Histone Methylation Dynamics and Gene Regulation Occur through the Sensing of One-Carbon Metabolism

Authors
Mentch SJ1, Mehrmohamadi M2, Huang L3, Liu X4, Gupta D4, Mattocks D5, Gómez Padilla P4, Ables G5, Bamman MM6, Thalacker-Mercer AE4, Nichenametla SN5, Locasale JW7.
10-21-2015
12:00pm
PST
Categories
Transcription Mechanism & Biology
Speaker
Roman Camarda
Abstract
S-adenosylmethionine (SAM) and S-adenosylhomocysteine (SAH) link one-carbon metabolism to methylation status. However, it is unknown whether regulation of SAM and SAH by nutrient availability can be directly sensed to alter the kinetics of key histone methylation marks. We provide evidence that the status of methionine metabolism is sufficient to determine levels of histone methylation by modulating SAM and SAH. This dynamic interaction led to rapid changes in H3K4me3, altered gene transcription, provided feedback regulation to one-carbon metabolism, and could be fully recovered upon restoration of methionine. Modulation of methionine in diet led to changes in metabolism and histone methylation in the liver. In humans, methionine variability in fasting serum was commensurate with concentrations needed for these dynamics and could be partly explained by diet. Together these findings demonstrate that flux through methionine metabolism and the sensing of methionine availability may allow direct communication to the chromatin state in cells.