Rice transposable elements: a survey of 73,000 sequence-tagged-connectors.

As part of an international effort to sequence the rice genome, the Clemson University Genomics Institute is developing a sequence-tagged-connector (STC) framework. This framework includes the generation of deep-coverage BAC libraries from O. sativa ssp. japonica c.v. Nipponbare and the sequencing of both ends of the genomic DNA insert of the BAC clones. Here, we report a survey of the transposable elements (TE) in >73,000 STCs. A total of 6848 STCs were found homologous to regions of known TE sequences (E<10(-5)) by FASTX search of STCs against a set of 1358 TE protein sequences obtained from GenBank. Of these TE-containing STCs (TE-STCs), 88% (6027) are related to retroelements and the remaining are transposase homologs. Nearly all DNA transposons known previously in plants were present in the STCs, including maize Ac/Ds, En/Spm, Mutator, and mariner-like elements. In addition, 2746 STCs were found to contain regions homologous to known miniature inverted-repeat transposable elements (MITEs). The distribution of these MITEs in regions near genes was confirmed by EST comparisons to MITE-containing STCs, and our results showed that the association of MITEs with known EST transcripts varies by MITE type. Unlike the biased distribution of retroelements in maize, we found no evidence for the presence of gene islands when we correlated TE-STCs with a physical map of the CUGI BAC library. These analyses of TEs in nearly 50 Mb of rice genomic DNA provide an interesting and informative preview of the rice genome.

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

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 research aimed at determining the genome structure of Ochrobactrum anthropi, an opportunistic human pathogen that has potential applications in biodegradation of hazardous organic compounds. A BAC library for O. anthropi was constructed that provides a 70-fold genome coverage based on an estimated genome size of 4.8 Mb. The library contains 3072 clones with an average insert size of 112 kb. High-density colony filters of the library were made, and a physical map of the genome was constructed using a hybridization without replacement strategy. In addition, 1536 BAC clones were fingerprinted with HindIII and analyzed using IMAGE and Fingerprint Contig software (FPC, Sanger Centre, U.K.). The FPC results supported the hybridization data, resulting in the formation of two major contigs representing the two major replicons of the O. anthropi genome. After determining a reduced tiling path, 138 BAC ends from the reduced tile were sequenced for a preliminary gene survey. A search of the public databases with the BLASTX algorithm resulted in 77 strong hits (E-value < 0.001), of which 89% showed similarity to a wide variety of prokaryotic genes. These results provide a contig-based physical map to assist the cloning of important genomic regions and the potential sequencing of the O. anthropi genome.

Physical map and organization of chromosome 7 in the rice blast fungus, Magnaporthe grisea.

The rice blast fungus Magnaporthe grisea is a highly destructive plant pathogen and one of the most important for studying various aspects of host-plant interactions. It has been widely adopted as a model organism because it is ideally suited for genetic and biological studies. To facilitate map-based cloning, chromosome walking, and genome organization studies of M. grisea, a complete physical map of chromosome 7 was constructed using a large-insert (130 kb) bacterial artificial chromosome (BAC) library. Using 147 chromosome 7-specific single-copy BAC clones and 20 RFLP markers on chromosome 7, 625 BAC clones were identified by hybridization. BAC clones were digested with HindIII, and fragments were size separated on analytical agarose gels to create DNA fingerprints. Hybridization contigs were constructed using a random cost algorithm, whereas fingerprinting contigs were constructed using the software package FPC. Results from both methods were generally in agreement, but numerous anomalies were observed. The combined data produced five robust anchored contigs after gap closure by chromosomal walking. The genetic and physical maps agreed closely. The final physical map was estimated to cover >95% of the 4.2 Mb of chromosome 7. Based on the contig maps, a minimum BAC tile containing 42 BAC clones was created, and organization of repetitive elements and expressed genes of the chromosome was investigated.

An algorithm for the assembly of robust physical maps based on a combination of multi-level hybridization data and fingerprinting data.

We have developed an algorithm which combines data obtained from restriction digestion experiments and hybridization experiments to construct robust physical maps of whole chromosomes. The algorithm has been incorporated into a program which accepts hybridization data consisting of an unordered hybridization matrix and fingerprinting data containing band coordinates for each clone. The combined data is used to produce a non-redundant, ordered matrix which can be further reduced to represent a minimum tile coverage of the chromosome. In addition, the method also takes into account multi-level hybridization events which allows for an improved treatment of the hybridization data. The program is evaluated against several other contig building programs using simulated and real data sets. Finally, it is applied to construct a physical map of the 4.1 Mb genome of Ochrobactrum anthropi based on 1387 clones and 70 probes, as well as 624 fingerprints.