Molecular organization of the cut locus of Drosophila melanogaster

Mutations of the cut locus (ct) of Drosophila can be divided into four groups based on their phenotypes and complementation patterns. Each group alters the phenotype of a different set of tissues. Two hundred kilobases of ct DNA, located in 7B1-2, have been cloned by chromosomal walking, and the cloned sequences have been used to analyze more than 40 mutants. Based on the location of transposable element mutations and the extent of deficiencies and an inversion, four cut locus regions can be defined. Mutations in each region affect the phenotype of a different set of tissues. The most centromere proximal region contains mutations that are null for cut locus function. Within individual regions, a higher level of organization can be detected.     

A Cytogenetic Analysis of Chromosomal Region 31 of Drosophila Melanogaster

Cytogenetic region 31 of the second chromosome of Drosophila melanogaster was screened for recessive lethal mutations. One hundred and thirty nine new recessive lethal alleles were isolated that fail to complement Df(2L)J2 (31A-32A). These new alleles, combined with preexisting mutations in the region, define 52 complementation groups, 35 of which have not previously been described. Among the new mutations were alleles of the cdc2 and mfs(2)31 genes. Six new deficiencies were also isolated and characterized identifying 16 deficiency subintervals within region 31. The new deficiencies were used to further localize three loci believed to encode non-histone chromosomal proteins. Suvar(2)1/Su(var)214, a dominant suppressor of position-effect variegation (PEV), maps to 31A-B, while the recessive suppressors of PEV mfs(2)31 and wdl were localized to regions 31E and 31F-32A, respectively. In addition, the cytological position of several mutations that interact with heterochromatin were more precisely defined.     

Deficiency screening for genomic regions with effects on environmental sensitivity of the sensory bristles of Drosophila melanogaster

Environmental canalization is defined as a reduction in the effect of external environmental perturbations on a phenotype, while phenotypic plasticity is defined as the production of different phenotypes in alternative environments. These terms describe different aspects of the same phenomenon, that is, the sensitivity of the phenotype to the environment. Genetic regulation of the environmental sensitivity has been a central topic in the field of evolutionary biology. In this study, we performed deficiency screening to detect genomic regions with effects on the environmental sensitivity of Drosophila melanogaster sensory bristles. We used a collection of isogenic deficiency strains established by the DrosDel Project for screening. We screened 423 genomic deficiencies that encompassed approximately 63.6% of the entire D. melanogaster genome. We identified 29 genomic deficiencies showing significant effects on environmental sensitivity, suggesting that multiple genomic regions may influence phenotypic variation. We also found significant correlations among the effects of deficiencies on environmental sensitivity for different bristle traits, suggesting that the same genetic mechanism can regulate environmental sensitivity of multiple traits. Current high-resolution mapping will facilitate the examination of individual candidate genes using mutations or RNAi approaches in future studies.     

Cardiomyopathy is associated with ribosomal protein gene haplo-insufficiency in Drosophila melanogaster

The Minute syndrome in Drosophila melanogaster is characterized by delayed development, poor fertility, and short slender bristles. Many Minute loci correspond to disruptions of genes for cytoplasmic ribosomal proteins, and therefore the phenotype has been attributed to alterations in translational processes. Although protein translation is crucial for all cells in an organism, it is unclear why Minute mutations cause effects in specific tissues. To determine whether the heart is sensitive to haplo-insufficiency of genes encoding ribosomal proteins, we measured heart function of Minute mutants using optical coherence tomography. We found that cardiomyopathy is associated with the Minute syndrome caused by haplo-insufficiency of genes encoding cytoplasmic ribosomal proteins. While mutations of genes encoding non-Minute cytoplasmic ribosomal proteins are homozygous lethal, heterozygous deficiencies spanning these non-Minute genes did not cause a change in cardiac function. Deficiencies of genes for non-Minute mitochondrial ribosomal proteins also did not show abnormal cardiac function, with the exception of a heterozygous disruption of mRpS33. We demonstrate that cardiomyopathy is a common trait of the Minute syndrome caused by haplo-insufficiency of genes encoding cytoplasmic ribosomal proteins. In contrast, most cases of heterozygous deficiencies of genes encoding non-Minute ribosomal proteins have normal heart function in adult Drosophila.     

DNA repair defects and other (mus)takes in Drosophila melanogaster.

Preservation of the structural integrity of DNA in any organism is crucial to its health and survival. Such preservation is achieved by an extraordinary cellular arsenal of damage surveillance and repair functions, many of which are now being defined at the gene and protein levels. Mutants hypersensitive to the killing effects of DNA-damaging agents have been instrumental in helping to identify DNA repair-related genes and to elucidate repair mechanisms. In Drosophila melanogaster, such strains are generally referred to as mutagen-sensitive (mus) mutants and currently define more than 30 genetic loci. Whereas most mus mutants have been recovered on the basis of hypersensitivity to the monofunctional alkylating agent methyl methanesulfonate, they nevertheless constitute a phenotypically diverse group, with many mutants having effects beyond mutagen sensitivity. These phenotypes include meiotic dysfunctions, somatic chromosome instabilities, chromatin abnormalities, and cell proliferation defects. Within the last few years numerous mus and other DNA repair-related genes of Drosophila have been molecularly cloned, providing new insights into the functions of these genes. This article outlines strategies for isolating mus mutations and reviews recent advances in the Drosophila DNA repair field, emphasizing mutant analysis and gene cloning.     

A deficiency screen for dominant suppressors of telomeric silencing in Drosophila

Heterochromatin is a specialized chromatin structure in chromosomal regions associated with repeated DNA sequences and low concentrations of genes. Formation of heterochromatin is determined in large part by enzymes that modify histones and structural proteins that bind to these modified histones in a cooperative fashion. In Drosophila, mutations in genes that encode heterochromatic proteins are often dominant and increase expression of genes placed into heterochromatic positions. To find components of telomeric heterochromatin in Drosophila, we screened a collection of autosomal deficiencies for dominant suppressors of silencing of a transgene at the telomere of chromosome 2L. While many deficiency chromosomes are associated with dominant suppressors, in the cases tested on chromosome 2 the suppressor mapped to the 2L telomere, rather than the deficiency. We infer that background effects may hamper the search for genes that play a role in telomeric heterochromatin formation and that either very few genes participate in this pathway or mutations in these genes are not dominant suppressors of telomeric position effect. The data also suggest that the 2L telomere region plays a major role in telomeric silencing.     

Identification and functional analysis of antifungal immune response genes in Drosophila

Essential aspects of the innate immune response to microbial infection appear to be conserved between insects and mammals. Although signaling pathways that activate NF-kappaB during innate immune responses to various microorganisms have been studied in detail, regulatory mechanisms that control other immune responses to fungal infection require further investigation. To identify new Drosophila genes involved in antifungal immune responses, we selected genes known to be differentially regulated in SL2 cells by microbial cell wall components and tested their roles in antifungal defense using mutant flies. From 130 mutant lines, sixteen mutants exhibited increased sensitivity to fungal infection. Examination of their effects on defense against various types of bacteria and fungi revealed nine genes that are involved specifically in defense against fungal infection. All of these mutants displayed defects in phagocytosis or activation of antimicrobial peptide genes following infection. In some mutants, these immune deficiencies were attributed to defects in hemocyte development and differentiation, while other mutants showed specific defects in immune signaling required for humoral or cellular immune responses. Our results identify a new class of genes involved in antifungal immune responses in Drosophila.     

Spectra of molecular changes induced in DNA of Drosophila spermatozoa by 1-ethyl-1-nitrosourea and X-rays

Mutations induced in Drosophila spermatozoa at the alcohol dehydrogenase Adh locus by 1-ethyl-1-nitrosourea (ENU) were compared to X-ray-induced mutations using genetic tests for complementation, southern blotting, western blotting and northern blotting. 8 of 10 ENU-induced mutations complemented all known adjacent loci and were presumed to be intragenic. In contrast, 8 of 30 X-ray-induced mutations were intragenic. Southern blot analysis showed that 2 of 7 intragenic mutations induced by X-rays were altered at the Adh locus, whereas all 8 intragenic ENU mutants appeared normal. Western blot analysis showed 4 of 7 intragenic mutants induced by X-rays produced a detectable polypeptide; 1 of the 4 had normal molecular weight and charge. In contrast, 7 of the 8 intragenic mutants induced by ENU produced a polypeptide of normal molecular weight and charge. One ENU and two X-ray-induced mutants, which had normal southern blots and no detectable polypeptide, produced normal molecular weight mRNA by northern blots. The interpretation of these results is that in spermatozoa X-rays induce primarily deletions that either produce deficiencies of the Adh locus or nonsense mutations within the locus, whereas ENU induces primarily missense mutations. This forward mutation assay based on loss of enzymatic activity efficiently recovered a broad spectrum of mutations ranging from missense to intragenic deletions and multi-locus deficiencies. Only 3 of these 40 mutations produced a polypeptide detectable as an electrophoretic variant.     

Introducing defined chromosomal rearrangements into the mouse genome

Chromosomal rearrangements have been instrumental in genetic studies in Drosophila. Visibly marked deficiencies (deletions) are used in mapping studies and region-specific mutagenesis screens by providing segmental haploidy required to uncover recessive mutations. Marked recessive lethal inversions are used as balancer chromosomes to maintain recessive lethal mutations and to maintain the integrity of mutagenized chromosomes. In mice, studies on series of radiation-induced deletions that surround several visible mutations have yielded invaluable functional genomic information in the regions analyzed. However, most regions of the mouse genome are not accessible to such analyses due to a lack of marked chromosomal rearrangements. Here we describe a method to generate defined chromosomal rearrangements using the Cre--loxP recombination system based on a published strategy [R. Ramirez-Solis, P. Liu, and A. Bradley, (1995) Nature 378, 720--724]. Various types of rearrangements, such as deletions, duplications, inversions, and translocations, can be engineered using this strategy. Furthermore, the rearrangements can be visibly marked with coat color genes, providing essential reagents for large-scale recessive genetic screens in the mouse. The ability to generate marked chromosomal rearrangements will help to elevate the level of manipulative mouse genetics to that of Drosophila genetics.     

Isolation and characterization of mutants for the vesicular acetylcholine transporter gene in Drosophila melanogaster

The Drosophila vesicular acetylcholine transporter gene (Vacht) is nested within the first intron of the choline acetyltransferase gene (Cha). To isolate Vacht mutants, we performed an F(2) genetic screen and identified mutations that failed to complement Df(3R)Cha(5), a deletion lacking Cha and the surrounding genes. Of these mutations, three mapped to a small genomic region where Cha resides. Complementation tests with a Cha mutant allele and rescue experiments using a transgenic Vacht minigene have revealed that two of these three mutations are nonconditional lethal alleles of Vacht (Vacht(1) and Vacht(2) ). The other is a new temperature-sensitive allele of Cha (Cha(ts3) ). Newly isolated Vacht mutants were used to reexamine the existing Cha mutations. We found that all deficiencies uncovering Cha also lack Vacht function, reflecting the nested organization of the two genes. The effective lethal phase for Vacht(1) is the embryonic stage, whereas that for Vacht(2) is the larval stage. Viable first-instar larvae homozygous for Vacht(2) showed reduced motility. Adult flies heterozygous for Vacht mutations were found to have defective responses in the dorsal longitudinal muscles following high-frequency brain stimulation. Since cholinergic synapses have been shown to be involved in the giant fiber pathway that mediates this response, the result suggested that reduction in the Vacht activity to 50% causes an abnormality in cholinergic transmission when stressed by a high-frequency stimulus.     

Evidence for Coadaptation: Negative Correlation between Lethal Genes and Polymorphic Inversions in DROSOPHILA MELANOGASTER

Through examination of all available data on lethal and inversion frequencies on the second chromosome in natural populations of Drosophila melanogaster, we have discovered that there is a clear negative correlation between the two quantities. Lethal genes are located more densely on the regions of standard gene arrangement than the inverted regions, and this accounts for the negative correlation. To reveal the underlying mechanism of the phenomena, we have carried out an experiment and found that effect of EMS-induced mutations on the inversion-carrying chromosome is more severe than that on the standard chromosome. We interpret these results as evidence for coadaptation or position-effect within the inversion chromosomes. New mutations within the coadapted gene complex are quickly eliminated from the population and polymorphic inversions are kept free of mutants through selective elimination.     

Formaldehyde mutagenesis of the eT1 balanced region in Caenorhabditis elegans: dose-response curve and the analysis of mutational events

In this study we have generated a dose-response curve for the formaldehyde induction of recessive lethal mutations in the eT1(III;V)-balanced region of C. elegans. We have mapped 96 out of 112 formaldehyde-induced lesions to either LGIII or LGV and genetically analyzed 31 lesions that mapped to LGV. Our findings showed that a 4-h treatment with 0.1% formaldehyde gave the best mutation induction frequency with the least side effects. We found that formaldehyde induced putative point mutations, deficiencies and more complex lesions in C. elegans. We isolated 11 putative point mutations, 3 of which defined new genes and 8 were alleles of known genes. One of the new genes, let-450, is currently the left-most known gene on LGV. We also isolated 5 deficiencies. Our formaldehyde-induced lesions increased the number of zones in the eT1-balanced region of LGV from 22 to 34.     

Identification of Regions Interacting with Ovo(d) Mutations: Potential New Genes Involved in Germline Sex Determination or Differentiation in Drosophila Melanogaster

Only a few Drosophila melanogaster germline sex determination genes are known, and there have been no systematic screens to identify new genes involved in this important biological process. The ovarian phenotypes produced by females mutant for dominant alleles of the ovo gene are modified in flies with altered doses of other loci involved in germline sex determination in Drosophila (Sex-lethal(+), sans fille(+) and ovarian tumor(+)). This observation constitutes the basis for a screen to identify additional genes required for proper establishment of germline sexual identity. We tested 300 deletions, which together cover ~58% of the euchromatic portion of the genome, for genetic interactions with ovo(D). Hemizygosity for more than a dozen small regions show interactions that either partially suppress or enhance the ovarian phenotypes of females mutant for one or more of the three dominant ovo mutations. These regions probably contain genes whose products act in developmental hierarchies that include ovo(+) protein.     

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.     

Maxillopedia is the Tribolium ortholog of proboscipedia

SUMMARY Null mutations in the Drosophila melanogaster homeotic gene proboscipedia ( pb ) cause transformation of the adult labial palps to legs. The similar phenotype produced by mutations in the Tribolium castaneum homeotic complex (HOMC) gene maxillopedia ( mxp ) has led to suggestions that the two genes may be orthologous. We have cloned the Tribolium ortholog of pb , which predicts a protein with a homeodomain identical to that of Drosophila Pb. The two proteins also share several additional regions of identity, including an N-box, a motif unique to Pb orthologs. We have identified a frameshift mutation within Tribolium pb associated with an mxp null mutation, demonstrating that Tribolium pb corresponds to the mxp genetic locus. Thus, we will refer to the cloned gene as mxp . In addition, we have begun to construct a molecular map of the Tribolium HOMC. Two overlapping BAC clones which span the mxp locus also include the Tribolium labial ortholog ( Tclabial   ) and part of Tczerknüllt , indicating that the order of these genes in the HOMC is conserved between Drosophila and Tribolium.     

Genetic Analysis of Fin Development in Zebrafish Identifies Furin and Hemicentin1 as Potential Novel Fraser Syndrome Disease Genes

Using forward genetics, we have identified the genes mutated in two classes of zebrafish fin mutants. The mutants of the first class are characterized by defects in embryonic fin morphogenesis, which are due to mutations in a Laminin subunit or an Integrin alpha receptor, respectively. The mutants of the second class display characteristic blistering underneath the basement membrane of the fin epidermis. Three of them are due to mutations in zebrafish orthologues of FRAS1, FREM1, or FREM2, large basement membrane protein encoding genes that are mutated in mouse bleb mutants and in human patients suffering from Fraser Syndrome, a rare congenital condition characterized by syndactyly and cryptophthalmos. Fin blistering in a fourth group of zebrafish mutants is caused by mutations in Hemicentin1 (Hmcn1), another large extracellular matrix protein the function of which in vertebrates was hitherto unknown. Our mutant and dose-dependent interaction data suggest a potential involvement of Hmcn1 in Fraser complex-dependent basement membrane anchorage. Furthermore, we present biochemical and genetic data suggesting a role for the proprotein convertase FurinA in zebrafish fin development and cell surface shedding of Fras1 and Frem2, thereby allowing proper localization of the proteins within the basement membrane of forming fins. Finally, we identify the extracellular matrix protein Fibrillin2 as an indispensable interaction partner of Hmcn1. Thus we have defined a series of zebrafish mutants modelling Fraser Syndrome and have identified several implicated novel genes that might help to further elucidate the mechanisms of basement membrane anchorage and of the disease''s aetiology. In addition, the novel genes might prove helpful to unravel the molecular nature of thus far unresolved cases of the human disease.     

Identification of Drosophila mutants altering defense of and endurance to Listeria monocytogenes infection

We extended the use of Drosophila beyond being a model for signaling pathways required for pattern recognition immune signaling and show that the fly can be used to identify genes required for pathogenesis and host-pathogen interactions. We performed a forward genetic screen to identify Drosophila mutations altering sensitivity to the intracellular pathogen Listeria monocytogenes. We recovered 18 mutants with increased susceptibility to infection, none of which were previously shown to function in a Drosophila immune response. Using secondary screens, we divided these mutants into two groups: In the first group, mutants have reduced endurance to infections but show no change in bacterial growth. This is a new fly immunity phenotype that is not commonly studied. In the second group, mutants have a typical defense defect in which bacterial growth is increased and survival is decreased. By further challenging mutant flies with L. monocytogenes mutants, we identified subgroups of fly mutants that affect specific stages of the L. monocytogenes life cycle, exit from the vacuole, or actin-based movement. There is no overlap between our genes and the hundreds of genes identified in Drosophila S2 cells fighting L. monocytogenes infection, using genomewide RNAi screens in vitro. By using a whole-animal model and screening for host survival, we revealed genes involved in physiologies different from those that were found in previous screens, which all had defects in defensive immune signaling.