Epigenetic regulation of genes involved in cell growth, survival, or differentiation through histone modifications is an important determinant of cancer development and outcome. The basic science of epigenetics uses analytical tools that, although powerful, are not well suited to the analysis of heterogeneous cell populations found in human cancers, or for monitoring the effects of drugs designed to modulate epigenetic mechanisms in patients. To address this, we selected three clinically relevant histone marks (H3K27me3, H3K9ac, and H3K9me2), modulated their expression levels by in vitro treatments to generate high and low expressing control cells, and tested the relative sensitivity of candidate antibodies to detect the differences in expression levels by flow cytometry using a range of sample preparation techniques. We identified monoclonal antibodies to all three histone marks that were suitable for flow cytometry. Staining intensities were reduced with increasing formaldehyde concentration, and were not affected by ionic strength or by alcohol treatment. A protocol suitable for clinical samples was then developed, to allow combined labeling of histone marks and surface antigens while preserving light scatter signals. This was applied to normal donor blood, and to samples obtained from 25 patients with leukemia (predominantly acute myeloid leukemia). Significant cellular heterogeneity in H3K9ac and H3K27me3 staining was seen in normal peripheral blood, but the patterns were very similar between individual donors. In contrast, H3K27me3 in particular showed considerable inter-patient heterogeneity in the leukemia cell populations. Although further refinements are likely needed to fully optimize sample staining protocols, "flow epigenetics" appears to be technically feasible, and to have potential both in basic research, and in clinical application. V C 2013 International Society for Advancement of Cytometry Key terms epigenetics; histone; leukemia; flow cytometry; drug treatment WITH the rapid development and application of sequencing technologies, it is becoming evident that alterations at the genome level are unlikely to explain the heterogeneity of human cancers (1), and there is increasing recognition that epigenetic mechanisms also play a major role in cancer development and progression. The epigenetic regulation of genes is complex, and occurs at the levels of DNA, histone proteins, and RNA (2-4). DNA methylation at promoter regions can cause long term gene silencing, whereas histone modifications, predominantly affecting lysines in the N-terminal tails of the core histone proteins H3 and H4, are more dynamic and associated with relatively short term plasticity.The most frequent lysine modifications of histone proteins ("marks") involve acetylation and methylation, although phosphorylation, ubiquitylation and sumoylation can also occur at these sites. Histone acetylation, which alters the charge distribution, is typically associated with open chromatin that enables gene transcription, whereas meth...
