Longer Lives, Fewer Age-Related Illnesses
Living long and well may eventually be more possible, thanks to a surprise result of the work of scientists at The Wistar Institute in Philadelphia. While developing a new cancer drug, the researchers discovered that mice lacking a specific protein live longer lives with fewer age-related illnesses. The mice, which lack the TRAP-1 protein, demonstrated less age-related tissue degeneration, obesity, and spontaneous tumor formation when compared to normal mice. The teams findings could change how scientists view the metabolic networks within cells.
A release from the institute notes that in healthy cells, TRAP-1 is an important regulator of metabolism and has been shown to regulate energy production in mitochondria, organelles that generate chemically useful energy for the cell. In the mitochondria of cancer cells, TRAP-1 is universally overproduced.
The Wistar study, which was published online in August 2014 in the journal Cell Reports, shows how “knockout” mice bred to lack the TRAP-1 protein compensate for this loss by switching to alternative cellular mechanisms for making energy.
The release quotes Dario C. Altieri M.D., director of The Wistar Institute’s National Cancer Institute-designated Cancer Center, as saying, “We see this astounding change in TRAP-1 knockout mice, where they show fewer signs of aging and are less likely to develop cancers. Our findings provide an unexpected explanation for how TRAP-1 and related proteins regulate metabolism within our cells. We usually link the reprogramming of metabolic pathways with human diseases, such as cancer. What we didn’t expect to see were healthier mice with fewer tumors.”
Altieri and his colleagues created the TRAP-1 knockout mice as part of their ongoing investigation into their novel drug, Gamitrinib, which targets the protein in the mitochondria of tumor cells. TRAP-1 is a member of the heat shock 90 (HSP90) protein family, which are “chaperone” proteins that guide the physical formation of other proteins and serve a regulatory function within mitochondria. Tumors use HSP90 proteins, like TRAP-1, to help survive therapeutic attack.
“In tumors, the loss of TRAP-1 is devastating, triggering a host of catastrophic defects, including metabolic problems that ultimately result in in death of the tumor cells,” Altieri said. “Mice that lack TRAP-1 from the start, however, have three weeks in the womb to compensate for the loss of the protein.”
The researchers found that in their knockout mice, the loss of TRAP-1 causes mitochondrial proteins to misfold, which then triggers a compensatory response that causes cells to consume more oxygen and metabolize more sugar. This causes mitochondria in knockout mice to produce deregulated levels of ATP, the chemical used as an energy source to power all the everyday molecular reactions that allow a cell to function.