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• Introduction to CLC Genomics Workbench
  • Contact information
  • Download and installation
    • Program download
    • Installation on Microsoft Windows
    • Installation on Mac OS X
    • Installation on Linux with an installer
  • System requirements
    • Limitations on maximum number of cores
  • Workbench Licenses
    • Request an evaluation license
    • Download a license using a license order ID
    • Import a license from a file
    • Upgrade license
    • Configure license server connection
    • Download a static license on a non-networked machine
    • Viewing mode
    • Start in safe mode
    • CLC Sequence Viewer vs. Workbenches
  • When the program is installed: Getting started
    • Quick start
  • Plugins
    • Install
    • Uninstall
    • Updating plugins
  • Network configuration
  • Latest improvements
• User interface
  • View Area
    • Open view
    • History and Info views
    • Close views
    • Save changes in a view
    • Undo/Redo
    • Arrange views in View Area
    • Moving a view to a different screen
    • Side Panel
  • Zoom and selection in View Area
    • Zoom in
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    • Selecting, panning and zooming
  • Toolbox and Status Bar
    • Processes
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  • Workspace
  • List of shortcuts
• Data management and search
  • Navigation Area
    • Data structure
    • Create new folders
    • Sorting folders
    • Multiselecting elements
    • Moving and copying elements
    • Change element names
    • Delete, restore and remove elements
    • Show folder elements in a table
  • Metadata
    • Importing Metadata
    • Advanced Metadata Import
    • Associating data elements with metadata
    • Working with data and metadata
  • Working with tables
    • Filtering tables
  • Customized attributes on data locations
    • Filling in values
    • What happens when a clc object is copied to another data location?
    • Searching
  • Local search
    • Quick search
    • Advanced search
• User preferences and settings
  • General preferences
  • View preferences
    • Import and export Side Panel settings
  • Data preferences
  • Advanced preferences
  • Export/import of preferences
  • View settings for the Side Panel
• Printing
  • Selecting which part of the view to print
  • Page setup
  • Print preview
• Import/export of data and graphics
  • Standard import
    • External files
  • Import tracks
    • GFF3 format
  • Import high-throughput sequencing data
    • Illumina
    • PacBio
    • Fasta read files
    • Sanger sequencing data
    • Ion Torrent
    • Complete Genomics
    • General notes on handling paired data
    • SAM and BAM mapping files
  • Import RNA spike-in controls
  • Data export
    • Export of folders and multiple elements in CLC format
    • Export of dependent elements
    • Export history
    • The CLC format
    • Backing up data from the CLC Workbench
    • Export of tables
  • Export graphics to files
    • File formats
  • Export graph data points to a file
  • Copy/paste view output
• Data download
  • Download reference genome data
    • Selecting data types for download
    • Cytogenetic ideograms
  • Search for Sequences at NCBI
    • NCBI search options
    • Handling of NCBI search results
  • Search for structures at NCBI
    • Structure search options
    • Handling of NCBI structure search results
    • Save structure search parameters
  • UniProt (Swiss-Prot/TrEMBL) search
    • UniProt search options
    • Handling of UniProt search results
    • Save UniProt search parameters
  • SRA search
    • SRA search options
    • SRA search output
    • Downloading reads and metadata from SRA
    • How reads are downloaded
  • Sequence web info
• Running tools, handling results and batching
  • Running tools
  • Handling results
  • Batch processing
    • Standard batch processing
    • Batch overview
    • Parameters for batch runs
    • Running the analysis and organizing the results
    • Batch launching workflows with multiple inputs
• Workflows
  • Creating a workflow
    • Adding workflow elements
    • Configuring workflow elements
    • Locking and unlocking parameters
    • Connecting workflow elements
    • Output
    • Input
    • Layout
    • Input modifying tools
    • Workflow validation
    • Workflow creation helper tools
    • Adding to workflows
    • Snippets in workflows
    • Change the order of tracks in the Genome Browser View
  • Distributing and installing workflows
    • Creating a workflow installation file
    • Installing a workflow
    • Managing workflows
    • Workflow identification and versioning
    • Automatic update of workflow elements
  • Executing a workflow
  • Open copy of installed workflow
• Viewing and editing sequences
  • View sequence
    • Sequence settings in Side Panel
    • Selecting parts of the sequence
    • Editing the sequence
    • Sequence region types
  • Circular DNA
    • Using split views to see details of the circular molecule
    • Mark molecule as circular and specify starting point
  • Working with annotations
    • Viewing annotations
    • Adding annotations
    • Edit annotations
    • Removing annotations
  • Element information
  • View as text
  • Sequence Lists
• BLAST search
  • Running BLAST searches
    • BLAST at NCBI
    • BLAST against local data
  • Output from BLAST searches
    • Graphical overview for each query sequence
    • Overview BLAST table
    • BLAST graphics
    • BLAST HSP table
    • BLAST hit table
    • Extracting a consensus sequence from a BLAST result
  • Local BLAST databases
    • Make pre-formatted BLAST databases available
    • Download NCBI pre-formatted BLAST databases
    • Create local BLAST databases
  • Manage BLAST databases
  • Bioinformatics explained: BLAST
    • How does BLAST work?
    • Which BLAST program should I use?
    • Which BLAST options should I change?
    • Explanation of the BLAST output
    • I want to BLAST against my own sequence database, is this possible?
    • What you cannot get out of BLAST
    • Other useful resources
• 3D Molecule Viewer
  • Importing molecule structure files
    • From the Protein Data Bank
    • From your own file system
    • BLAST search against the PDB database
    • Import issues
  • Viewing molecular structures in 3D
    • Updating old structure files
  • Customizing the visualization
    • Visualization styles and colors
    • Project settings
  • Tools for linking sequence and structure
    • Show sequence associated with molecule
    • Link sequence or sequence alignment to structure
    • Transfer annotations between sequence and structure
  • Protein structure alignment
    • The Align Protein Structure dialog box
    • Example: alignment of calmodulin
    • The Align Protein Structure algorithm
• General sequence analyses
  • Extract Annotations
  • Extract sequences
  • Shuffle sequence
  • Dot plots
    • Create dot plots
    • View dot plots
    • Bioinformatics explained: Dot plots
    • Bioinformatics explained: Scoring matrices
  • Local complexity plot
  • Sequence statistics
    • Bioinformatics explained: Protein statistics
  • Join sequences
  • Pattern discovery
    • Pattern discovery search parameters
    • Pattern search output
  • Motif Search
    • Dynamic motifs
    • Motif search from the Toolbox
    • Java regular expressions
  • Create motif list
• Nucleotide analyses
  • Convert DNA to RNA
  • Convert RNA to DNA
  • Reverse complements of sequences
  • Reverse sequence
  • Translation of DNA or RNA to protein
  • Find open reading frames
    • Open reading frame parameters
• Protein analyses
  • Protein charge
  • Antigenicity
  • Hydrophobicity
    • Hydrophobicity graphs along sequence
    • Bioinformatics explained: Protein hydrophobicity
  • Pfam domain search
    • Download of Pfam database
    • Running Pfam Domain Search
  • Secondary structure prediction
  • Protein report
  • Reverse translation from protein into DNA
    • Bioinformatics explained: Reverse translation
  • Proteolytic cleavage detection
    • Bioinformatics explained: Proteolytic cleavage
• Primers
  • Primer design - an introduction
    • General concept
    • Scoring primers
  • Setting parameters for primers and probes
    • Primer Parameters
  • Graphical display of primer information
    • Compact information mode
    • Detailed information mode
  • Output from primer design
  • Standard PCR
    • When a single primer region is defined
    • When both forward and reverse regions are defined
    • Standard PCR output table
  • Nested PCR
  • TaqMan
  • Sequencing primers
  • Alignment-based primer and probe design
    • Specific options for alignment-based primer and probe design
    • Alignment based design of PCR primers
    • Alignment-based TaqMan probe design
  • Analyze primer properties
  • Find binding sites and create fragments
    • Binding parameters
    • Results - binding sites and fragments
  • Order primers
• Sequencing data analyses
  • Importing and viewing trace data
    • Trace settings in the Side Panel
  • Trim sequences
    • Trimming using the Trim tool
    • Manual trimming
  • Assemble sequences
  • Assemble sequences to reference
  • Sort sequences by name
  • Add sequences to an existing contig
  • View and edit contigs and read mappings
    • View settings in the Side Panel
    • Editing a contig or read mapping
    • Sorting reads
    • Read conflicts
    • Using the mapping
    • Extract parts of a mapping
    • Variance table
  • Reassemble contig
  • Secondary peak calling
• Cutting and cloning
  • Restriction site analyses
    • Dynamic restriction sites
    • Restriction Site Analysis
  • Restriction enzyme lists
  • Molecular cloning
    • Introduction to the cloning editor
    • The cloning workflow
    • Manual cloning
    • Insert restriction site
  • Gateway cloning
    • Add attB sites
    • Create entry clones (BP)
    • Create expression clones (LR)
  • Gel electrophoresis
    • Gel view
• Sequence alignment
  • Create an alignment
    • Gap costs
    • Fast or accurate alignment algorithm
    • Aligning alignments
    • Fixpoints
  • View alignments
    • Bioinformatics explained: Sequence logo
  • Edit alignments
    • Realignment
  • Join alignments
  • Pairwise comparison
    • The pairwise comparison table
    • Bioinformatics explained: Multiple alignments
• Phylogenetic trees
  • K-mer Based Tree Construction
  • Create tree
  • Model Testing
  • Maximum Likelihood Phylogeny
    • Bioinformatics explained
  • Tree Settings
    • Minimap
    • Tree layout
    • Node settings
    • Label settings
    • Background settings
    • Branch layout
    • Bootstrap settings
    • Visualizing metadata
    • Node right click menu
  • Metadata and phylogenetic trees
    • Table Settings and Filtering
    • Add or modify metadata on a tree
    • Undefined metadata values on a tree
    • Selection of specific nodes
• RNA structure
  • RNA secondary structure prediction
    • Selecting sequences for prediction
    • Secondary structure prediction parameters
    • Structure as annotation
  • View and edit secondary structures
    • Graphical view and editing of secondary structure
    • Tabular view of structures and energy contributions
    • Symbolic representation in sequence view
    • Probability-based coloring
  • Evaluate structure hypothesis
    • Selecting sequences for evaluation
    • Probabilities
  • Structure scanning plot
    • Selecting sequences for scanning
    • The structure scanning result
  • Bioinformatics explained: RNA structure prediction by minimum free energy minimization
    • The algorithm
    • Structure elements and their energy contribution
• Trimming, multiplexing and sequencing quality control
  • Trim Reads
    • Quality trimming
    • Adapter trimming
    • Trim adapter list
    • Length trimming
    • Trim output
  • Demultiplex reads
    • An example using Illumina barcoded sequences
  • Sequencing data quality control
    • QC Sequencing Report Content
    • Adapters
    • Running the quality control tool
  • Merge overlapping pairs
    • Using quality scores when merging
    • Report of merged pairs
• Tracks
  • Track lists
    • Zooming and navigating track views
    • Adding, removing and reordering tracks
    • Showing a track in a table
    • Open track from a track list in table view
    • Finding annotations on the genome
    • Extract sequences from tracks
    • Creating track lists in workflows
  • Retrieving reference data tracks
  • Merging tracks
  • Converting data to tracks and back
    • Convert to tracks
    • Convert from tracks
  • Annotate and filter tracks
    • Annotate with overlap information
    • Extract reads based on overlap
    • Filter annotations on name
    • Filter Based on Overlap
  • Graphs
    • Create GC Content Graph
    • Create Mapping Graph
    • Identify Graph Threshold Areas
• Read mapping
  • Map Reads to Reference
    • Selecting reads and reference
    • Including or excluding regions (masking)
    • Mapping parameters
    • Mapping paired reads
    • Non-specific matches
    • Gap placement
    • Mapping computational requirements
    • Reference caching
  • Mapping output
    • Mapping output options
    • Mapped reads coloring
    • Reads track output from a read mapping
    • Stand-alone read mapping
    • Mapping table
    • Mapping view settings
    • Overlapping paired reads
    • Find broken pair mates
  • Mapping reports
    • Summary mapping report
    • Detailed mapping report
  • Mapping SOLid reads in color space
    • Viewing color space information
    • Mapping in color space
  • Local realignment
    • Method
    • Realignment of unaligned ends
    • Guided realignment
    • Multi-pass local realignment
    • Known limitations
    • Computational requirements
    • How to run the Local Realignment tool
  • Merge mapping results
  • Remove duplicate mapped reads
    • Algorithm details and parameters
    • Running the duplicate reads removal
  • Extract consensus sequence
  • Sample reads
• Resequencing
  • Create Statistics for Target Regions
    • Running the Create Statistics for Target Regions
    • Coverage summary report
    • Per-region statistics
    • Coverage table
    • Coverage graph
  • InDels and Structural Variants
    • How to run the InDels and Structural Variants tool
    • The Structural Variants and InDels output
    • The InDels and Structural Variants detection algorithm
    • The InDels and Structural Variants detection algorithm - Step 1: Creating Left- and Right breakpoint signatures
    • The InDels and Structural Variants detection algorithm - Step 2: Creating Structural variant signatures
    • Theoretically expected structural variant signatures
    • How sequence complexity is calculated
  • Coverage analysis
  • Variant Detectors - overview
    • Differences in the variants called by the different tools
    • How the variant detection tools work
  • Fixed Ploidy Variant Detection
    • Ploidy and sensitivity
  • Low Frequency Variant Detection
  • Basic Variant Detection
  • Variant Detectors - error model estimation
  • Variant Detectors - filters
    • General filters
    • Noise filters
  • Variant Detectors - the outputs
    • The variant track output
    • The annotated table output
    • The report
  • The Fixed Ploidy and Low Frequency variant callers: detailed descriptions
    • The Fixed Ploidy Variant Caller: Models and methods
    • The Low Frequency Variant caller: Models and methods
  • Variant data
    • Variant tracks
    • The annotated variant table
    • Variant types
  • Detailed information about overlapping paired reads
  • Annotate and filter variants
    • Filter against known variants
    • Annotating from known variants
    • Annotate with exon numbers
    • Annotate with flanking sequence
    • Identify candidate variants
    • Filter marginal variant calls
    • Filter reference variants
  • Comparing variants
    • Compare variants within group
    • Compare sample variants
    • Fisher exact test
    • Trio analysis
    • Filter Against Control Reads
  • Predicting functional consequences
    • Amino acid changes
    • Predict splice site effect
    • GO enrichment analysis
    • Conservation score annotation
    • Link Variants to 3D Protein Structure
    • Download 3D Protein Structure Database
  • Identify Known Mutations from Sample Mappings
    • How to run the Identify Known Mutations from Sample Mappings tool
    • Output from the Identify Known Mutations from Sample Mappings tool
• RNA-Seq Analysis tools
  • RNA-Seq analysis
    • Specifying reads and reference
    • Defining mapping options for RNA-Seq
    • The EM estimation algorithm
    • Calculating expression values from RNA-Seq
    • Specifying RNA-Seq outputs
    • Expression tracks
    • Reads track
    • RNA-Seq report
    • Gene fusion reporting
  • Create Combined RNA-Seq Report
  • Advanced RNA-Seq Tools
    • TMM Normalization
    • Metadata for RNA-Seq
  • PCA for RNA-Seq
    • Principal component analysis plot (2D)
    • Principal component analysis plot (3D)
  • Differential Expression for RNA-Seq
    • The statistical model
    • Output of the Differential Expression for RNA-Seq tool
    • Statistical comparison tracks
    • The volcano plot
  • Create Heat Map for RNA-Seq
    • Clustering of features and samples
    • The heat map view
  • Create Expression Browser
    • The expression browser
  • Create Venn Diagram for RNA-Seq
    • Venn diagram table view
  • Gene Set Test
• Microarray and Small RNA Analysis
  • Small RNA analysis
    • Extract and count
    • Downloading miRBase
    • Annotating and merging small RNA samples
    • Working with the small RNA sample
    • Exploring novel miRNAs
  • Experimental design
    • Setting up an experiment
    • Organization of the experiment table
    • Adding annotations to an experiment
    • Scatter plot view of an experiment
    • Cross-view selections
  • Working with tracks and experiments
    • Data structures for transcriptomics
    • Running the Create Track from Experiment tool
    • Interpreting the results of the Create Track from Experiment tool
    • Visualizing RNA-Seq read tracks for the experiment
  • Transformation and normalization
    • Selecting transformed and normalized values for analysis
    • Transformation
    • Normalization
  • Quality control
    • Creating box plots - analyzing distributions
    • Hierarchical clustering of samples
    • Principal component analysis
  • Statistical analysis - identifying differential expression
    • Empirical analysis of DGE
    • Tests on proportions
    • Gaussian-based tests
    • Corrected p-values
    • Volcano plots - inspecting the result of the statistical analysis
  • Feature clustering
    • Hierarchical clustering of features
    • K-means/medoids clustering
  • Annotation tests
    • Hypergeometric tests on annotations
    • Gene set enrichment analysis
  • General plots
    • Histogram
    • MA plot
    • Scatter plot
• De novo sequencing
  • De novo assembly
    • Best practices
    • How it works
    • Resolve repeats using reads
    • Automatic paired distance estimation
    • Optimization of the graph using paired reads
    • AGP export
    • Bubble resolution
    • Converting the graph to contig sequences
    • Summary
    • Randomness in the results
    • SOLiD data support in de novo assembly
    • De novo assembly parameters
    • De novo assembly report
  • Map Reads to Contigs
• Epigenomics
  • ChIP-Seq Analysis
    • Quality Control of ChIP-Seq data
    • Learning peak shapes
    • Applying peak shape filters to call peaks
    • Running the Transcription Factor ChIP-Seq tool
  • Annotate with nearby gene information
• Legacy tools
  • Import Roche 454
  • Import SOLiD
• Appendix
  • Use of multi-core computers
  • Graph preferences
  • BLAST databases
    • Peptide sequence databases
    • Nucleotide sequence databases
    • Adding more databases
  • Proteolytic cleavage enzymes
  • Restriction enzymes database configuration
  • Technical information about modifying Gateway cloning sites
  • IUPAC codes for amino acids
  • IUPAC codes for nucleotides
  • Formats for import and export
    • List of bioinformatic data formats
    • List of graphics data formats
  • SAM/BAM export format specification
    • Flags
  • Gene expression annotation files and microarray data formats
    • GEO (Gene Expression Omnibus)
    • Affymetrix GeneChip
    • Illumina BeadChip
    • Gene ontology annotation files
    • Generic expression and annotation data file formats
  • Translation Tables
    • 1. Standard
    • 2. Vertebrate Mitochondrial
    • 3. Yeast Mitochondrial
    • 4. Mold Mitochondrial; Protozoan Mitochondrial; Coelenterate Mitochondrial; Mycoplasma; Spiroplasma
    • 5. Invertebrate Mitochondrial
    • 6. Ciliate Nuclear; Dasycladacean Nuclear; Hexamita Nuclear
    • 9. Echinoderm Mitochondrial; Flatworm Mitochondrial
    • 10. Euplotid Nuclear
    • 11. Bacterial and Plant Plastid
    • 12. Alternative Yeast Nuclear
    • 13. Ascidian Mitochondrial
    • 14. Alternative Flatworm Mitochondrial
    • 15. Blepharisma Macronuclear
    • 16. Chlorophycean Mitochondrial
    • 21. Trematode Mitochondrial
    • 22. Scenedesmus Obliquus Mitochondrial
    • 23. Thraustochytrium Mitochondrial
    • 24. Pterobranchia Mitochondrial
    • 25. Candidate Division SR1 and Gracilibacteria
  • Custom codon frequency tables
  • Comparison of track comparison tools
  • Matrices for alignment calculation
    • PAM30 log-odds matrix
    • PAM60 log-odds matrix
    • BLOSUM42 log-odds matrix
    • BLOSUM62 log-odds matrix
    • BLOSUM80 log-odds matrix
• Bibliography

Amino acid changes

This tool annotates variants with amino acid changes and creates a track for visual inspection of the amino acid changes. It takes a variant track as input and also requires a track with coding regions and a reference sequence.

To add information about amino acid changes to a variant track:

        Toolbox | Resequencing Analysis () | Functional Consequences () | Amino Acid Changes ()

If you are connected to a server, the first wizard step will ask you where you would like to run the analysis. Next, you must provide the variant track to be annotated with amino acid changes (see figure 25.63).

Figure 25.63: The amino acid changes annotation tool takes variant tracks as input.

Click on the button labeled Next to go to the next wizard step (figure 25.64).

Figure 25.64: Select CDS, mRNA, and sequence track and choose whether or not you would like to filter away synonymous variants.

In this step you get the following options:

• Select CDS track Click on the folder icon () in the right side of the wizard to select a CDS track. The CDS track is used to determine the reading frame and exon location to be used for translation. If you do not already have CDS, mRNA, and sequence tracks in the Workbench, you can download it by clicking on the Download icon () found in the upper right corner of the Workbench. Select Download Reference Genome Data () as described in Download reference genome data.
• Select mRNA track Click on the folder icon () in the right side of the wizard to select the mRNA track. The mRNA track is used to determine whether the variant is inside or outside the region covered by the transcript. The mRNA track is optional. If you choose to provide an mRNA track you annotate variants that are located in the mRNA but also outside the region covering the coding sequence, in cases where such variants have been detected. If you choose not to provide an mRNA track, variants found outside the CDS region will not be annotated.
• Select sequence track Click on the folder icon () in the right side of the wizard to select the reference sequence track.
• Filtering and annotation
  • The "Filter synonymous variants" option allows you to filter away synonymous variants that does not cause any change to the encoded amino acid.
  • By default, the tool will filter out CDS regions that have no variants. You can choose to include them in your amino acid annotation track by deselecting the "Filter CDs regions with no variants" option.
  • The genetic code is the code that is used for amino acid translation (see http://www.ncbi.nlm.nih.gov/Taxonomy/Utils/wprintgc.cgi). The default option is "1 standard", the vertebrate standard code. If relevant, you can use the drop-down list to change to the genetic code that applies to you organism.

Click on the button labeled Next, choose whether you would like to open or save the results and click on the button labeled Finish.

Two types of outputs are generated:

1. A variant track that has been annotated with the amino acid changes. The added information can be accessed via the tooltips in the variant track or in the extra columns that have been added to the variant table. The extra columns provide information about the amino acid changes (see http://www.ncbi.nlm.nih.gov/Taxonomy/Utils/wprintgc.cgi). The variant track opens in track view and the table view can be accessed by clicking on the table icon found in the lower left corner of the View Area.
2. An amino acid track that displays a graphical presentation of the amino acid changes. The track is based on the CDS track and in addition to the amino acid sequence of the coding sequence, all amino acids that have been affected by variants are shown as individual amino acids below the amino acid track. Changes causing a frameshift are symbolized with two arrow heads, and variants causing premature stop are marked with an asterisk. An example is shown in figure 25.65.

Figure 25.65: The variant track and the amino acid track is here presented together with the reference sequence and the mRNA and CDS tracks. An insertion (purple arrow) has caused a frameshift (red arrow) that has changed an alanine to a stop codon (blue arrow).

For each variant in the input track, the following information is added:

• Coding region change. This describes the relative position on the coding DNA level, using the nomenclature proposed at http://varnomen.hgvs.org/. Variants inside exons and in the untranslated regions of the transcript will also be annotated with the distance to the nearest exon. E.g. "c.-4A>C" describes a SNV four bases upstream of the start codon, while "c.*4A>C" describes a SNV four bases downstream of the stop codon.
• Amino acid change. This describes the change on the protein level. For example, single amino-acid changes caused by SNVs are listed as "p.[Gly261Cys]", denoting that in the protein sequence (hence the "p.") the Glycine at position 261 is changed into Cysteine. Frame-shifts caused by nucleotide insertions and deletions are listed with the extension fs, for example p.[Pro244fs] denoting a frameshift at position 244 coding for Proline. For further details of the nomenclature see the "Recommendations for the description of protein sequence variants (v2.0)" at http://varnomen.hgvs.org/.
• Coding region change in longest transcript. When there are many transcript variants for a gene, the coding region change for all transcripts are listed in the "Coding region change" column. For quick reference, the longest transcript is often used, and there is a special column only listing the coding region change for the longest transcript.
• Amino acid change in longest transcript. This is similar to the above, just on the protein level.
• Other variants within codon. If there are other variants within the same codon, this column will have a "Yes". In this case, it should be manually investigated whether the two variants are linked by reads.
• Non-synonymous. Will have a "Yes" if the variant is non-synonymous at the protein level for any transcript. If the filter "Filter synonymous" was applied, this column will only contain entries labeled "Yes". A hyphen, "-", indicates the variant was present outside of a coding region.

An example of the output is given in figure 25.66.

Figure 25.66: The resulting amino acid changes in track and table views. When the variant table has been opened by double-clicking on the text found in the left side of the View Area, the variant table and the variant track are linked. When clicking on an entry in the table, this position will be brought into focus in the variant track.

The top track view displays a track list with the reference sequence, mRNA, CDS, variant, and amino acid tracks. The lower table view is the variant table that has been opened from the track list by double-clicking on the variant track name found in the left-hand side of the View Area. When opening the variant table in split view from the track list, the table and the variant track are linked.

An example illustrating a situation where different variants affect the same codon is shown in figure 25.67.

Figure 25.67: Amino acids encoded from codons that potentially could have been affected by more than one variant are marked with a hash symbol (#) as the graphically presented amino acid changes always only include a single variant (a SNV, MNV, insertion, or deletion). Shown here are three different variants, present only one at the time, and the consequences of the three individual deletions. In cases where the deletion is found in a codon that is affected with an amino acid change, the arrow also include the deletion (situation 1) in the two other scenarios, the codon containing the deletion is changed to a codon that encodes the same amino acid, and the effect is therefore not seen until in the subsequent amino acid.

In this example three single nucleotide deletions are shown along with the resulting amino acid changes based on scenarios where only one deletion is present at the time. The first affected amino acid is shown for each of the three deletions. As the first deletion affect the encoded amino acid, this amino acid change is shown with a four nucleotide long arrow (that includes the deletion). The other two deletions do not affect the encoded amino acid as the frameshift was "synonymous" at the position encoded by the codon where the deletion was introduced. The effect is first seen at the next amino acid position (763 and 764, respectively), which does not contain a deletion, and therefore is illustrated with a three nucleotide long arrow.

The hash symbol (#) on the changed amino acids symbolize that more than one variant can be present in the region encoding this specific amino acid. The simultaneous presence of multiple variants within the same codon is not predicted by the amino acid changes tool. Manual inspection of the reads is required to be able to detect multiple variants within one codon.

The amino acid track

The colors of the amino acids in the amino acid track can be changed in the Side Panel under Track layout and "Amino acids track" (see figure 25.68).

Figure 25.68: The colors of the amino acids can be changed in the Side Panel under "Amino acids track".

Four different color schemes are available under "Amino acid colors":

• Gray All amino acids are shown in gray.
• Group Colors the amino acids in groups by the following properties:
  • Purple neutral, polar
  • Turquoise neutral, nonpolar
  • Orange acidic, polar
  • Blue basic ,polar
  • Bright green other (functional properties)
• Polarity Colors the amino acids according to the following categories:
  • Green neutral, polar
  • Black neutral, nonpolar
  • Red acidic, polar
  • Blue basic ,polar
• Rasmol Colors the amino acids according to the Rasmol color scheme (see http://www.openrasmol.org/doc/rasmol.html).

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