AIMS: Our aim was to evaluate and optimise methylation-sensitive restriction enzyme assays for use in formalin-fixed, paraffin-embedded tissue (FFPET) samples, in order to improve the application of the HUMARA X-chromosome inactivation assay to FFPET samples. METHODS: We extracted DNA from normal male colon and thyroid FFPET. Several DNA clean-up procedures and restriction enzyme buffer compositions were tested for two methylation-sensitive enzymes, HhaI and HpaII and a non-methylation-sensitive isoschizomere, MspI. RESULTS: By including both a non-methylation-sensitive control enzyme and DNA from male archival specimens in our experiments, we were able to detect even subtle degrees of incomplete digestion. We showed that FFPET-derived DNA is a poor substrate for restriction enzymes, especially for methylation-sensitive restriction endonucleases. An optimised DNA clean-up protocol and restriction enzyme buffer-mix allowed us to achieve complete digestion. CONCLUSIONS: The combination of multiple, rigorous controls, DNA clean-up and restriction buffer optimisation increases the reliability of HUMARA-based X-chromosome inactivation analysis of FFPET samples. Analogous approaches are likely to allow optimisation of other restriction enzyme-based assays of FFPET samples.
AIMS: Our aim was to evaluate and optimise methylation-sensitive restriction enzyme assays for use in formalin-fixed, paraffin-embedded tissue (FFPET) samples, in order to improve the application of the HUMARA X-chromosome inactivation assay to FFPET samples. METHODS: We extracted DNA from normal male colon and thyroid FFPET. Several DNA clean-up procedures and restriction enzyme buffer compositions were tested for two methylation-sensitive enzymes, HhaI and HpaII and a non-methylation-sensitive isoschizomere, MspI. RESULTS: By including both a non-methylation-sensitive control enzyme and DNA from male archival specimens in our experiments, we were able to detect even subtle degrees of incomplete digestion. We showed that FFPET-derived DNA is a poor substrate for restriction enzymes, especially for methylation-sensitive restriction endonucleases. An optimised DNA clean-up protocol and restriction enzyme buffer-mix allowed us to achieve complete digestion. CONCLUSIONS: The combination of multiple, rigorous controls, DNA clean-up and restriction buffer optimisation increases the reliability of HUMARA-based X-chromosome inactivation analysis of FFPET samples. Analogous approaches are likely to allow optimisation of other restriction enzyme-based assays of FFPET samples.