Annealing complementary primers
Introduction
A simple and cheap way to make a short (< 100 bp) piece of DNA is to order two complementary primers from a company such as Invitrogen. Other options are described under part fabrication and annealing and primer extension. Having annealed the primers, you most likely want to use them as an insert into a vector (the linked page describes BioBrick vectors). Here are some pages that describe methods to assemble two parts if they correspond to a BioBricks standard -
Method
Primer reconstitution
When the primers arrive, redissolve them in 50 mM Tris buffer to yield a concentration of ~800 ng/μl. See this page on reconstituting primers for more information.
Annealing Mix
- For the annealing mix one recipe that works is as follows -
- 8 μL of each of the concentrated primers.
- 4 μL of salt solution (10 mM NaCl)
- 20 μL of water
Option 1
Anneal the primers by heating them at least 5°C above their melting point and cooling them down slowly in stages using a Thermocycler. Melting temperature calculations can best be done using software such as VectorNTI or data may come with the primers themselves.
Option 2
A simpler approach is to add the above mix in a PCR tube to a beaker of boiling water and just allow the water to cool down naturally. Most primers pairs with length less than 100bp should be fully melted at 100oC and certainly any non-specific binding should be melted at that temperature.
Notes
- Unless you have ordered your primers with 5' phosphate added you will probably improve the efficiency of any subsequent cloning steps by adding the 5' phosphate using a protocol such as PNK Treatment of DNA Ends
- As the paired oligos cool, they will also form multimers of your insert. To release them, you should heat the mixture of your vector and insert DNA to about 65C and let it cool prior to adding ligase.
- The salt shields the negative charges on the single-stranded DNA molecules, allowing them to come close enough to bind. The salt concentration listed above is designed to give an excess of positive sodium ions over negatively charged DNA bases.
