Monday 24 March 2014

5mC-PCR: preserving methylation status during polymerase chain reaction

Methylation analysis is hampered by the simple fact that PCR amplification removes methylation marks from native DNA. We came up with a simple idea to produce a thermo-stable DNA methyltransferase to preserve methylation status through PCR cycles, allowing amplification of DNA and simplified analysis. The first thing we did was approach some enzyme companies to see if anyone had something suitable on their books, they did not. But they did seem to think this was a good idea so we designed a pretty simple experiment to test it: this involved going back to basics, to how PCR was performed before the application of Taq polymerase - we added Dnmt1 after each amplification cycle to copy methylation marks onto the daughter strands.





Demonstrating preservation of 5-mC: As a thermostable Dnmt1 is not commercially available we decided to introduce an additional step to ensure the methylation status is maintained during PCR amplification. We used commercial human DNA methyltransferase (Dnmt1) and the methyl donor S-adenosyl-L-methionine (SAM) after every PCR cycle to copy the methylation marks from the template strand to the newly formed complimentary strand. As the Dnmt1 will degrade at high-temperature and the SAM degrades at neutral pH and high temperatures, we need to add fresh reagents (Dnmt1 and SAM) at 37°C as the last step of each cycle.

We designed a synthetic oligo 122bp long containing a single unmethylated/methylated CpG inserted in a methylation sensitive restriction enzyme site for ClaI.

We set up 50 µl PCR reactions using Phusion HF polymerase, 20 ng of template and the following cycling conditions: 30s at 98°C, then 6 cycles of 10s at 98°C, 10s at 59°C, 10s at 72°C and 20 min at 37°C. Immediately on cooling to 37°C, the program was paused (1 min) for the addition of fresh Dnmt1, BSA and SAM. For convenience/accuracy, BSA (final 100 µg/ml) and SAM (final 160 µM) were premixed with a small amount of Dnmt1 buffer (final 0.05X) so that 1 µl could be added in each cycle.

NEB define 1 unit of Dnmt1 as the amount of enzyme required to catalyse the transfer of 1 pmol of methyl group to poly dI.dC substrate in a total reaction volume of 25 μl in 30 minutes at 37°C. The following amounts were added in the initial experiment:



PCR products were purified using a Zymo Clean & Concentrator Kit, digested using ClaI at 37°C for 30min, purified again and run on a 2% agarose gel:

Results: The final gels show the multiple reactions we set up to demonstrate the plausibility of preserving 5mC during a few cycles of PCR.


  1. Cla1 should have cut this template, but there are cut and uncut bands (incomplete digest?).
  2. Cla1 should have cut this template (the methyl mark was not amplified), but there are cut and uncut bands (probably from the methylated template - success?)
  3. Cla1 should have cut this template, but there is a significant uncut band (de novo activity?)
  4. Cla1 should not have cut this template and there is only an uncut band (success).
  5. Cla1 should not have cut this template (success).
Conclusions: Dnmt-PCR works (lane 3 vs. 4)! It turns out that Dnmt1 may also have some de novo activity, not only the widely accepted maintenance one, so optimisation of the Dnmt1 incubation time/amounts is needed.

According to the literature, the maintenance vs de novo activity of Dnmt1 is in the order of 1-2 magnitudes, so hopefully we can manage to find optimum conditions. e.g. This paper shows that hDnmt1 has about 10% de novo activity, and that its Zn binding N-terminal domain is responsible for preventing the de novo methylation:

Bestor, T. H. Activation of mammalian DNA methyltransferase by cleavage of a Zn binding regulatory domain. EMBO J., 11: 2611–2617, 1992.

Unfortunately this is one of those projects that ran out of steam in our labs. Rather than leaving it to languish in a lab-book I thought I'd write it up here and who knows maybe someone else can push it forward.

Thanks very much to Martin Bachman the PhD student who did most of the work, and Santiago Uribe Lewis the post-doc who thought my idea was a useful enough one for his research on imprinting to take a risk on the project.

5 comments:

  1. That's good James, better share the partial success of our idea than bury it in the lab book. One reason for the partial success could be that newly formed strands (ie unmethylated) reaneal and so DNMT1 doesn't have a template!?

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  2. This is one of those things that has great uses if it's optimized. Targeted bisulfite seq is the obvious one, I guess.

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  3. Thanks for sharing. I'll try to push it!

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  4. Damn you all. This was my idea. Granted, considering the simplicity and the payoff, it was only a matter of time. So more power to you anyway!

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  5. Hi James,
    I want to study methylation of tumor DNA samples, but I have very very few quantities.
    Do you think I can use your technique to perform 4 or 5 PCR cycles in order to have more material, whithout changing the methylation level ? (expected more or less 5 percent)
    Regards,
    Simon

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