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22 materials found

Authors: Jared Simpson  or joachimwolff  or jmchilton 


Informatics on High-Throughput Sequencing Data 2018 Module 6-De Novo Assmebly

Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data, where the focus is on Illumina reads although information is applicable to all sequencer reads.

Informatics on High-Throughput Sequencing Data 2018 Module 6-De Novo Assmebly https://tess.elixir-europe.org/materials/informatics-on-high-throughput-sequencing-data-2018-module-6-de-novo-assmebly Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data, where the focus is on Illumina reads although information is applicable to all sequencer reads. Researchers Post-Doctoral Fellows Biologists, Genomicists, Computer Scientists Graduate students
Informatics on High-Throughput Sequencing Data 2018 Module 1-Introduction to High-Throughput Sequencing

Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data, where the focus is on Illumina reads although information is applicable to all sequencer reads.

Informatics on High-Throughput Sequencing Data 2018 Module 1-Introduction to High-Throughput Sequencing https://tess.elixir-europe.org/materials/informatics-on-high-throughput-sequencing-data-2018-module-1-introduction-to-high-throughput-sequencing Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data, where the focus is on Illumina reads although information is applicable to all sequencer reads. Researchers Graduate students Post-Doctoral Fellows Biologists, Genomicists, Computer Scientists
Bioinformatics for Cancer Genomics 2018 Module 5-Genome Assembly

Course covers the key bioinformatics concepts and tools required to analyze cancer genomic data sets and access and work with data sets in the cloud.

Bioinformatics for Cancer Genomics 2018 Module 5-Genome Assembly https://tess.elixir-europe.org/materials/bioinformatics-for-cancer-genomics-2018-module-5-genome-assembly Course covers the key bioinformatics concepts and tools required to analyze cancer genomic data sets and access and work with data sets in the cloud. Researchers Graduate students Biologists, Genomicists, Computer Scientists Post-Doctoral Fellows
Bioinformatics for Cancer Genomics 2018 Module 4-Genome Alignment

Course covers the key bioinformatics concepts and tools required to analyze cancer genomic data sets and access and work with data sets in the cloud.

Bioinformatics for Cancer Genomics 2018 Module 4-Genome Alignment https://tess.elixir-europe.org/materials/bioinformatics-for-cancer-genomics-2018-module-4-genome-alignment Course covers the key bioinformatics concepts and tools required to analyze cancer genomic data sets and access and work with data sets in the cloud. Researchers Graduate students Biologists, Genomicists, Computer Scientists Post-Doctoral Fellows
Bioinformatics for Cancer Genomics 2017 Module 3-Genome Alignment and Assembly

Course covers the bioinformatics tools required to analyze genomic data sets.

Bioinformatics for Cancer Genomics 2017 Module 3-Genome Alignment and Assembly https://tess.elixir-europe.org/materials/bioinformatics-for-cancer-genomics-2017-module-3-genome-alignment-and-assembly Course covers the bioinformatics tools required to analyze genomic data sets. Researchers Graduate students Biologists, Genomicists, Computer Scientists Post-Doctoral Fellows
Informatics on High-Throughput Sequencing Data 2017 Module 6-De Novo Assembly

Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data with a focus on Illumina reads.

Informatics on High-Throughput Sequencing Data 2017 Module 6-De Novo Assembly https://tess.elixir-europe.org/materials/informatics-on-high-throughput-sequencing-data-2017-module-6-de-novo-assembly Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data with a focus on Illumina reads. Researchers Graduate Students Post-Doctoral Fellows Biologists, Genomicists, Computer Scientists
Informatics on High-Throughput Sequencing Data 2017 Module 1-Introduction to High-Throughput Sequencing

Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data with a focus on Illumina reads.

Informatics on High-Throughput Sequencing Data 2017 Module 1-Introduction to High-Throughput Sequencing https://tess.elixir-europe.org/materials/informatics-on-high-throughput-sequencing-data-module-1-introduction-to-high-throughput-sequencing Course covers the bioinformatics tools available for managing and interpreting high-throughput sequencing data with a focus on Illumina reads. Researchers Graduate students Biologists, Genomicists, Computer Scientists Post-Doctoral Fellows
High-Throughput Biology 2017 Module 6-De Novo Assembly

Course covers the key bioinformatics concepts and tools required to analyze DNA- and RNA- sequence reads using a reference genome.

High-Throughput Biology 2017 Module 6-De Novo Assembly https://tess.elixir-europe.org/materials/high-throughput-biology-2017-module-6-de-novo-assembly Course covers the key bioinformatics concepts and tools required to analyze DNA- and RNA- sequence reads using a reference genome. Researchers Graduate students Biologists, Genomicists, Computer Scientists Post-Doctoral Fellows
High-Throughput Biology 2017 Module 1-Introduction to High-Throughput Sequencing

Course covers the key bioinformatics concepts and tools required to analyze DNA- and RNA- sequence reads using a reference genome.

High-Throughput Biology 2017 Module 1-Introduction to High-Throughput Sequencing https://tess.elixir-europe.org/materials/high-throughput-biology-2017-module-1-introduction-to-high-throughput-sequencing Course covers the key bioinformatics concepts and tools required to analyze DNA- and RNA- sequence reads using a reference genome. Graduate students Post-Doctoral Fellows Researchers Biologists, Genomicists, Computer Scientists
Data Manipulation - Collections: Rule Based Uploader

A collection of microtutorials explaining data manipulation within Galaxy Questions of the tutorial: - How to use the rule based uploader to create complex collections Objectives of the tutorial: - Learn about the Rule Based Uploader

Resource type: Tutorial

Data Manipulation - Collections: Rule Based Uploader https://tess.elixir-europe.org/materials/data-manipulation-collections-rule-based-uploader A collection of microtutorials explaining data manipulation within Galaxy Questions of the tutorial: - How to use the rule based uploader to create complex collections Objectives of the tutorial: - Learn about the Rule Based Uploader
Genome Annotation - Genome Annotation

Genome annotation is a multi-level process that includes prediction of protein-coding genes, as well as other functional genome units such as structural RNAs, tRNAs, small RNAs, pseudogenes, control regions, direct and inverted repeats, insertion sequences, transposons and other mobile elements.

Resource type: Tutorial

Genome Annotation - Genome Annotation https://tess.elixir-europe.org/materials/genome-annotation-genome-annotation Genome annotation is a multi-level process that includes prediction of protein-coding genes, as well as other functional genome units such as structural RNAs, tRNAs, small RNAs, pseudogenes, control regions, direct and inverted repeats, insertion sequences, transposons and other mobile elements.
Introduction to Galaxy - Rule Based Uploader

Galaxy is a scientific workflow, data integration, and data and analysis persistence and publishing platform that aims to make computational biology accessible to research scientists that do not have computer programming experience. Questions of the tutorial: - How to use the rule based...

Resource type: Tutorial

Introduction to Galaxy - Rule Based Uploader https://tess.elixir-europe.org/materials/introduction-to-galaxy-rule-based-uploader Galaxy is a scientific workflow, data integration, and data and analysis persistence and publishing platform that aims to make computational biology accessible to research scientists that do not have computer programming experience. Questions of the tutorial: - How to use the rule based uploader to create complex collections Objectives of the tutorial: - Learn about the Rule Based Uploader
Epigenetics - Hi-C analysis of Drosophila melanogaster cells using HiCExplorer

DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements. Questions of the tutorial: - Why is a Hi-C analysis useful? - What is...

Resource type: Tutorial

Epigenetics - Hi-C analysis of Drosophila melanogaster cells using HiCExplorer https://tess.elixir-europe.org/materials/epigenetics-hi-c-analysis-of-drosophila-melanogaster-cells-using-hicexplorer DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements. Questions of the tutorial: - Why is a Hi-C analysis useful? - What is 'chromosome conformation capture'? - What are main steps in order to generate and plot a Hi-C contact matrix?
Introduction to Galaxy Analyses - IGV Introduction

Galaxy is a scientific workflow, data integration, and data and analysis persistence and publishing platform that aims to make computational biology accessible to research scientists that do not have computer programming experience.

Resource type: Tutorial

Introduction to Galaxy Analyses - IGV Introduction https://tess.elixir-europe.org/materials/galaxy-introduction-igv-introduction Galaxy is a scientific workflow, data integration, and data and analysis persistence and publishing platform that aims to make computational biology accessible to research scientists that do not have computer programming experience.
Development in Galaxy - Tool Dependencies and Containers

Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - What are the advantages of running my Galaxy tool inside of a container? - How does Galaxy find a container...

Resource type: Tutorial

Development in Galaxy - Tool Dependencies and Containers https://tess.elixir-europe.org/materials/development-in-galaxy-tool-dependencies-and-containers Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - What are the advantages of running my Galaxy tool inside of a container? - How does Galaxy find a container to run my tool in? - What are BioContainers and how are they related to Galaxy? Objectives of the tutorial: - Explore the differences between containerizing Galaxy and tool execution. - Discuss the advantages of containerizing tools. - Learn to build best practice tools ready to be containerized.
Development in Galaxy - Galaxy Code Architecture

Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - How is the Galaxy code structured? - What do the various other projects related to Galaxy do? - What...

Resource type: Slides

Development in Galaxy - Galaxy Code Architecture https://tess.elixir-europe.org/materials/development-in-galaxy-galaxy-code-architecture Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - How is the Galaxy code structured? - What do the various other projects related to Galaxy do? - What happens when I start Galaxy? Objectives of the tutorial: - Explore various aspects of the Galaxy codebase. - Understand the various top-level files and modules in Galaxy. - Understand how dependencies work in Galaxy's frontend and backend.
Development in Galaxy - Tool Dependencies and Conda

Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - How can I connect tools to applications and libraries? - What are the advantages of declaring dependencies...

Resource type: Tutorial

Development in Galaxy - Tool Dependencies and Conda https://tess.elixir-europe.org/materials/development-in-galaxy-tool-dependencies-and-conda Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - How can I connect tools to applications and libraries? - What are the advantages of declaring dependencies for my tool? - What are Conda and Bioconda? - What are Conda recipes and environments? - How do I find and use existing Conda recipes? - How do I develop Conda recipes for use within Galaxy tools? Objectives of the tutorial: - Learn to use existing Conda recipes to enable best practice tool dependency management in Galaxy. - Learn the basics of building Conda recipes and contributing to Bioconda. - Learn to use Planemo to assist in developing Galaxy tools from existing and new Conda recipes.
Development in Galaxy - Tool development and integration into Galaxy

Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - What is a tool for Galaxy? - How to build a tool/wrapper with the good practices? - How to deal with the...

Resource type: Tutorial

Development in Galaxy - Tool development and integration into Galaxy https://tess.elixir-europe.org/materials/development-in-galaxy-tool-development-and-integration-into-galaxy Galaxy is an open-source project. Everyone can contribute to its development with core Galaxy development, integration of softwares in Galaxy environment, ... Questions of the tutorial: - What is a tool for Galaxy? - How to build a tool/wrapper with the good practices? - How to deal with the tool environment? Objectives of the tutorial: - Discover what is a wrapper and its structure - Use the Planemo utilities to develop a good wrapper - Deal with the dependencies - Write functional tests - Make a tool ready for publishing in a ToolShed
ChIP-Seq data analysis - Identification of the binding sites of the T-cell acute lymphocytic leukemia protein 1 (TAL1)

ChIP-sequencing is a method used to analyze protein interactions with DNA. Questions of the tutorial: - How is raw ChIP-seq data processed and analyzed? - What are the binding sites of Tal1? - Which genes are regulated by Tal1? Objectives of the tutorial: - Inspect read quality with FastQC -...

Resource type: Tutorial

ChIP-Seq data analysis - Identification of the binding sites of the T-cell acute lymphocytic leukemia protein 1 (TAL1) https://tess.elixir-europe.org/materials/chip-seq-data-analysis-identification-of-the-binding-sites-of-the-t-cell-acute-lymphocytic-leukemia-protein-1-tal1 ChIP-sequencing is a method used to analyze protein interactions with DNA. Questions of the tutorial: - How is raw ChIP-seq data processed and analyzed? - What are the binding sites of Tal1? - Which genes are regulated by Tal1? Objectives of the tutorial: - Inspect read quality with FastQC - Perform read trimming with Trimmomatic - Align trimmed reads with BWA - Assess quality and reproducibility of experiments - Identify Tal1 binding sites with MACS2 - Determine unique/common Tal1 binding sites from G1E and Megakaryocytes - Identify unique/common Tal1 peaks occupying gene promoters - Visually inspect Tal1 peaks with Trackster
Epigenetics - DNA Methylation data analysis

DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements. Questions of the tutorial: - What is methylation and why it cannot be...

Resource type: Tutorial

Epigenetics - DNA Methylation data analysis https://tess.elixir-europe.org/materials/epigenetics-dna-methylation-data-analysis DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements. Questions of the tutorial: - What is methylation and why it cannot be recognised by a normal NGS procedure? - Can a different methylation influence the expression of a gene? How? - Which tools you can use to analyse methylation data? Objectives of the tutorial: - Learn how to analyse methylation data - Get a first intuition what are common pitfalls.
Epigenetics - Introduction to DNA Methylation data analysis

DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements.

Epigenetics - Introduction to DNA Methylation data analysis https://tess.elixir-europe.org/materials/epigenetics-introduction DNA methylation is an epigenetic mechanism used by higher eukaryotes and involved in e.g. gene expression, X-Chromosome inactivating, imprinting, and gene silencing of germline specific gene and repetitive elements.
Sequence analysis - Mapping

Analyses of sequences Questions of the tutorial: - What two things are crucial for a correct mapping? - What is BAM? Objectives of the tutorial: - You will learn what mapping is - A genome browser is shown that helps you to understand your data

Resource type: Tutorial

Sequence analysis - Mapping https://tess.elixir-europe.org/materials/analysis-of-sequences-mapping Analyses of sequences Questions of the tutorial: - What two things are crucial for a correct mapping? - What is BAM? Objectives of the tutorial: - You will learn what mapping is - A genome browser is shown that helps you to understand your data