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• Introduction to CLC Main Workbench
  • Contact information and citation
  • Download and installation
    • General information about installing and upgrading Workbenches
    • 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
• 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 and removing locations
    • Data sharing information
    • Create new folders
    • Multiselecting elements
    • Copying and moving elements and folders
    • Change element names
    • Delete, restore and remove elements
    • Show folder elements in a table
  • Working with non-CLC format files
  • 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
  • Backing up data from the CLC Workbench
• User preferences and settings
  • General preferences
  • View preferences
  • 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
    • CLC Server data import and export
  • AWS Connections
• Import of data and graphics
  • Standard import
• Export of data and graphics
  • 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
    • GFF3 export
    • JSON export
    • Graphics export
    • Export history
  • Export graphics to files
    • File formats
  • Export graph data points to a file
  • Copy/paste view output
• Working with tables
  • Table view settings and column ordering
  • Filtering tables
• 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
  • Sequence web info
• 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
  • 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
• 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
• 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
• 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
  • Download 3D Protein Structure Database
  • 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
• Sequencing data analyses and Assembly
  • 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
    • Extracting reads from mappings
    • Variance table
  • Reassemble contig
  • Secondary peak calling
  • Extract Consensus Sequence
• Primers and probes
  • 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
• Cloning and restriction sites
  • 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
• 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
• Expression 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
• 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
• Utility tools
  • Extract Annotated Regions
  • Combine Reports
    • Combine Reports output
  • Modify Report Type
    • Modifying report types in workflows
  • Create Sequence List
  • Update Sequence Attributes in Lists
  • Split Sequence List
  • Rename Elements
  • Rename Sequences in Lists
• Appendix
  • 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
  • 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
  • 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

Primer Parameters

In this preference group a number of criteria can be set, which the selected primers must meet. All the criteria concern single primers, as primer pairs are not generated until the Calculate button is pressed. Parameters regarding primer and probe sets are described in detail for each reaction mode (see Standard PCR, Nested PCR, TaqMan or Sequencing primers).

• Length. Determines the length interval within which primers can be designed by setting a maximum and a minimum length. The upper and lower lengths allowed by the program are 50 and 10 nucleotides respectively.
• Melting temperature. Determines the temperature interval within which primers must lie. When the Nested PCR or TaqMan reaction type is chosen, the first pair of melting temperature interval settings relate to the outer primer pair i.e. not the probe. Melting temperatures are calculated by a nearest-neighbor model which considers stacking interactions between neighboring bases in the primer-template complex. The model uses state-of-the-art thermodynamic parameters [SantaLucia, 1998] and considers the important contribution from the dangling ends that are present when a short primer anneals to a template sequence [Bommarito et al., 2000]. A number of parameters can be adjusted concerning the reaction mixture and which influence melting temperatures (see below). Melting temperatures are corrected for the presence of monovalent cations using the model of [SantaLucia, 1998] and temperatures are further corrected for the presence of magnesium, deoxynucleotide triphosphates (dNTP) and dimethyl sulfoxide (DMSO) using the model of [von Ahsen et al., 2001].
• Inner melting temperature. This option is only activated when the Nested PCR or TaqMan mode is selected. In Nested PCR mode, it determines the allowed melting temperature interval for the inner/nested pair of primers, and in TaqMan mode it determines the allowed temperature interval for the TaqMan probe.
• Advanced parameters. A number of less commonly used options
  • Buffer properties. A number of parameters concerning the reaction mixture which influence melting temperatures.
    • Primer concentration. Specifies the concentration of primers and probes in units of nanomoles (). Note that in the case of a mix of primers, the concentration here refers to the individual primer and not the combined primers concentration.
    • Salt concentration. Specifies the concentration of monovalent cations (, and equivalents) in units of millimoles ()
    • Magnesium concentration. Specifies the concentration of magnesium cations () in units of millimoles ()
    • dNTP concentration. Specifies the combined concentration of all deoxynucleotide triphosphates in units of millimoles ()
    • DMSO concentration. Specifies the concentration of dimethyl sulfoxide in units of volume percent ()
  • GC content. Determines the interval of CG content (% C and G nucleotides in the primer) within which primers must lie by setting a maximum and a minimum GC content.
  • Self annealing. Determines the maximum self annealing value of all primers and probes. This determines the amount of base-pairing allowed between two copies of the same molecule. The self annealing score is measured in number of hydrogen bonds between two copies of primer molecules, with A-T base pairs contributing 2 hydrogen bonds and G-C base pairs contributing 3 hydrogen bonds.
  • Self end annealing. Determines the maximum self end annealing value of all primers and probes. This determines the number of consecutive base pairs allowed between the 3' end of one primer and another copy of that primer. This score is calculated in number of hydrogen bonds (the example below has a score of 4 - derived from 2 A-T base pairs each with 2 hydrogen bonds).

    AATTCCCTACAATCCCCAAA
                      ||
      AAACCCCTAACATCCCTTAA
    

    .
  • Secondary structure. Determines the maximum score of the optimal secondary DNA structure found for a primer or probe. Secondary structures are scored by the number of hydrogen bonds in the structure, and 2 extra hydrogen bonds are added for each stacking base-pair in the structure.
• 3' end G/C restrictions. When this checkbox is selected it is possible to specify restrictions concerning the number of G and C molecules in the 3' end of primers and probes. A low G/C content of the primer/probe 3' end increases the specificity of the reaction. A high G/C content facilitates a tight binding of the oligo to the template but also increases the possibility of mispriming. Unfolding the preference groups yields the following options:
  • End length. The number of consecutive terminal nucleotides for which to consider the C/G content
  • Max no. of G/C. The maximum number of G and C nucleotides allowed within the specified length interval
  • Min no. of G/C. The minimum number of G and C nucleotides required within the specified length interval
• 5' end G/C restrictions. When this checkbox is selected it is possible to specify restrictions concerning the number of G and C molecules in the 5' end of primers and probes. A high G/C content facilitates a tight binding of the oligo to the template but also increases the possibility of mis-priming. Unfolding the preference groups yields the same options as described above for the 3' end.
• Mode. Specifies the reaction type for which primers are designed:
  • Standard PCR. Used when the objective is to design primers, or primer pairs, for PCR amplification of a single DNA fragment.
  • Nested PCR. Used when the objective is to design two primer pairs for nested PCR amplification of a single DNA fragment.
  • Sequencing. Used when the objective is to design primers for DNA sequencing.
  • TaqMan. Used when the objective is to design a primer pair and a probe for TaqMan quantitative PCR.

  Each mode is described further in Standard PCR, Nested PCR, TaqMan and Sequencing primers.

• Calculate. Pushing this button will activate the algorithm for designing primers

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