• Manuals

Browse the manual

• Welcome to CLC Cancer Research Workbench
  • Introduction to CLC Cancer Research Workbench
  • Available documentation
  • The material covered by this manual
  • We welcome your comments and suggestions
  • Contact information
• Introduction to user interface, workflows, and tracks
  • The start screen
    • The getting started table
    • Import of example data
  • The user interface
    • The Toolbox
  • Workflows - an overview
  • The track format
    • Track types
    • The Genome Browser
• Getting started
  • Reference data
    • The Workbench Reference data location
    • Space requirements
    • Where reference data is downloaded from
    • Download and configure reference data
    • Troubleshooting reference data downloads
  • Create new folder
  • Import data
    • How to import data
• Preparing Raw Data
  • Prepare sequencing data - all application types
    • Import adapter trim list
    • How to run the 'Prepare Overlapping Raw Data' ready-to-use workflow
    • How to run the 'Prepare Raw Data' ready-to-use workflow
    • Output from the Prepare Overlapping Raw Data and Prepare Raw Data workflows
    • How to check the output reports
  • Analysis of sequencing data
• Whole genome sequencing (WGS)
  • Automatic analysis of sequencing data (WGS)
  • Identify Variants (WGS)
    • How to run the 'Identify Variants' ready-to-use workflow
    • Output from the Identify Variants workflow
  • Annotate Variants (WGS)
  • Filter Somatic Variants (WGS)
  • Identify Somatic Variants from Tumor Normal Pair (WGS)
  • Identify Known Variants in One Sample (WGS)
    • Import your known variants
    • Import your targeted regions
    • How to run the 'Identify Known Variants in One Sample' ready-to-use workflow
    • Output from the Identify Known Variants in One Sample
• Whole exome sequencing (WES)
  • Automatic analysis of sequencing data (WES)
  • Identify Variants (WES)
    • Import your targeted regions
    • How to run the 'Identify Variants' ready-to-use workflow
    • Output from the Identify Variants workflow
  • Annotate Variants (WES)
  • Filter Somatic Variants (WES)
  • Identify Somatic Variants from Tumor Normal Pair (WES)
    • Import your targeted regions
    • How to run the 'Identify Somatic Variants from Tumor Normal Pair' ready-to-use workflow
  • Identify Known Variants in One Sample (WES)
    • Import your known variants
    • Import your targeted regions
    • How to run the 'Identify Known Variants in One Sample' ready-to-use workflow
    • Output from the Identify Known Variants in One Sample
  • Identify and Annotate Variants (WES)
    • Import your targeted regions
    • How to run the 'Identify and Annotate Variants' ready-to-use workflow
    • Output from the Identify and Annotate Variants workflow
• Targeted amplicon sequencing (TAS)
  • Automatic analysis of sequencing data (TAS)
  • Identify Variants (TAS)
    • Import your targeted regions
    • How to run the 'Identify Variants' ready-to-use workflow
    • Output from the Identify Variants workflow
  • Annotate Variants (TAS)
  • Filter Somatic Variants (TAS)
  • Identify Somatic Variants from Tumor Normal Pair (TAS)
    • Import your targeted regions
    • How to run the 'Identify Somatic Variants from Tumor Normal Pair' ready-to-use workflow
  • Identify Known Variants in One Sample (TAS)
    • Import your known variants
    • Import your targeted regions
    • How to run the 'Identify Known Variants in One Sample' ready-to-use workflow
    • Output from the Identify Known Variants in One Sample
  • Identify and Annotate Variants (TAS)
    • Import your targeted regions
    • How to run the 'Identify and Annotate Variants' ready-to-use workflow
    • Output from the Identify and Annotate Variants workflow
• Whole Transcriptome Sequencing (WTS)
  • Automatic analysis of RNA-seq data
  • Analysis of multiple samples
  • Annotate Variants (WTS)
  • Compare variants in DNA and RNA
  • Identify Candidate Variants and Genes from Tumor Normal Pair
  • Identify variants and add expression values
  • Identify and Annotate Differentially Expressed Genes and Pathways
• How to edit application workflows
  • Introduction to customized data analysis
  • How to edit preinstalled workflows
• Using data from other workbenches
  • Open outputs from other workbenches
• Plugins
• Appendix
  • Workflows
  • Reference data overview
  • Mini dictionary
• Bibliography

Identify Somatic Variants from Tumor Normal Pair (WGS)

The "Identify Somatic Variants from Tumor Normal Pair (WGS)" ready-to-use workflow can be used to identify potential somatic variants in a tumor sample when you also have a normal/control sample from the same patient.

When running the "Identify Somatic Variants from Tumor Normal Pair (WGS)" the reads are mapped and the variants identified. An internal workflow removes germline variants that are found in the mapped reads of the normal/control sample and variants outside the target region are removed as they are likely to be false positives due to non-specific mapping of sequencing reads. Next, remaining variants are annotated with gene names, amino acid changes, conservation scores and information from clinically relevant databases like COSMIC (known cancer associated variants) and ClinVar (variants with clinically relevant association). Finally, information from dbSNP is added to see which of the detected variants have been observed before and which are completely new.

-dup1How to run the "Identify Somatic Variants from Tumor Normal Pair" ready-to-use workflow

1. Go to the toolbox and double-click on the "Identify Somatic Variants from Tumor Normal Pair" ready-to-use workflow (figure 5.21).

   
   Figure 5.21: The ready-to-use workflows are found in the toolbox.

   This will open the wizard shown in figure 5.22 where you can select the tumor sample reads.

   
   Figure 5.22: Select the tumor sample reads.

   When you have selected the tumor sample reads click on the button labeled Next.

2. In the next wizard step (figure 5.23), please specify the normal sample reads.

   
   Figure 5.23: Select the normal sample reads.

3. When you have selected the sample(s) you wish to analyze, click on the button labeled Next. This and the following step allow you to restrict the calling of InDels and structural variants to targeted regions in case you would like to focus on only a parts of your whole genome sequencing data. If you would like to use the full data set, you can click on the button labeled Next to go to the next wizard step (figure 5.24).

   
   Figure 5.24: Specify a target regions track if you would like to restrict the analysis to only parts of the whole genome sequencing data set, otherwise click on the button labeled "Next".

4. This step allows to specify a target regions track for the tumor sample in case you would like to restrict the analysis to only parts of the whole genome sequencing data set (figure 5.25).

   
   Figure 5.25: Specify a target regions track if you would like to restrict the analysis to only parts of the whole genome sequencing data set, otherwise click on the button labeled "Next".

5. Click on the button labeled Next to go to the next wizard step (figure 5.26).

   
   Figure 5.26: Specify the settings for the variant detection.

   In this wizard step you can adjust the settings used for variant detection. For a description of the different parameters that can be adjusted in the variant detection step, we refer to the description of the "Low Frequency Variant Detection" tool in the CLC Cancer Research Workbench user manual (http://www.clcsupport.com/clccancerresearchworkbench/current/index.php?manual=Low_Frequency_Variant_Detection.html). As general filters are applied to the different variant detectors that are available in CLC Cancer Research Workbench, the description of the filters are found in a separate section called "Filters" (see http://www.clcsupport.com/clccancerresearchworkbench/current/index.php?manual=Variant_Detectors_filters.html). If you click on "Locked Settings", you will be able to see all parameters used for variant detection in the ready-to-use workflow.

6. Click on the button labeled Next to go to the step where you can adjust the settings for removal of germline variants (figure 5.27)..

   
   Figure 5.27: Specify setting for removal of germline variants.

7. Click on the button labeled Next.

   In the next wizard step you can check the selected settings by clicking on the button labeled Preview All Parameters (figure 5.28).

   
   Figure 5.28: Check the parameters and save the results.

   In the Preview All Parameters wizard you can only check the settings, it is not possible to make any changes at this point. At the bottom of this wizard there are two buttons regarding export functions; one button allows specification of the export format, and the other button (the one labeled "Export Parameters") allows specification of the export destination. When selecting an export location, you will export the analysis parameter settings that were specified for this specific experiment.

8. Click on the button labeled OK to go back to the previous wizard step and choose Save.

   Note! If you choose to open the results, the results will not be saved automatically. You can always save the results at a later point.

Six different outputs are generated:

1. Read Mapping Tumor () The mapped sequencing reads for the tumor sample. The reads are shown in different colors depending on their orientation, whether they are single reads or paired reads, and whether they map unambiguously. For the color codes please see the description of sequence colors in the CLC Genomics Workbench manual that can be found here: http://www.clcsupport.com/clcgenomicsworkbench/current/index.php?manual=View_settings_in_Side_Panel.html.
2. Read Mapping Normal () The mapped sequencing reads for the normal sample. The reads are shown in different colors depending on their orientation, whether they are single reads or paired reads, and whether they map unambiguously. For the color codes please see the description of sequence colors in the CLC Genomics Workbench manual that can be found here: http://www.clcsupport.com/clcgenomicsworkbench/current/index.php?manual=View_settings_in_Side_Panel.html.
3. Mapping Report Tumor () The report consists of a number of tables and graphs that in different ways provide information about the mapped reads from the tumor sample.
4. Mapping Report Normal () The report consists of a number of tables and graphs that in different ways provide information about the mapped reads from the normal sample.
5. Annotated Somatic Variants () A variant track holding the identified and annotated somatic variants. The variants can be shown in track format or in table format. When holding the mouse over the detected variants in the Genome Browser view a tooltip appears with information about the individual variants. You will have to zoom in on the variants to be able to see the detailed tooltip.
6. Genome Browser View Tumor Normal Comparison () A collection of tracks presented together. Shows the annotated variants track together with the human reference sequence, genes, transcripts, coding regions, the mapped reads for both normal and tumor, the annotated somatic variants, information from the ClinVar and COSMIC databases, and finally a track showing the conservation score (see figure 5.29).

Figure 5.29: The Genome Browser View presents all the different data tracks together and makes it easy to compare different tracks.

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