Revision as of 16:36, 28 April 2017

Plant Biology 2017

Visit a collection of Plant Genomics databases and projects with resources for sequenced genomes, ontology development, genetic mapping, functional annotation of genes, mutants and phenotypes, genetic diversity, and bioinformatics tools. Representatives from the projects indicated below will be present to demonstrate tools for cutting-edge genomics and genetics research and to answer questions.

You can find us at Booth #215

Bioinformatics Mini-symposium

Plan to attend the Bioinformatics mini-symposium on Monday, June 26, 11:30 AM – 1:00 PM

Plant biology researchers increasingly rely on databases and other informatics resources to organize, integrate and provide access to the flood of plant biology data now available. We will present the latest developments, data and tools for several important plant informatics resources. Presentations:

• Araport - Agnes Chan (J. Craig Venter Institute)
• Gramene - Marcela Karey Tello-Ruiz (Cold Spring Harbor Laboratory)
• Planteome - Pankaj Jaiswal (Oregon State University)
• KBase - Bob Cottingham (Oak Ridge National Laboratory)
• TAIR - Eva Huala (Phoenix Bioinformatics)
• SGN - Lukas Muller (Boyce Thompson Institute)
• Splicing Stuff - John Brown (James Hutton Institute)
• BAR - Asher Pasha (University of Toronto)

Plant Genome Resources Outreach Booth

Projects with a Representative On Site

Schedule with a representative present at the booth

Gramene

File:Gramene logo 300.svg

See Gramene's web page for more information: http://www.gramene.org

Gramene is a curated resource for comparative functional genomics in crops and model plant species currently hosting 44 complete reference genomes. Its strength derives from the application of a phylogenetic framework for genome comparison and the use of ontologies to integrate structural and functional annotation data. Gene evolutionary histories are provided in phylogenetic gene trees using a method that infers orthologous relationships and complements whole genome alignments. Variation data is available for 10 species, including Arabidopsis, rice, and maize, and enriched with variant effect prediction. Gramene hosts metabolic pathways databases developed in house or by our collaborators in the BioCyc platform, which facilitates uploading, visualization and analysis. Recently, we began annotating metabolic pathways using the Reactome model, and have released a beta version of the Plant Reactome, a platform for the comparative analysis of plant metabolic and regulatory networks, featuring at present 121 curated rice pathways. We also host many genetic and QTL maps contributed by the broad research community. Gramene is supported by an NSF grant (IOS-1127112), and works closely with EBI-EMBL, OICR, and ASPB.

An overview of the Gramene comparative genomics database as well as latest developments and future plans will be presented by Marcela Karey Tello-Ruiz during the Bioinformatics Minisymposium on Monday, June 26th at 1:30pm.

Gramene talks & posters:

NNN – Gramene: Unifying Comparative Genomics and Pathway Resources for Plant Communities. Presented by Marcela Karey Tello-Ruiz

NNN – Comparative genomics reveals prevalence of coupled R-gene disease resistance systems in 11 species of the Oryzeae tribe. Presented by Joshua Stein

NNN – Presented by Yinping Jiao

Gramene representatives will be available to meet with users and answer questions at booth #205 throughout the meeting.

For more information please contact: Gramene Feedback

Funding: Our participation at this outreach booth is being made possible thanks to the funding support of NSF award #1127112 to "Gramene - Exploring Function through Comparative Genomics and Network Analysis".

Phoenix

Former TAIR

See Phoenix's web page for more information: http://www.arabidopsis.org

The Arabidopsis Information Resource (TAIR) maintains a database of genetic and molecular biology data for the model higher plant Arabidopsis thaliana. Data available from TAIR includes the complete genome sequence along with information concerning gene structures, gene product functions, metabolism, gene expression, DNA and seed stocks, genome maps, genetic and physical markers, publications, useful tools, and members of the Arabidopsis research community. Gene product function data is updated weekly from the latest published research literature and community data submissions. Gene structures are updated every 2 years using computational and manual methods as well as community submissions of new and updated genes. TAIR also provides extensive links from our data pages to other Arabidopsis resources.

For more information please contact: curator@arabidopsis.org

AraPort

Plant genomics has been an integral part of the JCVI legacy for many years. Starting with our work on the first sequencing project of a plant, Arabidopsis, we have expanded our activities to genome and EST projects for a wide range of plant species. These include rice, continued work on Arabidopsis, potato, maize, Medicago, soybean, tomato, barley, pine, onion, banana, various pulse crops (legumes) and several microbial pathogens that afflict important crops. Current work is focused primarily on improving the sequence and annotation of Medicago truncatula (barrel medic). We are also involved in consortia sequencing the genomes of Brassica oleracea, Medicago sativa (alfalfa) and Salix purpurea (willow, a potential bioenergy crop). In addition, we provide informatics support for and host the maize cell genomics database.

Medicago truncatula Genome Release v4.0.

We have continued to curate and improve the M. truncatula genome sequence and annotation. We have combined NexGen sequences with the previous BAC-based assemblies to produce the current Mt 4.0 release. Pseudomolecules were constructed from ALLPATHS scaffolds on the basis of alignments to both the optical and genetic (genotyping-by-sequencing - GBS) maps. Where possible, high quality contiguous BAC sequences were patched into the new v4 pseudomolecules to close sequencing gaps in the ALLPATHS assembly,. Whereas the Mt 3.5 release consisted of ~ 250 Mb in pseudomolecules and ~ 100 Mb of unanchored sequence, the Mt 4 pseudomolecules now encompass approximately 360 Mb of sequences spanning 390 Mb of which ~ 330 Mb aligns accurately with the optical map. Most of the sequences and genes that were previously on unanchored portion of Mt3.5 have now been incorporated into Mt4.0 pseudomolecules, with the exception of only ~20Mb of unplaced sequences. The new pseudomolecules were annotated by an in-house pipeline that combined Mt3.5 gene models, predictions from Augustus and FGENESH with expression data and protein matches primarily using Evidence Modeler (EVM). Medtr identifers have been preserved between Mt 3.5 and Mt 4.0. Many new identifiers have been instantiated to replace the gene identifiers previously found on the unanchored contigs. Look-up tables are provided to allow easy navigation between the two data sets.

An overview of the Medicago truncatula Genome Release v4 and the tools available on the JCVI Website will be given during the Genomic Tools Minisymposium on Sunday, July 21st at 4:10PM.

JCVI Poster:

P15029- Medicago truncatula Genome Resources at the J. Craig Venter Institute

Medicago truncatula resources at JCVI include:

BLAST Search: Search against Mtv3.5 and Mtv4.0 genome assemblies and annotations. Gene Information Pages: Search for your favorite gene by Idnetifier or Keyword. View all searches completed, functional assignments and gene structure.

JBrowse: View any region of the genome in a Google Maps style interface. Community Annotation: Do you have a favorite gene or gene family? You can manually curate the Medicago truncatula structure and functions. Our EuCAP interface has been improved to include the ability to associate mutant information.

Coming soon: MedicMine (Intermine) and WebApollo for gene structure curation by community annotators.

See the JCVI's web page for more information: http://www.jcvi.org/

The Bio-Analytic Resource for Plant Functional Genomics

See BAR's web page for more information: http://www.bar.utoronto.ca

The Bio-Analytic Resource at the University of Toronto is a collection of web-based tools for exploring, visualizing and mining large-scale data sets, primarily from Arabidopsis thaliana but also from several other plant species.

These tools include:

eFP Browser (electronic Fluorescent Pictograph Browser) for painting gene expression and other information onto diagrammatic representations of the particular experimental series from which the data were generated. eFP Browsers are available for Arabidopsis, poplar, Medicago truncatula, rice, barley, soybean, maize, potato and cell.

Expression Angler for identifying co-expressed, anti-correlated, or condition/tissue-specific genes using the "custom bait feature" in 5 of the gene expression data sets from the AtGenExpress Consortium, from our in-house database or from NASCArrays, or several other data sets.

Expression Browser for performing electronic northerns.

Arabidopsis Interactions Viewer for querying a database of almost 80,000 predicted and 28,566 documented protein-protein interactions in Arabidopsis.

Promomer for identifying over-represented n-mer words in the promoter of a gene of interest, or in promoters of co-expressed genes.

ePlant: A suite of interactive web-based tools that enables users to explore Arabidopsis data from the kilometre to nanometre scale, including natural variation data, organ and cell-type-specific gene expression patterns, subcellular localization, protein-protein interactions, and protein tertiary structures predicted for ~70% of the proteome.

Next-Gen Mapping: Allows for the rapid localization of recessive EMS induced mutations within an F2 mapping population that has been pooled and sequenced en masse using a next-generation sequencing platform.

Funding: The BAR is funded in part by Centre for the Analysis of Genome Evolution and Function, grants from the Canada Foundation for Innovation to NJP, and from Genome Canada to the Arabidopsis Research Group at the Department of Cell and Systems Biology, University of Toronto.

For more information please contact: Nick Provart (nicholas.provart@utoronto.ca)

Planteome

File:PO logo wiki.png

See PO's web page for more information: http://www.plantontology.org

The main objective of the Plant Ontology Consortium (POC) is to develop, curate and share controlled vocabularies (ontologies) that describe plant structures and growth and developmental stages and plant traits. The overall goal is to provide a semantic framework for meaningful cross-species queries across databases. The Plant Ontology (PO) and the Plant Trait Ontology (TO) have been developed with the primary goal to facilitate and accommodate functional annotation efforts in plant databases and by the plant research community at large.

As a part of the PO project, participating databases such as TAIR, NASC, Gramene, and MaizeGDB have been using PO to describe expression patterns of genes and phenotypes of mutants and natural variants.

Come see Poster # P28002: The Plant Ontology: A Tool for Linking Plant Anatomy and Development to Genomics Across Plant Taxa.

For more information please contact: PO Feedback

GrainGenes

Tripal

KBase

See KBase's web page for more information: http://kbase.us

The DOE Systems Biology Knowledgebase (KBase) is a collaborative effort designed to accelerate our understanding of microbes, microbial communities, and plants. It will be a community-driven, extensible and scalable open-source software framework and application system. KBase will offer free and open access to data, models and simulations, enabling scientists and researchers to build new knowledge and share their findings.

Systems Biology Knowledgebase (KBase)

Projects without a Representative On Site (Brochures available!)

SoyBase

Soybean Knowledge Base (SoyKB) is a comprehensive all-inclusive web resource for soybean translational genomics and breeding. SoyKB handles the management and integration of soybean genomics and multi-omics data (including genomics, transcriptomics, proteomics and metabolomics) along with gene function annotations, biological pathway and trait information. It has many useful tools including Affymetrix probeID search, gene family search, multiple gene/metabolite analysis, motif analysis tool, protein 3D structure viewer and download/upload capacity for experimental data and annotations. It has a user-friendly web interface together with genome browser and pathway viewer, which display data in an intuitive manner to the soybean researchers, breeders and consumers.

SoyKB has new innovative tools for soybean breeding including a graphical chromosome visualizer targeted towards ease of navigation for breeders. It integrates QTLs, traits, germplasm information along with genomic variation data such as single nucleotide polymorphisms (SNPs) and genome-wide association studies (GWAS) data from multiple genotypes, cultivars and G.soja. QTLs for multiple traits can be queried and visualized in the chromosome visualizer simultaneously and overlaid on top of the genes and other molecular markers as well as multi-omics experimental data for meaningful inferences.

SoyKB can be publicly accessed at http://soykb.org

Acknowledgements

The Outreach Booth was possible thanks to volunteer organizer:

• Marcela Karey Tello-Ruiz, Gramene