- DNase footprinting assay
A DNase footprinting assay is a DNA footprinting technique from molecular biology/biochemistry that detects DNA-protein interaction using the fact that a protein bound to DNA will often protect that DNA from enzymatic cleavage. This makes it possible to locate a protein binding site on a particular DNA molecule. The method uses an enzyme, deoxyribonuclease (DNase, for short) to cut the radioactively end-labeled DNA, followed by gel electrophoresis to detect the resulting cleavage pattern.
For example, the DNA fragment of interest may be PCR amplified using a 32P 5' labeled primer, with the end result being many DNA molecules with a radioactive label on one end of one strand of each double stranded molecule. Cleavage by DNase will produce fragments, the smaller of which will move further on the electrophoretic gel. The fragments which are smaller with respect to the 32P-labelled end will appear further on the gel than the longer fragments. The gel is then used to expose a special photographic film.
The cleavage pattern of the DNA in the absence of a DNA binding protein, typically referred to as free DNA, is compared to the cleavage pattern of DNA in the presence of a DNA binding protein. If the protein binds DNA, the binding site is protected from enzymatic cleavage. This protection will result in a clear area on the gel which is referred to as the "footprint".
By varying the concentration of the DNA-binding protein, the binding affinity of the protein can be estimated according to the minimum concentration of protein at which a footprint is observed.
This technique was developed by David Galas and Albert Schmitz at Geneva in 1977
- DNA footprinting
- DNase I
- ^ Brenowitz M, Senear DF, Shea MA, Ackers GK (1986). "Quantitative DNase footprint titration: a method for studying protein-DNA interactions". Methods in Enzymology 130: 132–81. doi:10.1016/0076-6879(86)30011-9. PMID 3773731.
- ^ Galas DJ, Schmitz A (Sep 1978). "DNAse footprinting: a simple method for the detection of protein-DNA binding specificity". Nucleic Acids Research 5 (9): 3157–70. doi:10.1093/nar/5.9.3157. PMC 342238. PMID 212715. http://nar.oxfordjournals.org/cgi/pmidlookup?view=long&pmid=212715.
Wikimedia Foundation. 2010.