Your search keyword '"Yaqin Ma"' showing total 5 results

1. A BAC-based physical map of Brachypodium distachyon and its comparative analysis with rice and wheat

Author

William Nelson, Frank M. You, Jan Dvorak, Yong Q. Gu, Carol Soderlund, John P. Vogel, Gerard R. Lazo, Ming-Cheng Luo, Olin D. Anderson, Naxin Huo, and Yaqin Ma

Subjects

Chromosomes, Artificial, Bacterial, lcsh:QH426-470, lcsh:Biotechnology, Genomics, Computational biology, Poaceae, Genome, Evolution, Molecular, Contig Mapping, lcsh:TP248.13-248.65, Genetics, Genome size, Triticum, Whole genome sequencing, Comparative genomics, Expressed Sequence Tags, biology, food and beverages, Oryza, biology.organism_classification, Physical Chromosome Mapping, DNA Fingerprinting, lcsh:Genetics, Brachypodium, Brachypodium distachyon, Edible Grain, Functional genomics, Genome, Plant, Biotechnology, Research Article

Abstract

BackgroundBrachypodium distachyon(Brachypodium) has been recognized as a new model species for comparative and functional genomics of cereal and bioenergy crops because it possesses many biological attributes desirable in a model, such as a small genome size, short stature, self-pollinating habit, and short generation cycle. To maximize the utility ofBrachypodium as a model for basic and applied research it is necessary to develop genomic resources for it. A BAC-based physical map is one of them. A physical map will facilitate analysis of genome structure, comparative genomics, and assembly of the entire genome sequence.ResultsA total of 67,151BrachypodiumBAC clones were fingerprinted with the SNaPshot HICF fingerprinting method and a genome-wide physical map of theBrachypodiumgenome was constructed. The map consisted of 671 contigs and 2,161 clones remained as singletons. The contigs and singletons spanned 414 Mb. A total of 13,970 gene-related sequences were detected in the BAC end sequences (BES). These gene tags aligned 345 contigs with 336 Mb of rice genome sequence, showing thatBrachypodiumand rice genomes are generally highly colinear. Divergent regions were mainly in the rice centromeric regions. A dot-plot ofBrachypodiumcontigs against the rice genome sequences revealed remnants of the whole-genome duplication caused by paleotetraploidy, which were previously found in rice and sorghum.Brachypodiumcontigs were anchored to the wheat deletion bin maps with the BES gene-tags, opening the door toBrachypodium-Triticeae comparative genomics.ConclusionThe construction of theBrachypodiumphysical map, and its comparison with the rice genome sequence demonstrated the utility of the SNaPshot-HICF method in the construction of BAC-based physical maps. The map represents an important genomic resource for the completion ofBrachypodiumgenome sequence and grass comparative genomics. A draft of the physical map and its comparisons with rice and wheat are available athttp://phymap.ucdavis.edu/brachypodium/.

Published

2009

2. Feasibility of physical map construction fromfingerprinted bacterial artificial chromosomelibraries of polyploid plant species.

Author

Ming-Cheng Luo, Yaqin Ma, You, Frank M., Anderson, Olin D., Kopecký, David, Šimková, Hana, Šafář, Jan, Doležel, Jaroslav, Gill, Bikram, McGuire, Patrick E., and Dvorak, Jan

Subjects

*BACTERIAL artificial chromosomes, *GENETICS, *GENOMES, *HUMAN fingerprints, *CHROMOSOMES

Abstract

Background: The presence of closely related genomes in polyploid species makes the assembly of total genomic sequence from shotgun sequence reads produced by the current sequencing platforms exceedingly difficult, if not impossible. Genomes of polyploid species could be sequenced following the ordered-clone sequencing approach employing contigs of bacterial artificial chromosome (BAC) clones and BAC-based physical maps. Although BAC contigs can currently be constructed for virtually any diploid organism with the SNaPshot high-informationcontent- fingerprinting (HICF) technology, it is currently unknown if this is also true for polyploid species. It is possible that BAC clones from orthologous regions of homoeologous chromosomes would share numerous restriction fragments and be therefore included into common contigs. Because of this and other concerns, physical mapping utilizing the SNaPshot HICF of BAC libraries of polyploid species has not been pursued and the possibility of doing so has not been assessed. The sole exception has been in common wheat, an allohexaploid in which it is possible to construct single-chromosome or single-chromosome-arm BAC libraries from DNA of flow-sorted chromosomes and bypass the obstacles created by polyploidy. Results: The potential of the SNaPshot HICF technology for physical mapping of polyploid plants utilizing global BAC libraries was evaluated by assembling contigs of fingerprinted clones in an in silico merged BAC library composed of single-chromosome libraries of two wheat homoeologous chromosome arms, 3AS and 3DS, and complete chromosome 3B. Because the chromosome arm origin of each clone was known, it was possible to estimate the fidelity of contig assembly. On average 97.78% or more clones, depending on the library, were from a single chromosome arm. A large portion of the remaining clones was shown to be library contamination from other chromosomes, a feature that is unavoidable during the construction of single-chromosome BAC libraries. Conclusions: The negligibly low level of incorporation of clones from homoeologous chromosome arms into a contig during contig assembly suggested that it is feasible to construct contigs and physical maps using global BAC libraries of wheat and almost certainly also of other plant polyploid species with genome sizes comparable to that of wheat. Because of the high purity of the resulting assembled contigs, they can be directly used for genome sequencing. It is currently unknown but possible that equally good BAC contigs can be also constructed for polyploid species containing smaller, more gene-rich genomes. [ABSTRACT FROM AUTHOR]

Published

2010

3. A BAC-based physical map of Brachypodium distachyon and its comparative analysis with rice and wheat.

Author

Gu, Yong Q., Yaqin Ma, Naxin Huo, Vogel, John P., You, Frank M., Lazo, Gerard R., Nelson, William M., Soderlund, Carol, Dvorak, Jan, Anderson, Olin D., and Ming-Cheng Luo

Subjects

*BRACHYPODIUM, *RICE, *WHEAT, *GENOMICS, *ENERGY crops

Abstract

Background: Brachypodium distachyon (Brachypodium) has been recognized as a new model species for comparative and functional genomics of cereal and bioenergy crops because it possesses many biological attributes desirable in a model, such as a small genome size, short stature, self-pollinating habit, and short generation cycle. To maximize the utility of Brachypodium as a model for basic and applied research it is necessary to develop genomic resources for it. A BAC-based physical map is one of them. A physical map will facilitate analysis of genome structure, comparative genomics, and assembly of the entire genome sequence. Results: A total of 67,151 Brachypodium BAC clones were fingerprinted with the SNaPshot HICF fingerprinting method and a genome-wide physical map of the Brachypodium genome was constructed. The map consisted of 671 contigs and 2,161 clones remained as singletons. The contigs and singletons spanned 414 Mb. A total of 13,970 gene-related sequences were detected in the BAC end sequences (BES). These gene tags aligned 345 contigs with 336 Mb of rice genome sequence, showing that Brachypodium and rice genomes are generally highly colinear. Divergent regions were mainly in the rice centromeric regions. A dot-plot of Brachypodium contigs against the rice genome sequences revealed remnants of the whole-genome duplication caused by paleotetraploidy, which were previously found in rice and sorghum. Brachypodium contigs were anchored to the wheat deletion bin maps with the BES gene-tags, opening the door to Brachypodium-Triticeae comparative genomics. Conclusion: The construction of the Brachypodium physical map, and its comparison with the rice genome sequence demonstrated the utility of the SNaPshot-HICF method in the construction of BAC-based physical maps. The map represents an important genomic resource for the completion of Brachypodium genome sequence and grass comparative genomics. A draft of the physical map and its comparisons with rice and wheat are available at http://phymap.ucdavis.edu/brachypodium/. [ABSTRACT FROM AUTHOR]

Published

2009

4. A high-throughput strategy for screening of bacterial artificial chromosome libraries and anchoring of clones on a genetic map constructed with single nucleotide polymorphisms.

Author

Ming-Cheng Luo, Kenong Xu, Yaqin Ma, Deal, Karin R., Nicolet, Charles M., and Dvorak, Jan

Subjects

ARTIFICIAL chromosomes, EUKARYOTIC cells, GENOMES, GENE mapping, OLIGONUCLEOTIDES

Abstract

Background: Current techniques of screening bacterial artificial chromosome (BAC) libraries for molecular markers during the construction of physical maps are slow, laborious and often assign multiple BAC contigs to a single locus on a genetic map. These limitations are the principal impediment in the construction of physical maps of large eukaryotic genomes. It is hypothesized that this impediment can be overcome by screening multidimensional pools of BAC clones using the highly parallel Illumina GoldenGate™ assay. Results: To test the efficacy of the Golden Gate assay in BAC library screening, multidimensional pools involving 302976 Aegilops tauschii BAC clones were genotyped for the presence/absence of specific gene sequences with multiplexed Illumina GoldenGate oligonucleotide assays previously used to place single nucleotide polymorphisms on an Ae. tauschii genetic map. Of 1384 alleleinformative oligonucleotide assays, 87.6% successfully clustered BAC pools into those positive for a BAC clone harboring a specific gene locus and those negative for it. The location of the positive BAC clones within contigs assembled from 199190 fingerprinted Ae. tauschii BAC clones was used to evaluate the precision of anchoring of BAC clones and contigs on the Ae. tauschii genetic map. For 41 (95%) assays, positive BAC clones were neighbors in single contigs. Those contigs could be unequivocally assigned to loci on the genetic map. For two (5%) assays, positive clones were in two different contigs and the relationships of these contigs to loci on the Ae. tauschii genetic map were equivocal. Screening of BAC libraries with a simple five-dimensional BAC pooling strategy was evaluated and shown to allow direct detection of positive BAC clones without the need for manual deconvolution of BAC clone pools. Conclusion: The highly parallel Illumina oligonucleotide assay is shown here to be an efficient tool for screening BAC libraries and a strategy for high-throughput anchoring of BAC contigs on genetic maps during the construction of physical maps of eukaryotic genomes. In most cases, screening of BAC libraries with Illumina oligonucleotide assays results in the unequivocal relationship of BAC clones with loci on the genetic map. [ABSTRACT FROM AUTHOR]

Published

2009

5. BatchPrimer3: A high throughput web application for PCR and sequencing primer design.

Author

You, Frank M., Huo, Naxin, Yong Qiang Gu, Ming-cheng Luo, Yaqin Ma, Hane, Dave, Lazo, Gerard R., Dvorak, Jan, and Anderson, Olin D.

Subjects

MICROSATELLITE repeats, COMPUTER software, POLYMERASE chain reaction, NUCLEOTIDES, GENETIC polymorphisms, GENE mapping, NUCLEOTIDE sequence

Abstract

Background: Microsatellite (simple sequence repeat -- SSR) and single nucleotide polymorphism (SNP) markers are two types of important genetic markers useful in genetic mapping and genotyping. Often, large-scale genomic research projects require high-throughput computer-assisted primer design. Numerous such web-based or standard-alone programs for PCR primer design are available but vary in quality and functionality. In particular, most programs lack batch primer design capability. Such a high-throughput software tool for designing SSR flanking primers and SNP genotyping primers is increasingly demanded. Results: A new web primer design program, BatchPrimer3, is developed based on Primer3. BatchPrimer3 adopted the Primer3 core program as a major primer design engine to choose the best primer pairs. A new scorebased primer picking module is incorporated into BatchPrimer3 and used to pick position-restricted primers. BatchPrimer3 v1.0 implements several types of primer designs including generic primers, SSR primers together with SSR detection, and SNP genotyping primers (including single-base extension primers, allele-specific primers, and tetra-primers for tetra-primer ARMS PCR), as well as DNA sequencing primers. DNA sequences in FASTA format can be batch read into the program. The basic information of input sequences, as a reference of parameter setting of primer design, can be obtained by pre-analysis of sequences. The input sequences can be pre-processed and masked to exclude and/or include specific regions, or set targets for different primer design purposes as in Primer3Web and primer3Plus. A tab-delimited or Excel-formatted primer output also greatly facilitates the subsequent primer-ordering process. Thousands of primers, including wheat conserved intron-flanking primers, wheat genome-specific SNP genotyping primers, and Brachypodium SSR flanking primers in several genome projects have been designed using the program and validated in several laboratories. Conclusion: BatchPrimer3 is a comprehensive web primer design program to develop different types of primers in a high-throughput manner. Additional methods of primer design can be easily integrated into future versions of BatchPrimer3. The program with source code and thousands of PCR and sequencing primers designed for wheat and Brachypodium are accessible at http://wheat.pw.usda.gov/demos/BatchPrimer3/. [ABSTRACT FROM AUTHOR]

Published

2008