Assay design considerations, Some key design considerations, Universal sybr – Bio-Rad SsoAdvanced™ Universal SYBR® Green Supermix User Manual

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SsoAdvanced

™

Universal SYBR

®

Green Supermix Instruction Manual

| 3

Assay Design Considerations

When using custom designed assays, several important considerations should be noted:

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Biological significance (correct isoform/splice variant chosen)

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Sequence quality and secondary structure — evaluate using web-based tools to understand
the complexity of the structure, as it can impact the reaction performance

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Sequence length — use the entire gene sequence, or a specific region of interest, to
optimally design an assay

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Sequence masking — use web-based masking tools to mask low complexity and repetitive
regions to avoid assay design in these regions

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Uniqueness of the sequence — use BLAST or BLAT to ensure no homology exists and help
avoid mispriming events

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Uniqueness of the assay — use in silico PCR, or Primer-BLAST, to “blast” the primers against
the genome of interest to validate primer design specificity

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Default settings in the software — ensure they are set correctly (for example, salt conditions,
oligo and amplicon sizes). The SsoAdvanced

™

universal SYBR

®

Green supermix and the

qPCR cycling protocols have been optimized for assays with a primer melting temperature
(T

m

) of 60ºC designed using the open source Primer3, Primer3Plus or Primer-BLAST, default

settings. For assays designed using other tools, the primer T

m

should be recalculated using

Primer3. Suggested settings: 50 mM Na

+

, 3 mM Mg

++

, 1.2 mM dNTPs, 250 nM annealing

oligo, SantaLucia/SantaLucia

Some Key Design Considerations

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For optimal PCR efficiency, design the amplicon size between 70 and 150 bp (<70 bp may be
needed for degraded/FFPE templates)

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Maintain primer lengths between 18 and 22 bp for good specificity and binding abilities

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Annealing temperatures between 58 and 62ºC are optimal (greater range can be obtained
using Bio-Rad’s Sso7d-based supermixes); temperatures >60ºC may result in less binding
efficiency and <58ºC may result in less specificity

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The optimal amplicon GC content should be within 40–60% (greater range can be obtained
using Bio-Rad’s Sso7d-based supermixes)

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Avoiding primer secondary structures reduces potential primer-dimer issues

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Avoid mispriming by ensuring there are no more than 2 Gs or Cs in the last 5 bases on the 3'
end of the primer

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Design your assay such that at least one primer spans an exon:exon junction site to avoid
gDNA amplification

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Alternatively, design the assay such that the primers are in separate exons and the intron
size is >1 kb

Tips to Get Started:

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Always evaluate the performance of the supermix following the recommended reaction and
cycling conditions prior to modification

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Be sure to set the activation time to 30 sec for cDNA and 2–3 min for genomic DNA

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The 2x supermix has been optimized for 20 µl reactions in 96-well plates and 10 µl reactions
in 384-well plates