Your search keyword '"Osoegawa, K."' showing total 113 results

101. A porcine BAC library with tenfold genome coverage: a resource for physical and genetic map integration.

Author

Fahrenkrug SC, Rohrer GA, Freking BA, Smith TP, Osoegawa K, Shu CL, Catanese JJ, and de Jong PJ

Subjects

Animals, Chromosomes, Microsatellite Repeats, Swine, Chromosome Mapping instrumentation, Chromosomes, Artificial, Bacterial, Gene Library, Genome, Physical Chromosome Mapping instrumentation

Published

2001

102. A physical map of the human genome.

Author

McPherson JD, Marra M, Hillier L, Waterston RH, Chinwalla A, Wallis J, Sekhon M, Wylie K, Mardis ER, Wilson RK, Fulton R, Kucaba TA, Wagner-McPherson C, Barbazuk WB, Gregory SG, Humphray SJ, French L, Evans RS, Bethel G, Whittaker A, Holden JL, McCann OT, Dunham A, Soderlund C, Scott CE, Bentley DR, Schuler G, Chen HC, Jang W, Green ED, Idol JR, Maduro VV, Montgomery KT, Lee E, Miller A, Emerling S, Kucherlapati, Gibbs R, Scherer S, Gorrell JH, Sodergren E, Clerc-Blankenburg K, Tabor P, Naylor S, Garcia D, de Jong PJ, Catanese JJ, Nowak N, Osoegawa K, Qin S, Rowen L, Madan A, Dors M, Hood L, Trask B, Friedman C, Massa H, Cheung VG, Kirsch IR, Reid T, Yonescu R, Weissenbach J, Bruls T, Heilig R, Branscomb E, Olsen A, Doggett N, Cheng JF, Hawkins T, Myers RM, Shang J, Ramirez L, Schmutz J, Velasquez O, Dixon K, Stone NE, Cox DR, Haussler D, Kent WJ, Furey T, Rogic S, Kennedy S, Jones S, Rosenthal A, Wen G, Schilhabel M, Gloeckner G, Nyakatura G, Siebert R, Schlegelberger B, Korenberg J, Chen XN, Fujiyama A, Hattori M, Toyoda A, Yada T, Park HS, Sakaki Y, Shimizu N, Asakawa S, Kawasaki K, Sasaki T, Shintani A, Shimizu A, Shibuya K, Kudoh J, Minoshima S, Ramser J, Seranski P, Hoff C, Poustka A, Reinhardt R, and Lehrach H

Subjects

Chromosomes, Artificial, Bacterial, Cloning, Molecular, DNA Fingerprinting, Gene Duplication, Humans, In Situ Hybridization, Fluorescence, Repetitive Sequences, Nucleic Acid, Contig Mapping, Genome, Human

Abstract

The human genome is by far the largest genome to be sequenced, and its size and complexity present many challenges for sequence assembly. The International Human Genome Sequencing Consortium constructed a map of the whole genome to enable the selection of clones for sequencing and for the accurate assembly of the genome sequence. Here we report the construction of the whole-genome bacterial artificial chromosome (BAC) map and its integration with previous landmark maps and information from mapping efforts focused on specific chromosomal regions. We also describe the integration of sequence data with the map.

Published

2001

103. Modular bacterial artificial chromosome vectors for transfer of large inserts into mammalian cells.

Author

Frengen E, Zhao B, Howe S, Weichenhan D, Osoegawa K, Gjernes E, Jessee J, Prydz H, Huxley C, and de Jong PJ

Subjects

Animals, Bacteriophage P1 genetics, Binding Sites genetics, COS Cells, Cell Line, Chromosomes, Bacterial genetics, Cloning, Molecular, DNA Transposable Elements, DNA, Recombinant genetics, Humans, Molecular Sequence Data, Plasmids genetics, Transfection, DNA genetics, Genetic Vectors genetics

Abstract

To facilitate the use of large-insert bacterial clones for functional analysis, we have constructed new bacterial artificial chromosome vectors, pPAC4 and pBACe4. These vectors contain two genetic elements that enable stable maintenance of the clones in mammalian cells: (1) The Epstein-Barr virus replicon, oriP, is included to ensure stable episomal propagation of the large insert clones upon transfection into mammalian cells. (2) The blasticidin deaminase gene is placed in a eukaryotic expression cassette to enable selection for the desired mammalian clones by using the nucleoside antibiotic blasticidin. Sequences important to select for loxP-specific genome targeting in mammalian chromosomes are also present. In addition, we demonstrate that the attTn7 sequence present on the vectors permits specific addition of selected features to the library clones. Unique sites have also been included in the vector to enable linearization of the large-insert clones, e. g., for optical mapping studies. The pPAC4 vector has been used to generate libraries from the human, mouse, and rat genomes. We believe that clones from these libraries would serve as an important reagent in functional experiments, including the identification or validation of candidate disease genes, by transferring a particular clone containing the relevant wildtype gene into mutant cells or transgenic or knock-out animals., (Copyright 2000 Academic Press.)

Published

2000

104. 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

105. A modular, positive selection bacterial artificial chromosome vector with multiple cloning sites.

Author

Frengen E, Weichenhan D, Zhao B, Osoegawa K, van Geel M, and de Jong PJ

Subjects

Binding Sites, Cloning, Molecular, DNA Restriction Enzymes, DNA Transposable Elements, DNA, Bacterial genetics, Molecular Sequence Data, Chromosomes, Bacterial genetics, Genetic Vectors genetics

Abstract

To construct large-insert libraries for the sequencing, mapping, and functional studies of complex genomes, we have constructed a new modular bacterial artificial chromosome (BAC) vector, pBACe3.6 (GenBank Accession No. U80929). This vector contains multiple cloning sites located within the sacB gene, allowing positive selection for recombinant clones on sucrose-containing medium. A recognition site for the PI-SceI nuclease has also been included, which permits linearization of recombinant DNA irrespective of the characteristics of the insert sequences. An attTn7 sequence present in pBACe3.6 permits retrofitting of BAC clones by Tn7-mediated insertion of desirable sequence elements into the vector portion. The ability to retrofit BAC clones will be useful for functional analysis of genes carried on the cloned inserts. The pBACe3.6 vector has been used for the construction of many genomic libraries currently serving as resources for large-scale mapping and sequencing., (Copyright 1999 Academic Press.)

Published

1999

106. Mapping of a novel human carbonyl reductase, CBR3, and ribosomal pseudogenes to human chromosome 21q22.2.

Author

Watanabe K, Sugawara C, Ono A, Fukuzumi Y, Itakura S, Yamazaki M, Tashiro H, Osoegawa K, Soeda E, and Nomura T

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, DNA, Complementary analysis, DNA, Complementary isolation & purification, Humans, Molecular Sequence Data, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Alcohol Oxidoreductases genetics, Chromosome Mapping, Chromosomes, Human, Pair 21 genetics, Pseudogenes genetics, Ribosomes genetics

Abstract

To find the genes contributing to Down syndrome, we constructed a 4-Mb sequence-ready map spanning chromosome 21q22.2 with megabase-sized cosmid/P1-derived artificial chromosome (PAC) contigs. The restriction map with rare cutting enzymes, followed by sequencing from the clustering sites, has defined CpG islands and revealed the genes associated with CpG islands (Accession No. D85771). Of these, two human carbonyl reductases (CBR; EC1.1.1.184) were found in a PAC 25P16 clone. CBR catalyzes the reduction of a large number of biologically and pharmacologically active carbonyl compounds to their corresponding alcohols and has been mapped in 21q22.1. To confirm these results, we sequenced the PAC clone in shotgun strategies and identified a novel carbonyl reductase, designated CBR3, 62 kb downstream from the original CBR. In addition, three ribosomal pseudogenes, L23a, S9, and L3, and some cDNAs with ESTs were mapped in the sequence. In conclusion, the sequence analysis for CpG islands predicted from the megabase-sized contigs will reveal and identify the genes involved in Down syndrome., (Copyright 1998 Academic Press.)

Published

1998

107. An improved approach for construction of bacterial artificial chromosome libraries.

Author

Osoegawa K, Woon PY, Zhao B, Frengen E, Tateno M, Catanese JJ, and de Jong PJ

Subjects

Animals, Bacteriophage P1 genetics, Chemical Fractionation methods, Electrophoresis, Agar Gel methods, Genetic Techniques, Genetic Vectors chemistry, Mice, Molecular Weight, Rats, Reproducibility of Results, Time Factors, Chromosomes, Bacterial genetics, Genome, Bacterial, Genomic Library

Abstract

Presented here are improved methodologies that enable the generation of highly redundant bacterial artificial chromosome/P1-derived artificial chromosome libraries, with larger and relatively uniform insert sizes. Improvements in vector preparation and enhanced ligation conditions reduce the number of background nonrecombinant clones. Preelectrophoresis of immobilized high-molecular-weight DNA removes inhibitors of the cloning process, while sizing DNA fragments twice within a single gel effectively eliminates small restriction fragments, thus increasing the average insert size of the clones. The size-fractionated DNA fragments are recovered by electroelution rather than the more common melting of gel slices with subsequent beta-agarase treatment. Concentration of the ligation products yields a 6- to 12-fold reduction in the number of electroporations required in preparing a library of desirable size. These improved methods have been applied to prepare PAC and BAC libraries from the human, murine, rat, canine, and baboon genomes with average insert sizes ranging between 160 and 235 kb., (Copyright 1998 Academic Press.)

Published

1998

108. Construction and characterization of a 10-fold genome equivalent rat P1-derived artificial chromosome library.

Author

Woon PY, Osoegawa K, Kaisaki PJ, Zhao B, Catanese JJ, Gauguier D, Cox R, Levy ER, Lathrop GM, Monaco AP, and de Jong PJ

Subjects

Animals, Chromosomes, Artificial, Yeast, DNA Restriction Enzymes, Electrophoresis, Gel, Pulsed-Field, Female, Genetic Markers, In Situ Hybridization, In Situ Hybridization, Fluorescence, Metaphase, Polymerase Chain Reaction, Rats, Rats, Inbred BN, Time Factors, Trinucleotide Repeat Expansion, Chromosomes genetics, Cloning, Molecular methods, Genomic Library

Abstract

A rat PAC library was constructed in the vector pPAC4 from genomic DNA isolated from female Brown Norway rats. This library consists of 215,409 clones arrayed in 614,384-well microtiter plates. An average insert size of 143 kb was estimated from 217 randomly isolated clones, thus representing approximately 10-fold genome coverage. This coverage provides a very high probability that the library contains a unique sequence in genome screening. Tests on randomly selected clones demonstrated that they are very stable, with only 4 of 130 clones showing restriction digest fragment alterations after 80 generations of serial growth. FISH analysis using 70 randomly chosen PACs revealed no significant chimeric clones. About 7% of the clones analyzed contained repetitive sequences related to centromeric regions that hybridized to some but not all centromeres. DNA plate pools and superpools were made, and high-density filters each containing an array of 8 plates in duplicate were prepared. Library screening on these superpools and appropriate filters with 10 single-locus rat markers revealed an average of 8 positive clones, in agreement with the estimated high genomic coverage of this library and representation of the rat genome. This library provides a new resource for rat genome analysis, in particular the identification of genes involved in models of multifactorial disease. The library and high-density filters are currently available to the scientific community.

Published

1998

109. An integrated map with cosmid/PAC contigs of a 4-Mb Down syndrome critical region.

Author

Osoegawa K, Susukida R, Okano S, Kudoh J, Minoshima S, Shimizu N, de Jong PJ, Groet J, Ives J, Lehrach H, Nizetic D, and Soeda E

Subjects

Bacteriophage P1 genetics, Chromosome Walking, Cloning, Molecular, Cosmids genetics, Exons genetics, Genetic Vectors genetics, Humans, Male, Restriction Mapping, Chromosome Mapping methods, Chromosomes, Human, Pair 21, Down Syndrome genetics, Gene Library

Abstract

The major phenotypic features of Down syndrome have been correlated with partial trisomies of chromosome 21, allowing us to define the candidate gene region to a 4-Mb segment on the 21q22.2 band. We present here a high-resolution physical map with megabase-sized cosmid/PAC contigs. This ordered clone library has provided unique material for the integration of a variety of mappable objects, including exons, cDNAs, restriction sites, etc. Furthermore, our results have exemplified a strategy for the completion of the chromosome 21 map to sequencing.

Published

1996

110. Isolation of a cosmid clone corresponding to an inv(21) breakpoint of a patient with transient abnormal myelopoiesis.

Author

Ohta T, Nakano M, Tsujita T, Abe K, Osoegawa K, Yamagata T, Yoshiura K, Jinno Y, Soeda E, Nakamura Y, and Niikawa N

Subjects

Adult, Base Sequence, Chromosome Walking, Cosmids genetics, Down Syndrome complications, Female, Humans, Infant, Newborn, Male, Molecular Sequence Data, Myeloproliferative Disorders complications, Sequence Tagged Sites, Chromosome Inversion, Chromosomes, Human, Pair 21, Cloning, Molecular methods, Myeloproliferative Disorders genetics

Abstract

Transient abnormal myelopoiesis (TAM) is a leukemoid reaction occurring occasionally on Down syndrome (DS) newborn infants. It has been hypothesized that "disomic homozygosity" in 21-trisomic cells plays an important role in the genesis of TAM, and the putative TAM gene was suggested to be mapped at a 21q11 region. We encountered a DS-associated TAM infant with a 47,XY,inv(21)(q11.1q22.13),+inv(21)(q11.1q22.13) karyotype. On the basis of another presumption that in this patient the putative TAM gene is disrupted by the break, we tried to isolate a breakpoint DNA. FISH analysis with cosmid clones corresponding to various sequence-tagged-site (STS) markers mapped at around 21q11.1-q11.2, we confirmed that the proximal breakpoint of the inv(21) was located between two STSs, G51E07 and D21S215, the latter locus being consistent with the previous tentative mapping. After construction of a cosmid contig encompassing between the two markers, we have isolated a cosmid clone corresponding to the proximal breakpoint of the inversion. This breakpoint was located near a previously identified duplicated region that is homologous to the sequence at 21q22.1. The isolated cosmid clone is useful for analysis of other TAM patients and for a search for a transcript at or flanking the breakpoint.

Published

1996

111. Cosmid assembly and anchoring to human chromosome 21.

Author

Soeda E, Hou DX, Osoegawa K, Atsuchi Y, Yamagata T, Shimokawa T, Kishida H, Soeda E, Okano S, and Chumakov I

Subjects

Animals, Base Sequence, Chromosome Mapping, DNA genetics, DNA isolation & purification, DNA Fingerprinting, DNA Primers, Fluorescent Dyes, Gene Library, Humans, Hybrid Cells, Mice, Molecular Sequence Data, Polymerase Chain Reaction, Chromosomes, Human, Pair 21, Cosmids

Abstract

A human chromosome 21-specific cosmid library from the Lawrence Livermore National Laboratory has been analyzed by two complementary methods, fingerprinting and hybridization; 40% coverage of the entire chromosome 21 has been achieved. To prepare a contig pool, approximately 9300 cosmid clones randomly selected from the library were fingerprinted and automatically assembled into 467 overlapping sets by the fluorescence-tagged restriction fragment method. The average size of the overlapping sets was 9.5 cosmids with minimal tiling paths consisting of 5.4 cosmids with a 10-kb extension each. However, as many as 10% of overlaps within members were estimated to be false. For regional localization, we hybridized gridded arrays of cosmids with inter-Alu-PCR probes obtained from YAC clones and somatic cell hybrids and assigned 592 cosmids to 26 subregions of 21q. Of these, 371 clones were incorporated into 139 contigs, anchoring the total 1864 cosmids to the subregion. The remaining 221 clones were mapped as orphans. To correlate the cytogenetic, YAC, and cosmid maps on 21q, the translocation breakpoints of the chromosomes contained in the somatic cell hybrids were mapped with respect to the STS content of the YACs. From the gene cluster regions, 176 ribosomal and 25 alphoid clones were isolated by hybridization. Together, these sets of anchored contigs and cosmids will provide a valuable resource for construction of a high-resolution map and for isolation of genes of interest from chromosome 21.

Published

1995

112. Streptomyces ATP nucleotide 3'-pyrophosphokinase-gene cloning and sequence analysis.

Author

Higuchi T, Mikuniya T, Osoegawa K, Ezaki S, Sumichika H, Mizui Y, Shoji T, Kishihara K, Muta S, and Kuhara S

Subjects

Amino Acid Sequence, Base Sequence, Cloning, Molecular, DNA, Bacterial, Molecular Sequence Data, Sequence Analysis, DNA, Sequence Homology, Amino Acid, Streptomyces genetics, Transcription, Genetic, Diphosphotransferases genetics, Genes, Bacterial, Streptomyces enzymology

Abstract

Streptomyces ATP nucleotide 3'-pyrophosphokinase is an extracellular enzyme that transfers 5'-beta, gamma-pyrophosphoryl groups of ATP to a variety of nucleotides at the 3'-OH site. The enzyme gene was cloned from partially Sau3AI-digested chromosomal DNA of S. morookaensis in S. lividans TK24/pIJ699 and then in E. coli JM83/pUC12. Some transformants produced the active enzyme. The gene was sequenced by the dideoxynucleotide termination procedure. Its GC content was 72%. Its putative promoter regions, showing little homology to that of the Streptomyces consensus type, were pointed out. No sequence homology was found between the pyrophosphokinase and any other known genes including those of the most mechanistically similar bacterial stringent factor and related proteins. Northern hybridization analysis showed that the gene is constitutionally polycistronic and expressed under transcriptional control. Nuclease S1 mapping indicated that the gene transcription starts from its translation initiation site.

Published

1994

113. Streptomyces ATP nucleotide 3'-pyrophosphokinase and its gene.

Author

Muta S, Osoegawa K, Ezaki S, Zubair M, Kuhara S, Mukai J, and Dixon R

Subjects

Base Sequence, Cloning, Molecular, DNA, Bacterial, Escherichia coli genetics, Genes, Bacterial, Klebsiella pneumoniae genetics, Methanobacterium genetics, Molecular Sequence Data, Diphosphotransferases, Phosphotransferases genetics, Streptomyces enzymology

Abstract

Streptomyces ATP nucleotide 3'-pyrophosphokinase is an extracellular, ribosome-independent, and stringent factor-mimic ppGpp synthetase with an unusually broad acceptor spectrum. The gene-containing DNA fragments cloned from chromosomal DNA of a producer S. morookaensis into pIJ699 and pUC plasmids were found to express the active enzyme in the transformed S. lividans TK24 and enteric E. coli JM109 and nitrogen-fixing Klebsiella pneumoniae M5a1 and 5022, respectively. Base sequence of the structural gene and the deduced amino acid sequence exhibited little homology to those of E. coli stringent factor and related proteins. Growth retardation was seen in some transformants.

Published

1992