Effects of Polycomb Group Mutations on the Expression of Ultrabithorax in the Drosophila Visceral Mesoderm

The Polycomb group (PcG) genes encode repressors of many developmental regulatory genes including homeotic genes and are known to act by modifying chromatin structure through complex formation. We describe how Ultrabithorax (Ubx) expression is affected by the PcG mutants in the visceral mesoderm. Mutant embryos of the genes extra sex combs (esc), Polycomb (Pc), additional sex combs (Asx) and pleiohomeotic (pho) were examined. In each mutation, Ubx was ectopically expressed outside of their normal domains along the anterior-posterior axis in the visceral mesoderm, which is consistent with the effect of PcG proteins repressing the homeotic genes in other tissues. All of these four PcG mutations exhibit complete or partial lack of midgut constriction. However, two thirds of esc mutant embryos did not show Ubx expression in parasegment 7 (PS7). Even in the embryos showing ectopic Ubx expression, the level of Ubx expression in the PcG mutations was weaker than that in normal embryos. We suggest that in PcG mutations the ectopic Ubx expression is caused by lack of PcG repressor proteins, while the weaker or lack of Ubx expression is due to the repression of Ubx by Abd-B protein which is ectopically expressed in PcG mutations as well.     

Genetic control of alcohol dehydrogenase levels in Drosophila

Among the progeny of Drosophila flies heterozygous for two noncomplementing Adh-negative alleles, two individuals were found that had recovered appreciable alcohol dehydrogenase activity, thereby surviving the ethanol medium used as a screen. The most likely explanation is that these Adh-positive flies are the product of intracistronic recombination within the Adh locus. Judging by the distribution of outside markers, one of the crossovers would have been a conventional reciprocal exchange while the other appears to have been an instance of nonreciprocal recombination. The enzymes produced in strains derived from the original survivors can be easily distinguished from wild-type enzymes ADH-S and ADH-F on the basis of their sensitivity to denaturing agents. None of various physical and catalytic properties tested revealed differences between the enzymes of the survivor strains except that in one of them the level of activity is 55–65% of the other. Quantitative immunological determinations of ADH gave estimates of enzyme protein which are proportional to the measured activity levels. These results are interpreted to indicate that different amounts of ADH protein are being accumulated in the two strains.This work was supported in part by NSF Grant PCM 76-19563.     

Opposing interactions between homothorax and Lobe define the ventral eye margin of Drosophila eye

Patterning in multi-cellular organisms involves progressive restriction of cell fates by generation of boundaries to divide an organ primordium into smaller fields. We have employed the Drosophila eye model to understand the genetic circuitry responsible for defining the boundary between the eye and the head cuticle on the ventral margin. The default state of the early eye is ventral and depends on the function of Lobe (L) and the Notch ligand Serrate (Ser). We identified homothorax (hth) as a strong enhancer of the L mutant phenotype of loss of ventral eye. Hth is a MEIS class gene with a highly conserved Meis-Hth (MH) domain and a homeodomain (HD). Hth is known to bind Extradenticle (Exd) via its MH domain for its nuclear translocation. Loss-of-function of hth, a negative regulator of eye, results in ectopic ventral eye enlargements. This phenotype is complementary to the L mutant phenotype of loss-of-ventral eye. However, if L and hth interact during ventral eye development remains unknown. Here we show that (i) L acts antagonistically to hth, (ii) Hth is upregulated in the L mutant background, and (iii) MH domain of Hth is required for its genetic interaction with L, while its homeodomain is not, (iv) in L mutant background ventral eye suppression function of Hth involves novel MH domain-dependent factor(s), and (v) nuclear localization of Exd is not sufficient to mediate the Hth function in the L mutant background. Further, Exd is not a critical rate-limiting factor for the Hth function. Thus, optimum levels of L and Hth are required to define the boundary between the developing eye and head cuticle on the ventral margin.     

Studies on transvection at the bithorax complex in Drosophila melanogaster

Summary We have studied the influence of some mutations in the bithorax complex on the observed synapsis dependent phenotype of the genotypes Cbx ¹Ubx¹/+ and bx ^34e/Ubx¹. The effect of these mutations is similar to that introduced by disruption of pairing or by the z ^a mutation. Among the bx mutations, we find that bx ⁸ behaves differently from most other bx mutations in its influence on the synapsis dependent phenotype. This observation induced us to map the position of bx ⁸ with respect to other bx mutations; we find that it maps between bx ^34e and bx ³. We show how some of the observations reported here can be fitted into a model of activation of the bithorax complex proposed by one of us.     

Genetic characterization of the mei-41 locus in Drosophila melanogaster

Summary The mutagen-sensitive mutant mus(1)104 ^D1 of Drosophila melanogaster maps to a position on the X chromosome very close to the meiotic mutant mei-41 ^D5 . Both mutants have been characterized as mutagen-sensitive and defective in post-replication repair. In the present report we show by complementation studies that mus(1)104 and mus(1)103 are allelic with mei-41. In addition, two reported alleles of mus(1)104 lie between the mei-41 alleles A10 and D5. The size of the mei-41 locus is estimated to be about 0.1 centimorgans (cM). Because several alleles of mei-41 have been shown to reduce recombination and increase meiotic chromosome loss and nondisjunction, mus(1)104 ^D1 females were examined for defects in meiosis. Although there was no evidence for reduced recombination on the second chromosome in homozygous mus(1)104 ^D1 females, heterozygous mus(1)104 ^D1 /mei-41 ^>D5 and mus(1)104 ^D1 /deficiency females showed reduced levels of recombination. However, there was no evidence of an increase in nondijunction in these females.We dedicate this article to the memory of Larry Sandler, who passed away suddenly on February 7, 1987     

Genetic control of macrochaetae development in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

The Drosophila head and body have a regular species-specific pattern of strictly defined number of external sensory organs—macrochaetae (large bristles). The pattern constancy and relatively simple organization of each bristle organ composed of only four specialized cells makes macrochaetae a convenient model to study the developmental patterns of spatial structures with a fixed number of elements in specific positions as well as the mechanisms of cell differentiation. The experimental data on the major genes and their products controlling three stages of macrochaetae development—the emergence of proneural clusters in the imaginal disc ectoderm, the precursor cell determination in the proneural clusters, and the specialization of cells of the definitive sensory organ—were reviewed. The role of the achaete-scute gene complex, EGFR and Notch signaling, and selector genes in these processes was considered. Analysis of published data allowed us to propose an integrated diagram of the system controlling macrochaetae development in D. melanogaster.     

Mobile elements and transposition events in the cut locus of Drosophila melanogaster

We have cloned from the Oregon R strain of Drosophila melanogaster a 240 kb segment of DNA that contains the cut (ct) locus, and characterized the region for the presence of repetitive elements. Within this region at least five copies of the suffix element were detected, as well as several putatively novel mobile elements. A number of mutations obtained from the unstable ct ^MR2 strain and its derivatives were mapped within the cut locus. Comparison between parental and daughter strains indicates that frequently two or more independent transposition events involving the cut locus occur simultaneously within a single germ cell, thus providing a molecular basis for the transposition explosion phenomenon.     

Genetic,ontogenetic, and tissue-specific variation of dipeptidases in Drosophila melanogaster

Three dipeptidases in Drosophila melanogaster are under independent genetic control and their structural genes have been localized, Dip-A to 2R and Dip-B and Dip-C to 3R (Voelker and Langley, 1978; Ohnishi and Voelker, 1981). These enzymes were characterized with respect to their substrate specificities, genetic variability (electrophoretic mobility and quantitative activity level), ontogeny (activity and isozyme pattern), and tissue localization. The dipeptide substrate specificities of DIP-A and DIP-B overlap each other considerably, but do not overlap with DIP-C. In natural populations, DIP-B and DIP-C are essentially monomorphic electrophoretically whereas DIP-A is polymorphic for three allozymes. Both DIP-A and DIP-B show quantitative genetic variation of activity level within an allozyme class. All three enzymes are expressed at all stages in the life cycle, but DIP-A and DIP-B activities vary considerably according to developmental stage and sex of adult. The tissue localizations of DIP-A and DIP-B activities show similar patterns and a nearly ubiquitous occurrence of both enzymes, but with particularly high values in larval and adult midguts and in the adult female reproductive system. These results suggest a general metabolic role for the enzymes, such as regulation of the concentrated pools of amino acids and oligopeptides found in Drosophila tissues.This work was supported by Public Health Service Grant GM 11546.Paper No. 7066 of the Journal Series of the North Carolina Agricultural Research Service, Raleigh.     

Adh n5: A temperature-sensitive mutant at the Adh locus in Drosophila

Individuals of an alcohol dehydrogenase-negative strain of Drosophila melanogaster designated Adh ⁿ⁵ are resistant to ethanol poisoning at low but not at high temperatures. The basis for this behavior is that Adh ⁿ⁵ flies contain a mutant form of alcohol dehydrogenase which is less heat stable than that of wild-type flies. The mutation in Adh ⁿ⁵ maps at, or very close to, the presumptive structural locus and is not complemented by any of 11 other alcohol dehydrogenase-null mutants.This research was supported by Grant No. GM 18254 from the National Institutes of Health and Grant No. M55.2217 from the National Cancer Institute.Publication No. 768 from the Department of Biology, Johns Hopkins University.     

Nucleotide divergence of the rp49 gene region between Drosophila melanogaster and two species of the Obscura group of Drosophila

Summary A 2.1-kb SStI fragment including the rp49 gene and the 3 end of the -serendipity gene has been cloned and sequenced in Drosophila pseudoobscura. rp49 maps at region 62 on the tip of chromosome II of this species. Both the coding and flanking regions have been aligned and compared with those of D. subobscura. There is no evidence for heterogeneity in the rate of silent substitution between the rp49 coding region and the rate of substitutions in flanking regions, the overall silent divergence per site being 0.19. Noncoding regions also differ between both species by different insertions/deletions, some of which are related to repeated sequences. The rp49 region of D. pseudoobscura shows a strong codon bias similar to those of D. subobscura and D. melanogaster. Comparison of the rates of silent (K _S ) and nonsilent (K _a ) substitutions of the rp49 gene and other genes completely sequenced in D. pseudoobscura and D. melanogaster confirms previous results indicating that rp49 is evolving slowly both at silent and nonsilent sites. According to the data for the rp49 region, D. pseudoobscura and D. subobscura lineages would have diverged some 9 Myr ago, if one assumes a divergence time of 30 Myr for the melanogaster and obscura groups.Offprint requests to: C. Segarra     

Rudimentary locus of Drosophila melanogaster: Partial purification of a carbamylphosphate synthase-aspartate transcarbamylase-dihydroorotase complex

Glutamine-dependent CPSase, ATCase, and DHOase from Drosophila, the first three enzymes in pyrimidine biosynthesis, show coordinate variation in activity throughout development. The three activities were highest in first instar larvae and decreased as development proceeded. The three activities cosediment in sucrose gradients as a single peak with a relative sedimentation coefficient of approximately 30S. CPSase, ATCase, and DHOase copurify during (NH₄) ₂SO₄ fractionation and during DEAE-cellulose and hydroxylapatite chromatography.This work was supported by a grant from the National Science Foundation (No. PCM75-22802). In addition, Stuart I. Tsubota was a NIH Predoctoral Trainee (No. 5T32-GM07 127) and Susan E. Germeraad was a Cystic Fibrosis Foundation Postdoctoral Fellow.     

Complex genetic interactions govern the temporal effects of <Emphasis Type="Italic">Antennapedia</Emphasis> on antenna-to-leg transformations in <Emphasis Type="Italic">Drosophila melanogaster</Emphasis>

The putative regulatory relationships between Antennapedia (Antp), spalt major (salm) and homothorax (hth) are tested with regard to the sensitive period of antenna-to-leg transformations. Although Antp expression repressed hth as predicted, contrary to expectations, hth did not show increased repression at higher Antp doses, whereas salm, a gene downstream of hth, did show such a dose response. Loss of hth allowed antenna-to-leg transformations but the relative timing of proximal-distal transformations was reversed, relative to transformations induced by ectopic Antp. Finally, overexpression of Hth was only partially able to rescue transformations induced by ectopic Antp. These results indicate that there may be additional molecules involved in antenna/leg identity and that spatial, temporal and dosage relationships are more subtle than suspected and must be part of a robust understanding of molecular network behaviour involved in determining appendage identity in Drosophila melanogaster.     

Expression Pattern Diversity and Functional Conservation Between Retroposed PRAT Genes from Drosophila melanogaster and Drosophila virilis

Gene duplication by retrotransposition duplicates only the coding and untranslated regions of a gene and, thus, biases retroduplicated genes toward having different expression patterns from their parental genes. As such, genes duplicated by retrotransposition are more likely to develop novel expression domains. To explore this idea further, we used the Prat/Prat2 gene duplication in Drosophila as a case study to examine the aftermath of a retrotransposition event that resulted in both the parent and the child gene becoming essential for survival. We used the Gal4-UAS transgene system with EGFP as a reporter to determine the developmental expression patterns of Prat and Prat2 from D. melanogaster (DmPrat and DmPrat2) and Prat from D. virilis (DvPrat). We also tested the functional equivalence of the protein products of DmPrat and DmPrat2. We found that each of the proteins could rescue DmPrat mutations, showing that the requirement for both Prat and Prat2 in Drosophila is not simply due to differences in protein function. In contrast, we found that the DmPrat and DmPrat2 genes have developed nonoverlapping patterns of expression, which correlate with their respective loss-of-function phenotypes. We further found that DvPrat expression is similar to DmPrat during development but differs in adult gonads. Thus, the function of the Prat retrogene has not diverged in the D. melanogaster and D. virilis lineages, while some aspects of its expression pattern have evolved. Finally, we have identified promoter elements, conserved upstream of DmPrat and DvPrat, that this retrogene has acquired to drive its expression.     

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.     

Selection at the alcohol dehydrogenase locus of Drosophila melanogaster: Effects of ethanol and temperature

Drosophila melanogaster larvae were subjected to 10 generations of selection on 6% ethanol at 17, 25, and 30°C. For each temperature there was a significant (P<0.01) increase in the frequency of the Adh isoallele. Controls with no ethanol showed no change in the frequency of the Adh ^F isoallele. Larvae subjected to stronger selection on 8% ethanol confirmed the results. When adults of various ages were subjected to 16 and 32°C, the ADH^F isoenzyme retained its twofold advantage in activity over ADH^S regardless of the temperature. The same result was obtained with larvae at 16 and 35°C. Although some effect of temperature was demonstrated, it was concluded that the effect was not strong enough for temperature to be a selective factor under the conditions studied. However, ethanol is a strong selective factor for laboratory populations.     

Dominant maternal interactions with Drosophila segmentation genes

Summary A systematic search for X chromosome loci showing a dominant maternal interaction with the segmentation genes Krüppel, hunchback, knirps and hairy was performed using deficiencies spanning 65% of the X chromosome. No interaction with the knirps gene was observed, but five regions of the X chromosome showed a maternal dominant interaction with the Krüppel gene. Two of these regions also show a maternal dominant interaction with either hunchback (region 10A7–10A8) or hairy (region 10E1–10F3). In all of these interactions dead embryos were observed which showed the same defects as embryos homozygous for the segmentation gene tested. These results suggest that a complex repartition of maternal products necessary for subsequent segmentation may occur in the Drosophila egg.     

Drosophila morgue and the intersection between protein ubiquitination and programmed cell death

In Drosophila, cell survival decisions are mediated by the integrated functions of the Grim-Reaper death activators and Inhibitor-of-Apoptosis-Proteins (IAPs), such as DIAP1, to regulate caspase activities. We recently identified a gene that enhances the actions of the Grim-Reaper proteins and negatively regulates the levels of DIAP1 protein. This gene, morgue, encodes a novel protein that contains both an F box and a ubiquitin conjugase domain. Interestingly, the Morgue conjugase domain lacks the active site cysteine required for covalent linkage to ubiquitin. Morgue could target IAPs and other proteins for ubiquitination and proteasome-dependent turnover by acting either in an SCF ubiquitin E3 ligase complex, or as a ubiquitin E2 conjugase enzyme variant (UEV) in conjunction with a catalytically active E2 conjugase. Morgue is evolutionarily conserved, as a Morgue ortholog was identified from the mosquito, Anopheles gambiae. Elucidation of morgue function should provide novel insights into the mechanisms of ubiquitination and programmed cell death.