Your search keyword '"Casstevens T"' showing total 12 results

1. The Practical Haplotype Graph, a platform for storing and using pangenomes for imputation

Author

Bradbury, P J, primary, Casstevens, T, additional, Jensen, S E, additional, Johnson, L C, additional, Miller, Z R, additional, Monier, B, additional, Romay, M C, additional, Song, B, additional, and Buckler, E S, additional

Published

2022

2. The Practical Haplotype Graph, a platform for storing and using pangenomes for imputation

Author

Bradbury, PJ, primary, Casstevens, T, additional, Jensen, SE, additional, Johnson, LC, additional, Miller, ZR, additional, Monier, B, additional, Romay, MC, additional, Song, B, additional, and Buckler, ES, additional

Published

2021

3. Practical Haplotype Graph, a platform for storing and using pangenomes for imputation.

Author

Bradbury, P J, Casstevens, T, Jensen, S E, Johnson, L C, Miller, Z R, Monier, B, Romay, M C, Song, B, and Buckler, E S

Subjects

*QUANTITATIVE genetics, *POPULATION genetics, *DATA compression, *REPRESENTATIONS of graphs, *WEB services, *HAPLOTYPES

Abstract

Motivation Pangenomes provide novel insights for population and quantitative genetics, genomics and breeding not available from studying a single reference genome. Instead, a species is better represented by a pangenome or collection of genomes. Unfortunately, managing and using pangenomes for genomically diverse species is computationally and practically challenging. We developed a trellis graph representation anchored to the reference genome that represents most pangenomes well and can be used to impute complete genomes from low density sequence or variant data. Results The Practical Haplotype Graph (PHG) is a pangenome pipeline, database (PostGRES & SQLite), data model (Java, Kotlin or R) and Breeding API (BrAPI) web service. The PHG has already been able to accurately represent diversity in four major crops including maize, one of the most genomically diverse species, with up to 1000-fold data compression. Using simulated data, we show that, at even 0.1× coverage, with appropriate reads and sequence alignment, imputation results in extremely accurate haplotype reconstruction. The PHG is a platform and environment for the understanding and application of genomic diversity. Availability and implementation All resources listed here are freely available. The PHG Docker used to generate the simulation results is https://hub.docker.com/ as maizegenetics/phg:0.0.27. PHG source code is at https://bitbucket.org/bucklerlab/practicalhaplotypegraph/src/master/. The code used for the analysis of simulated data is at https://bitbucket.org/bucklerlab/phg-manuscript/src/master/. The PHG database of NAM parent haplotypes is in the CyVerse data store (https://de.cyverse.org/de/) and named/iplant/home/shared/panzea/panGenome/PHG_db_maize/phg_v5Assemblies_20200608.db. Supplementary information Supplementary data are available at Bioinformatics online. [ABSTRACT FROM AUTHOR]

Published

2022

4. A sorghum practical haplotype graph facilitates genome‐wide imputation and cost‐effective genomic prediction

Author

Jensen, S.E., Charles, J.R., Muleta, K., Bradbury, P. J., Casstevens, T., Deshpande, S.P., Gore, M.A., Gupta, R., Ilut, D.C., Johnson, L., Lozano, R., Miller, Z., Ramu, P., Rathore, A., Romay, M.C., Upadhyaya, H.D., Varshney, R.K., Morris, G.P., Pressoir, G., Buckler, E.S., Ramstein, G.P., Jensen, S.E., Charles, J.R., Muleta, K., Bradbury, P. J., Casstevens, T., Deshpande, S.P., Gore, M.A., Gupta, R., Ilut, D.C., Johnson, L., Lozano, R., Miller, Z., Ramu, P., Rathore, A., Romay, M.C., Upadhyaya, H.D., Varshney, R.K., Morris, G.P., Pressoir, G., Buckler, E.S., and Ramstein, G.P.

Abstract

Successful management and utilization of increasingly large genomic datasets is essential for breeding programs to accelerate cultivar development. To help with this, we developed a Sorghum bicolor Practical Haplotype Graph (PHG) pangenome database that stores haplotypes and variant information. We developed two PHGs in sorghum that were used to identify genome‐wide variants for 24 founders of the Chibas sorghum breeding program from 0.01x sequence coverage. The PHG called single nucleotide polymorphisms (SNPs) with 5.9% error at 0.01x coverage—only 3% higher than PHG error when calling SNPs from 8x coverage sequence. Additionally, 207 progenies from the Chibas genomic selection (GS) training population were sequenced and processed through the PHG. Missing genotypes were imputed from PHG parental haplotypes and used for genomic prediction. Mean prediction accuracies with PHG SNP calls range from .57–.73 and are similar to prediction accuracies obtained with genotyping‐by‐sequencing or targeted amplicon sequencing (rhAmpSeq) markers. This study demonstrates the use of a sorghum PHG to impute SNPs from low‐coverage sequence data and shows that the PHG can unify genotype calls across multiple sequencing platforms. By reducing input sequence requirements, the PHG can decrease the cost of genotyping, make GS more feasible, and facilitate larger breeding populations. Our results demonstrate that the PHG is a useful research and breeding tool that maintains variant information from a diverse group of taxa, stores sequence data in a condensed but readily accessible format, unifies genotypes across genotyping platforms, and provides a cost‐effective option for genomic selection.

Published

2020

5. Gramene database in 2010: updates and extensions

Author

Youens-Clark, K., primary, Buckler, E., additional, Casstevens, T., additional, Chen, C., additional, DeClerck, G., additional, Derwent, P., additional, Dharmawardhana, P., additional, Jaiswal, P., additional, Kersey, P., additional, Karthikeyan, A. S., additional, Lu, J., additional, McCouch, S. R., additional, Ren, L., additional, Spooner, W., additional, Stein, J. C., additional, Thomason, J., additional, Wei, S., additional, and Ware, D., additional

Published

2010

6. Software engineering the mixed model for genome-wide association studies on large samples

Author

Zhang, Z., primary, Buckler, E. S., additional, Casstevens, T. M., additional, and Bradbury, P. J., additional

Published

2009

7. Gramene: a growing plant comparative genomics resource

Author

Liang, C., primary, Jaiswal, P., additional, Hebbard, C., additional, Avraham, S., additional, Buckler, E. S., additional, Casstevens, T., additional, Hurwitz, B., additional, McCouch, S., additional, Ni, J., additional, Pujar, A., additional, Ravenscroft, D., additional, Ren, L., additional, Spooner, W., additional, Tecle, I., additional, Thomason, J., additional, Tung, C.-w., additional, Wei, X., additional, Yap, I., additional, Youens-Clark, K., additional, Ware, D., additional, and Stein, L., additional

Published

2007

8. A sorghum practical haplotype graph facilitates genome-wide imputation and cost-effective genomic prediction.

Author

Jensen SE, Charles JR, Muleta K, Bradbury PJ, Casstevens T, Deshpande SP, Gore MA, Gupta R, Ilut DC, Johnson L, Lozano R, Miller Z, Ramu P, Rathore A, Romay MC, Upadhyaya HD, Varshney RK, Morris GP, Pressoir G, Buckler ES, and Ramstein GP

Subjects

Cost-Benefit Analysis, Genome, Genomics, Haplotypes, Sorghum genetics

Abstract

Successful management and utilization of increasingly large genomic datasets is essential for breeding programs to accelerate cultivar development. To help with this, we developed a Sorghum bicolor Practical Haplotype Graph (PHG) pangenome database that stores haplotypes and variant information. We developed two PHGs in sorghum that were used to identify genome-wide variants for 24 founders of the Chibas sorghum breeding program from 0.01x sequence coverage. The PHG called single nucleotide polymorphisms (SNPs) with 5.9% error at 0.01x coverage-only 3% higher than PHG error when calling SNPs from 8x coverage sequence. Additionally, 207 progenies from the Chibas genomic selection (GS) training population were sequenced and processed through the PHG. Missing genotypes were imputed from PHG parental haplotypes and used for genomic prediction. Mean prediction accuracies with PHG SNP calls range from .57-.73 and are similar to prediction accuracies obtained with genotyping-by-sequencing or targeted amplicon sequencing (rhAmpSeq) markers. This study demonstrates the use of a sorghum PHG to impute SNPs from low-coverage sequence data and shows that the PHG can unify genotype calls across multiple sequencing platforms. By reducing input sequence requirements, the PHG can decrease the cost of genotyping, make GS more feasible, and facilitate larger breeding populations. Our results demonstrate that the PHG is a useful research and breeding tool that maintains variant information from a diverse group of taxa, stores sequence data in a condensed but readily accessible format, unifies genotypes across genotyping platforms, and provides a cost-effective option for genomic selection., (© 2020 The Authors. The Plant Genome published by Wiley Periodicals, Inc. on behalf of Crop Science Society of America.)

Published

2020

9. Genetic Architecture of Domestication-Related Traits in Maize.

Author

Xue S, Bradbury PJ, Casstevens T, and Holland JB

Subjects

Chromosome Mapping methods, Chromosomes, Plant, Domestication, Genes, Plant, Genetic Variation, Genetics, Population, Genome-Wide Association Study methods, Genomics methods, Genotype, Models, Genetic, Phenotype, Plant Breeding methods, Polymorphism, Genetic, Quantitative Trait Loci, Selection, Genetic, Zea mays genetics

Abstract

Strong directional selection occurred during the domestication of maize from its wild ancestor teosinte, reducing its genetic diversity, particularly at genes controlling domestication-related traits. Nevertheless, variability for some domestication-related traits is maintained in maize. The genetic basis of this could be sequence variation at the same key genes controlling maize-teosinte differentiation (due to lack of fixation or arising as new mutations after domestication), distinct loci with large effects, or polygenic background variation. Previous studies permit annotation of maize genome regions associated with the major differences between maize and teosinte or that exhibit population genetic signals of selection during either domestication or postdomestication improvement. Genome-wide association studies and genetic variance partitioning analyses were performed in two diverse maize inbred line panels to compare the phenotypic effects and variances of sequence polymorphisms in regions involved in domestication and improvement to the rest of the genome. Additive polygenic models explained most of the genotypic variation for domestication-related traits; no large-effect loci were detected for any trait. Most trait variance was associated with background genomic regions lacking previous evidence for involvement in domestication. Improvement sweep regions were associated with more trait variation than expected based on the proportion of the genome they represent. Selection during domestication eliminated large-effect genetic variants that would revert maize toward a teosinte type. Small-effect polygenic variants (enriched in the improvement sweep regions of the genome) are responsible for most of the standing variation for domestication-related traits in maize., (Copyright © 2016 by the Genetics Society of America.)

Published

2016

10. Gramene database in 2010: updates and extensions.

Author

Youens-Clark K, Buckler E, Casstevens T, Chen C, Declerck G, Derwent P, Dharmawardhana P, Jaiswal P, Kersey P, Karthikeyan AS, Lu J, McCouch SR, Ren L, Spooner W, Stein JC, Thomason J, Wei S, and Ware D

Subjects

Chromosome Mapping, Genes, Plant, Genetic Variation, Genomics, Metabolic Networks and Pathways, Plants metabolism, Quantitative Trait Loci, Synteny, Databases, Genetic, Genome, Plant, Plants genetics

Abstract

Now in its 10th year, the Gramene database (http://www.gramene.org) has grown from its primary focus on rice, the first fully-sequenced grass genome, to become a resource for major model and crop plants including Arabidopsis, Brachypodium, maize, sorghum, poplar and grape in addition to several species of rice. Gramene began with the addition of an Ensembl genome browser and has expanded in the last decade to become a robust resource for plant genomics hosting a wide array of data sets including quantitative trait loci (QTL), metabolic pathways, genetic diversity, genes, proteins, germplasm, literature, ontologies and a fully-structured markers and sequences database integrated with genome browsers and maps from various published studies (genetic, physical, bin, etc.). In addition, Gramene now hosts a variety of web services including a Distributed Annotation Server (DAS), BLAST and a public MySQL database. Twice a year, Gramene releases a major build of the database and makes interim releases to correct errors or to make important updates to software and/or data.

Published

2011

11. The generation challenge programme platform: semantic standards and workbench for crop science.

Author

Bruskiewich R, Senger M, Davenport G, Ruiz M, Rouard M, Hazekamp T, Takeya M, Doi K, Satoh K, Costa M, Simon R, Balaji J, Akintunde A, Mauleon R, Wanchana S, Shah T, Anacleto M, Portugal A, Ulat VJ, Thongjuea S, Braak K, Ritter S, Dereeper A, Skofic M, Rojas E, Martins N, Pappas G, Alamban R, Almodiel R, Barboza LH, Detras J, Manansala K, Mendoza MJ, Morales J, Peralta B, Valerio R, Zhang Y, Gregorio S, Hermocilla J, Echavez M, Yap JM, Farmer A, Schiltz G, Lee J, Casstevens T, Jaiswal P, Meintjes A, Wilkinson M, Good B, Wagner J, Morris J, Marshall D, Collins A, Kikuchi S, Metz T, McLaren G, and van Hintum T

Abstract

The Generation Challenge programme (GCP) is a global crop research consortium directed toward crop improvement through the application of comparative biology and genetic resources characterization to plant breeding. A key consortium research activity is the development of a GCP crop bioinformatics platform to support GCP research. This platform includes the following: (i) shared, public platform-independent domain models, ontology, and data formats to enable interoperability of data and analysis flows within the platform; (ii) web service and registry technologies to identify, share, and integrate information across diverse, globally dispersed data sources, as well as to access high-performance computational (HPC) facilities for computationally intensive, high-throughput analyses of project data; (iii) platform-specific middleware reference implementations of the domain model integrating a suite of public (largely open-access/-source) databases and software tools into a workbench to facilitate biodiversity analysis, comparative analysis of crop genomic data, and plant breeding decision making.

Published

2008

12. Gramene: a growing plant comparative genomics resource.

Author

Liang C, Jaiswal P, Hebbard C, Avraham S, Buckler ES, Casstevens T, Hurwitz B, McCouch S, Ni J, Pujar A, Ravenscroft D, Ren L, Spooner W, Tecle I, Thomason J, Tung CW, Wei X, Yap I, Youens-Clark K, Ware D, and Stein L

Subjects

Arabidopsis genetics, Chromosome Mapping, Crops, Agricultural metabolism, Genetic Markers, Genetic Variation, Genomics, Internet, Oryza genetics, Poaceae genetics, Triticum genetics, User-Computer Interface, Zea mays genetics, Crops, Agricultural genetics, Databases, Genetic, Genome, Plant

Abstract

Gramene (www.gramene.org) is a curated resource for genetic, genomic and comparative genomics data for the major crop species, including rice, maize, wheat and many other plant (mainly grass) species. Gramene is an open-source project. All data and software are freely downloadable through the ftp site (ftp.gramene.org/pub/gramene) and available for use without restriction. Gramene's core data types include genome assembly and annotations, other DNA/mRNA sequences, genetic and physical maps/markers, genes, quantitative trait loci (QTLs), proteins, ontologies, literature and comparative mappings. Since our last NAR publication 2 years ago, we have updated these data types to include new datasets and new connections among them. Completely new features include rice pathways for functional annotation of rice genes; genetic diversity data from rice, maize and wheat to show genetic variations among different germplasms; large-scale genome comparisons among Oryza sativa and its wild relatives for evolutionary studies; and the creation of orthologous gene sets and phylogenetic trees among rice, Arabidopsis thaliana, maize, poplar and several animal species (for reference purpose). We have significantly improved the web interface in order to provide a more user-friendly browsing experience, including a dropdown navigation menu system, unified web page for markers, genes, QTLs and proteins, and enhanced quick search functions.

Published

2008