User:Jarle Pahr/PCR

http://nucleicacids.bitesizebio.com/articles/pcr-rescue/

^^ Tips on getting one band, by using one band of a first PCR as template for a second PCR:

https://eu.idtdna.com/pages/decoded/decoded-articles/core-concepts/decoded/2012/10/08/dna-oligonucleotide-resuspension-and-storage

http://www.spartanbio.com/wp-content/themes/spartan/assets/application_notes/17.pdf

For low-GC templates, some regions of the amplicon may have a melting temperature lower than the extension temperature, causing denaturation during the extension step and failure of the PCR reaction. (http://link.springer.com/article/10.1007%2Fs11274-010-0451-2?LI=true#page-1)

Polymerases

Polymerase	Speed (min/kb)	Fidelity	Supplier	Reference	5'-3' Exonuclease?	3'-5' exonuclease (proof reading)	Strand displacement?	Overhang?
Taq	1	Example	ex		Yes	No	Yes	3'-A
Phusion	0.25-0.50	Example	NEB	https://www.neb.com/protocols/1/01/01/pcr-protocol-m0530	No	Yes	No	No
Pfu	2	Example	Example		No	Yes	No
Q5	?	Example	NEB

Polymerases: http://oregonstate.edu/instruction/bb492/lectures/DNAI.html

BiteSize Bio - The best polymerases of 2008: http://bitesizebio.com/articles/the-best-polymerases-of-2008/

For a comparison of various polymerases, see http://barricklab.org/twiki/bin/view/Lab/ProtocolsTaq

Phusion polymerase

Note on Phusion polymerase:

Quotes from the protocol:

The final concentration of each primer in a reaction using Phusion DNA Polymerase may be 0.2–1 μM, while 0.5 μM is recommended.

During thermocycling, the denaturation step should be kept to a minimum. Typically, a 5–10 second denaturation at 98°C is recommended for most templates.

Annealing: Annealing temperatures required for use with Phusion tend to be higher than with other PCR polymerases. The NEB Tm calculator should be used to determine the annealing temperature when using Phusion. Typically, primers greater than 20 nucleotides in length anneal for 10–30 seconds at 3°C above the Tm of the lower Tm primer. If the primer length is less than 20 nucleotides, an annealing temperature equivalent to the Tm of the lower primer should be used. A temperature gradient can also be used to optimize

http://bitesizebio.com/articles/mind-your-p%E2%80%99s-and-q%E2%80%99s-a-short-primer-on-proofreading-polymerases/

[Phusion polymerase]

Finnzyme Tm calculator for use with Phusion: http://www.thermoscientificbio.com/webtools/tmc/

Strand displacement:

See https://www.neb.com/products/polymerases-and-amplification-technologies/polymerases-and-amplification-technologies/dna-polymerase-strand-displacement-activity

Home-grown polymerase

http://bitesizebio.com/articles/free-pcr-for-5-years-or-how-to-make-your-own-taq-and-pfu/

http://www.openbiotech.com/product_p/popentaq.htm

http://mama.indstate.edu/pfaffle/ptaq/

http://www.ncbi.nlm.nih.gov/pubmed/23326812

PCR programs

JPAPHUS1:

SOE:

Primers

Sequences for SLIC

Name	Length (bp)	Sequence	Tm (C) [calculated]	GC (% / bp)	Comment
rrnB p1_74bp_FWD	40	agccgggcgatgccaaccggGTTGCGCGGTCAGAAAATTA			For amplification of 74 bp promoter fragments plus SLIC linkers
rrnB p1_74bp_REV	39	ctccattattattgtacatgAGTGGTGGCGCATTATAGG	?
rrnB_p1_long_FWD	20	agccgggcgatgccaaccggGTATCCTACGCCCGTGGTTA	?		For amplification of 389 bp fragment plus SLIC linkers. Use together with rrnB p1_74bp_REV
GreA_60bp_FWD		agccgggcgatgccaaccggGGCGCAACGCCCTATAAAGT	?
GreA_long_FWD	40	agccgggcgatgccaaccggTCACCCTTAAGTACGCCGTT	59	50.00	For amplification of 399bp fragment plus SLIC linkers.
GreA_60bp_REV	45	ctccattattattgtacatgATAGTCATTTTACCCTGAAGTTCCC	?

Sequences for amplification from pSB-M1g

Name	Length (bp)	Sequence	Tm (C) [calculated]	GC (% / bp)	Comment
RBS-GFPstart	20	ATGGAGTCATGAACATATGG	56	40	For amplification from pSB-M1g, starting from RBS. Somewhat low GC content, and does not pass 5' end stability check in Clone Manager.
pSB-REV1	20	TCAAGGATGTGGATCTGCTG	57(2)/64.4(1)/57.3(3)	50	For amplification of vector backbone from pSB-M1g. Binds at same site as SeqMG1, between OriT and AgeI. Amplicon includes Colony PCR FWD2 site, but not the Seq5 site.
pSB-REV2	20	CCGGCTTTCTTAGACACTCT	60.5(1)	50	For amplification of vector backbone from pSB-M1g. Binds at beginning of SLIC linker B. Includes Colony PCR FWD2 and Seq5 sites, but not AgeI. Triggers primer dimer warning in Clone Manager.
GFP-END-FWD	20	CCAGATCACATGAAGCAGCA
GFP-END-REV		TTTGTATAGTTCATCCATGCC
GFP-END-LVA-EcoRI-BamHI-REV	72	_{agaggatcccttaagttaagctactaaagcgtagttttcgtcgtttgctgcTTTGTATAGTTCATCCATGCC}			Primer for amplification of end region of GFP from pSB-M1g with addition of LVA-tag plus EcoRI (italic) and BamHI (bold) sites.

Sequences for restriction-ligation cloning (RL cloning)

Name	Length (bp)	Sequence (PCR target sequence in bold)	Tm (C) [calculated]
rrnB p1_74bp_FWD_R	28	caaccggtGTTGCGCGGTCAGAAAATTA
rrnB p1_74bp_REV_R	27	gtacatgtAGTGGTGGCGCATTATAGG
GreA_60bp_FWD_R	28	taaccggtGGCGCAACGCCCTATAAAGT
GreA_60bp_REV_R	33	gtacatgtATAGTCATTTTACCCTGAAGTTCCC
LacUV5_49bp_R_FWD	43	caaccggtGCACCCCAGGCTTTACACTTTATGCTTCCGGCTCG	67.5(1)/60.7 (3)
LacUV5_49bp_R_REV	43	gtacatgtTCCACACATTATACGAGCCGGAAGCATAAAGTGTA
ArgI_46bp_R_FWD	41	caaccggtGCTTTAGACTTGCAAATGAATAATCATCCATAT	50.6(1)/44.7 (3)
ArgI_46bp_R_REV	41	gtacatgtTAAAATTCAATTTATATGGATGATTATTCATTT
iraP_61bp_R_FWD	49	caaccggtGCTGGTAATCAAACAAAAAATATTTGCGCAAAGTATTTCC	59.7(1)/52.4(3)
iraP_61_bp_R_REV	48	gtacatgtAAGTATTATTTTTATGACAAAGGAAATACTTTGCGCAAAT
LivJ_61_bp_R_FWD	48	caaccggtATTGTTAATAAACTGTCAAAATAGCTATTCCAATATCATA	47.8(1)/44.2(3)
LivJ_61_bp_R_REV	48	gtacatgtTGCTAAAACATACCCGATTTTTATGATATTGGAATAGCTA
His_61bp_R_FWD	49	caaccggtGCCATAAAATATATAAAAAAGCCCTTGCTTTCTAACGTGAA	65.5(1)/59.1(3)
His_61bp_R_REV	49	gtacatgtGTCTTTTAACCTAAACCACTTTCACGTTAGAAAGCAAGGGC
Thr_73bp_R_FWD	55	caaccggtAACTGGTTACCTGCCGTGAGTAAATTAAAATTTTATTGACTTAGGTC	51.7(1)/47.6(3)
Thr_73bp_R_REV	55	gtacatgtTGCCTATATTGGTTAAAGTATTTAGTGACCTAAGTCAATAAAATTTT

Sequences for Ligation-independent cloning (LIC):

Name	Length (bp)	Sequence
rrnB74bpLIC_FWD	36	gccgcgcggcagcctgGTTGCGCGGTCAGAAAATTA
rrnB75bpLIC_REV	33	caagaagaacccctAGTGGTGGCGCATTATAGG
GreA_60bpLIC_FWD	36	gccgcgcggcagcctgGGCGCAACGCCCTATAAAGT
GreA_60bpLIC_REV	39	caagaagaacccctATAGTCATTTTACCCTGAAGTTCCC
LacUV5_49bp_R_FWD		caaccggtGCACCCCAGGCTTTACACTTTATGCTTCCGGCTCG

For SacII-based LIC sequence, see http://www.nmr.chem.uu.nl/users/rob/protocols/licdetailed.html

Tm notes:

1: Finnzyme/Thermo Scientific Tm Calculator
2: Clone Manager
3: Primer 3

BioBrick sequences:

dNTPs

Average molecular weight: 487 g/mol

Oligomer annealing

http://www.bio.net/bionet/mm/methods/1997-March/056072.html

http://www.protocol-online.org/biology-forums/posts/23721.html

http://www.oligos.com/annOligonucleotides.htm

http://www.addgene.org/plasmid_protocols/annealed_oligo_cloning/

PCR techniques

"sticky end PCR method": Can be used to generate PCR products with restriction site-compatible overhang. Can be used to clone fragments which contain the same restriction site(s) as the vector.

Colony PCR

http://www.csun.edu/~mls42367/Protocols/Colony%20PCR.pdf

http://openwetware.org/wiki/Endy:Colony_PCR_protocol

https://www.researchgate.net/post/Protocol_for_colony_PCR

http://www.benchfly.com/video/57/how-to-perform-colony-pcr/

http://www.methodbook.net/pcr/pcrscreen.html

Emulsion PCR

http://www.plosone.org/article/info:doi/10.1371/journal.pone.0024910

Touchdown PCR

http://bitesizebio.com/articles/touchdown-pcr-a-primer-and-some-tips/

Hot-start

Primer Design

http://www.premierbiosoft.com/tech_notes/PCR_Primer_Design.html

http://www.molecularinfo.com/MTM/E/E1/E1-3.html

Optimization and troubleshooting

http://cshprotocols.cshlp.org/content/2009/4/pdb.ip66.full

http://www.embl.de/pepcore/pepcore_services/cloning/pcr_strategy/optimising_pcr/

http://www.protocol-online.org/biology-forums-2/posts/7644.html

http://www.protocol-online.org/biology-forums/posts/32105.html

http://europepmc.org/articles/PMC145803/pdf/241574.pdf

http://www.eppendorfna.com/int/index.php?l=131&action=products&contentid=109

http://www.bio-rad.com/evportal/en/NO/evolutionPortal.portal?_nfpb=true&_pageLabel=SolutionsLandingPage&catID=LUSO3HC4S

http://originally4.blogspot.no/2011/08/pcr-for-species-with-extreme-gc-content.html

http://forums.biotechniques.com/viewtopic.php?f=2&t=14795

http://books.google.no/books?id=eY4VwJCJLmIC&pg=PA36&lpg=PA36&dq=PCR+pentamer+stability&source=bl&ots=7RpaJimjSl&sig=hwt2K1QO4JiOgiJzPZdtozVZaoE&hl=no&sa=X&ei=-mFGUdmDM4qHtQaX8oEg&ved=0CIwBEOgBMAk#v=onepage&q=PCR%20pentamer%20stability&f=false

To do a quick, rough check on the thermocycling performance and corresponence between displayed and actual temperature, run a PCR program with a hold at 4 C at the end. Immediately after the display shows that 4C is reached and that the machine is holding the temperature, open the cover and feel the temperature of the heatblock. If it isn't cold, there is a significant time-lag/discorrespondence between the displayed and heatblock surface temperatures.

Purification of oligomers

See http://www.sigmaaldrich.com/life-science/custom-oligos/custom-dna/learning-center/best-purification.html

Desalting: Standard purification procedure to remove by-products from synthesis.

Reverse-phase cartridge purification (Sigma:"RP1"). Separates truncated and full-length products on the basis of difference in hydrophobicity between full-length products with DMT protecting group present, and truncated sequences without DMT group. Unsuited for longer oligomers, as the proportion of DMT-containing truncated sequences increase with oligomer length. From Sigma website:

"As the oligo length increases, the proportion of uncapped products (truncated sequences bearing the DMT) tends to increase. These impurities will not be removed by RP1 and thus for longer oligos, HPLC or PAGE is recommended."

HPLC reverse-phase:

From Sigma website:

"The resolution based on lipophilicity will decrease with the length of the oligo. Therefore, RP-HPLC is usually not recommended for purifying products longer than 50 bases. Although longer oligos (up to 80 bases) can be purified using this method, the purity and yields may be adversely affected."

PAGE:

From Sigma website:

"Anion- Exchange HPLC is limited by length (usually up to 40mers). The longer the oligonucleotide the lower the resolution on the Anion-Exchange HPLC column and thus the purity of the target oligo."

Comparison of calculated and reported Tm values

Oligomer	Tm (C) [Analytical]	Supplier
GFP-END-FWD	65.2	Sigma
GFP-END-REV	58.9	Sigma
GFP-END-LVA-REV	84.5	Sigma
pSB-SeqA	60.2	Sigma
LacUV5_49bp_R_FWD	88.3	Sigma
LacUV5_49bp_R_REV	78.1	Sigma
ArgI46bp_R_FWD	77.2	Sigma
ArgI46bp_R_REV	67.6	Sigma
rrnB p1_74bp_FWD	91.3	Sigma
rrnB p1_74_bp_REV	75.6	Sigma
GreA_60bp_FWD	91.6	Sigma
GreA_60bp_REV	74.5	Sigma
LacUV5_49bp_FWD	95.5	Sigma
LacUV5_49bp_REV	80.3	Sigma
pJP-1 seq5	53.9	Macrogen
pJP-1 seq6	53.9	Macrogen
COPCR1FWD2	58.4	Macrogen
COPCR1REV	58.4	Macrogen
SeqMG1	56.4	Macrogen
rrnB_p1_long_FWD	85.1	Macrogen
GreA_long_FWD	84.0	Macrogen
RF-LVA-EcoRI-FWD	80.5	Macrogen