we denote pvt-1. In five of nine plasmacytomas we analysed, the 6;15 translocation resulted from reciprocal recombination between the C kappa locus and a 4.5-kb region of pvt-1. Moreover, nearby we located the region shown by others to have undergone a complex (15;12;6) translocation in plasmacytoma PC7183. All the chromosome 6 breakpoints fell between 1 and 3 kb 5' to C kappa but only two were near J kappa genes. Thus the J kappa -C kappa region appears to be a recombination 'hot spot' in lymphocytes, but the breaks are unlikely to be mediated via V/J recombination enzymes. Comparison of a cloned 108-kb region across pvt-1 and another of 52 kb across c-myc established that the pvt-1 breakpoints lie at least 72 kb from the c-myc promoters. Since c-myc is expressed at a substantial level, the 6;15 translocation apparently activates c-myc. Activation may occur directly, at a remarkable distance along the chromosome, or indirectly, via a putative pvt-1 gene product.     

A Genetic Analysis of the Rose-Gespleten Region (68c8-69b5) of Drosophila Melanogaster

We describe a genetic analysis of the region 68C8-69B5 defined by Df(3L)vin-7. We have induced 35 new lethal mutations in this region, which together with 20 existing lethal mutations, visible mutations, genes identified by protein products and one gene deduced from complementation data fall into 37 complementation groups in this 35-band interval. Using existing and newly induced deficiencies we have assigned these to 11 intervals defined by deficiency breakpoints. Those mutations which fell in the same breakpoint interval as the Lsp-2 gene, which codes for the abundant larval serum protein 2, were the subject of detailed study. None was rescued by the active Lsp-2 gene transformed on to chromosome II and we conclude that, as yet, we have no lethal mutations of Lsp-2.     

Genetic and molecular analysis of fs(1)h, a maternal effect homeotic gene in Drosophila

Mutations at the Drosophila melanogaster locus female sterile (1) homeotic (fs(1)h) result in segmental abnormalities including missing organs and homeotic transformations in the progeny of mutant mothers. Homeotic transformations are enhanced when the zygotes carry one of several third chromosome mutations, specifically alleles or deficiencies of the trithorax (trx) locus, also called Regulator-of-bithorax, and some alleles of bithorax complex (BX-C) genes. These observations suggest that maternally derived fs(1)h+ product is required, in interaction with trx and BX-C genes, for normal segment specification. The fs(1)h gene and an adjacent gene, lethal (1) myospheroid (l(1)mys), have been cloned by chromosomal walking. Mutations of fs(1)h were found within a 13-kb stretch of DNA. Poly(A)+ RNAs migrating as a doublet at 7.6 kb and a single band at 5.9 kb, which are homologous to the fs(1)h+ chromosomal region, are found in ovaries and early embryos. The largest RNAs are derived from a 20-kb chromosomal region encompassing the sites of all mapped fs(1)h alleles.     

Genomic and cDNA clones of the homeotic locus Antennapedia in Drosophila.

Homeotic genes are involved in the control of developmental pathways: dominant mutations at the Antennapedia locus of Drosophila, for example, lead to replacement of the antennae on the head of the fly by mesothoracic legs. Using a combination of chromosome walking and jumping, we have cloned a DNA region from Drosophila containing Antennapedia. Five DNA inversion rearrangements which are associated with the Antennapedia mutant phenotype were localized within a 25-kb region. Genomic DNA sequences from this area were used as hybridization probes to screen cDNA libraries prepared from Drosophila embryonic and pupal poly(A)+ RNA. A 2.2-kb cDNA sequence (903) was isolated which appears to derive from at least four non-contiguous chromosomal regions that span 100 kb. It includes the positions of the inversion breakpoints. A second cDNA of 2.9 kb (909) is composed of sequences from at least three chromosomal regions, two of which are similar or identical to sequences contained in the 903 clone but the third is derived from genomic DNA within a putative 903 intron. The unusual size and complexity of this locus are discussed.     

Characterization of the NPHP1 locus: mutational mechanism involved in deletions in familial juvenile nephronophthisis

Familial juvenile nephronophthisis is an autosomal recessive, genetically heterogeneous kidney disorder representing the most frequent inherited cause of chronic renal failure in children. A gene, NPHP1, responsible for approximately 85% of the purely renal form of nephronophthisis, has been mapped to 2q13 and characterized. The major NPHP1 gene defect is a large homozygous deletion found in approximately 80% of the patients. In this study, by large-scale genomic sequencing and pulsed-field gel electrophoresis analysis, we characterized the complex organization of the NPHP1 locus and determined the mutational mechanism that results in the large deletion observed in most patients. We showed that the deletion is 290 kb in size and that NPHP1 is flanked by two large inverted repeats of approximately 330 kb. In addition, a second sequence of 45 kb located adjacent to the proximal 330-kb repeat was shown to be directly repeated 250 kb away within the distal 330-kb repeat deleting the sequence tag site (STS) 804H10R present in the proximal copy. The patients' deletion breakpoints appear to be located within the 45-kb repeat, suggesting an unequal recombination between the two homologous copies of this smaller repeat. Moreover, we demonstrated a nonpathologic rearrangement involving the two 330-kb inverted repeats found in 11 patients and, in the homozygous state, in 2 (1.3%) control individuals. This could be explained by interchromosomal mispairing of the 330-kb inverted repeat, followed by double recombination or by a prior intrachromosomal mispairing of these repeats, leading to an inversion of the NPHP1 region, followed by an interchromosomal unequal crossover event. This complex rearrangement, as well as the common deletion found in most patients, illustrates the high level of rearrangements occurring in the centromeric region of chromosome 2.