LM-PCR permits highly representative whole genome amplification of DNA isolated from small number of cells and paraffin-embedded tumor tissue sections.

Analysis of genetic changes is often hampered by insufficient starting DNA from limited clinical tissue specimens. We employed ligation-mediated PCR (LM-PCR) for global amplification of the genome to overcome this limitation, generating up to 5 microg of representative amplicons of genomic DNA from as little as one cell. We demonstrate successful global genome amplification in high-quality starting DNA source like laser-captured cultured cells, as well as partially degraded starting DNA from old formalin-fixed paraffin-embedded tissue sections. This process generates adaptor-tailed templates that can be repeatedly amplified almost ad infinitum. We have further modified this technique such that, instead of a single endonuclease digest, we can achieve higher amplicon coverage by combining 3 endonuclease digests prior to LM-PCR. As tested by examining amplification of STS sequences scattered genome-wide, the coverage was improved from the published 70% to 96%. The faithful representation of global losses and gains in the amplified genomic DNA was confirmed by array-comparative genomic hybridization. Further, we exemplify the utility of this technique for finer p53 point mutation analysis by PCR-SSCP. This technique is thus a clinically useful tool for globally amplifying and archiving DNA from finite sources like paraffin tissue sections, providing a potentially unlimited resource for genetic analyses.