University of Utah researchers have found that deficiency of an antioxidant response protein called nuclear erythroid-2 like factor-2 (Nrf2) delays or prevents hypertrophic cardiomyopathy, a type of a heart failure in which the heart muscle grows abnormally thick.
This new finding, published in the Oct. 1, 2013, issue of Cardiovascular Research, suggests that restoring the normal balance of reduction-oxidation chemical reactions in the body could prevent heart disease and other conditions caused by reductive stress.
Nuclear erythroid-2 like factor-2 (Nrf2) is a key regulatory protein in the signaling pathway that triggers the body's primary defense against oxidative stress, a condition where increased production of oxygen-containing free radicals causes cell damage. Many cardiac diseases, including hypertrophic cardiomyopathy, are linked to oxidative stress. However, in a previous study, University of Utah researchers demonstrated that reductive stress, the counterpart of oxidative stress, can also harm the heart due to excessive levels of an antioxidant called reduced glutathione.
"Heart muscle cells, like all cells, are sensitive to shifts in the chemical reactions occurring inside and around them," says Namakkal S. Rajasekaran, Ph.D., research assistant professor of internal medicine at the University of Utah and principal author on the study. "While antioxidants are widely considered an important defense against heart disease, an increasing body of evidence indicates that excessive antioxidant activity can harm the body by creating a condition of reductive stress."
Rajasekaran and his colleagues studied laboratory mice with heart disease caused by mutations in alpha B-Crystallin, a protein that normally helps other proteins fold inside cells. These mice develop mutant protein aggregation cardiomyopathy (MPAC), a type of heart failure characterized by reductive stress and protein aggregation, the clumping together of misfolded proteins.
"From our earlier research, we know that Nrf2 is a critical regulator of antioxidant activity and sustained activation of Nrf2 causes reductive stress, which contributes to MPAC," says Rajasekaran. "In this study, we investigated whether disrupting Nrf2 can decrease the activity of antioxidant pathways and prevent the development of cardiac disease."