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• Introduction
  • The concept of Biomedical Genomics Analysis
  • System requirements
  • Contact information
• Data import and export
• Reference Data Management
  • QIAGEN Sets
• SARS-CoV-2 workflows
  • Identify QIAseq SARS-CoV-2 Low Frequency and Shared Variants (Illumina)
  • Identify Ion AmpliSeq SARS-CoV-2 Low Frequency and Shared Variants (Ion Torrent)
  • SARS-CoV-2 workflow output
    • Summary outputs
    • Sample specific outputs
• QIAseq Panel Analysis
  • The Analyze QIAseq Panels guide
    • Import your reads
    • Start a QIAseq panel analysis
    • Upload to QCI Interpret
  • How to create a custom panel analysis workflow
    • Import QIAGEN Primers
  • Create a custom Trim adapter list (optional)
• Targeted DNA
  • The Identify QIAseq DNA Variants ready-to-use workflows
    • Output from the Identify QIAseq DNA Variants workflows
    • Quality Control for the Identify QIAseq DNA Variants workflow
    • Identify QIAseq DNA Somatic and Germline Variants from Tumor Normal Pair (Illumina)
    • Output from the Identify QIAseq DNA Somatic and Germline Variants from Tumor Normal Pair (Illumina) workflow
  • Create QIAseq DNA CNV Control Mapping workflows
    • Output from the Create QIAseq DNA CNV Control Samples workflow
  • The Identify TMB Status ready-to-use workflows
    • Output from the Identify TMB Status workflow
  • The Detect QIAseq MSI Status ready-to-use workflow
    • Output of the Detect QIAseq MSI Status workflow
  • Detect MSI Status with Baseline Creation ready-to-use workflow
  • Targeted DNA tools detailed description
    • Annotate Structural Variants
    • Convert Annotation Track Coordinates
    • Calculate TMB Score
    • Detect MSI Status
    • Extract Reads Matching Primers
    • Generate MSI Baseline
    • Refine Read Mapping
    • Remove and Annotate with Unique Molecular Index
    • Calculate Unique Molecular Index Groups
    • Create UMI Reads from Grouped Reads
    • Create UMI Reads from Reads
    • Remove Ligation Artifacts
    • Trim Primers of Mapped Reads
    • Identify Mispriming Events
    • Annotate Variants with Unique Molecular Index Info
    • Prepare Guidance Variant Track
    • Import Gene-Pseudogene Table
• Targeted RNAscan
  • The Detect QIAseq RNAscan Fusions ready-to-use workflow
    • Output from the Detect QIAseq RNAscan Fusions workflow
  • The Perform QIAseq RNA Fusion XP Analysis ready-to-use workflow
    • Output from the Perform QIAseq RNA Fusion XP Analysis workflow
  • Interpretation of fusion results
  • Targeted RNAscan tools detailed description
    • Detect and Refine Fusion Genes
    • Annotate Fusions with Known Fusion Information
    • QC for RNAscan Panels
    • Annotate RNA Variants
    • Import Known Fusion Information Track
• Immune Repertoire
  • Perform QIAseq Immune Repertoire Analysis ready-to-use workflow
    • Output from the Perform QIAseq Immune Repertoire Analysis workflow
  • QIAseq Immune Repertoire Expert Tools
    • Immune Repertoire Analysis
    • Compare Immune Repertoires
• Targeted Multimodal
  • Perform QIAseq Multimodal Analysis (Illumina) ready-to-use workflow
    • Output from the Perform QIAseq Multimodal Analysis (Illumina)
  • Perform QIAseq Multimodal Analysis with TMB and MSI (Illumina) ready-to-use workflow
    • Output from the Perform QIAseq Multimodal Analysis with TMB and MSI (Illumina)
  • Running the workflows in batch using Metadata
• Targeted RNA
  • The Quantify QIAseq RNA Expression ready-to-use workflow
    • Output from the Quantify QIAseq RNA Expression workflow
  • Targeted RNA tools detailed description
    • The Quantify QIAseq RNA tool
• UPX 3'
  • Demultiplex QIAseq UPX 3' reads
  • The Quantify QIAseq UPX 3' ready-to-use workflow
    • Output from the Quantify QIAseq UPX 3' workflow
• Exome
  • Identify QIAseq Exome Germline Variants
    • Output from the Identify QIAseq Exome Germline Variants ready-to-use workflow
  • Create QIAseq Exome CNV Control Mapping
    • Output from the Create QIAseq Exome CNV Control Mapping workflow
  • Identify QIAseq Exome Causal Inherited Variants in Trio
    • Output from the Identify QIAseq Exome Causal Inherited Variants in Trio ready-to-use workflow
• Targeted Methyl
  • The Detect QIAseq Methylation ready-to-use workflow
    • Output from the Detect QIAseq Methylation workflow
  • Targeted Methyl associated tools
    • Finding differentially methylated regions
    • Create Methylation Level Heat Map
• QCI Interpret Integration
  • Configuration of the Upload to QCI Interpret tool
  • The Upload to QCI Interpret tool
• QIAseq miRNA Analysis
  • QIAseq miRNA Quantification
    • QIAseq miRNA Quantification outputs
    • Naming isomiRs
  • QIAseq miRNA Differential Expression
  • QIAseq miRNA Expert Tools
    • Create UMI Reads for miRNA
• TruSight Oncology 500
  • The Perform TSO500 DNA Analysis (Illumina) workflow
    • Output from the Perform TSO500 DNA Analysis
  • The Perform TSO500 RNA Analysis (Illumina) workflow
    • Output from the Perform TSO500 RNA Analysis
• QIAGEN GeneRead DNA Panel Analysis
  • The QIAGEN GeneRead Panel Analysis workflow
    • Output from the QIAGEN GeneRead Panel Analysis
  • Trim Primers and their Dimers from Mapping
• Ready-to-use workflows descriptions and guidelines
  • General Workflow
  • Somatic Cancer
  • Hereditary Disease
• Getting started
  • Import sequencing data
  • Prepare Raw Data
• Whole genome sequencing (WGS)
  • General Workflows (WGS)
    • Annotate Variants (WGS)
    • Identify Known Variants in One Sample (WGS)
  • Somatic Cancer (WGS)
    • Filter Somatic Variants (WGS)
    • Identify Somatic Variants from Tumor Normal Pair (WGS)
    • Identify Variants (WGS)
  • Hereditary Disease (WGS)
    • Filter Causal Variants (WGS-HD)
    • Identify Causal Inherited Variants in Family of Four (WGS)
    • Identify Causal Inherited Variants in Trio (WGS)
    • Identify Rare Disease Causing Mutations in Family of Four (WGS)
    • Identify Rare Disease Causing Mutations in Trio (WGS)
    • Identify Variants (WGS-HD)
• Whole exome sequencing (WES)
  • General Workflows (WES)
    • Annotate Variants (WES)
    • Annotate Variants with Effect Scores (WES)
    • Identify Known Variants in One Sample (WES)
  • Somatic Cancer (WES)
    • Filter Somatic Variants (WES)
    • Identify Somatic Variants from Tumor Normal Pair (WES)
    • Identify Variants (WES)
    • Identify and Annotate Variants (WES)
  • Hereditary Disease (WES)
    • Filter Causal Variants (WES-HD)
    • Identify Causal Inherited Variants in Family of Four (WES)
    • Identify Causal Inherited Variants in Trio (WES)
    • Identify Rare Disease Causing Mutations in Family of Four (WES)
    • Identify Rare Disease Causing Mutations in Trio (WES)
    • Identify Variants (WES-HD)
    • Identify and Annotate Variants (WES-HD)
• Targeted amplicon sequencing (TAS)
  • General Workflows (TAS)
    • Annotate Variants (TAS)
    • Identify Known Variants in One Sample (TAS)
  • Somatic Cancer (TAS)
    • Filter Somatic Variants (TAS)
    • Identify Somatic Variants from Tumor Normal Pair (TAS)
    • Identify Variants (TAS)
    • Identify and Annotate Variants (TAS)
  • Hereditary Disease (TAS)
    • Filter Causal Variants (TAS-HD)
    • Identify Causal Inherited Variants in Family of Four (TAS)
    • Identify Causal Inherited Variants in Trio (TAS)
    • Identify Rare Disease Causing Mutations in Family of Four (TAS)
    • Identify Rare Disease Causing Mutations in Trio (TAS)
    • Identify Variants (TAS-HD)
    • Identify and Annotate Variants (TAS-HD)
• Whole Transcriptome Sequencing (WTS)
  • 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
• General tools
  • CNV and LOH Detection
    • Region-level CNV track (Region CNVs)
    • Target-level CNV track (Target CNVs)
    • Gene-level annotation track (Gene CNVs)
    • Loss-of-heterozygosity track
    • CNV results report
    • CNV algorithm report
  • Structural Variant Caller
    • Output from the Structural Variant Caller
  • Target Region Coverage Analysis
    • Output from Target Region Coverage Analysis
• Batching workflows
• Legacy tools
  • Detect Fusion Genes
  • Refine Fusion Genes
• Appendices
  • Install and uninstall plugins
    • Installation of plugins
    • Uninstalling plugins
• Bibliography

Identify Causal Inherited Variants in Trio (TAS)

The Identify Causal Inherited Variants in a Trio (TAS) ready-to-use workflow identifies putative disease causing inherited variants by creating a list of variants present in both affected individuals and subtracting all variants in the unaffected individual. The workflow includes a back-check for all family members.

Run the Identify Causal Inherited Variants in a Trio (TAS) workflow

To run the Identify Causal Inherited Variants in a Trio (TAS) workflow, go to:

        Toolbox | Ready-to-Use Workflows | Targeted Amplicon Sequencing () | Hereditary Disease () | Identify Causal Inherited Variants in a Trio (TAS) ()

1. Double-click on the Identify Causal Inherited Variants in a Trio (TAS) tool to start the analysis. If you are connected to a server, you will first be asked where you would like to run the analysis.

2. The sequencing reads from the different family members are specified one at a time in successive dialogs (figure 22.54).

   The sequencing reads from the different family members are specified one at a time in the appropriate window. The panel in the left side of the wizard shows the kind of input that should be provided. Select by double-clicking on the reads file name or click once on the file and then on the arrow pointing to the right side in the middle of the wizard.

   
   Figure 22.54: Specify the sequencing reads for the appropriate family member.

3. Select the targeted region file (figure 22.55).

   The targeted region file is a file that specifies which regions have been sequenced, when working with whole exome sequencing or targeted amplicon sequencing data. This file is something that you must provide yourself, as this file depends on the technology used for sequencing. You can obtain the targeted regions file from the vendor of your targeted sequencing reagents.

   
   Figure 22.55: Select the targeted region file you used for sequencing.

4. Select which reference data set should be used to identify causal inherited variants (figure 22.56).

   
   Figure 22.56: Choose the relevant reference Data Set to identify causal inherited variants.

5. Specify the Hapmap populations that should be used for filtering out variants found in the Hapmap database (figure 22.57).

   
   Figure 22.57: Select the relevant Hapmap population(s).

6. Specify the parameters for the Fixed Ploidy Variant Detection tool for each family member successively (figure 22.58).

   The parameters used by the Fixed Ploidy Variant Detection tool can be adjusted. We have optimized the parameters to the individual analyses, but you may want to tweak some of the parameters to fit your particular sequencing data. A good starting point could be to run an analysis with the default settings.

   
   Figure 22.58: Specify the parameters for the Fixed Ploidy Variant Detection tool.

   The parameters that can be set are:

   • Required variant probability is the minimum probability value of the 'variant site' required for the variant to be called. Note that it is not the minimum value of the probability of the individual variant. For the Fixed Ploidy Variant detector, if a variant site - and not the variant itself - passes the variant probability threshold, then the variant with the highest probability at that site will be reported even if the probability of that particular variant might be less than the threshold. For example if the required variant probability is set to 0.9 then the individual probability of the variant called might be less than 0.9 as long as the probability of the entire variant site is greater than 0.9.
   • Ignore broken pairs: When ticked, reads from broken pairs are ignored. Broken pairs may arise for a number of reasons, one being erroneous mapping of the reads. In general, variants based on broken pair reads are likely to be less reliable, so ignoring them may reduce the number of spurious variants called. However, broken pairs may also arise for biological reasons (e.g. due to structural variants) and if they are ignored some true variants may go undetected. Please note that ignored broken pair reads will not be considered for any non-specific match filters.
   • Minimum coverage: Only variants in regions covered by at least this many reads are called.
   • Minimum count: Only variants that are present in at least this many reads are called.
   • Minimum frequency: Only variants that are present at least at the specified frequency (calculated as 'count'/'coverage') are called.

7. Specify the parameters for the QC for Targeted Sequencing tool for for each family member successively (figure 22.59).

   When working with targeted data (WES or TAS data), quality checks for the targeted sequencing is included in the workflows. Again, you can choose to use the default settings, or you can choose to adjust the parameters.

   
   Figure 22.59: Specify the parameters for the QC for Targeted Sequencing tool.

   The parameters that can be set are:

   • Minimum coverage provides the length of each target region that has at least this coverage.
   • Ignore non-specific matches: reads that are non-specifically mapped will be ignored.
   • Ignore broken pairs: reads that belong to broken pairs will be ignored.

8. In the last wizard step you can check the selected settings by clicking on the button labeled Preview All Parameters. In the Preview All Parameters wizard you can only check the settings, and if you wish to make changes you have to use the Previous button from the wizard to edit parameters in the relevant windows.

9. Choose to Save your results and click on the button labeled Finish.

Output from the Identify Causal Inherited Variants in a Trio (TAS) workflow

The following outputs are generated:

• Reads Tracks One for each family member. The reads mapped to the reference sequence.
• Variants in ... One track for each family member. The variants identified in each of the family members. The variant track can be opened in table view to see all information about the variants.
• Putative Causal Variants in Child The putative disease-causing variants identified in the child. The variant track can be opened in table view to see all information about the variants.
• Gene List with Putative Causal Variants Gene track with the identified putative causal variants in the child. The gene track can be opened in table view to see the gene names.
• Target Region Coverage Report One for each family member. The report consists of a number of tables and graphs that in different ways provide information about the mapped reads from each sample.
• Target Region Coverage One track for each individual. When opened in table format, it is possible to see a range of different information about the targeted regions, such as target region length, read count, and base count.
• An Amino Acid Track Shows the consequences of the variants at the amino acid level in the context of the original amino acid sequence. A variant introducing a stop mutation is illustrated with a red amino acid.
• Track List This is a collection of tracks shown together in a view that makes it easy to compare information from the individual tracks, such as compare the identified variants with the read mappings and information from databases.

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