Your search keyword '"Sayer, D"' showing total 3 results

1. A multi-site study using high-resolution HLA genotyping by next generation sequencing.

Author

Holcomb, C. L., Höglund, B., Anderson, M. W., Blake, L. A., Böhme, I., Egholm, M., Ferriola, D., Gabriel, C., Gelber, S. E., Goodridge, D., Hawbecker, S., Klein, R., Ladner, M., Lind, C., Monos, D., Pando, M. J., Pröll, J., Sayer, D. C., Schmitz-Agheguian, G., and Simen, B. B.

Subjects

HLA histocompatibility antigens, NUCLEOTIDE sequence, GENETIC polymorphisms, MOLECULAR cloning, BLIND experiment, COMPUTER software, HUMAN genetics

Abstract

The high degree of polymorphism at human leukocyte antigen (HLA) class I and class II loci makes high-resolution HLA typing challenging. Current typing methods, including Sanger sequencing, yield ambiguous typing results because of incomplete genomic coverage and inability to set phase for HLA allele determination. The 454 Life Sciences Genome Sequencer (GS FLX) next generation sequencing system coupled with software can provide very high-resolution HLA genotyping. High-throughput genotyping can be achieved by use of primers with multiplex identifier (MID) tags to allow pooling of the amplicons generated from different individuals prior to sequencing. We have conducted a double-blind study in which eight laboratory sites performed amplicon sequencing using GS FLX standard chemistry and genotyped the same 20 samples for HLA-A, -B, -C, DPB1, DQA1, DQB1, DRB1, DRB3, DRB4, and DRB5 (DRB3/4/5) in a single sequencing run. The average sequence read length was 250 base pairs and the average number of sequence reads per amplicon was 672, providing confidence in the allele assignments. Of the 1280 genotypes considered, assignment was possible in 95% of the cases. Failure to assign genotypes was the result of researcher procedural error or the presence of a novel allele rather than a failure of sequencing technology. Concordance with known genotypes, in cases where assignment was possible, ranged from 95.3% to 99.4% for the eight sites, with overall concordance of 97.2%. We conclude that clonal pyrosequencing using the GS FLX platform and software allows reliable identification of HLA genotypes at high resolution. [ABSTRACT FROM AUTHOR]

Published

2011

2. High-resolution, high-throughput HLA genotyping by next-generation sequencing.

Author

Bentley, G., Higuchi, R., Hoglund, B., Goodridge, D., Sayer, D., Trachtenberg, E. A., and Erlich, H. A.

Subjects

HLA histocompatibility antigens, HEMATOPOIETIC stem cell transplantation, SEVERE combined immunodeficiency, CELL lines, NUCLEOTIDES, GENETIC polymorphisms, GENOMICS, COMPUTER software

Abstract

The human leukocyte antigen (HLA) class I and class II loci are the most polymorphic genes in the human genome. Hematopoietic stem cell transplantation requires allele-level HLA typing at multiple loci to select the best matched unrelated donors for recipient patients. In current methods for HLA typing, both alleles of a heterozygote are amplified and typed or sequenced simultaneously, often making it difficult to unambiguously determine the sequence of the two alleles. Next-generation sequencing methods clonally propagate in parallel millions of single DNA molecules, which are then also sequenced in parallel. Recently, the read lengths obtainable by one such next-generation sequencing method (454 Life Sciences, Inc.) have increased to >250 nucleotides. These clonal read lengths make possible setting the phase of the linked polymorphisms within an exon and thus the unambiguous determination of the sequence of each HLA allele. Here we demonstrate this capacity as well as show that the throughput of the system is sufficiently high to enable a complete, 7-locus HLA class I and II typing for 24 or 48 individual DNAs in a single GS FLX sequencing run. Highly multiplexed amplicon sequencing is facilitated by the use of sample-specific internal sequence tags (multiplex identification tags or MIDs) in the primers that allow pooling of samples yet maintain the ability to assign sequences to specific individuals. We have incorporated an HLA typing software application developed by Conexio Genomics (Freemantle, Australia) that assigns HLA genotypes for these 7 loci (HLA-A, -B, -C, DRB1, DQA1, DQB1, DPB1), as well as for DRB3, DRB4, and DRB5 from 454 sequence data. The potential of this HLA sequencing system to analyze chimeric mixtures is demonstrated here by the detection of a rare HLA-B allele in a mixture of two homozygous cell lines (1/100), as well as by the detection of the rare nontransmitted maternal allele present in the blood of a severe combined immunodeficiency disease syndrome (SCIDS) patient. [ABSTRACT FROM AUTHOR]

Published

2009

3. Sequencing-based typing identifies novel alleles due to single nucleotide polymorphisms in ‘conserved’ regions.

Author

Smith, L. K., Sayer, D. C., Whidborne, R. S., and Christiansen, F. T.

Subjects

*NUCLEOTIDES, *GENETIC polymorphisms, *HLA histocompatibility antigens, *IMMUNOGENETICS, *IMMUNOLOGY

Abstract

The Royal Perth Hospital laboratory has been using sequencing-based typing for all HLA loci since 2002. In the period to October 2005, approximately 12,000 HLA A and HLA B, 5000 HLA C and DQB1, and 17,000 DRB1 requests have been processed. Twenty nine novel alleles have been identified in that time. These comprise 10 HLA-A (including one null allele), five HLA-B, six HLA-C, six DRB1 (including a null allele), and one DQB1 novel allele. (At the time of identifying the DRB1 null allele, there were no other reported examples.) In addition, we have seen one example of a blast-specific HLA-A null allele. One HLA-A allele (HLA-A*0264) and one HLA-B allele (HLA-B*400104) were subsequently identified in other laboratories and submitted to the international ImMunoGeneTics project (IMGT) database. [ABSTRACT FROM AUTHOR]

Published

2007