The study, published recently in the journal Cell, was led by Pere Puigsever of Harvard Medical School and the Dana-Farber Cancer Institute and included Patrick Griffin, co-chair of the TSRI Department of Molecular Medicine, and Theodore Kamenecka, TSRI Associate Professor of Molecular Medicine. The compound they identified, called SR-18292, modifies a protein known as PGC-1α. This protein plays a pivotal role in energy balance and helps control genes involved in energy metabolism. When cells overexpress PGC-1, during fasting or starvation, for example, glucose production in the liver soars. But when scientists modify PGC-1α function through a process called acetylation, glucose production declines. “This protein was generally considered non-druggable,” said Griffin. “But the team approached the problem through the process of acetylation, which means we can influence the protein’s behavior indirectly. SR-18292 increases acetylation of PGC-1, which in turn shuts down glucose production in liver cells.”
Suppressing this overproduction makes PGC-1αa target ripe for exploitation in anti-diabetes treatments. “After the screening process found several potential candidates, the TSRI team designed derivatives of those initial hits,” Griffin said. “We selected this compound based on its ability to induce acetylation and the fact that it had good pharmaceutical properties–so we could use it in animal models of Type 2 diabetes.” While it isn’t known at this point what protein or enzyme is directly targeted by SR-18292, Griffin explained, this new compound, plus several others we’ve made, can be used as chemical tools to study the regulation of glucose metabolism. The researchers added that these same small molecules could one day be developed as either a single agent to treat diabetes, or used in combination with current anti-diabetic drugs. The first author of the study, “Small Molecule Screen Identifies Selective PGC-1α Gluconeogenic Inhibitors that Ameliorate Type 2 Diabetes,” is Kfir Sharabi of Dana-Farber and Harvard Medical School. Other authors include Hua Lin of TSRI; Clint D. J. Tavares, John E. Dominy and Amy K. Rines of Dana-Farber and Harvard Medical School; Mark P. Jedrychowski and Steve P. Gygi of Harvard Medical School; Joao Paulo Camporez and Rachel J. Perry of Howard Hughes Medical Institute and Yale University; Jaemin Lee and Umut Ozcan of Boston Children's Hospital, Harvard Medical School; Marc Hickey, Melissa Bennion, Michelle Palmer, Partha P. Nag, Josh A. Bittker and José Perez of the Broad Institute of MIT and Harvard University.
The study was supported by the National Institutes of Health (grants F32 DK102293-01, U54HG005032, R24DK080261, R01DK-409369, 2U2CDK059635, R03DA032468 and R01 DK069966), the American Heart Association (15POST22880002) and the American Diabetes Association (1-16-PDF-111 and 7-12-MN-68).