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Fast qPCR assay optimization and validation techniques for HTS

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American Biotechnologist

Fast qPCR assay optimization and validation techniques for HTS discusses steps for designing a successful qPCR assay, including: 1) Designing primers after running a BLAST search to check for homologous sequences and secondary structures in the target cDNA that could interfere with amplification. 2) Testing primer pairs through a temperature gradient and dilution series to validate the assay's dynamic range before running it hundreds or thousands of times. 3) Choosing an amplicon size between 75-200bp ideally, though larger sizes are possible with new fast reagents. Following these steps at the beginning leads to more effective analysis later.

Health & Medicine
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Fast qPCR assay optimization and validation techniques for HTS Francisco Bizouarn International Field Application Specialist Gene Expression Division Bio-Rad Laboratories
Generating a good assay is easy AMPLIFICATION • Following a few simple steps: – Design assay – Run a gradient – Run a dilution series to validate assay dynamic range • A little extra effort in the beginning will make a tremendous amount of difference in the analysis when the assay is run hundreds or thousands of times. www.bio-rad.com/genomics/pcrsupport
Assay design AMPLIFICATION • Often oversimplified by the use of software or by many companies that offer design services and softwares. • Design a critical parameter. • Following a few simple steps will increase the chances of designing a successful assay. • Let’s use an example: target CCL26 in HUVEC cells www.bio-rad.com/genomics/pcrsupport
CCL26 cDNA sequence AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
Sequence Alignment (BLAST) AMPLIFICATION • Prior to designing primers, it’s a good idea to run a sequence homology analysis. (BLAST) • This allows the identification of sequences that may co- amplify or interfere with our intended target. • The data is freely available, so why not make use of it. • http://blast.ncbi.nlm.nih.gov www.bio-rad.com/genomics/pcrsupport
CCL26 with homologous sequences AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
CCL26 with homologous sequences AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
2nd structure analysis of CCL26 AMPLIFICATION • DNA is often seen as a linear polymer. • In it’s single stranded state (cDNA) regions that have complimentary sequences will tend to hybridize generating hairpins that may inhibit primer annealing. • Avoiding these sequences when possible will improve amplification effiecency. • http://mfold.bioinfo.rpi.edu/cgi-bin/dna- form1.cgi www.bio-rad.com/genomics/pcrsupport
CCL26 with 2nd structures AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
CCL26 with 2nd structures AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
Amplicon size AMPLIFICATION • Classic qPCR rules dictate that amplification products be between 75 and 200 bp in length. • These limits are not absolute. It is better to design a larger amplicon than to risk target specificity and primer annealing issues • New “ultra fast” reagents allow much larger amplicons to be used in qPCR. www.bio-rad.com/genomics/pcrsupport
Design primers AMPLIFICATION • Some primer design packages will take both sequence homology and secondary structure issues into account when designing assays. • Due to the restrictions imposed on the design software, they can fail. • Although not recommended, designing assays by “thumb” can be performed. GCGGAATCTT TTCTGAAGGC TACATGGACC • There are also databases of freely available primers and probes that have been previously tested. www.bio-rad.com/genomics/pcrsupport
CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
Using Thermal Gradients AMPLIFICATION • Thermal optimization is often the first parameter an individual using PCR will test to get the optimal reaction conditions. • Unfortunately many qPCR users often ignore this parameter, as though antiquated, in favor of more elaborate primer design software packages. • Finding the correct annealing temperature at which to run an assay is critical. www.bio-rad.com/genomics/pcrsupport
Assay optimization AMPLIFICATION For 1 Rev 1 5’ 3’ For 2 Rev 2 For 1 For 2 Rev 1 Rev 2 10o above design { 5o below design www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQTM SYBR® Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Optimal Annealing Range AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Effect of Annealing Temp on C(t) AMPLIFICATION C(t) vs Annealing Temp 72 70 68 66 Annealing Temp 64 62 60 58 56 54 52 25 30 35 40 45 50 55 C(t) CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Different reagents behave very differently AMPLIFICATION C(t) vs Annealing Temp C(t) vs Annealing Temp 72 72 70 70 68 68 66 66 Annealing Temp Annealing Temp 64 64 62 62 60 60 58 58 56 56 54 54 52 52 25 30 35 40 45 50 55 25 30 35 40 45 50 55 C(t) C(t) CCl26 amplified using Bio-Rad Sso Fast EVA Green Supermix: CCl26 amplified using Other Reagent A: 5ul Assay 5ul Assay98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt 95oC 5min / 50x 95oC 15 sec 55-70oC 60 sec / melt analysis analysis C(t) vs Annealing Temp C(t) vs Annealing Temp 72 72 70 70 68 68 66 66 Annealing Temp Annealing Temp 64 64 62 62 60 60 58 58 56 56 54 54 52 52 25 30 35 40 45 50 55 25 30 35 40 45 50 55 C(t) C(t) CCl26 amplified using Other Reagent B: 5 ul Assay CCl26 amplified using Other Reagent C: 5ul Assay 95oC 20sec / 50x 95oC 3 sec 55-70oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 55-70oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
How did they fare? AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
Primer Titration AMPLIFICATION • Primer concentration plays an important role in qPCR amplification. • Typical concentrations go from 200nM to 500nM but can vary from 50nM to 800nM and sometimes higher. • High primer concentrations dramatically increase the incidence of non specific amplification and primer-dimers. • Reasonably well designed assays work best at normal primer concentrations www.bio-rad.com/genomics/pcrsupport
100nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
100nM each Primer AMPLIFICATION Replicates Mean C(t) : 27.24 Standard Deviation : 0.284 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.59 Standard Deviation : 0.184 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
300nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
300nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.54 Standard Deviation : 0.185 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
400nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
400nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.51 Standard Deviation : 0.269 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
600nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
600nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.49 Standard Deviation : 0.233 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
800nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
800nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.58 Standard Deviation : 0.193 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Melt curve AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Increased primer concentrations can increase nonspecific amplification products generated. AMPLIFICATION 200nM Socs1 primers Conditions: 95oC 3min / 50x 95oC 10 sec 55-70oC 30 sec / melt analysis 400nM Socs1 primers Conditions: 95oC 3min / 50x 95oC 10 sec 55-70oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Large dynamic range AMPLIFICATION GAPDH amplified using Bio-Rad SsoFast EVAGreen Supermix: 20ul Assay 98oC 30sec / 50x 95oC 1 sec 60oC 1 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
High sensitivity assay AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
High sensitivity assay AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Standard Curve AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
2nd Structures on template AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT Maintain forward primer at 200nM Titer reverse primer www.bio-rad.com/genomics/pcrsupport
200nM forward -- 100nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 100nM reverse AMPLIFICATION Replicates Mean C(t) : 35.91 Standard Deviation : 0.540 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 200nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 200nM reverse AMPLIFICATION Replicates Mean C(t) : 31.13 Standard Deviation : 0.200 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 300nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 300nM reverse AMPLIFICATION Replicates Mean C(t) : 29.33 Standard Deviation : 0.209 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 400nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 400nM reverse AMPLIFICATION Replicates Mean C(t) : 28.20 Standard Deviation : 0.168 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 600nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 600nM reverse AMPLIFICATION Replicates Mean C(t) : 27.19 Standard Deviation : 0.104 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 800nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
200nM forward -- 800nM reverse AMPLIFICATION Replicates Mean C(t) : 26.95 Standard Deviation : 0.062 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
AT rich sequences on template AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT Maintain forward primer at 200nM Titer reverse primer www.bio-rad.com/genomics/pcrsupport
Large amplicons AMPLIFICATION • Classic qPCR rules dictate that amplification products be between 75 and 200 bp in length. • New “ultra fast” reagents allow much larger amplicons to be used in qPCR. • Extending the size of the amplicon should be considered when trying to circumvent secondary structures, sequence homology and unfavorable regions. • Proper validation is required. www.bio-rad.com/genomics/pcrsupport
Large amplicons – dynamic range AMPLIFICATION •B-Actin 1076 bp amplicon from plasmid •109 to 10 copy per well 10 fold dilution 109 copies series •5 ul asay run on CFX384 using Bio- Rad’s SsoFast EVA Green Supermix 10 copies •Protocol : 98oC 3 min 45 x 95oC 1 sec 66oC 5 sec melt curve www.bio-rad.com/genomics/pcrsupport
Large amplicons - sensitivity AMPLIFICATION •B-Actin 1076 bp amplicon from plasmid •105 to 200 copy per well 2 fold dilution series 105 copies •5 ul asay run on CFX384 using Bio- Rad’s SsoFast EVA Green Supermix 200 copies •Protocol : 98oC 3 min 45 x 95oC 1 sec 66oC 5 sec melt curve www.bio-rad.com/genomics/pcrsupport
Sequence Homology AMPLIFICATION • Designing primers on a region of template sequence homologous to another gene should be avoided if possible. • When inevitable, a single primer can be designed to anneal on a homologous region for a series of genes. The other primer should annealing on a clean region or one that has no homology with genes annealed by the first primer. • Multiple primers should be designed and tested. • If a single primer anneals multiple targets, it will generate a linear amplification of DNA where as if both primers anneal, the amplification will be exponential. www.bio-rad.com/genomics/pcrsupport
Inhibitors AMPLIFICATION Blood Serum <2.5 % 10 % CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x95oC 1 sec 60oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Inhibitors AMPLIFICATION Blood Serum <0.0098 % 0.039 % <0.0089% 0.039% CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: CCl26 amplified using Other Reagent A: 5ul Assay 5ul Assay 95oC 3 min / 50x 95oC 10 sec 60oC 60 sec / melt 95oC 5min / 50x 95oC 15 sec 60oC 60 sec / melt analysis <0.0089% <0.0089% 0.039% 0.039% CCl26 amplified using Other Reagent B: 5ul Assay CCl26 amplified using Other Reagent C: 5ul Assay 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Scale effect on reproducibility AMPLIFICATION 45 6 40 5 35 4 delta C(t) 40 pg X C(t) 30 1 pg X 3 delta 25 2 20 1 15 0 2.5 5 10 20 Volume (ul) CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 2.5-20 ul Assay 98oC 30sec / 50x 95oC 1 sec 60oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Quality reagents are scalable AMPLIFICATION 45 45 6 6 40 40 5 5 35 35 4 4 delta C(t) 40 pg 40 pg delta C(t) C(t) C(t) 30 1 pg 30 1 pg 3 3 delta delta 25 25 2 2 20 1 20 1 15 0 15 0 2.5 5 10 20 2.5 5 10 20 Volume (ul) Volume (ul) CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: CCl26 amplified using Other Reagent A: 2.5-20 ul Assay 2.5-20 ul Assay 95oC 3 min / 50x 95oC 10 sec 60oC 60 sec / melt 95oC 5min / 50x 95oC 15 sec 60oC 60 sec / melt analysis 45 45 6 6 40 40 5 5 35 35 4 4 delta C(t) delta C(t) 40 pg 40 pg C(t) C(t) 30 1 pg 30 1 pg 3 3 delta delta 25 25 2 2 20 1 20 1 15 0 15 0 2.5 5 10 20 2.5 5 10 20 Volume (ul) Volume (ul) CCl26 amplified using Other Reagent B: 2.5-20 ul Assay CCl26 amplified using Other Reagent C: 2.5-20 ul Assay 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
Throughput AMPLIFICATION • The CFX384 real-time PCR detection system brings flexibility and ease of use to researchers performing high-throughput real- time PCR in a 384-well format. • With up to 4-target detection, unsurpassed thermal cycler performance, and powerful, yet easy-to-use software, the CFX384 system has been designed for the way you work. – FAST – shorten the time from experiment setup to results – FRIENDLY – a new standard for ease of use, delivering data you can trust with no maintenance – FLEXIBLE – customize a set up that fits individual laboratory needs www.bio-rad.com/genomics/pcrsupport
Speed AMPLIFICATION SsoFast EvaGreen Supermix Sso7d from Sulfolobus solfataricus – 7kD, 63 aa. – Thermostable (Tm >90°C) – No sequence preference – Binds to dsDNA (3-6 bp/protein molecule) – Monomeric • Minimal inhibition of PCR by use of EvaGreen • Higher activity • Tolerant to PCR inhibitors www.bio-rad.com/genomics/pcrsupport
Conclusions AMPLIFICATION • The key to speeding up any screening process begins with proper design and optimization. • qPCR assay optimization and dynamic range validation require very little time and effort and help guarantee that the results will be reproducible and comparable form experiment to experiment. • If potentially interfering elements are discovered at the design and optimization phases, they can be accounted for and possible corrected. • As demands for shorter run times increase, proper care in the selection of reagents and instruments is required. www.bio-rad.com/genomics/pcrsupport
AMPLIFICATION • Thank You! www.bio-rad.com/genomics/pcrsupport

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Fast qPCR assay optimization and validation techniques for HTS

  • 1. Fast qPCR assay optimization and validation techniques for HTS Francisco Bizouarn International Field Application Specialist Gene Expression Division Bio-Rad Laboratories
  • 2. Generating a good assay is easy AMPLIFICATION • Following a few simple steps: – Design assay – Run a gradient – Run a dilution series to validate assay dynamic range • A little extra effort in the beginning will make a tremendous amount of difference in the analysis when the assay is run hundreds or thousands of times. www.bio-rad.com/genomics/pcrsupport
  • 3. Assay design AMPLIFICATION • Often oversimplified by the use of software or by many companies that offer design services and softwares. • Design a critical parameter. • Following a few simple steps will increase the chances of designing a successful assay. • Let’s use an example: target CCL26 in HUVEC cells www.bio-rad.com/genomics/pcrsupport
  • 4. CCL26 cDNA sequence AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 5. Sequence Alignment (BLAST) AMPLIFICATION • Prior to designing primers, it’s a good idea to run a sequence homology analysis. (BLAST) • This allows the identification of sequences that may co- amplify or interfere with our intended target. • The data is freely available, so why not make use of it. • http://blast.ncbi.nlm.nih.gov www.bio-rad.com/genomics/pcrsupport
  • 6. CCL26 with homologous sequences AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 7. CCL26 with homologous sequences AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 8. 2nd structure analysis of CCL26 AMPLIFICATION • DNA is often seen as a linear polymer. • In it’s single stranded state (cDNA) regions that have complimentary sequences will tend to hybridize generating hairpins that may inhibit primer annealing. • Avoiding these sequences when possible will improve amplification effiecency. • http://mfold.bioinfo.rpi.edu/cgi-bin/dna- form1.cgi www.bio-rad.com/genomics/pcrsupport
  • 9. CCL26 with 2nd structures AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 10. CCL26 with 2nd structures AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 11. Amplicon size AMPLIFICATION • Classic qPCR rules dictate that amplification products be between 75 and 200 bp in length. • These limits are not absolute. It is better to design a larger amplicon than to risk target specificity and primer annealing issues • New “ultra fast” reagents allow much larger amplicons to be used in qPCR. www.bio-rad.com/genomics/pcrsupport
  • 12. Design primers AMPLIFICATION • Some primer design packages will take both sequence homology and secondary structure issues into account when designing assays. • Due to the restrictions imposed on the design software, they can fail. • Although not recommended, designing assays by “thumb” can be performed. GCGGAATCTT TTCTGAAGGC TACATGGACC • There are also databases of freely available primers and probes that have been previously tested. www.bio-rad.com/genomics/pcrsupport
  • 13. CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 14. Using Thermal Gradients AMPLIFICATION • Thermal optimization is often the first parameter an individual using PCR will test to get the optimal reaction conditions. • Unfortunately many qPCR users often ignore this parameter, as though antiquated, in favor of more elaborate primer design software packages. • Finding the correct annealing temperature at which to run an assay is critical. www.bio-rad.com/genomics/pcrsupport
  • 15. Assay optimization AMPLIFICATION For 1 Rev 1 5’ 3’ For 2 Rev 2 For 1 For 2 Rev 1 Rev 2 10o above design { 5o below design www.bio-rad.com/genomics/pcrsupport
  • 16. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQTM SYBR® Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 17. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 18. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 19. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 20. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 21. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 22. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 23. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 24. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 25. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 26. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 27. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 28. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 29. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 30. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 31. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 32. Gradient analysis AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 33. Optimal Annealing Range AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 34. Effect of Annealing Temp on C(t) AMPLIFICATION C(t) vs Annealing Temp 72 70 68 66 Annealing Temp 64 62 60 58 56 54 52 25 30 35 40 45 50 55 C(t) CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 35. Different reagents behave very differently AMPLIFICATION C(t) vs Annealing Temp C(t) vs Annealing Temp 72 72 70 70 68 68 66 66 Annealing Temp Annealing Temp 64 64 62 62 60 60 58 58 56 56 54 54 52 52 25 30 35 40 45 50 55 25 30 35 40 45 50 55 C(t) C(t) CCl26 amplified using Bio-Rad Sso Fast EVA Green Supermix: CCl26 amplified using Other Reagent A: 5ul Assay 5ul Assay98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt 95oC 5min / 50x 95oC 15 sec 55-70oC 60 sec / melt analysis analysis C(t) vs Annealing Temp C(t) vs Annealing Temp 72 72 70 70 68 68 66 66 Annealing Temp Annealing Temp 64 64 62 62 60 60 58 58 56 56 54 54 52 52 25 30 35 40 45 50 55 25 30 35 40 45 50 55 C(t) C(t) CCl26 amplified using Other Reagent B: 5 ul Assay CCl26 amplified using Other Reagent C: 5ul Assay 95oC 20sec / 50x 95oC 3 sec 55-70oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 55-70oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 36. CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 37. How did they fare? AMPLIFICATION CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: 5ul Assay 95oC 60sec / 50x95oC 10 sec 55-70oC 60 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 38. CCL26 primer design AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT www.bio-rad.com/genomics/pcrsupport
  • 39. Primer Titration AMPLIFICATION • Primer concentration plays an important role in qPCR amplification. • Typical concentrations go from 200nM to 500nM but can vary from 50nM to 800nM and sometimes higher. • High primer concentrations dramatically increase the incidence of non specific amplification and primer-dimers. • Reasonably well designed assays work best at normal primer concentrations www.bio-rad.com/genomics/pcrsupport
  • 40. 100nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 41. 100nM each Primer AMPLIFICATION Replicates Mean C(t) : 27.24 Standard Deviation : 0.284 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 42. 200nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 43. 200nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.59 Standard Deviation : 0.184 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 44. 300nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 45. 300nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.54 Standard Deviation : 0.185 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 46. 400nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 47. 400nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.51 Standard Deviation : 0.269 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 48. 600nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 49. 600nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.49 Standard Deviation : 0.233 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 50. 800nM each Primer AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 51. 800nM each Primer AMPLIFICATION Replicates Mean C(t) : 26.58 Standard Deviation : 0.193 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 52. Melt curve AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 53. Increased primer concentrations can increase nonspecific amplification products generated. AMPLIFICATION 200nM Socs1 primers Conditions: 95oC 3min / 50x 95oC 10 sec 55-70oC 30 sec / melt analysis 400nM Socs1 primers Conditions: 95oC 3min / 50x 95oC 10 sec 55-70oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 54. Large dynamic range AMPLIFICATION GAPDH amplified using Bio-Rad SsoFast EVAGreen Supermix: 20ul Assay 98oC 30sec / 50x 95oC 1 sec 60oC 1 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 55. High sensitivity assay AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 56. High sensitivity assay AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 57. Standard Curve AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 58oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 58. 2nd Structures on template AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT Maintain forward primer at 200nM Titer reverse primer www.bio-rad.com/genomics/pcrsupport
  • 59. 200nM forward -- 100nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 60. 200nM forward -- 100nM reverse AMPLIFICATION Replicates Mean C(t) : 35.91 Standard Deviation : 0.540 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 61. 200nM forward -- 200nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 62. 200nM forward -- 200nM reverse AMPLIFICATION Replicates Mean C(t) : 31.13 Standard Deviation : 0.200 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 63. 200nM forward -- 300nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 64. 200nM forward -- 300nM reverse AMPLIFICATION Replicates Mean C(t) : 29.33 Standard Deviation : 0.209 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 65. 200nM forward -- 400nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 66. 200nM forward -- 400nM reverse AMPLIFICATION Replicates Mean C(t) : 28.20 Standard Deviation : 0.168 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 67. 200nM forward -- 600nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 68. 200nM forward -- 600nM reverse AMPLIFICATION Replicates Mean C(t) : 27.19 Standard Deviation : 0.104 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 69. 200nM forward -- 800nM reverse AMPLIFICATION CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 70. 200nM forward -- 800nM reverse AMPLIFICATION Replicates Mean C(t) : 26.95 Standard Deviation : 0.062 CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x 95oC 1 sec 55-70oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 71. AT rich sequences on template AMPLIFICATION CTGGAATTGA GGCTGAGCCA AAGACCCCAG GGCCGTCTCA GTCTCATAAA AGGGGATCAG GCAGGAGGAG TTTGGGAGAA ACCTGAGAAG GGCCTGATTT GCAGCATCAT GATGGGCCTC TCCTTGGCCT CTGCTGTGCT CCTGGCCTCC CTCCTGAGTC TCCACCTTGG AACTGCCACA CGTGGGAGTG ACATATCCAA GACCTGCTGC TTCCAATACA GCCACAAGCC CCTTCCCTGG ACCTGGGTGC GAAGCTATGA ATTCACCAGT AACAGCTGCT CCCAGCGGGC TGTGATATTC ACTACCAAAA GAGGCAAGAA AGTCTGTACC CATCCAAGGA AAAAATGGGT GCAAAAATAC ATTTCTTTAC TGAAAACTCC GAAACAATTG TGACTCAGCT GAATTTTCAT CCGAGGACGC TTGGACCCCG CTCTTGGCTC TGCAGCCCTC TGGGGAGCCT GCGGAATCTT TTCTGAAGGC TACATGGACC CGCTGGGGAG GAGAGGGTGT TTCCTCCCAG AGTTACTTTA ATAAAGGTTG TTCATAGAGT TGACTTGTTC AT Maintain forward primer at 200nM Titer reverse primer www.bio-rad.com/genomics/pcrsupport
  • 72. Large amplicons AMPLIFICATION • Classic qPCR rules dictate that amplification products be between 75 and 200 bp in length. • New “ultra fast” reagents allow much larger amplicons to be used in qPCR. • Extending the size of the amplicon should be considered when trying to circumvent secondary structures, sequence homology and unfavorable regions. • Proper validation is required. www.bio-rad.com/genomics/pcrsupport
  • 73. Large amplicons – dynamic range AMPLIFICATION •B-Actin 1076 bp amplicon from plasmid •109 to 10 copy per well 10 fold dilution 109 copies series •5 ul asay run on CFX384 using Bio- Rad’s SsoFast EVA Green Supermix 10 copies •Protocol : 98oC 3 min 45 x 95oC 1 sec 66oC 5 sec melt curve www.bio-rad.com/genomics/pcrsupport
  • 74. Large amplicons - sensitivity AMPLIFICATION •B-Actin 1076 bp amplicon from plasmid •105 to 200 copy per well 2 fold dilution series 105 copies •5 ul asay run on CFX384 using Bio- Rad’s SsoFast EVA Green Supermix 200 copies •Protocol : 98oC 3 min 45 x 95oC 1 sec 66oC 5 sec melt curve www.bio-rad.com/genomics/pcrsupport
  • 75. Sequence Homology AMPLIFICATION • Designing primers on a region of template sequence homologous to another gene should be avoided if possible. • When inevitable, a single primer can be designed to anneal on a homologous region for a series of genes. The other primer should annealing on a clean region or one that has no homology with genes annealed by the first primer. • Multiple primers should be designed and tested. • If a single primer anneals multiple targets, it will generate a linear amplification of DNA where as if both primers anneal, the amplification will be exponential. www.bio-rad.com/genomics/pcrsupport
  • 76. Inhibitors AMPLIFICATION Blood Serum <2.5 % 10 % CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 5ul Assay 98oC 30sec / 50x95oC 1 sec 60oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 77. Inhibitors AMPLIFICATION Blood Serum <0.0098 % 0.039 % <0.0089% 0.039% CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: CCl26 amplified using Other Reagent A: 5ul Assay 5ul Assay 95oC 3 min / 50x 95oC 10 sec 60oC 60 sec / melt 95oC 5min / 50x 95oC 15 sec 60oC 60 sec / melt analysis <0.0089% <0.0089% 0.039% 0.039% CCl26 amplified using Other Reagent B: 5ul Assay CCl26 amplified using Other Reagent C: 5ul Assay 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 78. Scale effect on reproducibility AMPLIFICATION 45 6 40 5 35 4 delta C(t) 40 pg X C(t) 30 1 pg X 3 delta 25 2 20 1 15 0 2.5 5 10 20 Volume (ul) CCl26 amplified using Bio-Rad SsoFast EVAGreen Supermix: 2.5-20 ul Assay 98oC 30sec / 50x 95oC 1 sec 60oC 5 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 79. Quality reagents are scalable AMPLIFICATION 45 45 6 6 40 40 5 5 35 35 4 4 delta C(t) 40 pg 40 pg delta C(t) C(t) C(t) 30 1 pg 30 1 pg 3 3 delta delta 25 25 2 2 20 1 20 1 15 0 15 0 2.5 5 10 20 2.5 5 10 20 Volume (ul) Volume (ul) CCl26 amplified using Bio-Rad iQ SYBR Green Supermix: CCl26 amplified using Other Reagent A: 2.5-20 ul Assay 2.5-20 ul Assay 95oC 3 min / 50x 95oC 10 sec 60oC 60 sec / melt 95oC 5min / 50x 95oC 15 sec 60oC 60 sec / melt analysis 45 45 6 6 40 40 5 5 35 35 4 4 delta C(t) delta C(t) 40 pg 40 pg C(t) C(t) 30 1 pg 30 1 pg 3 3 delta delta 25 25 2 2 20 1 20 1 15 0 15 0 2.5 5 10 20 2.5 5 10 20 Volume (ul) Volume (ul) CCl26 amplified using Other Reagent B: 2.5-20 ul Assay CCl26 amplified using Other Reagent C: 2.5-20 ul Assay 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis 95oC 20sec / 50x 95oC 3 sec 60oC 30 sec / melt analysis www.bio-rad.com/genomics/pcrsupport
  • 80. Throughput AMPLIFICATION • The CFX384 real-time PCR detection system brings flexibility and ease of use to researchers performing high-throughput real- time PCR in a 384-well format. • With up to 4-target detection, unsurpassed thermal cycler performance, and powerful, yet easy-to-use software, the CFX384 system has been designed for the way you work. – FAST – shorten the time from experiment setup to results – FRIENDLY – a new standard for ease of use, delivering data you can trust with no maintenance – FLEXIBLE – customize a set up that fits individual laboratory needs www.bio-rad.com/genomics/pcrsupport
  • 81. Speed AMPLIFICATION SsoFast EvaGreen Supermix Sso7d from Sulfolobus solfataricus – 7kD, 63 aa. – Thermostable (Tm >90°C) – No sequence preference – Binds to dsDNA (3-6 bp/protein molecule) – Monomeric • Minimal inhibition of PCR by use of EvaGreen • Higher activity • Tolerant to PCR inhibitors www.bio-rad.com/genomics/pcrsupport
  • 82. Conclusions AMPLIFICATION • The key to speeding up any screening process begins with proper design and optimization. • qPCR assay optimization and dynamic range validation require very little time and effort and help guarantee that the results will be reproducible and comparable form experiment to experiment. • If potentially interfering elements are discovered at the design and optimization phases, they can be accounted for and possible corrected. • As demands for shorter run times increase, proper care in the selection of reagents and instruments is required. www.bio-rad.com/genomics/pcrsupport
  • 83. AMPLIFICATION • Thank You! www.bio-rad.com/genomics/pcrsupport