Your search keyword '"Hoskins, Roger A."' showing total 24 results

1. A library of MiMICs allows tagging of genes and reversible, spatial and temporal knockdown of proteins in Drosophila.

Author

Nagarkar-Jaiswal S, Lee PT, Campbell ME, Chen K, Anguiano-Zarate S, Gutierrez MC, Busby T, Lin WW, He Y, Schulze KL, Booth BW, Evans-Holm M, Venken KJ, Levis RW, Spradling AC, Hoskins RA, and Bellen HJ

Subjects

Animals, Animals, Genetically Modified, Blotting, Western, Brain metabolism, Drosophila Proteins metabolism, Drosophila melanogaster metabolism, Drosophila melanogaster physiology, Gene Expression, Green Fluorescent Proteins genetics, Green Fluorescent Proteins metabolism, Larva genetics, Larva metabolism, Learning physiology, Microscopy, Confocal, Time Factors, Tumor Suppressor Proteins genetics, Tumor Suppressor Proteins metabolism, alpha Catenin genetics, alpha Catenin metabolism, DNA Transposable Elements genetics, Drosophila Proteins genetics, Drosophila melanogaster genetics, Gene Library, Mutagenesis, Insertional, RNA Interference

Abstract

Here, we document a collection of ∼7434 MiMIC (Minos Mediated Integration Cassette) insertions of which 2854 are inserted in coding introns. They allowed us to create a library of 400 GFP-tagged genes. We show that 72% of internally tagged proteins are functional, and that more than 90% can be imaged in unfixed tissues. Moreover, the tagged mRNAs can be knocked down by RNAi against GFP (iGFPi), and the tagged proteins can be efficiently knocked down by deGradFP technology. The phenotypes associated with RNA and protein knockdown typically correspond to severe loss of function or null mutant phenotypes. Finally, we demonstrate reversible, spatial, and temporal knockdown of tagged proteins in larvae and adult flies. This new strategy and collection of strains allows unprecedented in vivo manipulations in flies for many genes. These strategies will likely extend to vertebrates.

Published

2015

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

Author

Hoskins RA, Carlson JW, Wan KH, Park S, Mendez I, Galle SE, Booth BW, Pfeiffer BD, George RA, Svirskas R, Krzywinski M, Schein J, Accardo MC, Damia E, Messina G, Méndez-Lago M, de Pablos B, Demakova OV, Andreyeva EN, Boldyreva LV, Marra M, Carvalho AB, Dimitri P, Villasante A, Zhimulev IF, Rubin GM, Karpen GH, and Celniker SE

Subjects

Animals, Chromosome Mapping, Chromosomes, Artificial, Bacterial, Computational Biology, Contig Mapping, High-Throughput Nucleotide Sequencing, In Situ Hybridization, Fluorescence, Molecular Sequence Data, Polytene Chromosomes, Restriction Mapping, Drosophila melanogaster genetics, Genome

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., (© 2015 Hoskins et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2015

3. Diversity and dynamics of the Drosophila transcriptome.

Author

Brown JB, Boley N, Eisman R, May GE, Stoiber MH, Duff MO, Booth BW, Wen J, Park S, Suzuki AM, Wan KH, Yu C, Zhang D, Carlson JW, Cherbas L, Eads BD, Miller D, Mockaitis K, Roberts J, Davis CA, Frise E, Hammonds AS, Olson S, Shenker S, Sturgill D, Samsonova AA, Weiszmann R, Robinson G, Hernandez J, Andrews J, Bickel PJ, Carninci P, Cherbas P, Gingeras TR, Hoskins RA, Kaufman TC, Lai EC, Oliver B, Perrimon N, Graveley BR, and Celniker SE

Subjects

Alternative Splicing genetics, Animals, Drosophila melanogaster anatomy & histology, Drosophila melanogaster cytology, Female, Male, Molecular Sequence Annotation, Nerve Tissue metabolism, Organ Specificity, Poly A genetics, Polyadenylation, Promoter Regions, Genetic genetics, RNA, Long Noncoding genetics, RNA, Messenger genetics, RNA, Messenger metabolism, Sex Characteristics, Stress, Physiological genetics, Drosophila melanogaster genetics, Gene Expression Profiling, Transcriptome genetics

Abstract

Animal transcriptomes are dynamic, with each cell type, tissue and organ system expressing an ensemble of transcript isoforms that give rise to substantial diversity. Here we have identified new genes, transcripts and proteins using poly(A)+ RNA sequencing from Drosophila melanogaster in cultured cell lines, dissected organ systems and under environmental perturbations. We found that a small set of mostly neural-specific genes has the potential to encode thousands of transcripts each through extensive alternative promoter usage and RNA splicing. The magnitudes of splicing changes are larger between tissues than between developmental stages, and most sex-specific splicing is gonad-specific. Gonads express hundreds of previously unknown coding and long non-coding RNAs (lncRNAs), some of which are antisense to protein-coding genes and produce short regulatory RNAs. Furthermore, previously identified pervasive intergenic transcription occurs primarily within newly identified introns. The fly transcriptome is substantially more complex than previously recognized, with this complexity arising from combinatorial usage of promoters, splice sites and polyadenylation sites.

Published

2014

4. Comparative analysis of the transcriptome across distant species.

Author

Gerstein MB, Rozowsky J, Yan KK, Wang D, Cheng C, Brown JB, Davis CA, Hillier L, Sisu C, Li JJ, Pei B, Harmanci AO, Duff MO, Djebali S, Alexander RP, Alver BH, Auerbach R, Bell K, Bickel PJ, Boeck ME, Boley NP, Booth BW, Cherbas L, Cherbas P, Di C, Dobin A, Drenkow J, Ewing B, Fang G, Fastuca M, Feingold EA, Frankish A, Gao G, Good PJ, Guigó R, Hammonds A, Harrow J, Hoskins RA, Howald C, Hu L, Huang H, Hubbard TJ, Huynh C, Jha S, Kasper D, Kato M, Kaufman TC, Kitchen RR, Ladewig E, Lagarde J, Lai E, Leng J, Lu Z, MacCoss M, May G, McWhirter R, Merrihew G, Miller DM, Mortazavi A, Murad R, Oliver B, Olson S, Park PJ, Pazin MJ, Perrimon N, Pervouchine D, Reinke V, Reymond A, Robinson G, Samsonova A, Saunders GI, Schlesinger F, Sethi A, Slack FJ, Spencer WC, Stoiber MH, Strasbourger P, Tanzer A, Thompson OA, Wan KH, Wang G, Wang H, Watkins KL, Wen J, Wen K, Xue C, Yang L, Yip K, Zaleski C, Zhang Y, Zheng H, Brenner SE, Graveley BR, Celniker SE, Gingeras TR, and Waterston R

Subjects

Animals, Caenorhabditis elegans embryology, Caenorhabditis elegans growth & development, Chromatin genetics, Cluster Analysis, Drosophila melanogaster growth & development, Gene Expression Regulation, Developmental genetics, Histones metabolism, Humans, Larva genetics, Larva growth & development, Models, Genetic, Molecular Sequence Annotation, Promoter Regions, Genetic genetics, Pupa genetics, Pupa growth & development, RNA, Untranslated genetics, Sequence Analysis, RNA, Caenorhabditis elegans genetics, Drosophila melanogaster genetics, Gene Expression Profiling, Transcriptome genetics

Abstract

The transcriptome is the readout of the genome. Identifying common features in it across distant species can reveal fundamental principles. To this end, the ENCODE and modENCODE consortia have generated large amounts of matched RNA-sequencing data for human, worm and fly. Uniform processing and comprehensive annotation of these data allow comparison across metazoan phyla, extending beyond earlier within-phylum transcriptome comparisons and revealing ancient, conserved features. Specifically, we discover co-expression modules shared across animals, many of which are enriched in developmental genes. Moreover, we use expression patterns to align the stages in worm and fly development and find a novel pairing between worm embryo and fly pupae, in addition to the embryo-to-embryo and larvae-to-larvae pairings. Furthermore, we find that the extent of non-canonical, non-coding transcription is similar in each organism, per base pair. Finally, we find in all three organisms that the gene-expression levels, both coding and non-coding, can be quantitatively predicted from chromatin features at the promoter using a 'universal model' based on a single set of organism-independent parameters.

Published

2014

5. Comparative validation of the D. melanogaster modENCODE transcriptome annotation.

Author

Chen ZX, Sturgill D, Qu J, Jiang H, Park S, Boley N, Suzuki AM, Fletcher AR, Plachetzki DC, FitzGerald PC, Artieri CG, Atallah J, Barmina O, Brown JB, Blankenburg KP, Clough E, Dasgupta A, Gubbala S, Han Y, Jayaseelan JC, Kalra D, Kim YA, Kovar CL, Lee SL, Li M, Malley JD, Malone JH, Mathew T, Mattiuzzo NR, Munidasa M, Muzny DM, Ongeri F, Perales L, Przytycka TM, Pu LL, Robinson G, Thornton RL, Saada N, Scherer SE, Smith HE, Vinson C, Warner CB, Worley KC, Wu YQ, Zou X, Cherbas P, Kellis M, Eisen MB, Piano F, Kionte K, Fitch DH, Sternberg PW, Cutter AD, Duff MO, Hoskins RA, Graveley BR, Gibbs RA, Bickel PJ, Kopp A, Carninci P, Celniker SE, Oliver B, and Richards S

Subjects

Animals, Cluster Analysis, Drosophila melanogaster classification, Evolution, Molecular, Exons, Female, Genome, Insect, Humans, Male, Nucleotide Motifs, Phylogeny, Position-Specific Scoring Matrices, Promoter Regions, Genetic, RNA Editing, RNA Splice Sites, RNA Splicing, Reproducibility of Results, Transcription Initiation Site, Computational Biology methods, Drosophila melanogaster genetics, Gene Expression Profiling, Molecular Sequence Annotation, Transcriptome

Abstract

Accurate gene model annotation of reference genomes is critical for making them useful. The modENCODE project has improved the D. melanogaster genome annotation by using deep and diverse high-throughput data. Since transcriptional activity that has been evolutionarily conserved is likely to have an advantageous function, we have performed large-scale interspecific comparisons to increase confidence in predicted annotations. To support comparative genomics, we filled in divergence gaps in the Drosophila phylogeny by generating draft genomes for eight new species. For comparative transcriptome analysis, we generated mRNA expression profiles on 81 samples from multiple tissues and developmental stages of 15 Drosophila species, and we performed cap analysis of gene expression in D. melanogaster and D. pseudoobscura. We also describe conservation of four distinct core promoter structures composed of combinations of elements at three positions. Overall, each type of genomic feature shows a characteristic divergence rate relative to neutral models, highlighting the value of multispecies alignment in annotating a target genome that should prove useful in the annotation of other high priority genomes, especially human and other mammalian genomes that are rich in noncoding sequences. We report that the vast majority of elements in the annotation are evolutionarily conserved, indicating that the annotation will be an important springboard for functional genetic testing by the Drosophila community., (© 2014 Chen et al.; Published by Cold Spring Harbor Laboratory Press.)

Published

2014

6. Drosophila P elements preferentially transpose to replication origins.

Author

Spradling AC, Bellen HJ, and Hoskins RA

Subjects

Animals, Base Sequence, Binding Sites genetics, Chromosomes, Insect genetics, DNA Replication genetics, Drosophila Proteins genetics, Heterochromatin genetics, Models, Genetic, Promoter Regions, Genetic genetics, Time Factors, DNA Transposable Elements genetics, Drosophila melanogaster genetics, Mutagenesis, Insertional, Replication Origin genetics

Abstract

The P transposable element recently invaded wild Drosophila melanogaster strains worldwide. A single introduced copy can multiply and spread throughout the fly genome in just a few generations, even though its cut-and-paste transposition mechanism does not inherently increase copy number. P element insertions preferentially target the promoters of a subset of genes, but why these sites are hotspots remains unknown. We show that P elements selectively target sites that in tissue-culture cells bind origin recognition complex proteins and function as replication origins. The association of origin recognition complex-binding sites with selected promoters and their absence near clustered differentiation genes may dictate P element site specificity. Inserting at unfired replication origins during S phase may allow P elements to be both repaired and reduplicated, thereby increasing element copy number. The advantage transposons gain by moving from replicated to unreplicated genomic regions may contribute to the association of heterochromatin with late-replicating genomic regions.

Published

2011

7. MiMIC: a highly versatile transposon insertion resource for engineering Drosophila melanogaster genes.

Author

Venken KJ, Schulze KL, Haelterman NA, Pan H, He Y, Evans-Holm M, Carlson JW, Levis RW, Spradling AC, Hoskins RA, and Bellen HJ

Subjects

Animals, Bioengineering, Drosophila Proteins genetics, Gene Expression Regulation, Introns, Mutagenesis, Insertional, Recombinant Fusion Proteins analysis, Repetitive Sequences, Nucleic Acid, DNA Transposable Elements genetics, Drosophila melanogaster genetics

Abstract

We demonstrate the versatility of a collection of insertions of the transposon Minos-mediated integration cassette (MiMIC), in Drosophila melanogaster. MiMIC contains a gene-trap cassette and the yellow+ marker flanked by two inverted bacteriophage ΦC31 integrase attP sites. MiMIC integrates almost at random in the genome to create sites for DNAmanipulation. The attP sites allow the replacement of the intervening sequence of the transposon with any other sequence through recombinase-mediated cassette exchange (RMCE). We can revert insertions that function as gene traps and cause mutant phenotypes to revert to wild type by RMCE and modify insertions to control GAL4 or QF overexpression systems or perform lineage analysis using the Flp recombinase system. Insertions in coding introns can be exchanged with protein-tag cassettes to create fusion proteins to follow protein expression and perform biochemical experiments. The applications of MiMIC vastly extend the D. melanogaster toolkit.

Published

2011

8. The Drosophila gene disruption project: progress using transposons with distinctive site specificities.

Author

Bellen HJ, Levis RW, He Y, Carlson JW, Evans-Holm M, Bae E, Kim J, Metaxakis A, Savakis C, Schulze KL, Hoskins RA, and Spradling AC

Subjects

Alleles, Animals, Gene Expression, Genome, Insect, Models, Genetic, Mutation, Phenotype, DNA Transposable Elements, Drosophila Proteins genetics, Drosophila melanogaster genetics, Genes, Insect, Mutagenesis, Insertional methods

Abstract

The Drosophila Gene Disruption Project (GDP) has created a public collection of mutant strains containing single transposon insertions associated with different genes. These strains often disrupt gene function directly, allow production of new alleles, and have many other applications for analyzing gene function. Here we describe the addition of ∼7600 new strains, which were selected from >140,000 additional P or piggyBac element integrations and 12,500 newly generated insertions of the Minos transposon. These additions nearly double the size of the collection and increase the number of tagged genes to at least 9440, approximately two-thirds of all annotated protein-coding genes. We also compare the site specificity of the three major transposons used in the project. All three elements insert only rarely within many Polycomb-regulated regions, a property that may contribute to the origin of "transposon-free regions" (TFRs) in metazoan genomes. Within other genomic regions, Minos transposes essentially at random, whereas P or piggyBac elements display distinctive hotspots and coldspots. P elements, as previously shown, have a strong preference for promoters. In contrast, piggyBac site selectivity suggests that it has evolved to reduce deleterious and increase adaptive changes in host gene expression. The propensity of Minos to integrate broadly makes possible a hybrid finishing strategy for the project that will bring >95% of Drosophila genes under experimental control within their native genomic contexts.

Published

2011

9. The developmental transcriptome of Drosophila melanogaster.

Author

Graveley BR, Brooks AN, Carlson JW, Duff MO, Landolin JM, Yang L, Artieri CG, van Baren MJ, Boley N, Booth BW, Brown JB, Cherbas L, Davis CA, Dobin A, Li R, Lin W, Malone JH, Mattiuzzo NR, Miller D, Sturgill D, Tuch BB, Zaleski C, Zhang D, Blanchette M, Dudoit S, Eads B, Green RE, Hammonds A, Jiang L, Kapranov P, Langton L, Perrimon N, Sandler JE, Wan KH, Willingham A, Zhang Y, Zou Y, Andrews J, Bickel PJ, Brenner SE, Brent MR, Cherbas P, Gingeras TR, Hoskins RA, Kaufman TC, Oliver B, and Celniker SE

Subjects

Alternative Splicing genetics, Animals, Base Sequence, Drosophila Proteins genetics, Drosophila melanogaster embryology, Exons genetics, Female, Genes, Insect genetics, Genome, Insect genetics, Male, MicroRNAs genetics, Oligonucleotide Array Sequence Analysis, Protein Isoforms genetics, RNA Editing genetics, RNA, Messenger analysis, RNA, Messenger genetics, RNA, Small Untranslated analysis, RNA, Small Untranslated genetics, Sequence Analysis, Sex Characteristics, Drosophila melanogaster genetics, Drosophila melanogaster growth & development, Gene Expression Profiling, Gene Expression Regulation, Developmental genetics, Transcription, Genetic genetics

Abstract

Drosophila melanogaster is one of the most well studied genetic model organisms; nonetheless, its genome still contains unannotated coding and non-coding genes, transcripts, exons and RNA editing sites. Full discovery and annotation are pre-requisites for understanding how the regulation of transcription, splicing and RNA editing directs the development of this complex organism. Here we used RNA-Seq, tiling microarrays and cDNA sequencing to explore the transcriptome in 30 distinct developmental stages. We identified 111,195 new elements, including thousands of genes, coding and non-coding transcripts, exons, splicing and editing events, and inferred protein isoforms that previously eluded discovery using established experimental, prediction and conservation-based approaches. These data substantially expand the number of known transcribed elements in the Drosophila genome and provide a high-resolution view of transcriptome dynamics throughout development.

Published

2011

10. Genome-wide analysis of promoter architecture in Drosophila melanogaster.

Author

Hoskins RA, Landolin JM, Brown JB, Sandler JE, Takahashi H, Lassmann T, Yu C, Booth BW, Zhang D, Wan KH, Yang L, Boley N, Andrews J, Kaufman TC, Graveley BR, Bickel PJ, Carninci P, Carlson JW, and Celniker SE

Subjects

3' Untranslated Regions genetics, Animals, Chromosome Mapping, Drosophila melanogaster embryology, Expressed Sequence Tags, Gene Expression Profiling, Gene Expression Regulation genetics, Genome-Wide Association Study, Transcription Initiation Site, Computational Biology, Drosophila melanogaster genetics, Genome, Insect genetics, Promoter Regions, Genetic

Abstract

Core promoters are critical regions for gene regulation in higher eukaryotes. However, the boundaries of promoter regions, the relative rates of initiation at the transcription start sites (TSSs) distributed within them, and the functional significance of promoter architecture remain poorly understood. We produced a high-resolution map of promoters active in the Drosophila melanogaster embryo by integrating data from three independent and complementary methods: 21 million cap analysis of gene expression (CAGE) tags, 1.2 million RNA ligase mediated rapid amplification of cDNA ends (RLM-RACE) reads, and 50,000 cap-trapped expressed sequence tags (ESTs). We defined 12,454 promoters of 8037 genes. Our analysis indicates that, due to non-promoter-associated RNA background signal, previous studies have likely overestimated the number of promoter-associated CAGE clusters by fivefold. We show that TSS distributions form a complex continuum of shapes, and that promoters active in the embryo and adult have highly similar shapes in 95% of cases. This suggests that these distributions are generally determined by static elements such as local DNA sequence and are not modulated by dynamic signals such as histone modifications. Transcription factor binding motifs are differentially enriched as a function of promoter shape, and peaked promoter shape is correlated with both temporal and spatial regulation of gene expression. Our results contribute to the emerging view that core promoters are functionally diverse and control patterning of gene expression in Drosophila and mammals.

Published

2011

11. The transcriptional diversity of 25 Drosophila cell lines.

Author

Cherbas L, Willingham A, Zhang D, Yang L, Zou Y, Eads BD, Carlson JW, Landolin JM, Kapranov P, Dumais J, Samsonova A, Choi JH, Roberts J, Davis CA, Tang H, van Baren MJ, Ghosh S, Dobin A, Bell K, Lin W, Langton L, Duff MO, Tenney AE, Zaleski C, Brent MR, Hoskins RA, Kaufman TC, Andrews J, Graveley BR, Perrimon N, Celniker SE, Gingeras TR, and Cherbas P

Subjects

Animals, Cell Line, Cluster Analysis, Exons, Female, Gene Expression Profiling, Male, Molecular Sequence Data, Signal Transduction genetics, Transcription Factors genetics, Drosophila melanogaster genetics, Genetic Variation, Transcription, Genetic

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.

Published

2011

12. Identification of functional elements and regulatory circuits by Drosophila modENCODE.

Author

Roy S, Ernst J, Kharchenko PV, Kheradpour P, Negre N, Eaton ML, Landolin JM, Bristow CA, Ma L, Lin MF, Washietl S, Arshinoff BI, Ay F, Meyer PE, Robine N, Washington NL, Di Stefano L, Berezikov E, Brown CD, Candeias R, Carlson JW, Carr A, Jungreis I, Marbach D, Sealfon R, Tolstorukov MY, Will S, Alekseyenko AA, Artieri C, Booth BW, Brooks AN, Dai Q, Davis CA, Duff MO, Feng X, Gorchakov AA, Gu T, Henikoff JG, Kapranov P, Li R, MacAlpine HK, Malone J, Minoda A, Nordman J, Okamura K, Perry M, Powell SK, Riddle NC, Sakai A, Samsonova A, Sandler JE, Schwartz YB, Sher N, Spokony R, Sturgill D, van Baren M, Wan KH, Yang L, Yu C, Feingold E, Good P, Guyer M, Lowdon R, Ahmad K, Andrews J, Berger B, Brenner SE, Brent MR, Cherbas L, Elgin SC, Gingeras TR, Grossman R, Hoskins RA, Kaufman TC, Kent W, Kuroda MI, Orr-Weaver T, Perrimon N, Pirrotta V, Posakony JW, Ren B, Russell S, Cherbas P, Graveley BR, Lewis S, Micklem G, Oliver B, Park PJ, Celniker SE, Henikoff S, Karpen GH, Lai EC, MacAlpine DM, Stein LD, White KP, and Kellis M

Subjects

Animals, Binding Sites, Computational Biology methods, Drosophila Proteins genetics, Drosophila Proteins metabolism, Drosophila melanogaster growth & development, Drosophila melanogaster metabolism, Epigenesis, Genetic, Gene Expression Regulation, Genes, Insect, Genomics methods, Histones metabolism, Nucleosomes genetics, Nucleosomes metabolism, Promoter Regions, Genetic, RNA, Small Untranslated genetics, RNA, Small Untranslated metabolism, Transcription Factors metabolism, Transcription, Genetic, Chromatin genetics, Chromatin metabolism, Drosophila melanogaster genetics, Gene Regulatory Networks, Genome, Insect, Molecular Sequence Annotation

Abstract

To gain insight into how genomic information is translated into cellular and developmental programs, the Drosophila model organism Encyclopedia of DNA Elements (modENCODE) project is comprehensively mapping transcripts, histone modifications, chromosomal proteins, transcription factors, replication proteins and intermediates, and nucleosome properties across a developmental time course and in multiple cell lines. We have generated more than 700 data sets and discovered protein-coding, noncoding, RNA regulatory, replication, and chromatin elements, more than tripling the annotated portion of the Drosophila genome. Correlated activity patterns of these elements reveal a functional regulatory network, which predicts putative new functions for genes, reveals stage- and tissue-specific regulators, and enables gene-expression prediction. Our results provide a foundation for directed experimental and computational studies in Drosophila and related species and also a model for systematic data integration toward comprehensive genomic and functional annotation.

Published

2010

13. A molecularly defined duplication set for the X chromosome of Drosophila melanogaster.

Author

Venken KJ, Popodi E, Holtzman SL, Schulze KL, Park S, Carlson JW, Hoskins RA, Bellen HJ, and Kaufman TC

Subjects

Animals, Chromosome Mapping, Gene Dosage genetics, Genes, Insect, Molecular Sequence Data, Drosophila melanogaster genetics, Mutagenesis, Insertional, X Chromosome genetics

Abstract

We describe a molecularly defined duplication kit for the X chromosome of Drosophila melanogaster. A set of 408 overlapping P[acman] BAC clones was used to create small duplications (average length 88 kb) covering the 22-Mb sequenced portion of the chromosome. The BAC clones were inserted into an attP docking site on chromosome 3L using ΦC31 integrase, allowing direct comparison of different transgenes. The insertions complement 92% of the essential and viable mutations and deletions tested, demonstrating that almost all Drosophila genes are compact and that the current annotations of the genome are reasonably accurate. Moreover, almost all genes are tolerated at twice the normal dosage. Finally, we more precisely mapped two regions at which duplications cause diplo-lethality in males. This collection comprises the first molecularly defined duplication set to cover a whole chromosome in a multicellular organism. The work presented removes a long-standing barrier to genetic analysis of the Drosophila X chromosome, will greatly facilitate functional assays of X-linked genes in vivo, and provides a model for functional analyses of entire chromosomes in other species.

Published

2010

14. Versatile P[acman] BAC libraries for transgenesis studies in Drosophila melanogaster.

Author

Venken KJ, Carlson JW, Schulze KL, Pan H, He Y, Spokony R, Wan KH, Koriabine M, de Jong PJ, White KP, Bellen HJ, and Hoskins RA

Subjects

Animals, Base Sequence, Molecular Sequence Data, Animals, Genetically Modified genetics, Chromosome Mapping methods, Chromosomes, Artificial, Bacterial genetics, Cloning, Molecular methods, Drosophila melanogaster genetics, Gene Library

Abstract

We constructed Drosophila melanogaster bacterial artificial chromosome libraries with 21-kilobase and 83-kilobase inserts in the P[acman] system. We mapped clones representing 12-fold coverage and encompassing more than 95% of annotated genes onto the reference genome. These clones can be integrated into predetermined attP sites in the genome using UC31 integrase to rescue mutations. They can be modified through recombineering, for example, to incorporate protein tags and assess expression patterns.

Published

2009

15. Sequence finishing and mapping of Drosophila melanogaster heterochromatin.

Author

Hoskins RA, Carlson JW, Kennedy C, Acevedo D, Evans-Holm M, Frise E, Wan KH, Park S, Mendez-Lago M, Rossi F, Villasante A, Dimitri P, Karpen GH, and Celniker SE

Subjects

Animals, Chromosome Mapping, Chromosomes, Artificial, Bacterial, Contig Mapping, Genome, In Situ Hybridization, Fluorescence, Physical Chromosome Mapping, Drosophila melanogaster genetics, Heterochromatin genetics, Sequence Analysis, DNA

Abstract

Genome sequences for most metazoans and plants are incomplete because of the presence of repeated DNA in the heterochromatin. The heterochromatic regions of Drosophila melanogaster contain 20 million bases (Mb) of sequence amenable to mapping, sequence assembly, and finishing. We describe the generation of 15 Mb of finished or improved heterochromatic sequence with the use of available clone resources and assembly methods. We also constructed a bacterial artificial chromosome-based physical map that spans 13 Mb of the pericentromeric heterochromatin and a cytogenetic map that positions 11 Mb in specific chromosomal locations. We have approached a complete assembly and mapping of the nonsatellite component of Drosophila heterochromatin. The strategy we describe is also applicable to generating substantially more information about heterochromatin in other species, including humans.

Published

2007

16. Exploring strategies for protein trapping in Drosophila.

Author

Quiñones-Coello AT, Petrella LN, Ayers K, Melillo A, Mazzalupo S, Hudson AM, Wang S, Castiblanco C, Buszczak M, Hoskins RA, and Cooley L

Subjects

Animals, Blotting, Western, Crosses, Genetic, DNA Primers, Databases, Genetic, Drosophila Proteins metabolism, Green Fluorescent Proteins metabolism, Polymerase Chain Reaction methods, Recombinant Fusion Proteins metabolism, Sequence Analysis, DNA, DNA Transposable Elements genetics, Drosophila Proteins isolation & purification, Drosophila melanogaster genetics, Green Fluorescent Proteins genetics, Mutagenesis, Insertional methods, Recombinant Fusion Proteins genetics

Abstract

The use of fluorescent protein tags has had a huge impact on cell biological studies in virtually every experimental system. Incorporation of coding sequence for fluorescent proteins such as green fluorescent protein (GFP) into genes at their endogenous chromosomal position is especially useful for generating GFP-fusion proteins that provide accurate cellular and subcellular expression data. We tested modifications of a transposon-based protein trap screening procedure in Drosophila to optimize the rate of recovering useful protein traps and their analysis. Transposons carrying the GFP-coding sequence flanked by splice acceptor and donor sequences were mobilized, and new insertions that resulted in production of GFP were captured using an automated embryo sorter. Individual stocks were established, GFP expression was analyzed during oogenesis, and insertion sites were determined by sequencing genomic DNA flanking the insertions. The resulting collection includes lines with protein traps in which GFP was spliced into mRNAs and embedded within endogenous proteins or enhancer traps in which GFP expression depended on splicing into transposon-derived RNA. We report a total of 335 genes associated with protein or enhancer traps and a web-accessible database for viewing molecular information and expression data for these genes.

Published

2007

17. P[acman]: a BAC transgenic platform for targeted insertion of large DNA fragments in D. melanogaster.

Author

Venken KJ, He Y, Hoskins RA, and Bellen HJ

Subjects

Animals, Animals, Genetically Modified, DNA Repair, Genes, Insect, Genetic Vectors, Molecular Sequence Data, Mutagenesis, Plasmids, Recombination, Genetic, Transgenes, Transposases metabolism, Chromosomes, Artificial, Bacterial, Cloning, Molecular methods, DNA Transposable Elements, Drosophila melanogaster genetics, Gene Transfer Techniques, Siphoviridae genetics

Abstract

We describe a transgenesis platform for Drosophila melanogaster that integrates three recently developed technologies: a conditionally amplifiable bacterial artificial chromosome (BAC), recombineering, and bacteriophage PhiC31-mediated transgenesis. The BAC is maintained at low copy number, facilitating plasmid maintenance and recombineering, but is induced to high copy number for plasmid isolation. Recombineering allows gap repair and mutagenesis in bacteria. Gap repair efficiently retrieves DNA fragments up to 133 kilobases long from P1 or BAC clones. PhiC31-mediated transgenesis integrates these large DNA fragments at specific sites in the genome, allowing the rescue of lethal mutations in the corresponding genes. This transgenesis platform should greatly facilitate structure/function analyses of most Drosophila genes.

Published

2006

18. Y chromosome and other heterochromatic sequences of the Drosophila melanogaster genome: how far can we go?

Author

Carvalho AB, Vibranovski MD, Carlson JW, Celniker SE, Hoskins RA, Rubin GM, Sutton GG, Adams MD, Myers EW, and Clark AG

Subjects

Animals, Databases, Nucleic Acid, Expressed Sequence Tags, Sequence Analysis, DNA methods, Drosophila melanogaster genetics, Heterochromatin genetics, Y Chromosome genetics

Abstract

Whole genome shotgun assemblies have proven remarkably successful in reconstructing the bulk of euchromatic genes, with the only limit appearing to be determined by the sequencing depth. For genes imbedded in heterochromatin, however, the low cloning efficiency of repetitive sequences, combined with the computational challenges, demand that additional clues be used to annotate the sequences. One approach that has proven very successful in identifying protein coding genes in Y-linked heterochromatin of Drosophila melanogaster has been to make a BLASTable database of the small, unmapped contigs and fragments leftover at the end of a shotgun assembly, and to attempt to capture these by blasting with an appropriate query sequence. This approach often yields a staggered alignment of contigs from the unmapped set to the query sequence, as though the disjoint contigs represent small portions of the gene. Further inspection frequently shows that the contigs are broken by very large, heterochromatic introns. Methods of this sort are being expanded to make best use of all available clues to determine which unmapped contigs are associated with genes. These include use of EST libraries, and, in the case of the Y chromosome, testing of male specific genes and reduced shotgun depth of relevant contigs. It appears much more hopeful than anyone would have imagined that whole genome shotgun assemblies can recover the great bulk of even heterochromatic genes.

Published

2003

19. Heterochromatic sequences in a Drosophila whole-genome shotgun assembly.

Author

Hoskins RA, Smith CD, Carlson JW, Carvalho AB, Halpern A, Kaminker JS, Kennedy C, Mungall CJ, Sullivan BA, Sutton GG, Yasuhara JC, Wakimoto BT, Myers EW, Celniker SE, Rubin GM, and Karpen GH

Subjects

Algorithms, Animals, Contig Mapping, DNA Transposable Elements genetics, Databases, Genetic, Software, Drosophila melanogaster genetics, Genome, Heterochromatin genetics, Sequence Analysis, DNA methods

Abstract

Background: Most eukaryotic genomes include a substantial repeat-rich fraction termed heterochromatin, which is concentrated in centric and telomeric regions. The repetitive nature of heterochromatic sequence makes it difficult to assemble and analyze. To better understand the heterochromatic component of the Drosophila melanogaster genome, we characterized and annotated portions of a whole-genome shotgun sequence assembly., Results: WGS3, an improved whole-genome shotgun assembly, includes 20.7 Mb of draft-quality sequence not represented in the Release 3 sequence spanning the euchromatin. We annotated this sequence using the methods employed in the re-annotation of the Release 3 euchromatic sequence. This analysis predicted 297 protein-coding genes and six non-protein-coding genes, including known heterochromatic genes, and regions of similarity to known transposable elements. Bacterial artificial chromosome (BAC)-based fluorescence in situ hybridization analysis was used to correlate the genomic sequence with the cytogenetic map in order to refine the genomic definition of the centric heterochromatin; on the basis of our cytological definition, the annotated Release 3 euchromatic sequence extends into the centric heterochromatin on each chromosome arm., Conclusions: Whole-genome shotgun assembly produced a reliable draft-quality sequence of a significant part of the Drosophila heterochromatin. Annotation of this sequence defined the intron-exon structures of 30 known protein-coding genes and 267 protein-coding gene models. The cytogenetic mapping suggests that an additional 150 predicted genes are located in heterochromatin at the base of the Release 3 euchromatic sequence. Our analysis suggests strategies for improving the sequence and annotation of the heterochromatic portions of the Drosophila and other complex genomes.

Published

2002

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

Author

Celniker SE, Wheeler DA, Kronmiller B, Carlson JW, Halpern A, Patel S, Adams M, Champe M, Dugan SP, Frise E, Hodgson A, George RA, Hoskins RA, Laverty T, Muzny DM, Nelson CR, Pacleb JM, Park S, Pfeiffer BD, Richards S, Sodergren EJ, Svirskas R, Tabor PE, Wan K, Stapleton M, Sutton GG, Venter C, Weinstock G, Scherer SE, Myers EW, Gibbs RA, and Rubin GM

Subjects

Animals, Physical Chromosome Mapping methods, Research Design, X Chromosome genetics, Drosophila melanogaster genetics, Euchromatin genetics, Genome, Sequence Analysis, DNA methods

Abstract

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.

Published

2002

21. Heterochromatic sequences in a Drosophila whole-genome shotgun assembly

Author

Hoskins, Roger A, Smith, Christopher D, Carlson, Joseph W, Carvalho, A Bernardo, Halpern, Aaron, Kaminker, Joshua S, Kennedy, Cameron, Mungall, Chris J, Sullivan, Beth A, Sutton, Granger G, Yasuhara, Jiro C, Wakimoto, Barbara T, Myers, Eugene W, Celniker, Susan E, Rubin, Gerald M, and Karpen, Gary H

Subjects

Genome, Bioinformatics, Human Genome, DNA, Biological Sciences, Contig Mapping, Databases, Drosophila melanogaster, Genetic, Heterochromatin, Information and Computing Sciences, Genetics, DNA Transposable Elements, Animals, Generic health relevance, Sequence Analysis, Algorithms, Software, Environmental Sciences, Biotechnology

Abstract

BACKGROUND:Most eukaryotic genomes include a substantial repeat-rich fraction termed heterochromatin, which is concentrated in centric and telomeric regions. The repetitive nature of heterochromatic sequence makes it difficult to assemble and analyze. To better understand the heterochromatic component of the Drosophila melanogaster genome, we characterized and annotated portions of a whole-genome shotgun sequence assembly. RESULTS:WGS3, an improved whole-genome shotgun assembly, includes 20.7 Mb of draft-quality sequence not represented in the Release 3 sequence spanning the euchromatin. We annotated this sequence using the methods employed in the re-annotation of the Release 3 euchromatic sequence. This analysis predicted 297 protein-coding genes and six non-protein-coding genes, including known heterochromatic genes, and regions of similarity to known transposable elements. Bacterial artificial chromosome (BAC)-based fluorescence in situ hybridization analysis was used to correlate the genomic sequence with the cytogenetic map in order to refine the genomic definition of the centric heterochromatin; on the basis of our cytological definition, the annotated Release 3 euchromatic sequence extends into the centric heterochromatin on each chromosome arm. CONCLUSIONS:Whole-genome shotgun assembly produced a reliable draft-quality sequence of a significant part of the Drosophila heterochromatin. Annotation of this sequence defined the intron-exon structures of 30 known protein-coding genes and 267 protein-coding gene models. The cytogenetic mapping suggests that an additional 150 predicted genes are located in heterochromatin at the base of the Release 3 euchromatic sequence. Our analysis suggests strategies for improving the sequence and annotation of the heterochromatic portions of the Drosophila and other complex genomes.

Published

2002

22. Genome-guided transcript assembly by integrative analysis of RNA sequence data.

Author

Boley, Nathan, Stoiber, Marcus H, Booth, Benjamin W, Wan, Kenneth H, Hoskins, Roger A, Bickel, Peter J, Celniker, Susan E, and Brown, James B

Subjects

NUCLEOTIDE sequence, GENE expression, GENETIC transcription, ALTERNATIVE RNA splicing, DROSOPHILA melanogaster, PROMOTERS (Genetics)

Abstract

The identification of full length transcripts entirely from short-read RNA sequencing data (RNA-seq) remains a challenge in the annotation of genomes. Here we describe an automated pipeline for genome annotation that integrates RNA-seq and gene-boundary data sets, which we call Generalized RNA Integration Tool, or GRIT. Applying GRIT to Drosophila melanogaster short-read RNA-seq, cap analysis of gene expression (CAGE) and poly(A)-site-seq data collected for the modENCODE project, we recovered the vast majority of previously annotated transcripts and doubled the total number of transcripts cataloged. We found that 20% of protein coding genes encode multiple protein-localization signals and that, in 20-d-old adult fly heads, genes with multiple polyadenylation sites are more common than genes with alternative splicing or alternative promoters. GRIT demonstrates 30% higher precision and recall than the most widely used transcript assembly tools. GRIT will facilitate the automated generation of high-quality genome annotations without the need for extensive manual annotation. [ABSTRACT FROM AUTHOR]

Published

2014

23. A BAC-Based Physical Map of the Major Autosomes of Drosophila melanogaster.

Author

Hoskins, Roger A., Nelson, Catherine R., Berman, Benjamin P., Laverty, Todd R., George, Reed A., Ciesiotka, Lisa, Naeemuddin, Mohammed, Arenson, Andrew D., Durbin, James, David, Robert G., Tabor, Paul E., Bailey, Michael R., DeShazo, Denise R., Catanese, Joseph, Mammoser, Aaron, Osoegawa, Kazutoyo, de Jong, Pieter J., Celniker, Susan E., Gibbs, Richard A., and Rubin, Gerald M.

Subjects

*GENE mapping, *ANIMAL genome mapping, *DROSOPHILA melanogaster, *GENETICS

Abstract

Discusses the construction of a bacterial artificial chromosome-based physical map of chromosomes of Drosophila melanogaster. Use of the fruit fly Drosophila melanogaster as an animal model in metazoan genetics and molecular biology; Procedure of the construction of the gene map; Features of the genetic map.

Published

2000

24. The Genome Sequence of Drosophila melanogaster.

Author

Adams, Mark D., Celniker, Susan E., Holt, Robert A., Evans, Cheryl A., Gocayne, Jeannine D., Amanatides, Peter G., Scherer, Steven E., Li, Peter W., Hoskins, Roger A., Galle, Richard F., George, Reed A., Lewis, Suzanna E., Richards, Stephen, Ashburner, Michael, Henderson, Scott N., Sutton, Granger G., Wortman, Jennifer R., Yandell, Hark D., and Zhang, Qing

Subjects

*DROSOPHILA melanogaster, *GENOMES, *DROSOPHILA genetics, *ANALYTICAL chemistry, *GENETICS

Abstract

Discusses the genome sequence of Drosophila melanogaster. Description of the Drosophila genome; Structure of the genome; Annotation of the Drosophila genome; Significance of the genomic sequence in analyzing processes common to all cells.

Published

2000