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• Introduction to CLC Genomics Workbench
  • Contact information and citation
  • Download and installation
    • Installation on Microsoft Windows
    • Installation on macOS
    • 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 manager connection
    • Download a static license on a non-networked machine
    • Viewing mode
    • Start in safe mode
  • Plugins
    • Install
    • Uninstall
    • Updating plugins
  • Network configuration
  • History of the CLC Workbenches
• User interface
  • View Area
    • Close views
    • Save changes in a view
    • Undo/Redo
    • Arrange views in View Area
    • Moving a view to a different screen
    • Side Panel
  • Zoom functionality in the View Area
  • Toolbox and Favorites tabs
    • Toolbox tab
    • Favorites tab
  • Processes tab and Status bar
  • History and Element Info views
  • Workspace
  • List of shortcuts
• Data management and search
  • Navigation Area
    • Data structure
    • Adding locations
    • 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
  • 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 custom attributes
  • Searching for data in CLC Locations
    • Quick Search
    • Local Search
• User preferences and settings
  • General preferences
  • View preferences
    • Import and export Side Panel settings
  • Data preferences
  • Advanced preferences
  • Export/import of preferences
  • Side Panel view settings
• Printing
  • Selecting which part of the view to print
  • Page setup
  • Print preview
• Connections to other systems
  • CLC Server connection
  • AWS Connections
• Import/export of data and graphics
  • Standard import
    • External files
  • Import tracks
    • GFF3 format
    • VCF import
  • Import high-throughput sequencing data
    • Illumina
    • PacBio
    • Fasta read files
    • Sanger sequencing data
    • Ion Torrent
    • MGI/BGI
    • General notes on handling paired data
    • SAM and BAM mapping files
  • Import RNA spike-in controls
  • Import Primers
    • Import Primer Pairs
  • Data export
    • Export formats
    • Export parameters
    • Specifying the exported file name(s)
    • Export of folders and data elements in CLC format
    • Export of dependent elements
    • Export of tables
    • Export in VCF format
    • GFF3 export
    • JSON export
    • Graphics export
    • Export history
    • Backing up data from the CLC Workbench
  • Export graphics to files
    • File formats
  • Export graph data points to a file
  • CLC Server data import and export
  • Copy/paste view output
• Data download
  • Search for Sequences at NCBI
    • NCBI search options
    • Handling of NCBI search results
  • Search for PDB Structures at NCBI
    • Structure search options
    • Handling of NCBI structure search results
    • Save structure search parameters
  • Search for Sequences in UniProt (Swiss-Prot/TrEMBL)
    • UniProt search options
    • Handling of UniProt search results
  • Search for Reads in SRA
    • Searching SRA
    • Downloading reads and metadata from SRA
    • Troubleshooting SRA downloads
  • Sequence web info
• References management
  • Download Genomes
  • QIAGEN Sets
  • Custom Sets
    • Copy to References
    • Export a Custom Data Set
    • Import a Custom Data Set
  • Imported Data
  • Exporting reference data outside of the Reference Data Manager framework
• Running tools, handling results and batching
  • Running tools
    • Running a tool on a CLC Server
  • Handling results
  • Batch processing
• Metadata
  • Creating metadata tables
    • Importing metadata
    • Creating a metadata table directly in the Workbench
  • Associating data elements with metadata
    • Associate Data Automatically
    • Associate Data with Row
  • Working with data and metadata
    • Finding data elements based on metadata
    • Viewing metadata associations
    • Removing metadata associations
    • Identifying metadata rows without associated data
    • Editing Metadata tables
  • Moving, copying and exporting metadata
• Workflows
  • Creating and editing workflows
    • Adding elements to a workflow
    • Connecting workflow elements
    • Ordering inputs
    • Validating a workflow
    • Viewing the flow of elements in a workflow
    • Adjusting the workflow layout
    • The Configuration Editor view
    • Snippets in workflows
    • Customizing the Workflow Editor
  • Workflow elements
    • Anatomy of workflow elements
    • Basic configuration of workflow elements
    • Configuring input and output elements
    • Control flow elements
    • Track lists as workflow outputs
    • Input modifying tools
  • Launching workflows individually and in batches
    • Workflow Result Metadata tables
    • Running workflows in batch mode
    • Running part of a workflow multiple times
  • Advanced workflow batching
    • Batching workflows with more than one input changing per run
    • Multiple levels of batching
  • Template workflows
    • Import with Metadata
    • Prepare Raw Data
    • Identify DNA Germline Variants workflow
    • RNA-Seq and Differential Gene Expression Analysis workflow
  • Managing workflows
    • Updating workflows
    • Creating a workflow installation file
    • Installing a workflow
• Viewing and editing sequences
  • Sequence Lists
    • Creating sequence lists
    • Graphical view of sequence lists
    • Table view of sequence lists
    • Annotation Table view of sequence lists
    • Working with paired sequences in lists
  • View sequences
    • Sequence settings in Side Panel
    • Selecting parts of the sequence
    • Editing the sequence
    • Sequence region types
    • Circular DNA
  • Working with annotations
    • Viewing annotations
    • Adding annotations
    • Editing annotations
    • Export annotations to a gff3 format file
    • Removing annotations
  • Element information
  • View as text
• 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?
    • Where can I get the BLAST+ programs
    • 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
  • 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
  • Align Protein Structure
    • Example: alignment of calmodulin
    • The Align Protein Structure algorithm
  • Generate Biomolecule
• General sequence analyses
  • Annotate with GFF/GTF/GVF file
  • 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
  • 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
  • Download Pfam Database
  • Pfam domain search
  • Find and Model Structure
    • Create structure model
    • Model structure
  • 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 reads from a mapping
    • Variance table
  • Reassemble contig
  • Secondary peak calling
  • Extract Consensus Sequence
  • Combine Reports
    • Combine Reports output
• Cutting and cloning
  • Restriction site analyses
    • Dynamic restriction sites
    • Restriction Site Analysis
    • Insert restriction site
  • Restriction enzyme lists
  • Restriction Based Cloning
    • Introduction to the Cloning Editor
    • The restriction cloning workflow
    • Manual cloning
  • Homology Based Cloning
    • Working with homology based cloning
    • Adjust the homology based cloning design
    • Homology Based Cloning outputs
    • Detailed description of the Homology Based Cloning wizard
    • Working with mutations
  • 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
• Tracks
  • Track types
  • Working with tracks
    • Visualizing, zooming and navigating tracks
    • Showing a track in a table
    • The Chromosome Table view
    • Finding annotations on the genome
    • Extract sequences from tracks
  • Track lists
  • Retrieving reference data tracks
  • Merge Annotation Tracks
  • Merge Variant Tracks
  • Track Conversion
    • Convert to Tracks
    • Convert from Tracks
  • Annotate and Filter
    • Annotate with Exon Numbers
    • Annotate with Overlap Information
    • Filter Annotations on Name
    • Filter Based on Overlap
  • Graphs
    • Create GC Content Graph
    • Create Mapping Graph
    • Identify Graph Threshold Areas
• Prepare sequencing data
  • QC for Sequencing Reads
    • Per-sequence analysis
    • Per-base analysis
    • Over-representation analyses
  • Trim Reads
    • Quality trimming
    • Adapter trimming
    • Trim adapter list
    • Homopolymer trimming
    • Sequence trimming
    • Sequence filtering
    • Trim output
  • Demultiplex Reads
    • Demultiplexing single reads
    • Demultiplexing paired reads
    • Entering barcodes
    • Demultiplexing output options
    • Running Demultiplex Reads in workflows
• Quality control for resequencing analysis
  • QC for Targeted Sequencing
    • Coverage summary report
    • Per-region statistics
    • Coverage table
    • Coverage graph
    • Gene coverage
  • Target Region Coverage Analysis
    • Output from Target Region Coverage Analysis
  • QC for Read Mapping
    • References
    • Mapped read statistics
    • Statistics table for each mapping
  • Whole Genome Coverage Analysis
  • Combine Reports
    • Combine Reports output
    • Report types supported
  • Create Sample Report
    • Create Sample Report output
• Read mapping
  • Map Reads to Reference
    • Selecting the reads
    • References and masking
    • Mapping parameters
    • Mapping paired reads
    • Non-specific matches
    • Gap placement
    • Mapping computational requirements
    • Reference caching
    • Mapping output options
    • Summary mapping report
  • Reads tracks and stand-alone read mappings
    • Coloring of mapped reads
    • Reads tracks
    • Stand-alone read mapping
  • Local Realignment
    • Method
    • Realignment of unaligned ends
    • Guided realignment
    • Multi-pass local realignment
    • Known limitations
    • Computational requirements
    • Run the Local Realignment tool
  • Merge Read Mappings
  • Remove Duplicate Mapped Reads
    • Algorithm details and parameters
    • Running remove duplicate mapped reads
  • Extract Consensus Sequence
• Variant detection
  • Variant Detection tools
    • Differences in the variants called by the different tools
    • How the variant detection tools work
    • Detailed information about overlapping paired reads
  • Fixed Ploidy Variant Detection
  • Low Frequency Variant Detection
  • Basic Variant Detection
  • Variant Detection - filters
    • General filters
    • Noise filters
  • Variant Detection - the outputs
    • Variant tracks
    • The annotated variant table
    • The variant detection report
  • Fixed Ploidy and Low Frequency Detection tools: detailed descriptions
    • Variant Detection - error model estimation
    • The Fixed Ploidy Variant Detection tool: Models and methods
    • The Low Frequency Variant Detection tool: Models and methods
  • Copy Number Variant Detection
    • The Copy Number Variant Detection tool
    • Region-level CNV track (Region CNVs)
    • Target-level CNV track (Target CNVs)
    • Gene-level annotation track (Gene CNVs)
    • CNV results report
    • CNV algorithm report
  • Identify Known Mutations from Sample Mappings
    • Run the Identify Known Mutations from Sample Mappings tool
    • Output from the Identify Known Mutations from Sample Mappings tool
  • InDels and Structural Variants
    • Run the InDels and Structural Variants tool
    • The Structural Variants and InDels output
    • The InDels and Structural Variants detection algorithm
    • Theoretically expected structural variant signatures
    • How sequence complexity is calculated
• Resequencing analysis
  • Variant filtering
    • Filter against Known Variants
    • Remove Marginal Variants
    • Remove Homozygous Reference Variants
    • Remove Variants Present in Control Reads
  • Variant annotation
    • Annotate from Known Variants
    • Remove Information from Variants
    • Annotate with Effect Scores
    • Annotate with Conservation Score
    • Annotate with Flanking Sequence
    • Annotate with Repeat and Homopolymer Information
  • Variants comparison
    • Identify Shared Variants
    • Identify Enriched Variants in Case vs Control Samples
    • Trio Analysis
  • Variant quality control
    • Create Variant Track Statistics Report
  • Functional consequences
    • Amino Acid Changes
    • Predict Splice Site Effect
    • GO Enrichment Analysis
    • Download 3D Protein Structure Database
    • Link Variants to 3D Protein Structure
  • Create Consensus Sequences from Variants
• RNA-Seq and Small RNA analysis
  • RNA-Seq normalization
  • Create Expression Browser
    • The expression browser
    • Expression browser plot
  • miRNA analysis
    • Quantify miRNA
    • Annotate with RNAcentral Accession Numbers
    • Create Combined miRNA Report
    • Extract IsomiR Counts
    • Explore Novel miRNAs
  • RNA-Seq Tools
    • RNA-Seq Analysis
    • Detect and Refine Fusion Genes
  • Expression Plots
    • PCA for RNA-Seq
    • Create Heat Map for RNA-Seq
    • Create K-medoids Clustering for RNA-Seq
  • Differential Expression
    • Pre-filtering data for Differential Expression
    • The GLM model
    • Differential Expression in Two Groups
    • Differential Expression for RNA-Seq
    • Create Venn Diagram for RNA-Seq
    • Gene Set Test
• Microarray analysis
  • Experimental design
    • Setting up a microarray experiment
    • Organization of the experiment table
    • Adding annotations to an experiment
    • Scatter plot view of an experiment
    • Cross-view selections
  • Transformation and normalization
    • Selecting transformed and normalized values for analysis
    • Transformation
    • Normalization
  • Quality control
    • Create Box Plot
    • Hierarchical Clustering of Samples
    • Principal Component Analysis
  • Feature clustering
    • Hierarchical clustering of features
    • K-means/medoids clustering
  • Statistical analysis - identifying differential expression
    • Tests on proportions
    • Gaussian-based tests
    • Corrected p-values
    • Volcano plots - inspecting the result of the statistical analysis
  • Annotation tests
    • Hypergeometric Tests on Annotations
    • Gene Set Enrichment Analysis
  • General plots
    • Histogram
    • MA plot
    • Scatter plot
• De Novo sequencing
  • The CLC de novo assembly algorithm
    • 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
  • De Novo Assembly
    • Best practices
    • Randomness in the results
    • De novo assembly parameters
    • De novo assembly report
    • De novo assembly output
  • Map Reads to Contigs
• Epigenomics analysis
  • Histone Chip-Seq
  • 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
    • Peak track
  • Annotate with nearby gene information
  • Bisulfite Sequencing
    • Detecting DNA methylation
    • Map Bisulfite Reads to Reference
    • Call Methylation Levels
    • Create RRBS-fragment Track
  • Advanced Peak Shape Tools
    • Learn Peak Shape Filter
    • Apply Peak Shape Filter
    • Score Regions
• Utility tools
  • Extract Annotated Regions
  • Extract Reads
  • Filter on Custom Criteria
  • Merge Overlapping Pairs
  • Track tools
  • Create Sequence List
  • Update Sequence Attributes in Lists
  • Split Sequence List
  • Subsample Sequence List
  • Rename Elements
  • Rename Sequences in Lists
• Legacy tools
  • QIAGEN GeneReader Sequencing Import (legacy)
• 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

Subsections

• Selected input sequences
• References
• Spike-in quality control
• Read quality control
• Mapping statistics
• Fragment statistics
• Distribution of biotypes
• Gene/transcript length coverage

---

RNA-Seq report

An example of an RNA-Seq report generated if you choose the Create report option is shown in figure 31.46.

Figure 31.49: Report of an RNA-Seq run.

The report is a collection of the sections described below, some sections included only based on the input provided when starting the tool. If a section is flagged with a pink highlight, it means that something has almost certainly gone wrong in the sample preparation or analysis. A warning message tailored to the highlighted section is added to the report to help troubleshoot the issue. The report can be exported in PDF or Excel format.

Selected input sequences

Information about the sequence reads provided as input, including the number of reads in each sample, as well as information about the reference sequences used and their lengths.

References

Information about the total number of genes and transcripts found in the reference:

• Transcripts per gene. A graph showing the number of transcripts per gene.
• Exons per transcript. A graph showing the number of exons per transcript.
• Length of transcripts. A graph showing the distribution of transcript lengths.

Spike-in quality control

• Spike-in plot. A plot shows the expression of each spike-in as a function of the known concentration of that spike-in (see figure 31.47 to see an optimal spike-in plot).

  
  Figure 31.50: Spike-in plot showing how the points fall close to the regression line at high concentration.

• Summary table. A table provides more details on the spike-in detection. Figure 31.48 shows a failed spike-in control, with a table where results that require attention are highlighted in pink.

  
  Figure 31.51: Summary table where less than optimal results are highlighted.

  Under the table, a warning message explains what the optimal value was, and offers some troubleshooting measures: When samples have poor correlation between known and measured spike-in concentrations, it indicates problems with the spike-in protocol, or a more serious problem with the sample. To troubleshoot, check that the correct spike-in file has been selected, and control the integrity of the sample RNA. Also, if fewer than 10000 reads mapped to spike-ins, check that the correct spike-in sequences are specified, and consider using more spike-in mix in future experiments.

Read quality control

This section includes:

• A strand specificity table that indicates the direction of the RNA fragment that generated the read. Strandedness can only be defined for reads that map to a gene or transcript. Of these reads, the number of "Reads with known strand" is used in determining the percentage of reads ignored due to being on the wrong strand, and the subsequent percentage of reads with the wrong strand. In a strand-specific protocol, almost all reads are generated from a specific orientation, but otherwise a mix of both orientations is expected.
  • A warning message will appear if over 90% of reads were mapped in the same orientation but the tool was run without using a strand specific setting ("Forward"/"Reverse").
  • If over 25% of the reads were filtered away due to the strand specific setting, try to re-run the tool with strand specific setting "Both". However, if a strand-specific protocol was used, library preparation may have failed.
• A percentage of mapped paired-end reads containing read-through adapters. If present in above 10% of the reads, adapters may lead to false positive variant calls or incorrect transcript quantification (because reads must align within transcript annotations to be counted towards expression). Read-through adapters can be removed using the Trim Reads tool. In future experiments, consider selecting fragments that are longer than the read size. Note that single base extensions such as TA overhangs will also be classed as read-through adapters, and in these cases the additional base should be trimmed. Note also that trimming of read starts (5' trim) can lead to spurious detection of read-through adapters, because the trimming increases the number of read pairs where the end of one read aligns over the (trimmed) start of the other.
• A paired distance graph (only included if paired reads are used) shows the distribution of paired-end distances, which is equivalent to the distribution of sequenced RNA fragment sizes. There should be a single broad peak at the target fragment size. An asymmetric peak may indicate problems in size selection.

Mapping statistics

Shows statistics on:

• Paired reads or Single reads. The table included depends on the reads used. The table shows the number of reads mapped or unmapped, and in the case of paired reads, how many reads mapped in pairs and in broken pairs.

  If over 50% of the reads did not map, and the correct reference genome was selected, this indicates a serious problem with the sample. To troubleshoot, the report offers the following options:

  • Check that the correct reference genome and any relevant gene/mRNA tracks have been provided.
  • The mapping parameters may be too strict. Try resetting them to the default values.
  • Try mapping the unmapped reads against possible contaminants. If the sample is contaminated, enrich for the target species before library preparation in future experiments.
  • Library preparation may have failed. Check the quality of the sample RNA.

  In case paired reads are used and over 40% of them mapped as broken pairs, if the counting scheme is not set to "Count paired reads as one and broken pairs as two" in the Expression settings dialog, the report hints that there could be problems with the tool settings, a low quality reference sequence, or incomplete gene/mRNA annotations. It could also indicate a more serious problem with the sample. To troubleshoot, it is suggested to:

  • Check that the correct reference genome and any relevant gene/mRNA tracks have been provided.
  • Try re-running the tool with the "Auto-detect paired distances" option selected.
  • Check that the paired-end distances on the reads are set correctly. These are shown in the "Element Information" view on the reads. If these are correct, try re-running the tool without the "Auto-detect paired distances" option.
  • Try mapping the reads against possible contaminants. If the sample is contaminated, enrich for the target species before library preparation in future experiments.

• Match specificity. Shows a graph of the number of match positions for the reads. Most reads will be mapped 0 or 1 time, but there will also be reads matching more than once in the reference.The maximum number of match positions is limited in the Maximum number of hits for a read setting in figure 31.36. Note that the number of reads that are mapped 0 times includes both the number of reads that cannot be mapped at all and the number of reads that matches to more than the Maximum number of hits for a read parameter.

Fragment statistics

• Fragment counting. Lists the total number of fragments used for calculating expression, divided into uniquely and non-specifically mapped reads, as well as uncounted fragments (see the point below on match specificity for details).

• UMI fragment counting. Lists the total number of distinct UMI fragments used for calculating expression. This table is only included if the Library type setting is 3' sequencing and if the input reads are single end reads annotated with UMIs by tools of the Biomedical Genomics Analysis plugin.

• Counted fragments by type. Divides the fragments that are counted into different types, e.g., uniquely mapped, non-specifically mapped, mapped. A last column gives the percentage of fragments mapped for a particular type.
  • Total gene reads. All reads that map to the gene.
  • - Intron. From the total gene reads, reads that fall partly or entirely within an intron.
  • - Exon. From the total gene reads, reads that fall entirely within an exon or in an exon-exon junction.
  • - - Exon. From the total gene - exon reads, reads that map completely within an exon
  • - - Exon-exon. From the total gene - exon reads, reads that map across an exon junction as specified in figure 31.43 .
  • Intergenic. All reads that map partly or entirely between genes.
  • Total. Total amount of reads for a particular type.

• Counted UMI fragments by type. Divides the distinct UMI fragments that are counted into different types, e.g., uniquely mapped, non-specifically mapped, mapped. The table contains the same rows as the 'Counted fragments by type' table (see above). It is only included in the report if the Library type setting is 3' sequencing and if the input reads are single end reads annotated with UMIs by tools of the Biomedical Genomics Analysis plugin.

Distribution of biotypes

Table generated from biotype annotations present on the input gene or mRNA tracks. If using both gene and mRNA tracks, the biotypes in the report are taken from the mRNA track.

• For genes, biotypes can be any of the following columns: "gene_biotype", "biotype", "gbkey", "type". The first one in this list is chosen.
• For transcripts, biotypes can be any of the following columns: "transcript_biotype", "biotype", "gbkey", "type". The first one in this list is chosen.

The biotypes are "as a percentage of all transcripts" or "as a percentage of all genes". For a poly-A enrichment experiment, it is expected that the majority of reads correspond to protein-coding regions. For an rRNA depletion protocol, a variety of non-coding RNA regions may also be observed. The percentage of reads mapping to rRNA should usually be <15%.

If over 15% of the reads mapped to rRNA, it could be that the poly-A enrichment/rRNA depletion protocol failed. The sample can still be used for differential expression and variant calling, but expression values such as TPM and RPKM may not be comparable to those of other samples. To troubleshoot the issues in future experiments, check for rRNA depletion prior to library preparation. Also, if an rRNA depletion kit was used, check that the kit matches the species being studied.

Gene/transcript length coverage

Plot showing the normalized coverage across a gene/transcript body for four different groupings of gene/transcript length (figure 31.49).

Figure 31.52: Gene/transcript length coverage plot.

To generate this plot, every transcript is rescaled to have a length of 100. For every read that is assigned to a transcript, we get its start and end coordinates in this "transcript-length-normalized" coordinate system [0,100]. We then increment counters from the read start position to the read end position. After all the reads have been counted, the average 5' count is the average value of the counters at position 0,1,2...49. The average 3' count is the value at positions 51,52,53...100. The difference between average 3' and 5' normalized counts is the difference between these values as a percentage of the maximum number of counts seen at any position.

The lines should be flat in the center of the plot, and the plot should be approximately symmetric. An erratic line may indicate that there are few genes/transcripts in the given length range. Lines showing normalized count higher on the 3'end indicates the presence of polyA tails in the reads, consequence of degraded RNAs. Future experiments may benefit from using an rRNA depletion protocol.

In the table below the plot, a difference between average 3' and 5' normalized counts higher than 25 warns that variants may not be called in low coverage regions, and that TPM or RPKM values may be unreliable. Most transcripts are <10000 bp long, so a warning is raised if many reads map to features longer than this. One possible cause is that no mRNA track has been provided for an organism with extensive splicing.

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