Your search keyword '"Randall-Maher, J"' showing total 4 results

1. Analysis of human mRNAs with the reference genome sequence reveals potent errors, polymorphisms, and RNA editing

Author

Furey, T S, Diekhans, M, Lu, Y T, Graves, T A, Oddy, L, Randall-Maher, J, Hillier, L W, Wilson, R K, and Haussler, D

Subjects

human mRNAs, SNPs, RNA editing

Abstract

The NCBI Reference Sequence (RefSeq) project and the NIH Mammalian Gene Collection (MGC) together define a set of similar to30,000 nonredundant human mRNA sequences with identified coding regions representing 17,000 distinct loci. These high-quality mRNA sequences allow for the identification of transcribed regions in the human genome sequence, and many researchers accept them as the correct representation of each defined gene sequence. Computational comparison of these mRNA sequences and the recently published essentially finished human genome sequence reveals several thousand undocumented nonsynonymous substitution and frame shift discrepancies between the two resources. Additional analysis is undertaken to verify that the euchromatic human genome is sufficiently complete-containing nearly the whole mRNA collection, thus allowing for a comprehensive analysis to be undertaken. Many of the discrepancies will prove to be genuine polymorphisms in the human population, somatic cell genomic variants, or examples of RNA editing. It is observed that the genome sequence variant has significant additional support from other mRNAs and ESTs, almost four times more often than does the mRNA variant, suggesting that the genome sequence is more accurate. In similar to15% of these cases, there is substantial support for both variants, suggestive of an undocumented polymorphism. An initial screening against a 24-individual genomic DNA diversity panel verified 60% of a small set of potential single nucleotide polymorphisms from which successful results could be obtained. We also find statistical evidence that a few of these discrepancies are due to RNA editing. Overall, these results suggest that the mRNA collections may contain a substantial number of errors. For current and future mRNA collections, it may be prudent to fully reconcile each genome sequence discrepancy, classifying each as a polymorphism, site of RNA editing or somatic cell variation, or genome sequence error.

Published

2004

2. Sequence and comparative analysis of the chicken genome provide unique perspectives on vertebrate evolution

Author

Hillier, LW, Miller, W, Birney, E, Warren, W, Hardison, RC, Ponting, CP, Bork, P, Burt, DW, Groenen, MAM, Delany, ME, Dodgson, JB, Chinwalla, AT, Cliften, PF, Clifton, SW, Delehaunty, KD, Fronick, C, Fulton, RS, Graves, TA, Kremitzki, C, Layman, D, Magrini, V, McPherson, JD, Miner, TL, Minx, P, Nash, WE, Nhan, MN, Nelson, JO, Oddy, LG, Pohl, CS, Randall-Maher, J, Smith, SM, Wallis, JW, Yang, SP, Romanov, MN, Rondelli, CM, Paton, B, Smith, J, Morrice, D, Daniels, L, Tempest, HG, Robertson, L, Masabanda, JS, Griffin, DK, Vignal, A, Fillon, V, Jacobbson, L, Kerje, S, Andersson, L, Crooijmans, RPM, Aerts, J, Van Der Poel, JJ, Ellegren, H, Caldwell, RB, Hubbard, SJ, Grafham, DV, Kierzek, AM, McLaren, SR, Overton, IM, Arakawa, H, Beattie, KJ, Bezzubov, Y, Boardman, PE, Bonfield, JK, Croning, MDR, Davies, RM, Francis, MD, Humphray, SJ, Scott, CE, Taylor, RG, Tickle, C, Brown, WRA, Rogers, J, Buerstedde, JM, Wilson, SA, Stubbs, L, Ovcharenko, I, Gordon, L, Lucas, S, Miller, MM, Inoko, H, Shiina, T, Kaufman, J, Salomonsen, J, Skjoedt, K, Wong, GKS, Wang, J, Liu, B, Yu, J, Yang, H, Nefedov, M, Koriabine, M, and DeJong, PJ

Subjects

animal structures

Abstract

© 2004 Nature Publishing Group. We present here a draft genome sequence of the red jungle fowl, Gallus gallus. Because the chicken is a modern descendant of the dinosaurs and the first non-mammalian amniote to have its genome sequenced, the draft sequence of its genome - composed of approximately one billion base pairs of sequence and an estimated 20,000-23,000 genes - provides a new perspective on vertebrate genome evolution, while also improving the annotation of mammalian genomes. For example, the evolutionary distance between chicken and human provides high specificity in detecting functional elements, both non-coding and coding. Notably, many conserved non-coding sequences are far from genes and cannot be assigned to defined functional classes. In coding regions the evolutionary dynamics of protein domains and orthologous groups illustrate processes that distinguish the lineages leading to birds and mammals. The distinctive properties of avian microchromosomes, together with the inferred patterns of conserved synteny, provide additional insights into vertebrate chromosome architecture.

Published

2014

3. A nuclear single-nucleotide polymorphism (SNP) potentially useful for the separation of Rhodnius prolixus from members of the Rhodnius robustus cryptic species complex (Hemiptera: Reduviidae).

Author

Pavan MG, Mesquita RD, Lawrence GG, Lazoski C, Dotson EM, Abubucker S, Mitreva M, Randall-Maher J, and Monteiro FA

Subjects

Animals, Chromosomes, Insect, DNA, Intergenic genetics, Gene Order, Genes, Insect, Haplotypes, Molecular Sequence Data, Phylogeny, Reduviidae classification, Rhodnius classification, Species Specificity, Polymorphism, Single Nucleotide, Reduviidae genetics, Rhodnius genetics

Abstract

The design and application of rational strategies that rely on accurate species identification are pivotal for effective vector control. When morphological identification of the target vector species is impractical, the use of molecular markers is required. Here we describe a non-coding, single-copy nuclear DNA fragment that contains a single-nucleotide polymorphism (SNP) with the potential to distinguish the important domestic Chagas disease vector, Rhodnius prolixus, from members of the four sylvatic Rhodnius robustus cryptic species complex. A total of 96 primer pairs obtained from whole genome shotgun sequencing of the R. prolixus genome (12,626 random reads) were tested on 43 R. prolixus and R. robustus s.l. samples. One of the seven amplicons selected (AmpG) presented a SNP, potentially diagnostic for R. prolixus, on the 280th site. The diagnostic nature of this SNP was then confirmed based on the analysis of 154 R. prolixus and R. robustus s.l. samples representing the widest possible geographic coverage. The results of a 60% majority-rule Bayesian consensus tree and a median-joining network constructed based on the genetic variability observed reveal the paraphyletic nature of the R. robustus species complex, with respect to R. prolixus. The AmpG region is located in the fourth intron of the Transmembrane protein 165 gene, which seems to be in the R. prolixus X chromosome. Other possible chromosomal locations of the AmpG region in the R. prolixus genome are also presented and discussed., (Copyright © 2013 Elsevier B.V. All rights reserved.)

Published

2013

4. Generation and annotation of the DNA sequences of human chromosomes 2 and 4.

Author

Hillier LW, Graves TA, Fulton RS, Fulton LA, Pepin KH, Minx P, Wagner-McPherson C, Layman D, Wylie K, Sekhon M, Becker MC, Fewell GA, Delehaunty KD, Miner TL, Nash WE, Kremitzki C, Oddy L, Du H, Sun H, Bradshaw-Cordum H, Ali J, Carter J, Cordes M, Harris A, Isak A, van Brunt A, Nguyen C, Du F, Courtney L, Kalicki J, Ozersky P, Abbott S, Armstrong J, Belter EA, Caruso L, Cedroni M, Cotton M, Davidson T, Desai A, Elliott G, Erb T, Fronick C, Gaige T, Haakenson W, Haglund K, Holmes A, Harkins R, Kim K, Kruchowski SS, Strong CM, Grewal N, Goyea E, Hou S, Levy A, Martinka S, Mead K, McLellan MD, Meyer R, Randall-Maher J, Tomlinson C, Dauphin-Kohlberg S, Kozlowicz-Reilly A, Shah N, Swearengen-Shahid S, Snider J, Strong JT, Thompson J, Yoakum M, Leonard S, Pearman C, Trani L, Radionenko M, Waligorski JE, Wang C, Rock SM, Tin-Wollam AM, Maupin R, Latreille P, Wendl MC, Yang SP, Pohl C, Wallis JW, Spieth J, Bieri TA, Berkowicz N, Nelson JO, Osborne J, Ding L, Meyer R, Sabo A, Shotland Y, Sinha P, Wohldmann PE, Cook LL, Hickenbotham MT, Eldred J, Williams D, Jones TA, She X, Ciccarelli FD, Izaurralde E, Taylor J, Schmutz J, Myers RM, Cox DR, Huang X, McPherson JD, Mardis ER, Clifton SW, Warren WC, Chinwalla AT, Eddy SR, Marra MA, Ovcharenko I, Furey TS, Miller W, Eichler EE, Bork P, Suyama M, Torrents D, Waterston RH, and Wilson RK

Subjects

Animals, Base Composition, Base Sequence, Centromere genetics, Conserved Sequence genetics, CpG Islands genetics, Euchromatin genetics, Expressed Sequence Tags, Gene Duplication, Genetic Variation genetics, Genomics, Humans, Molecular Sequence Data, Physical Chromosome Mapping, Polymorphism, Genetic genetics, Primates genetics, Proteins genetics, Pseudogenes genetics, RNA, Messenger analysis, RNA, Messenger genetics, RNA, Untranslated analysis, RNA, Untranslated genetics, Recombination, Genetic genetics, Sequence Analysis, DNA, Chromosomes, Human, Pair 2 genetics, Chromosomes, Human, Pair 4 genetics

Abstract

Human chromosome 2 is unique to the human lineage in being the product of a head-to-head fusion of two intermediate-sized ancestral chromosomes. Chromosome 4 has received attention primarily related to the search for the Huntington's disease gene, but also for genes associated with Wolf-Hirschhorn syndrome, polycystic kidney disease and a form of muscular dystrophy. Here we present approximately 237 million base pairs of sequence for chromosome 2, and 186 million base pairs for chromosome 4, representing more than 99.6% of their euchromatic sequences. Our initial analyses have identified 1,346 protein-coding genes and 1,239 pseudogenes on chromosome 2, and 796 protein-coding genes and 778 pseudogenes on chromosome 4. Extensive analyses confirm the underlying construction of the sequence, and expand our understanding of the structure and evolution of mammalian chromosomes, including gene deserts, segmental duplications and highly variant regions.

Published

2005