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2. The Release 6 Drosophila melanogaster reference genome

Author

Hoskins, R. A., Carlson, J. W., Wan, K. H., Park, S., Mendez, I., Galle, S. E., Booth, B., Pfeiffer1, B. D., George, R. A., Svirskas, R., Krzywinski, M., Schein, J., Accardo, M. C., Damia, E., Messina, Giovanni, Mendez Lago, M., Demakova, O. V., Andreyeva, E. N., Boldyreva, L. V., Marra, M., Carvalho, A. B., Dimitri, Patrizio, Villasante, A., Zhimulev, I. F., Rubin, G. M., Karpen, G. H., and Celniker, S. E.

Subjects
drosophila genome sequence, Heterochromatin, cytogenetic mapping
Published
2015

3. The Release 6 reference sequence of the Drosophila melanogaster genome

Author

Hoskins, R, Carlson, J, Wan, K, Park, S, Mendez, I, Galle, S, Booth, B, Pfeiffer, B, George, R, Svirskas, R, Krzywinski, M, Schein, J, Accardo, M, Damia, E, Messina, G, Mendez-Lago, M, De Pablos, B, Demakova, O, Andreyeva, E, Boldyreva, L, Marra, M, Carvalho, A, Dimitri, P, Villasante, A, Zhimulev, I, Rubin, G, Karpen, G, Celniker, S, Hoskins R. A., Carlson J. W., Wan K. H., Park S., Mendez I., Galle S. E., Booth B. W., Pfeiffer B. D., George R. A., Svirskas R., Krzywinski M., Schein J., Accardo M. C., Damia E., Messina G., Mendez-Lago M., De Pablos B., Demakova O. V., Andreyeva E. N., Boldyreva L. V., Marra M., Carvalho A. B., Dimitri P., Villasante A., Zhimulev I. F., Rubin G. M., Karpen G. H., Celniker S. E., Hoskins, R, Carlson, J, Wan, K, Park, S, Mendez, I, Galle, S, Booth, B, Pfeiffer, B, George, R, Svirskas, R, Krzywinski, M, Schein, J, Accardo, M, Damia, E, Messina, G, Mendez-Lago, M, De Pablos, B, Demakova, O, Andreyeva, E, Boldyreva, L, Marra, M, Carvalho, A, Dimitri, P, Villasante, A, Zhimulev, I, Rubin, G, Karpen, G, Celniker, S, Hoskins R. A., Carlson J. W., Wan K. H., Park S., Mendez I., Galle S. E., Booth B. W., Pfeiffer B. D., George R. A., Svirskas R., Krzywinski M., Schein J., Accardo M. C., Damia E., Messina G., Mendez-Lago M., De Pablos B., Demakova O. V., Andreyeva E. N., Boldyreva L. V., Marra M., Carvalho A. B., Dimitri P., Villasante A., Zhimulev I. F., Rubin G. M., Karpen G. H., and Celniker S. E.

Abstract

Drosophila melanogaster plays an important role in molecular, genetic, and genomic studies of heredity, development, metabolism, behavior, and human disease. The initial reference genome sequence reported more than a decade ago had a profound impact on progress in Drosophila research, and improving the accuracy and completeness of this sequence continues to be important to further progress. We previously described improvement of the 117-Mb sequence in the euchromatic portion of the genome and 21 Mb in the heterochromatic portion, using a whole-genome shotgun assembly, BAC physical mapping, and clone-based finishing. Here, we report an improved reference sequence of the single-copy and middle-repetitive regions of the genome, produced using cytogenetic mapping to mitotic and polytene chromosomes, clone-based finishing and BAC fingerprint verification, ordering of scaffolds by alignment to cDNA sequences, incorporation of other map and sequence data, and validation by whole-genome optical restriction mapping. These data substantially improve the accuracy and completeness of the reference sequence and the order and orientation of sequence scaffolds into chromosome arm assemblies. Representation of the Y chromosome and other heterochromatic regions is particularly improved. The new 143.9-Mb reference sequence, designated Release 6, effectively exhausts clone-based technologies for mapping and sequencing. Highly repeat-rich regions, including large satellite blocks and functional elements such as the ribosomal RNA genes and the centromeres, are largely inaccessible to current sequencing and assembly methods and remain poorly represented. Further significant improvements will require sequencing technologies that do not depend on molecular cloning and that produce very long reads.

Published
2015

4. Exploiting position effects and the gypsy retrovirus insulator to engineer precisely expressed transgenes

Author

Markstein, M., Pitsouli, Chrysoula, Villalta, C., Celniker, S. E., Perrimon, N., and Pitsouli, Chrysoula [0000-0003-4074-9684]

Subjects
insulator element, Genome, Insect, Genome, Wing, Animals, Genetically Modified, Retrovirus, Drosophila Proteins, Wings, Animal, Tissue Distribution, Transgenes, transcription factor GAL4, Recombination, Genetic, Regulation of gene expression, Genetics, Receptors, Notch, article, luciferase, Chromatin, Drosophila melanogaster, Phenotype, Position effect, priority journal, Myogenic Regulatory Factors, Larva, Attachment Sites, Microbiological, Drosophila, Female, Insulator Elements, Plasmids, Saccharomyces cerevisiae Proteins, gene locus, phenotype, Transgene, DNA transcription, Molecular Sequence Data, Biology, Article, Animals, controlled study, HSP70 Heat-Shock Proteins, Epigenetics, nonhuman, transgene, nucleotide sequence, biology.organism_classification, Cytoskeletal Proteins, Retroviridae, Gene Expression Regulation, gene expression
Abstract

A major obstacle to creating precisely expressed transgenes lies in the epigenetic effects of the host chromatin that surrounds them. Here we present a strategy to overcome this problem, employing a Gal4-inducible luciferase assay to systematically quantify position effects of host chromatin and the ability of insulators to counteract these effects at phiC31 integration loci randomly distributed throughout the Drosophila genome. We identify loci that can be exploited to deliver precise doses of transgene expression to specific tissues. Moreover, we uncover a previously unrecognized property of the gypsy retrovirus insulator to boost gene expression to levels severalfold greater than at most or possibly all un-insulated loci, in every tissue tested. These findings provide the first opportunity to create a battery of transgenes that can be reliably expressed at high levels in virtually any tissue by integration at a single locus, and conversely, to engineer a controlled phenotypic allelic series by exploiting several loci. The generality of our approach makes it adaptable to other model systems to identify and modify loci for optimal transgene expression. © 2008 Nature Publishing Group. 40 476 483 Cited By :231

Published
2008

7. A Drosophila full-length cDNA resource

Author

Stapleton, M., Carlson, J., Brokstein, P., Yu, C., Champe, M., George, R., Guarin, H., Kronmiller, B., Pacleb, J., Park, S., Wan, K., Gerald Rubin, and Celniker, S. E.

Subjects
DNA, Complementary, Drosophila melanogaster, Base Sequence, Research, Databases, Genetic, Molecular Sequence Data, Animals, Genes, Insect, Amino Acid Sequence, Sequence Analysis, DNA
Abstract

High-quality full-insert sequence for 8,921 putative full-length cDNA clones in the Drosophila Gene Collection has been generated and compared to the annotated Release 3 genomic sequence. More than 5,300 cDNAs have been identifieed that contain a complete and accurate protein-coding sequence, corresponding to at least one splice form for 40% of the predicted D. melanogaster genes., Background A collection of sequenced full-length cDNAs is an important resource both for functional genomics studies and for the determination of the intron-exon structure of genes. Providing this resource to the Drosophila melanogaster research community has been a long-term goal of the Berkeley Drosophila Genome Project. We have previously described the Drosophila Gene Collection (DGC), a set of putative full-length cDNAs that was produced by generating and analyzing over 250,000 expressed sequence tags (ESTs) derived from a variety of tissues and developmental stages. Results We have generated high-quality full-insert sequence for 8,921 clones in the DGC. We compared the sequence of these clones to the annotated Release 3 genomic sequence, and identified more than 5,300 cDNAs that contain a complete and accurate protein-coding sequence. This corresponds to at least one splice form for 40% of the predicted D. melanogaster genes. We also identified potential new cases of RNA editing. Conclusions We show that comparison of cDNA sequences to a high-quality annotated genomic sequence is an effective approach to identifying and eliminating defective clones from a cDNA collection and ensure its utility for experimentation. Clones were eliminated either because they carry single nucleotide discrepancies, which most probably result from reverse transcriptase errors, or because they are truncated and contain only part of the protein-coding sequence.

Published
2002

8. Systematic determination of patterns of gene expression during Drosophila embryogenesis

Author

Tomancak, P., Beaton, A., Weiszmann, R., Kwan, E., Shu, S., Lewis, S. E., Richards, S., Ashburner, M., Hartenstein, V., Celniker, S. E., and Gerald Rubin

Subjects
animal structures, Drosophila melanogaster, Research, Gene Expression Profiling, Databases, Genetic, Image Processing, Computer-Assisted, Animals, Cluster Analysis, Database Management Systems, Gene Expression Regulation, Developmental, Genes, Insect, In Situ Hybridization, Oligonucleotide Array Sequence Analysis
Abstract

As a first step to creating a comprehensive atlas of gene-expression patterns during Drosophila embryogenesis, 2,179 genes have been examinded by in situ hybridization to fixed Drosophila embryos. Of the genes assayed, 63.7% displayed dynamic expression patterns that were documented with 25,690 digital photomicrographs of individual embryos., Background Cell-fate specification and tissue differentiation during development are largely achieved by the regulation of gene transcription. Results As a first step to creating a comprehensive atlas of gene-expression patterns during Drosophila embryogenesis, we examined 2,179 genes by in situ hybridization to fixed Drosophila embryos. Of the genes assayed, 63.7% displayed dynamic expression patterns that were documented with 25,690 digital photomicrographs of individual embryos. The photomicrographs were annotated using controlled vocabularies for anatomical structures that are organized into a developmental hierarchy. We also generated a detailed time course of gene expression during embryogenesis using microarrays to provide an independent corroboration of the in situ hybridization results. All image, annotation and microarray data are stored in publicly available database. We found that the RNA transcripts of about 1% of genes show clear subcellular localization. Nearly all the annotated expression patterns are distinct. We present an approach for organizing the data by hierarchical clustering of annotation terms that allows us to group tissues that express similar sets of genes as well as genes displaying similar expression patterns. Conclusions Analyzing gene-expression patterns by in situ hybridization to whole-mount embryos provides an extremely rich dataset that can be used to identify genes involved in developmental processes that have been missed by traditional genetic analysis. Systematic analysis of rigorously annotated patterns of gene expression will complement and extend the types of analyses carried out using expression microarrays.

Published
2002

14. Correction: Benchmarking tools for the alignment of functional noncoding DNA.

Author

Pollard, D. A., Bergman, C. M., Stoye, J., Celniker, S. E., and Eisen, M. B.

Subjects
DNA
Abstract

A correction to the article "Benchmarking Tools for the Alignment of Functional Noncoding DNA," by D. A. Pollard, C. M. Bergman, J. Stoye, S. E. Celniker and M. B. Eisen that was published in the 2004 issue of the periodical "BMC Bioinformatics" is presented.

Published
2004
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15. The transcriptional diversity of 25 Drosophila cell lines

Author

Cherbas, L., Willingham, A., Zhang, D., Yang, L., Zou, Y., Eads, B. D., Carlson, J. W., Landolin, J. M., Kapranov, P., Dumais, J, Samsonova, A., Choi, J.-H., Roberts, J., Davis, C. A., Tang, H., van Baren, M. J., Ghosh, S., Dobin, A., Bell, K., Lin, W., Langton, L., Duff, M. O., Tenney, A. E., Zaleski, C., Brent, M. R., Hoskins, R. A., Kaufman, T. C., Andrews, J., Graveley, B. R., Perrimon, N., Celniker, S. E., Gingeras, T. R., and Cherbas, P.

Abstract

Drosophila melanogaster cell lines are important resources for cell biologists. Here, we catalog the expression of exons, genes, and unannotated transcriptional signals for 25 lines. Unannotated transcription is substantial (typically 19% of euchromatic signal). Conservatively, we identify 1405 novel transcribed regions; 684 of these appear to be new exons of neighboring, often distant, genes. Sixty-four percent of genes are expressed detectably in at least one line, but only 21% are detected in all lines. Each cell line expresses, on average, 5885 genes, including a common set of 3109. Expression levels vary over several orders of magnitude. Major signaling pathways are well represented: most differentiation pathways are “off” and survival/growth pathways “on.” Roughly 50% of the genes expressed by each line are not part of the common set, and these show considerable individuality. Thirty-one percent are expressed at a higher level in at least one cell line than in any single developmental stage, suggesting that each line is enriched for genes characteristic of small sets of cells. Most remarkable is that imaginal disc-derived lines can generally be assigned, on the basis of expression, to small territories within developing discs. These mappings reveal unexpected stability of even fine-grained spatial determination. No two cell lines show identical transcription factor expression. We conclude that each line has retained features of an individual founder cell superimposed on a common “cell line“ gene expression pattern., Organismic and Evolutionary Biology

Published
2010
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16. Deletion mutations affecting autonomously replicating sequence ARS1 of Saccharomyces cerevisiae

Author

Celniker, S E, Sweder, K, Srienc, F, Bailey, J E, and Campbell, J L

Abstract

DNAs that contain specific yeast chromosomal sequences called ARSs transform Saccharomyces cerevisiae at high frequency and can replicate extrachromosomally as plasmids when introduced into S. cerevisiae by transformation. To determine the boundaries of the minimal sequences required for autonomous replication in S. cerevisiae, we have carried out in vitro mutagenesis of the first chromosomal ARS described, ARS1. Rather than identifying a distinct and continuous segment that mediates the ARS+ phenotype, we find three different functional domains within ARS1. We define domain A as the 11-base-pair (bp) sequence that is also found at most other ARS regions. It is necessary but not sufficient for high-frequency transformation. Domain B, which cannot mediate high-frequency transformation, or replicate by itself, is required for efficient, stable replication of plasmids containing domain A. Domain B, as we define it, is continuous with domain A in ARS1, but insertions of 4 bp between the two do not affect replication. The extent of domain B has an upper limit of 109 bp and a lower limit of 46 bp in size. There is no obvious sequence homology between domain B of ARS1 and any other ARS sequence. Finally, domain C is defined on the basis of our deletions as at least 200 bp flanking domain A on the opposite side from domain B and is also required for the stability of domain A in S. cerevisiae. The effect of deletions of domain C can be observed only in the absence of domain B, at least by the assays used in the current study, and the significance of this finding is discussed.

Published
1984
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17. Transabdominal, a dominant mutant of the Bithorax Complex, produces a sexually dimorphic segmental transformation in Drosophila.

Author

Celniker, S E and Lewis, E B

Abstract

Transabdominal (Tab), a dominant mutation in the Bithorax Complex (BX-C) of Drosophila, creates a sexually dimorphic pattern of segmental transformation that has complete penetrance and expressivity. Specific regions within the notum of the second thoracic segment (T2) are transformed into abdominal-like cuticle; thus, the Tab/ + notum has sets of short stripes that are black in males and only bordered with black in females. Also, Tab/ + abdominal tergites, A1-A6, inclusive, have small patches of A7-like tergite cuticle. Tab is inseparable from an 89E/90D inversion, whose DNA breakpoint in 89E is at +188 kb in the infra-abdominal-8 (iab-8) region of the BX-C. When probed with a pupal cDNA from the iab-7 region, labeling above background was not detected in wild-type wing discs but was detected in, and confined to, the notal region of Tab/ + wing discs. The Tab/ + phenotype is assumed to result from cis-overexpression of iab-7 in localized regions of segments T2-A6, inclusive.

Published
1987

18. Deletion mutations affecting autonomously replicating sequence ARS1 of Saccharomyces cerevisiae

Author

Celniker, S. E., Sweder, K., Srienc, F., Bailey, J. E., Campbell, J. L., Celniker, S. E., Sweder, K., Srienc, F., Bailey, J. E., and Campbell, J. L.

Abstract

DNAs that contain specific yeast chromosomal sequences called ARSs transform Saccharomyces cerevisiae at high frequency and can replicate extrachromosomally as plasmids when introduced into S. cerevisiae by transformation. To determine the boundaries of the minimal sequences required for autonomous replication in S. cerevisiae, we have carried out in vitro mutagenesis of the first chromosomal ARS described, ARS1. Rather than identifying a distinct and continuous segment that mediates the ARS+ phenotype, we find three different functional domains within ARS1. We define domain A as the 11-base-pair (bp) sequence that is also found at most other ARS regions. It is necessary but not sufficient for high-frequency transformation. Domain B, which cannot mediate high-frequency transformation, or replicate by itself, is required for efficient, stable replication of plasmids containing domain A. Domain B, as we define it, is continuous with domain A in ARS1, but insertions of 4 bp between the two do not affect replication. The extent of domain B has an upper limit of 109 bp and a lower limit of 46 bp in size. There is no obvious sequence homology between domain B of ARS1 and any other ARS sequence. Finally, domain C is defined on the basis of our deletions as at least 200 bp flanking domain A on the opposite side from domain B and is also required for the stability of domain A in S. cerevisiae. The effect of deletions of domain C can be observed only in the absence of domain B, at least by the assays used in the current study, and the significance of this finding is discussed.

Published
1984

21. Finishing a whole-genome shotgun: release 3 of the Drosophila melanogaster euchromatic genome sequence

Author

Celniker, S. E., Wheeler, D. A., Kronmiller, B., Carlson, J. W., Halpern, A., Patel, S., Adams, M., Champe, M., Dugan, S. P., Frise, E., Hodgson, A., George Weinstock, Hoskins, R. A., Laverty, T., Muzny, D. M., Nelson, C. R., Pacleb, J. M., Park, S., Pfeiffer, B. D., Richards, S., Sodergren, E. J., Svirskas, R., Tabor, P. E., Wan, K., Stapleton, M., Sutton, G. G., Venter, C., Weinstock, G., Scherer, S. E., Myers, E. W., Gibbs, R. A., and Rubin, G. M.

Subjects
Euchromatin, animal structures, Drosophila melanogaster, Genome, X Chromosome, Research Design, Research, Animals, Sequence Analysis, DNA, Physical Chromosome Mapping
Abstract

The Drosophila melanogaster genome was the first metazoan genome to be sequenced by whole-genome shotgun. Now, the sequence has been finished in a process designed to close gaps, improve sequence quality and validate the assembly., Background The Drosophila melanogaster genome was the first metazoan genome to have been sequenced by the whole-genome shotgun (WGS) method. Two issues relating to this achievement were widely debated in the genomics community: how correct is the sequence with respect to base-pair (bp) accuracy and frequency of assembly errors? And, how difficult is it to bring a WGS sequence to the accepted standard for finished sequence? We are now in a position to answer these questions. Results Our finishing process was designed to close gaps, improve sequence quality and validate the assembly. Sequence traces derived from the WGS and draft sequencing of individual bacterial artificial chromosomes (BACs) were assembled into BAC-sized segments. These segments were brought to high quality, and then joined to constitute the sequence of each chromosome arm. Overall assembly was verified by comparison to a physical map of fingerprinted BAC clones. In the current version of the 116.9 Mb euchromatic genome, called Release 3, the six euchromatic chromosome arms are represented by 13 scaffolds with a total of 37 sequence gaps. We compared Release 3 to Release 2; in autosomal regions of unique sequence, the error rate of Release 2 was one in 20,000 bp. Conclusions The WGS strategy can efficiently produce a high-quality sequence of a metazoan genome while generating the reagents required for sequence finishing. However, the initial method of repeat assembly was flawed. The sequence we report here, Release 3, is a reliable resource for molecular genetic experimentation and computational analysis.

24. The Drosophila genome.

Author

Celniker SE

Subjects
Animals, Gene Expression, Genetic Predisposition to Disease, Humans, Insect Proteins genetics, Insect Proteins physiology, Recombination, Genetic, Drosophila melanogaster genetics, Genes, Insect, Genome
Abstract

The past year has been a spectacular one for Drosophila research. The sequencing and annotation of the Drosophila melanogaster genome has allowed a comprehensive analysis of the first three eukaryotes to be sequenced-yeast, worm and fly-including an analysis of the fly's influences as a model for the study of human disease. This year has also seen the initiation of a full-length cDNA sequencing project and the first analysis of Drosophila development using high-density DNA microarrays containing several thousand Drosophila genes. For the first time homologous recombination has been demonstrated in flies and targeted gene disruptions may not be far off.

Published
2000
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25. The genome sequence of Drosophila melanogaster.

Author

Adams MD, Celniker SE, Holt RA, Evans CA, Gocayne JD, Amanatides PG, Scherer SE, Li PW, Hoskins RA, Galle RF, George RA, Lewis SE, Richards S, Ashburner M, Henderson SN, Sutton GG, Wortman JR, Yandell MD, Zhang Q, Chen LX, Brandon RC, Rogers YH, Blazej RG, Champe M, Pfeiffer BD, Wan KH, Doyle C, Baxter EG, Helt G, Nelson CR, Gabor GL, Abril JF, Agbayani A, An HJ, Andrews-Pfannkoch C, Baldwin D, Ballew RM, Basu A, Baxendale J, Bayraktaroglu L, Beasley EM, Beeson KY, Benos PV, Berman BP, Bhandari D, Bolshakov S, Borkova D, Botchan MR, Bouck J, Brokstein P, Brottier P, Burtis KC, Busam DA, Butler H, Cadieu E, Center A, Chandra I, Cherry JM, Cawley S, Dahlke C, Davenport LB, Davies P, de Pablos B, Delcher A, Deng Z, Mays AD, Dew I, Dietz SM, Dodson K, Doup LE, Downes M, Dugan-Rocha S, Dunkov BC, Dunn P, Durbin KJ, Evangelista CC, Ferraz C, Ferriera S, Fleischmann W, Fosler C, Gabrielian AE, Garg NS, Gelbart WM, Glasser K, Glodek A, Gong F, Gorrell JH, Gu Z, Guan P, Harris M, Harris NL, Harvey D, Heiman TJ, Hernandez JR, Houck J, Hostin D, Houston KA, Howland TJ, Wei MH, Ibegwam C, Jalali M, Kalush F, Karpen GH, Ke Z, Kennison JA, Ketchum KA, Kimmel BE, Kodira CD, Kraft C, Kravitz S, Kulp D, Lai Z, Lasko P, Lei Y, Levitsky AA, Li J, Li Z, Liang Y, Lin X, Liu X, Mattei B, McIntosh TC, McLeod MP, McPherson D, Merkulov G, Milshina NV, Mobarry C, Morris J, Moshrefi A, Mount SM, Moy M, Murphy B, Murphy L, Muzny DM, Nelson DL, Nelson DR, Nelson KA, Nixon K, Nusskern DR, Pacleb JM, Palazzolo M, Pittman GS, Pan S, Pollard J, Puri V, Reese MG, Reinert K, Remington K, Saunders RD, Scheeler F, Shen H, Shue BC, Sidén-Kiamos I, Simpson M, Skupski MP, Smith T, Spier E, Spradling AC, Stapleton M, Strong R, Sun E, Svirskas R, Tector C, Turner R, Venter E, Wang AH, Wang X, Wang ZY, Wassarman DA, Weinstock GM, Weissenbach J, Williams SM, WoodageT, Worley KC, Wu D, Yang S, Yao QA, Ye J, Yeh RF, Zaveri JS, Zhan M, Zhang G, Zhao Q, Zheng L, Zheng XH, Zhong FN, Zhong W, Zhou X, Zhu S, Zhu X, Smith HO, Gibbs RA, Myers EW, Rubin GM, and Venter JC

Subjects
Animals, Biological Transport genetics, Chromatin genetics, Cloning, Molecular, Computational Biology, Contig Mapping, Cytochrome P-450 Enzyme System genetics, DNA Repair genetics, DNA Replication genetics, Drosophila melanogaster metabolism, Euchromatin, Gene Library, Genes, Insect, Heterochromatin genetics, Insect Proteins chemistry, Insect Proteins genetics, Insect Proteins physiology, Nuclear Proteins genetics, Protein Biosynthesis, Transcription, Genetic, Drosophila melanogaster genetics, Genome, Sequence Analysis, DNA
Abstract

The fly Drosophila melanogaster is one of the most intensively studied organisms in biology and serves as a model system for the investigation of many developmental and cellular processes common to higher eukaryotes, including humans. We have determined the nucleotide sequence of nearly all of the approximately 120-megabase euchromatic portion of the Drosophila genome using a whole-genome shotgun sequencing strategy supported by extensive clone-based sequence and a high-quality bacterial artificial chromosome physical map. Efforts are under way to close the remaining gaps; however, the sequence is of sufficient accuracy and contiguity to be declared substantially complete and to support an initial analysis of genome structure and preliminary gene annotation and interpretation. The genome encodes approximately 13,600 genes, somewhat fewer than the smaller Caenorhabditis elegans genome, but with comparable functional diversity.

Published
2000
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26. A BAC-based physical map of the major autosomes of Drosophila melanogaster.

Author

Hoskins RA, Nelson CR, Berman BP, Laverty TR, George RA, Ciesiolka L, Naeemuddin M, Arenson AD, Durbin J, David RG, Tabor PE, Bailey MR, DeShazo DR, Catanese J, Mammoser A, Osoegawa K, de Jong PJ, Celniker SE, Gibbs RA, Rubin GM, and Scherer SE

Subjects
Animals, Centromere genetics, Chromatin genetics, Chromosomes, Bacterial genetics, Cloning, Molecular, DNA Fingerprinting, Euchromatin, Gene Library, Genes, Insect, Genetic Markers, Genetic Vectors, In Situ Hybridization, Repetitive Sequences, Nucleic Acid, Restriction Mapping, Sequence Analysis, DNA, Sequence Tagged Sites, Telomere genetics, Contig Mapping, Drosophila melanogaster genetics, Genome
Abstract

We constructed a bacterial artificial chromosome (BAC)-based physical map of chromosomes 2 and 3 of Drosophila melanogaster, which constitute 81% of the genome. Sequence tagged site (STS) content, restriction fingerprinting, and polytene chromosome in situ hybridization approaches were integrated to produce a map spanning the euchromatin. Three of five remaining gaps are in repeat-rich regions near the centromeres. A tiling path of clones spanning this map and STS maps of chromosomes X and 4 was sequenced to low coverage; the maps and tiling path sequence were used to support and verify the whole-genome sequence assembly, and tiling path BACs were used as templates in sequence finishing.

Published
2000
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27. Comparative genomics of the eukaryotes.

Author

Rubin GM, Yandell MD, Wortman JR, Gabor Miklos GL, Nelson CR, Hariharan IK, Fortini ME, Li PW, Apweiler R, Fleischmann W, Cherry JM, Henikoff S, Skupski MP, Misra S, Ashburner M, Birney E, Boguski MS, Brody T, Brokstein P, Celniker SE, Chervitz SA, Coates D, Cravchik A, Gabrielian A, Galle RF, Gelbart WM, George RA, Goldstein LS, Gong F, Guan P, Harris NL, Hay BA, Hoskins RA, Li J, Li Z, Hynes RO, Jones SJ, Kuehl PM, Lemaitre B, Littleton JT, Morrison DK, Mungall C, O'Farrell PH, Pickeral OK, Shue C, Vosshall LB, Zhang J, Zhao Q, Zheng XH, and Lewis S

Subjects
Animals, Apoptosis genetics, Biological Evolution, Caenorhabditis elegans chemistry, Caenorhabditis elegans physiology, Cell Adhesion genetics, Cell Cycle genetics, Drosophila melanogaster chemistry, Drosophila melanogaster physiology, Fungal Proteins chemistry, Fungal Proteins genetics, Genes, Duplicate, Genetic Diseases, Inborn genetics, Genetics, Medical, Helminth Proteins chemistry, Helminth Proteins genetics, Humans, Immunity genetics, Insect Proteins chemistry, Insect Proteins genetics, Multigene Family, Neoplasms genetics, Protein Structure, Tertiary, Saccharomyces cerevisiae chemistry, Saccharomyces cerevisiae physiology, Signal Transduction genetics, Caenorhabditis elegans genetics, Drosophila melanogaster genetics, Genome, Proteome, Saccharomyces cerevisiae genetics
Abstract

A comparative analysis of the genomes of Drosophila melanogaster, Caenorhabditis elegans, and Saccharomyces cerevisiae-and the proteins they are predicted to encode-was undertaken in the context of cellular, developmental, and evolutionary processes. The nonredundant protein sets of flies and worms are similar in size and are only twice that of yeast, but different gene families are expanded in each genome, and the multidomain proteins and signaling pathways of the fly and worm are far more complex than those of yeast. The fly has orthologs to 177 of the 289 human disease genes examined and provides the foundation for rapid analysis of some of the basic processes involved in human disease.

Published
2000
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28. Development of the indirect flight muscle attachment sites in Drosophila: role of the PS integrins and the stripe gene.

Author

Fernandes JJ, Celniker SE, and VijayRaghavan K

Subjects
Animals, DNA-Binding Proteins genetics, Drosophila melanogaster metabolism, Flight, Animal, Immunohistochemistry, Integrin alpha Chains, Integrins immunology, Larva metabolism, Metamorphosis, Biological, Muscles metabolism, Neuromuscular Junction metabolism, Transcription Factors genetics, Drosophila Proteins, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Genes, Insect, Integrins physiology, Muscle Development
Abstract

Using markers that are expressed at muscle attachment sites, we have examined the early pupal development (first 36 hr) of Indirect Flight Muscle (IFM) attachments in the fruit fly Drosophila melanogaster. Expression of the Drosophila homologs of vertebrate integrins, the Position-Specific (PS) antigens, is known to differentially mark epidermal (PS1alpha) and muscle (PS2alpha) components of the developing IFM attachment sites. During myogenesis, PS2alpha is detected transiently in imaginal myoblasts that fuse with persistent larval muscles to give rise to the Dorsal Longitudinal Muscles (DLMs), but not in myoblasts that fuse de novo to give rise to the Dorso Ventral Muscles. The integrins are not expressed at attachment sites when the muscle fibers first make their appearance (12-20 hr). Following muscle-epidermal contact, PS1 and PS2 are detected at muscle attachment sites. PS1 expression is at the muscle ends and also in the long epidermal processes that connect the developing muscle fibers to their sites of attachment in the epidermis, while PS2 expression is restricted to the muscle ends. Epidermal cells that will contribute to the adult attachment sites are defined as early as the third larval instar. Both anterior and posterior sites of attachment of the IFMs are marked by the expression of reporter beta-galactosidase activity in a P-element line B14.0, which is an insertion at the stripe locus. B14.0 (stripe) is seen in distinct domains in the wing and leg imaginal discs which give rise to the thoracic cuticle. The expression is maintained during pupal development. The B14.0 (stripe) expressing epidermal cells contact the developing muscle fibers, leading to the formation of the myotendon junction. We show that the dorsal and ventral attachment sites of one group of IFMs, the DVMs arise from two different imaginal discs (wing and leg, respectively), which may explain the differential effect of mutations such as bendless on these muscles. Attachment sites for the other group of IFMs, the DLMs, on the other hand, arise from one imaginal disc (wing). B14.0 (stripe) expression defines epidermal cells of the adult attachment sites and is likely to function during early events leading to the formation of muscle-epithelial contacts. The PS integrins are detected at later stages, suggesting a role in the stabilization and maturation of the muscle-epidermal contacts into myotendon junctions.

Published
1996
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29. Muscle development in the four-winged Drosophila and the role of the Ultrabithorax gene.

Author

Fernandes J, Celniker SE, Lewis EB, and VijayRaghavan K

Subjects
Alleles, Animals, Cell Count, Cell Movement genetics, DNA-Binding Proteins genetics, Drosophila melanogaster cytology, Female, Gene Expression Regulation, Developmental, Larva cytology, Larva growth & development, Male, Metamorphosis, Biological, Motor Neurons cytology, Muscles cytology, Muscles innervation, Mutation, Wings, Animal cytology, Wings, Animal growth & development, Drosophila Proteins, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Genes, Homeobox, Genes, Insect, Homeodomain Proteins, Muscle Development, Transcription Factors
Abstract

Background: In the fruitfly Drosophila melanogaster, segment identity is specified by the homoeotic selector genes of the bithorax and Antennapedia complexes. The functions of these genes in the segmental specification of the Drosophila ectoderm have been well studied, but their roles in muscle development have been relatively poorly investigated. Recent experiments have strongly suggested that homeotic selector genes are directly involved in one aspect of mesodermal patterning during Drosophila embryogenesis. But muscle development is a complex process, requiring for its completion the correct positioning of the epidermis, the nervous system and the developing muscles in a segment-specific manner. Many aspects of homeotic selector gene function in this process remain to be understood., Results: In flies that are homozygous for three mutant alleles (anterobithorax, bithorax3, postbithorax) of the Ultrabithorax gene, the third thoracic segment (T3) is transformed towards the second (T2). The adults have two pairs of wings, but the homeotically transformed T3 (HT3) has only rudimentary indirect flight muscles. We used the 'four-winged' fly to study the role of homeotic selector genes in the development of the indirect flight muscles, which we classify into four 'events'. First, the determination of the segment-specific pattern of myoblasts in the larval thorax; second, the specific pattern of migration of myoblasts during metamorphosis; third, the fusion of myoblasts to form adult indirect flight muscles and fourth, the development of the branching pattern of adult motor innervation. Our study shows that the segmental identity of the epidermis determines the segment-specific pattern and number of myoblasts on the larval discs, and the pattern of their migration during metamorphosis. The segmental identity of the mesoderm, however, is crucial for the fusion of myoblasts to form indirect flight muscles, and also influences the branching pattern of innervation of indirect flight muscles., Conclusions: Segmental information expressed in the ectoderm, and the autonomous function of homeotic selector genes in the mesoderm, are both required for the complete development of indirect flight muscles.

Published
1994
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30. Yeast DNA replication in vitro: initiation and elongation events mimic in vivo processes.

Author

Celniker SE and Campbell JL

Subjects
Aphidicolin, Cell Cycle, Cell Nucleus metabolism, Cloning, Molecular, DNA Polymerase II antagonists & inhibitors, DNA Restriction Enzymes, Diterpenes pharmacology, Kinetics, Mutation, Plasmids, Saccharomyces cerevisiae drug effects, Templates, Genetic, DNA Replication drug effects, Saccharomyces cerevisiae genetics
Abstract

An enzyme system prepared from Saccharomyces cerevisiae carries out the replication of exogenous yeast plasmid DNA. Replication in vitro mimics that in vivo in that DNA synthesis in extracts of strain cdc8, a temperature-sensitive DNA replication mutant, is thermolabile relative to the wild-type, and in that aphidicolin inhibits replication in vitro. Furthermore, only plasmids containing a functional yeast replicator, ARS, initiate replication at a specific site in vitro. Analysis of replicative intermediates shows that plasmid YRp7, which contains the chromosomal replicator ARS1, initiates bidirectional replication in a 100 bp region within the sequence required for autonomous replication in vivo. Plasmids containing ARS2, another chromosomal replicator, and the ARS region of the endogenous yeast plasmid 2 microns circle give similar results, suggesting that ARS sequences are specific origins of chromosomal replication. Used in conjunction with deletion mapping, the in vitro system allows definition of the minimal sequences required for the initiation of replication.

Published
1982
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