91Ƭ

Skip to main content
MenuSearch & Directory

SLU Research: High Fat or ‘Ketogenic’ Diets Could Prevent, Reverse Heart Failure

by Maggie Rotermund on 10/26/2020
Media Inquiries

Maggie Rotermund
Senior Media Relations Specialist
maggie.rotermund@slu.edu
314-977-8018

Reserved for members of the media.

10/26/2020

ST. LOUIS – Research from Saint Louis University finds that high fat or “ketogenic” diets could completely prevent, or even reverse heart failure caused by a metabolic process.

The research team, led by Kyle S. McCommis, Ph.D., assistant professor in Biochemistry and Molecular Biology at SLU, looked at a metabolic process that seems to be turned down in failing human hearts.

Kyle McCommis, Ph.D.
Kyle S. McCommis, Ph.D., is an assistant professor in Biochemistry and Molecular Biology. Submitted photo.

In an animal model, drastic heart failure in mice was bypassed by switching to high fat or “ketogenic” diets, which could completely prevent, or even reverse the heart failure.

“Thus, these studies suggest that consumption of higher fat and lower carbohydrate diets may be a nutritional therapeutic intervention to treat heart failure,” McCommis said.

The findings, were published online Oct. 26 in . This research, which was initiated during McCommis’ postdoctoral and junior faculty positions at Washington University School of Medicine, then was completed at Saint Louis University School of Medicine.

The heart’s myocardium requires vast amounts of chemical energy stored in nutrients to fuel cardiac contraction. To maintain this high metabolic capacity, the heart is flexible and can adapt to altered metabolic fuel supplies during diverse developmental, nutritional, or physiologic conditions. Impaired flexibility, however, is associated with cardiac dysfunction in conditions including diabetes and heart failure.

The mitochondrial pyruvate carrier (MPC) complex, composed of MPC1 and MPC2, is required for pyruvate import into the mitochondria. This study demonstrates that MPC expression is decreased in failing human and mouse hearts, and that genetic deletion of the MPC in mice leads to cardiac remodeling and dysfunction.

“Interestingly, this heart failure can be prevented or even reversed by providing a high-fat, low carbohydrate “ketogenic” diet,” McCommis said. “A 24-hour fast in mice, which is also “ketogenic” also provided significant improvement in heart remodeling.”

Diets with higher fat content, but enough carbohydrates to limit ketosis also significantly improved heart failure in mice lacking cardiac MPC expression.

“Our study reveals a critical role for mitochondrial pyruvate utilization in cardiac function, and highlights the potential of dietary interventions to enhance cardiac fat metabolism to prevent or reverse cardiac dysfunction and remodeling in the setting of MPC-deficiency,” McCommis said.

Ongoing studies will seek to uncover the importance of ketone body versus fate metabolism in this process of improved cardiac remodeling.

Takeaways

This study is supported by the National Institutes of Health grants K99/R00 HL136658 (to KSM), R01 HL133178 (to RWG), and R01 HL119225 and R01 DK104735 (to BNF) supported these studies.

The work also was supported with core resources of the Nutrition Obesity Research Center, Diabetes Research Center and Institute for Clinical and Translational Sciences (ICTS) at the Washington University School of Medicine.

Other authors include Attila Kovacs, Department of Medicine, Washington University School of Medicine; Carla K. Weinheimer, Department of Medicine, Washington University School of Medicine; Trevor M. Shew, Department of Medicine, Washington University School of Medicine; Timothy R. Koves, Duke Molecular Physiology Institute, Duke University School of Medicine; Olga R. Ilkayeva of Duke Molecular Physiology Institute, Duke University School of Medicine; Dakota R. Kamm, Department of Biochemistry and Molecular Biology, Saint Louis University School of Medicine; Kelly D. Pyles, Department of Biochemistry and Molecular Biology, Saint Louis University School of Medicine; M. Todd King, Laboratory of Metabolic Control, National Institute on Alcohol Abuse and Alcoholism, National Institutes of Health; Richard L. Veech, Laboratory of Metabolic Control, National Institute on Alcohol Abuse and Alcoholism, National Institutes of Health; Brian J. DeBosch, Departments of Pediatrics and Cell Biology and Physiology, Washington University School of Medicine; Deborah M. Muoio, Duke Molecular Physiology Institute, Duke University School of Medicine; Richard W. Gross, Department of Medicine, Washington University School of Medicine and Department of Chemistry, Washington University in St. Louis; and Brian N. Finck, Department of Medicine, Washington University School of Medicine.

Veech passed away during the preparation of the manuscript.

Saint Louis University School of Medicine

Established in 1836, Saint Louis University School of Medicine has the distinction of awarding the first medical degree west of the Mississippi River. The school educates physicians and biomedical scientists, conducts medical research, and provides health care on a local, national and international level. Research at the school seeks new cures and treatments in five key areas: cancer, liver disease, heart/lung disease, aging and brain disease, and infectious diseases.