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• Introduction
  • The concept of CLC Single Cell Analysis Module
  • Contact information
  • System requirements
  • Installing modules
    • Licensing modules
    • Uninstalling modules
  • Installing server extensions
    • Licensing server extensions
• Reference data management
  • QIAGEN Sets
• Running tools and workflows
• Data import
  • Import Cell Annotations
  • Import Cell Clusters
  • Import Cell Clonotypes
  • Import Expression Matrix
    • HDF5 formats
    • Other formats
  • Import Peak Count Matrix
  • Import Space Ranger
  • Cell format in importers
  • Import Immune Reference Segments
    • IMSEQ
    • IMGT
    • Output from Import Immune Reference Segments
• Data export
  • Export Cell Ranger HDF5 Expression Matrix
  • Export AnnData Expression Matrix
  • Export h5Seurat Expression Matrix
  • Export Loom Expression Matrix
  • Export MEX Expression Matrix
  • Export TXT Expression Matrix
  • Export Peak Count Matrix
• Prepare Reads
  • Annotate Single Cell Reads
    • Setting the sample name
    • Interpreting the output of Annotate Single Cell Reads
• Creating a Gene Expression Matrix
  • Single Cell RNA-Seq Analysis
    • The Single Cell RNA-Seq Analysis report
    • The Single Cell RNA-Seq Analysis algorithm
  • QC for Single Cell
    • Empty droplets filter
    • Count-based and extra-chromosomal filters
    • Doublets filter
    • Interpreting the output of QC for Single Cell
    • Choosing barcodes to retain
    • The cell calling algorithm
    • The doublet calling algorithm
  • Normalize Single Cell Data
    • When is batch correction appropriate?
    • Interpreting the output of Normalize Single Cell Data
    • The Normalize Single Cell Data algorithm
• Cell Type Classification
  • Browse QIAGEN Cell Ontology
  • Predict Cell Types
    • Interpreting the output of Predict Cell Types
    • Cell type refinement
  • Train Cell Type Classifier
    • Features used for training and prediction
    • Interpreting the output of Train Cell Type Classifier
    • SVMs for cell type classification
  • Update Cell Type Classifier
  • The Cell Type Classifier element
• Expression Analysis
  • Differential Expression for Single Cell
    • Interpreting the output of Differential Expression for Single Cell
    • The differential expression algorithm
  • Create Expression Plot
    • The Heat Map output of Create Expression Plot
    • The Dot Plot output of Create Expression Plot
    • The Violin Plot output of Create Expression Plot
• Velocity Analysis
  • Single Cell Velocity Analysis
    • Interpreting the output of Single Cell Velocity Analysis
    • The velocity estimation algorithm
  • Differential Velocity for Single Cell
  • Score Velocity Genes
    • Interpreting the output of Score Velocity Genes
  • Create Phase Portrait Plot
  • Velocity analysis in workflows
• Spatial Transcriptomics
  • The Spatial Transcriptomics Plot element
• Chromatin Accessibility
  • Single Cell ATAC-Seq Analysis
    • Interpreting the output of Single Cell ATAC-Seq Analysis
    • The report output from Single Cell ATAC-Seq Analysis
    • The Single Cell ATAC-Seq Analysis algorithm
  • Split Read Mapping by Cell
  • Differential Accessibility for Single Cell
    • The differential accessibility algorithm
• Immune Repertoire
  • Single Cell V(D)J-Seq Analysis
    • The report output from Single Cell V(D)J-Seq Analysis
    • The clonotype identification algorithm
  • The Cell Clonotypes element
    • Primary and secondary clonotypes
    • Cell Clonotypes tables
    • Cell Clonotypes alignments
    • Cell Clonotypes Sankey plot
  • Filter Cell Clonotypes
  • Combine Cell Clonotypes
  • Compare Cell Clonotypes
    • Interpreting the output of Compare Cell Clonotypes
  • Convert Clonotypes to Cell Annotations
• Noise reduction through feature selection and dimensionality reduction
  • Feature selection and dimensionality reduction
    • Calculation of estimated biological variation
• Cell Annotation
  • Cluster Single Cell Data
    • The Cluster Single Cell Data algorithm
  • Create Heat Map for Cell Abundance
    • Interpreting the output of Create Heat Map for Cell Abundance
  • Create Cell Annotations from Hashtags
• Dimensionality reduction
  • UMAP for Single Cell
  • tSNE for Single Cell
• Single cell low-dimensional plots functionality
  • Manual annotation
  • Visualizing different types of matrices
  • Create Subset
  • Extract to Table
  • Launching of Create Expression Plot
  • Launching of Create Heat Map for Cell Abundance
  • Launching of Differential Accessibility for Single Cell
  • Launching of Differential Expression for Single Cell
  • Launching of Differential Velocity for Single Cell
  • Launching of Score Velocity Genes
• Utility tools
  • Combine Cell Annotations
  • Update Cell Annotations
  • Convert Metadata to Cell Annotations
  • Combine Cell Clusters
  • Update Cell Clusters
  • Add Information to Plot
  • Update Single Cell Sample Name
• Single cell template workflows from reads
  • Expression Analysis from Reads
    • Configuring the batch units for Expression Analysis from Reads
    • Output from Expression Analysis from Reads
  • Chromatin Accessibility Analysis from Reads
    • Configuring the batch units for Chromatin Accessibility Analysis from Reads
    • Output from Chromatin Accessibility Analysis from Reads
  • Chromatin Accessibility and Expression Analysis from Reads
    • Configuring the batch units for Chromatin Accessibility and Expression Analysis from Reads
    • Output from Chromatin Accessibility and Expression Analysis from Reads
    • Importing reads
  • Immune Repertoire Analysis from Reads (10xV(D)J)
    • Output from Immune Repertoire Analysis from Reads (10xV(D)J)
  • Immune Repertoire and Expression Analysis from Reads (10xV(D)J)
    • Configuring the batch units for Immune Repertoire and Expression Analysis from Reads (10xV(D)J)
    • Output from Immune Repertoire and Expression Analysis from Reads (10xV(D)J)
• Single cell template workflows from imported data
  • Expression Analysis from Matrix
    • Output from Expression Analysis from Matrix
  • Chromatin Accessibility and Expression Analysis from Matrix
    • Output of Chromatin Accessibility and Expression Analysis from Matrix
  • Immune Repertoire and Expression Analysis from Clonotypes and Matrix
    • Output from Immune Repertoire and Expression Analysis from Clonotypes and Matrix
  • Importing data
• Bibliography

IMGT

For the IMGT format, the header contains 15 elements, separated by "|". Only the following are read and used during import:

• (1) Accession number(s).
• (2) The segment name, including chain, segment type, ID and allele, in the format: <chain><type><ID>*<allele>, for example "TRAV1*01".

  Chain and segment type are the same as for IMSEQ. For B cells constant genes, the segment type contains instead the letter corresponding to the encoded isotype.

• (3) Species.
• (4) Allele functionality: F (functional), P (pseudogene) or ORF (open reading frame).
• (5) Extracted label(s): EX1, CH1 and C-REGION for C segments, and V-REGION, D-REGION, J-REGION for V, D, J segments, respectively.
• (8) The start of the codon, counting from 1, or "NR" for non coding labels.
• (9) The number of nucleotides added in 5' in the format +n.

The IMGT database contains chains, segment types and labels that are not listed above and are not supported. These are silently ignored.

When importing files in the IMGT format, the following options are available (see figure 4.13):

• Which allele functionality(ies) should be imported. At least one must be chosen.
• Which species should be imported. After choosing the fasta file, the desired species can be chosen from the list of species identified in the file.

If element (9) in the header is not empty, the corresponding number of nucleotides are removed from the 5' end of the sequence.

Identification of the conserved amino acid

The nucleotide sequence (with IMGT gaps for the V segments), starting from position in element (8) in the header, is first translated to amino acids using the standard genetic code. The position of the conserved amino acid is calculated, and, if identified, translated to the position of the first nucleotide in the corresponding codon. Segments where the amino acid cannot be identified are silently ignored.

For the V segments, the amino acid position is calculated as follows:

• If the amino acid at position 104 is C, then position 104 is used.
• Otherwise, the position of the last occurrence of C after position 104 is used, if present.
• Otherwise, if the amino acid at position 104, 105 or 103 (in this order) is one base pair mutation away from C and not a stop codon (i.e. R, S, C, F, G, W, Y), then this position is used.

For the J segments, all 3 open reading frames (starting from nucleotide position 1, 2 or 3) are used. Note that "." below denotes any amino acid. The amino acid position is calculated as follows:

• The amino acid sequence "(F|W)G.G", if present, is identified.
  • The open reading frame that contains the amino acid sequence, no stop codon and has the lowest nucleotide starting position, if any, is used.
  • Otherwise, the open reading frame that contains the amino acid sequence and at least one stop codon, if any, is used. If multiple open reading frames match this criteria, none are used.
• Otherwise, the amino acid sequences "(F|W)X.G" and "(F|W)G.X", if present, are identified. Here, X denotes the amino acids that are one base pair mutation away from F/W and not a stop codon (i.e. A, R, S, C, D, E, V, W).
  • For each of the two amino acid sequences, the position is calculated as above.
  • If both amino acid sequences are present, the position that is closest to the end of the sequence is used.

V and J segments for which the amino acid position cannot be successfully identified are silently ignored.

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