Methods and reagents: Wayward PCR primers

Methods and reagents is a unique monthly column that highlights current
discussions in the newsgroup bionet.molbio.methds-reagnts, available on the
Internet. This month's column discusses the failure of PCR primers that have
been kept a long time to amplify DNA. For details on how to partake in the
newsgroup, see the accompanying box.

Some netters have noticed a loss in the ability to amplify DNA by the
polymerase chain reaction (PCR) when using the same batch of primers over a
period of time. PCR primers performed well shortly after being purchased, but
after storage for several months as diluted stocks in water within a
non-frost-free -20 degrees C freezer, these same primers failed to give the
same amount of amplified product in identical reactions. If new primers were
purchased, the reactions gave good results and acted just like the old primers
did before storage.

Bad seed, bad storage or bad company?
*************************************
The reason behind this phenomenon has been baffling netters as they search for
a way to avoid buying a new set of primers every few months. One idea is that
the failure occurs when doing long and accurate (LA) PCR, a sometimes difficult
operation in itself, and that the carryover that contaminates products from
earlier PCR samples used as template is to blame. This has been described by
Wayne Barnes as the `bad seed' in an earlier Methods and reagents column [see
TIBS 19 (1994), 341-342]. It could explain why PCR fails over time, but cannot
explain why newly purchased primers would work.

Some netters became highly concerned about the storage conditions for their own
primers when hearing of this, because larger projects requiring as many as
several hundred sets of primers could cost enormous sums of money to replace. 

One netter, Richard Maleszka (maleszka@rsbscentral.anu.edu.au), wrote about his
experience with long-term storage of primers frozen at -25 degrees C in water
at pH 7.0. He found that three-month-old primers of 22-24 nucleotides in length
initially worked beautifully, but after a longer storage period they didn't
yield any amplification product.

While others were calling for hard evidence that the primers are at fault, Mike
Cooley (mbcooley@ucdavis.edu) wrote that he has been using nested PCR to detect
very rare events, and is therefore pushing the sensitivity limit of PCR. He was
unable to amplify fragments from DNA that had succeeded about a year previously
under identical conditions. After ordering new oligos and performing
side-by-side comparisons with both sets of oligos, he confirmed that the
primers had `gone bad'.

Bad primers were also to blame for unreadable results in automated DNA
sequencing reactions using the dye-terminator chemistry combined with cycle
sequencing and subsequent analysis on the ABI model 373A sequencer. The same
conditions had previously given good results with fresh primers. 

Another netter observed loss of signal with 5'-fluorescent-tagged primers
stored at a concentration of 10 pmol/ul in Tris/EDTA buffer for six months.
Fluorescent signal strength was reduced three or more orders of magnitude
depending on the primer set, compared with the same primers used under the
identical conditions six months previously. However, it was not clear whether
the fluorescent label degraded or somehow detached from the oligo, or whether
the amplification was failing for some other reason.

Some paranoid biologists suggested that the companies producing the synthetic
oligos have somehow altered the process in order to make the primers unstable,
and that programmed obsolescence is part of a deviously clever money-making
ploy. Although this is unlikely, the time frame for successful use of the
oligos presents the companies with no reason to correct the problem. It is more
probable, however, that the relaxed manner in which molecular biologists
generally store their primer stocks has rendered them useless.

One possible cause of the failure is that the primers fall apart somehow or
that trace contaminants left over from the chemical synthesis reactions change
over time. This could cause degradation or modification of the synthetic DNA
even at low temperatures, or inhibit the activity of Taq polymerase during the
cycling program. For example, after the synthesis reactions, there could be a
slow alteration of the oligo at the 3'-base, which may prohibit its extension
by polymerase. 

Although freezing and thawing has not been found to adversely affect the
quality of double-stranded DNA samples as tested by visual inspection on
ethidium-bromide-stained agarose gels [1], a plausible cause could be multiple
freeze-thaw cycles. Roger Aeschbacher (aeschba@fmi.ch) suggested that some
primer sets cause PCR failure by nonspecific priming because they are more
likely to form primer dimers or intrastrand secondary structures, such as
hairpins, only after undergoing multiple cycles of warming and slow freezing.
This would not affect all sets of primers in the same way, explaining why some
may require fewer freeze-thaw cycles to become nonfunctional in PCR relatively
quickly, whilst others remain functional. That is, some primers fail after a
certain time and others purchased from the same company on the same date work
fine.

Waxing lyrical about hot start PCR
**********************************
Performing hot start PCR can sometimes correct the problem. Hot start PCR is a
method that produces cleaner PCR products by bringing the temperature of the
template DNA and primer mix above the threshold of nonspecific annealing before
the first enzymatic extension by the thermostable polymerase. This is
accomplished by withholding a critical component from the reaction mixture, and
is usually performed by separating the template and primers from the buffer
components and thermostable polymerase with a physical barrier of wax. The wax
melts between 60 degress C and 80 degress C, and the separated components mix by
convection. Denaturation of template occurs and subsequent cycling begins [2,3].

The use of wax for hot start PCR has been a hot topic on the net. Instead of
buying pre-fabricated wax nuggets for PCR, many netters have been making their
own from blocks of low-melting-temperature paraffin, canning wax or
Paraplast[R] medium, normally used for embedding pathological tissue specimens
[4]. Others have invented their own recipes, mixing anything from 10% to 80%
v/v mineral oil with the wax to soften it into more malleable lumps.

One method for creating beads the correct size to fit a PCR tube is to melt a
chunk of wax at 80 degrees C and pipet 50-100 ul aliquots onto a sheet of
aluminum foil or into the individual wells of a 96-well round-bottom microtiter
plate (the latter gives uniformity to the shape of the pellets). After cooling,
the foil/dish can be jarred upside down onto a piece of sterile filter paper on
the benchtop to dislodge the nuggets, and a sterile syringe needle may be used
to `prick up' the beads, which should be stored in a sterile container until
used.  One other useful method is to create a grease barrier, instead of a wax
barrier, by dispensing generic petroleum jelly from a syringe fitted with an
18-gauge needle [5].

Protecting your primers
***********************
While hot start PCR may help reduce nonspecific annealing to template DNA for
each individual problem primer set, this would be impractical on a larger
scale. A more permanent fix could be to denature the bad primer stock at 95
degrees C to 100 degrees C for 5 min and then quickly cool it in a dry
ice/ethanol bath or liquid nitrogen. This snap cooling would prevent any dimer
formation and possibly restore the stock to its former condition.

Although it is still not clear that the primers went belly up because of the
freezing and thawing cycles, one recommendation for protecting primer stocks
may be to avoid temperature fluctuations by aliquoting out dilutions of the
concentrated primers and storing them at 4 degrees C. Only thawing those to be
used during the course of one or two experiments could save the original stock
from an untimely demise. This would also be an intelligent prophylactic
maneuver to avoid the risk of introducing nucleases from ungloved fingers, or
other contaminants, into the undiluted primer stocks. A more long-term solution
would be to store the primers at -70 degrees C as lyophilized aliquots.

References 

[1] Anonymous (1983) BRL Focus 5(2), 10 

[2] D'Aquila, R. T. et al. (1991) Nucleic Acids Res. 19, 3749 

[3] Chou, Q. et al. (1992) Nucleic Acids Res. 20, 1717-1723 

[4] Wainwright, L. A. and Seifert, H. S. (1993) BioTechniques 14, 34-36 

[5] Horton, R. M., Hoppe, B. L. and Conti-Tronconi, B. M. (1994) BioTechniques
    16, 42-43

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Any statements made by the author are not meant to advocate the use of a
particular commercial product or endorse any company. All opinions are
those of the author and do not reflect the opinion of the National Cancer
Institute or the National Institutes of Health.

Copyright: This manuscript is not copyrighted by Elsevier Publishing Company.
However, you may not reproduce any portion for resale or edit the text for
redistribution, sale, or otherwise without written permission from the author.

You found this at the World Wide Web (WWW) Uniform Resource Locator (URL)
ftp://ftp.ncifcrf.gov/pub/methods/TIBS/jan95.txt

Any reference to this column must be cited as the following published article:
Hengen, P. N. 1994. Methods and reagents - Wayward PCR primers
Trends in Biochemical Sciences 20(1):42-44.

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* Paul N. Hengen, Ph.D.                           /--------------------------/*
* National Cancer Institute                       |Internet: pnh@ncifcrf.gov |*
* Laboratory of Mathematical Biology              |   Phone: (301) 846-5581  |*
* Frederick Cancer Research and Development Center|     FAX: (301) 846-5598  |*
* Frederick, Maryland 21702-1201 USA              /--------------------------/*
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