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We are dedicated to your success. Get back on track. View our expert recommendations for commonly encountered problem scenarios.
View the relevant questions below:
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Carefully designed crRNA target oligos and avoiding homology with other regions in the genome are critical for minimizing off-target effects.
Unfortunately, PAM is a necessary requirement for CRISPR gene editing. However, in its absence, you could use our Invitrogen™ GeneArt™ Precision TAL effector-based nuclease.
There are several ways to increase efficiency, for instance, adding antibiotic selection and/or FAC sorting to enrich for the transfected cells will both help.
Please see the following recommendations:
Reason | Solution |
Single-stranded (ss) oligonucleotides designed incorrectly | Make sure that each ss oligonucleotide contains the 5 nucleotides on the 3’ end required for cloning into the GeneArt CRISPR Nuclease Vector: Top strand includes GTTTT on the 3’ end Bottom strand includes CGGTG on the 3’ end |
Double-stranded (ds) oligonucleotides were degraded | Store the 5 nM ds oligonucleotide stock in 1X Oligonucleotide Annealing Buffer Avoid repeated freeze/thaw cycles; aliquot the 5 nM ds oligonucleotide stock and store at –20°C |
Oligonucleotide annealing reaction inefficient | Ensure that the annealing reaction was performed as directed If ambient temperature is >25°C, incubate the annealing reaction in a 25°C incubator. |
Please see the possible reasons and suggestions below:
Reason | Solution |
Single-stranded (ss) oligonucleotide designed incorrectly | Make sure that each (ss) oligonucleotide contains the 4 nucleotides on the 5’ end required for cloning into the GeneArt Genomic Cleavage Selection vector: Top strand includes AATT on the 5’ end Bottom strand includes CTAG on the 5’ end |
Double-stranded (ds) oligonucleotides were degraded | Store the 50 nM ds oligonucleotide stock in 1X ligation buffer at –20°C Avoid repeat freeze/thaw cycles, aliquot 50 nM ds oligonucleotides stock and store at –20°C |
Oligonucleotide annealing reaction was inefficient | Ensure that the annealing reaction was performed as directed If ambient temperature is >25°C, incubate the annealing reaction in a 25°C incubator |
This can occur if:
Too much OFP background can occur if there is plasmid contamination, and/or can be cell line– and target-dependent. Make sure to pick single clones when culturing the cleavage selection plasmid, or try to reduce the amount of vector that is included in the transfection.
Results are locus-dependent. We recommend using the GeneArt Genomic Cleavage Detection Kit (Cat. No. A24372) to verify cleavage on the endogenous genomic locus.
Please see the table below for common problems, possible causes, and recommendations:
DNA band appearance | Possible cause | Recommendation |
Smear | Lysate is too concentrated | Dilute lysate 2- to 4-fold and repeat the PCR reaction. |
Too faint | Lysate is too dilute | Double the amount of lysate in the PCR reaction. Do not use more than 4 µL of lysate in the PCR reaction. Lysate can inhibit the PCR reaction. |
Disparity in band intensity between amplicons | Lysate concentrations vary between samples | Purify the PCR products with the Invitrogen™ PureLink™ PCR Purification Kit. For best results in comparing samples, purify PCR and use the same quantity of DNA in each cleavage assay. 50 ng to 100 ng of DNA is enough for each reaction. |
No PCR product | Poor PCR primer design or GC-rich region | Redesign primers that are 18–22 bp, have 45–60% GC content, and a 52–58°C Tm range. For GC-rich regions, add 1–10 µL of 360 GC Enhancer in a 50 µL reaction and repeat the PCR amplification. |
Please see the table below for common problems, possible causes, and recommendations:
Problem | Possible cause | Recommendation |
No cleavage band visible | Nucleases unable to access target sequence or unable to cleave at target site Transfection efficiency too low | Design new targeting strategy at nearby sequences. |
Genomic modification too low | Optimize transfection protocol. | |
Omitted denaturing and reannealing step | Use Kit Control Template and Primers to verify the kit components and protocol. | |
Difficulty in analyzing gel data | Background interferes with the measurements of cleaved bands | Redesign the PCR primers to product a distinct cleaved banding pattern. |
Nonspecific cleavage bands | Intricate mutations at the target site. Digestion incubation too long. Too much Detection Enzyme added. Nonspecific cleavage by Detection Enzyme for certain target loci. | Redesign PCR primers to amplify target sequence. Use lysate from mock transfected cells or cells transfected with irrelevant plasmids as negative control to distinguish background from specific cleavage. |
For Research Use Only. Not for use in diagnostic procedures.