A marker-dense physical map of the Bradyrhizobium japonicum genome.

Bacterial artificial chromosome (BAC) clones are effective mapping and sequencing reagents for use with a wide variety of small and large genomes. This report describes the development of a physical framework for the genome of Bradyrhizobium japonicum, the nitrogen-fixing symbiont of soybean. A BAC library for B. japonicum was constructed that provides a 77-fold genome coverage based on an estimated genome size of 8.7 Mb. The library contains 4608 clones with an average insert size of 146 kb. To generate a physical map, the entire library was fingerprinted with HindIII, and the fingerprinted clones were assembled into contigs using the software (; Sanger Centre, UK). The analysis placed 3410 clones in six large contigs. The ends of 1152 BAC inserts were sequenced to generate a sequence-tagged connector (STC) framework. To join and orient the contigs, high-density BAC colony filters were probed with 41 known gene probes and 17 end sequences from contig boundaries. STC sequences were searched against the public databases using and algorithms. Query results allowed the identification of 113 high probability matches with putative functional identities that were placed on the physical map. Combined with the hybridization data, a high-resolution physical map with 194 positioned markers represented in two large contigs was developed, providing a marker every 45 kb. Of these markers, 177 are known or putative B. japonicum genes. Additionally, 1338 significant results (E < 10(-4)) were manually sorted by function to produce a functionally categorized database of relevant B. japonicum STC sequences that can also be traced to specific locations in the physical map.

Tomkins JP ，Wood TC ，Stacey MG ，Loh JT ，Judd A ，Goicoechea JL ，Stacey G ，Sadowsky MJ ，Wing RA ... -  《GENOME RESEARCH》

Integrated and sequence-ordered BAC- and YAC-based physical maps for the rat genome.

As part of the effort to sequence the genome of Rattus norvegicus, we constructed a physical map comprised of fingerprinted bacterial artificial chromosome (BAC) clones from the CHORI-230 BAC library. These BAC clones provide approximately 13-fold redundant coverage of the genome and have been assembled into 376 fingerprint contigs. A yeast artificial chromosome (YAC) map was also constructed and aligned with the BAC map via fingerprinted BAC and P1 artificial chromosome clones (PACs) sharing interspersed repetitive sequence markers with the YAC-based physical map. We have annotated 95% of the fingerprint map clones in contigs with coordinates on the version 3.1 rat genome sequence assembly, using BAC-end sequences and in silico mapping methods. These coordinates have allowed anchoring 358 of the 376 fingerprint map contigs onto the sequence assembly. Of these, 324 contigs are anchored to rat genome sequences localized to chromosomes, and 34 contigs are anchored to unlocalized portions of the rat sequence assembly. The remaining 18 contigs, containing 54 clones, still require placement. The fingerprint map is a high-resolution integrative data resource that provides genome-ordered associations among BAC, YAC, and PAC clones and the assembled sequence of the rat genome.

Krzywinski M ，Wallis J ，Gösele C ，Bosdet I ，Chiu R ，Graves T ，Hummel O ，Layman D ，Mathewson C ，Wye N ，Zhu B ，Albracht D ，Asano J ，Barber S ，Brown-John M ，Chan S ，Chand S ，Cloutier A ，Davito J ，Fjell C ，Gaige T ，Ganten D ，Girn N ，Guggenheimer K ，Himmelbauer H ，Kreitler T ，Leach S ，Lee D ，Lehrach H ，Mayo M ，Mead K ，Olson T ，Pandoh P ，Prabhu AL ，Shin H ，Tänzer S ，Thompson J ，Tsai M ，Walker J ，Yang G ，Sekhon M ，Hillier L ，Zimdahl H ，Marziali A ，Osoegawa K ，Zhao S ，Siddiqui A ，de Jong PJ ，Warren W ，Mardis E ，McPherson JD ，Wilson R ，Hübner N ，Jones S ，Marra M ，Schein J ... -  《GENOME RESEARCH》

Physical map and gene survey of the Ochrobactrum anthropi genome using bacterial artificial chromosome contigs.

Tomkins JP ，Miller-Smith H ，Sasinowski M ，Choi S ，Sasinowska H ，Verce MF ，Freedman DL ，Dean RA ，Wing RA ... -  《-》

A BAC-based physical map of the Hessian fly genome anchored to polytene chromosomes.

The Hessian fly (Mayetiola destructor) is an important insect pest of wheat. It has tractable genetics, polytene chromosomes, and a small genome (158 Mb). Investigation of the Hessian fly presents excellent opportunities to study plant-insect interactions and the molecular mechanisms underlying genome imprinting and chromosome elimination. A physical map is needed to improve the ability to perform both positional cloning and comparative genomic analyses with the fully sequenced genomes of other dipteran species. An FPC-based genome wide physical map of the Hessian fly was constructed and anchored to the insect's polytene chromosomes. Bacterial artificial chromosome (BAC) clones corresponding to 12-fold coverage of the Hessian fly genome were fingerprinted, using high information content fingerprinting (HIFC) methodology, and end-sequenced. Fluorescence in situ hybridization (FISH) co-localized two BAC clones from each of the 196 longest contigs on the polytene chromosomes. An additional 70 contigs were positioned using a single FISH probe. The 266 FISH mapped contigs were evenly distributed and covered 60% of the genome (95,668 kb). The ends of the fingerprinted BACs were then sequenced to develop the capacity to create sequenced tagged site (STS) markers on the BACs in the map. Only 3.64% of the BAC-end sequence was composed of transposable elements, helicases, ribosomal repeats, simple sequence repeats, and sequences of low complexity. A relatively large fraction (14.27%) of the BES was comprised of multi-copy gene sequences. Nearly 1% of the end sequence was composed of simple sequence repeats (SSRs). This physical map provides the foundation for high-resolution genetic mapping, map-based cloning, and assembly of complete genome sequencing data. The results indicate that restriction fragment length heterogeneity in BAC libraries used to construct physical maps lower the length and the depth of the contigs, but is not an absolute barrier to the successful application of the technology. This map will serve as a genomic resource for accelerating gene discovery, genome sequencing, and the assembly of BAC sequences. The Hessian fly BAC-clone assembly, and the names and positions of the BAC clones used in the FISH experiments are publically available at (http://genome.purdue.edu/WebAGCoL/Hfly/WebFPC/).

Aggarwal R ，Benatti TR ，Gill N ，Zhao C ，Chen MS ，Fellers JP ，Schemerhorn BJ ，Stuart JJ ... -  《BMC GENOMICS》

A BAC-based physical map of the channel catfish genome.

Xu P ，Wang S ，Liu L ，Thorsen J ，Kucuktas H ，Liu Z ... -  《GENOMICS》