Your search keyword '"Imelfort, Michael"' showing total 7 results

1. Inferring short tandem repeat variation from paired-end short reads.

Author

Cao MD, Tasker E, Willadsen K, Imelfort M, Vishwanathan S, Sureshkumar S, Balasubramanian S, and Bodén M

Subjects

Arabidopsis genetics, Bayes Theorem, Software, Genetic Variation, High-Throughput Nucleotide Sequencing methods, Sequence Analysis, DNA methods, Tandem Repeat Sequences

Abstract

The advances of high-throughput sequencing offer an unprecedented opportunity to study genetic variation. This is challenged by the difficulty of resolving variant calls in repetitive DNA regions. We present a Bayesian method to estimate repeat-length variation from paired-end sequence read data. The method makes variant calls based on deviations in sequence fragment sizes, allowing the analysis of repeats at lengths of relevance to a range of phenotypes. We demonstrate the method's ability to detect and quantify changes in repeat lengths from short read genomic sequence data across genotypes. We use the method to estimate repeat variation among 12 strains of Arabidopsis thaliana and demonstrate experimentally that our method compares favourably against existing methods. Using this method, we have identified all repeats across the genome, which are likely to be polymorphic. In addition, our predicted polymorphic repeats also included the only known repeat expansion in A. thaliana, suggesting an ability to discover potential unstable repeats.

Published

2014

2. Fast, accurate error-correction of amplicon pyrosequences using Acacia.

Author

Bragg L, Stone G, Imelfort M, Hugenholtz P, and Tyson GW

Subjects

Acacia chemistry, Algorithms, Gene Amplification, Sensitivity and Specificity, Sequence Alignment methods, Acacia genetics, RNA, Ribosomal genetics, Sequence Analysis, DNA methods

Published

2012

3. Bioinformatics tools and databases for analysis of next-generation sequence data.

Author

Lee HC, Lai K, Lorenc MT, Imelfort M, Duran C, and Edwards D

Subjects

Transcriptome genetics, Computational Biology methods, Databases, Nucleic Acid, Sequence Analysis, DNA methods, Software, Statistics as Topic methods

Abstract

Genome sequencing has been revolutionized by next-generation technologies, which can rapidly produce vast quantities of data at relatively low cost. With data production now no longer being limited, there is a huge challenge to analyse the data flood and interpret biological meaning. Bioinformatics scientists have risen to the challenge and a large number of software tools and databases have been produced and these continue to evolve with this rapidly advancing field. Here, we outline some of the tools and databases commonly used for the analysis of next-generation sequence data with comment on their utility.

Published

2012

4. De novo sequencing of plant genomes using second-generation technologies.

Author

Imelfort M and Edwards D

Subjects

Base Sequence, Molecular Sequence Data, Algorithms, Chromosome Mapping methods, DNA, Plant genetics, Genome, Plant genetics, Plants genetics, Sequence Analysis, DNA methods

Abstract

The ability to sequence the DNA of an organism has become one of the most important tools in modern biological research. Until recently, the sequencing of even small model genomes required substantial funds and international collaboration. The development of 'second-generation' sequencing technology has increased the throughput and reduced the cost of sequence generation by several orders of magnitude. These new methods produce vast numbers of relatively short reads, usually at the expense of read accuracy. Since the first commercial second-generation sequencing system was produced by 454 Technologies and commercialised by Roche, several other companies including Illumina, Applied Biosystems, Helicos Biosciences and Pacific Biosciences have joined the competition. Because of the relatively high error rate and lack of assembly tools, short-read sequence technology has mainly been applied to the re-sequencing of genomes. However, some recent applications have focused on the de novo assembly of these data. De novo assembly remains the greatest challenge for DNA sequencing and there are specific problems for second generation sequencing which produces short reads with a high error rate. However, a number of different approaches for short-read assembly have been proposed and some have been implemented in working software. In this review, we compare the current approaches for second-generation genome sequencing, explore the future direction of this technology and the implications for plant genome research.

Published

2009

5. Single nucleotide polymorphism discovery in barley using autoSNPdb.

Author

Duran C, Appleby N, Vardy M, Imelfort M, Edwards D, and Batley J

Subjects

DNA, Plant genetics, Databases, Genetic, Genetic Markers, Internet, Sequence Alignment, User-Computer Interface, Hordeum genetics, Polymorphism, Single Nucleotide, Sequence Analysis, DNA methods, Software

Abstract

Molecular markers are used to provide the link between genotype and phenotype, for the production of molecular genetic maps and to assess genetic diversity within and between related species. Single nucleotide polymorphisms (SNPs) are the most abundant molecular genetic marker. SNPs can be identified in silico, but care must be taken to ensure that the identified SNPs reflect true genetic variation and are not a result of errors associated with DNA sequencing. The SNP detection method autoSNP has been developed to identify SNPs from sequence data for any species. Confidence in the predicted SNPs is based on sequence redundancy, and haplotype co-segregation scores are calculated for a further independent measure of confidence. We have extended the autoSNP method to produce autoSNPdb, which integrates SNP and gene annotation information with a graphical viewer. We have applied this software to public barley expressed sequences, and the resulting database is available over the Internet. SNPs can be viewed and searched by sequence, functional annotation or predicted synteny with a reference genome, in this case rice. The correlation between SNPs and barley cultivar, expressed tissue type and development stage has been collated for ease of exploration. An average of one SNP per 240 bp was identified, with SNPs more prevalent in the 5' regions and simple sequence repeat (SSR) flanking sequences. Overall, autoSNPdb can provide a wealth of genetic polymorphism information for any species for which sequence data are available.

Published

2009

6. Discovering genetic polymorphisms in next-generation sequencing data.

Author

Imelfort M, Duran C, Batley J, and Edwards D

Subjects

Computational Biology, DNA, Plant genetics, Genome, Plant, Sequence Analysis, DNA instrumentation, Plants genetics, Polymorphism, Single Nucleotide, Sequence Analysis, DNA methods

Abstract

The ongoing revolution in DNA sequencing technology now enables the reading of thousands of millions of nucleotide bases in a single instrument run. However, this data quantity is often compromised by poor confidence in the read quality. The identification of genetic polymorphisms from this data is therefore problematic and, combined with the vast quantity of data, poses a major bioinformatics challenge. However, once these difficulties have been addressed, next-generation sequencing will offer a means to identify and characterize the wealth of genetic polymorphisms underlying the vast phenotypic variation in biological systems. We describe the recent advances in next-generation sequencing technology, together with preliminary approaches that can be applied for single nucleotide polymorphism discovery in plant species.

Published

2009

7. Genome sequencing approaches and successes.

Author

Imelfort M, Batley J, Grimmond S, and Edwards D

Subjects

Chromosomes, Artificial, Bacterial genetics, Genomics, Plants genetics, Crops, Agricultural genetics, DNA, Plant genetics, Genome, Plant, Sequence Analysis, DNA methods

Abstract

Sequence data is crucial to our understanding of crop growth and development, as differences in DNA sequence are responsible for almost all of the heritable differences between crop varieties and ecotypes. The sequence of a genome is often referred to as the genetic blueprint, and is the foundation for all additional information from the genome to the phenome. The value of DNA sequence is leading to rapid improvements in sequencing technology, increasing throughput, and reducing costs, and technological advances are accelerating with the introduction of novel approaches that are replacing the traditional Sanger-based methods. As genome sequencing becomes cheaper, it will be applied to a greater number of species with increasingly large and complex genomes. This will increase our understanding of how differences in the sequence relate to phenotypic observations, heritable traits, speciation, and evolution. Our understanding of plants will be greatly enhanced by this flow of sequence information, with direct benefit for crop improvement.

Published

2009