Improvements in public health have allowed humankind to survive to older ages than ever before, but, for many people, these added golden years are not spent in good health. Aging is a natural part of life, but it is associated with a greatly increased incidence of most chronic diseases, including various cancers, diabetes, and Alzheimer’s disease.

The laboratory of Kris Burkewitz, assistant professor of cell and developmental biology, wants to figure out if there is a way to break the links between the aging process and disease so that we can stay healthy longer, allowing us to better enjoy our later years. To accomplish this goal, the Burkewitz lab focuses on how cells organize their internal compartments, or organelles, and how organelle structures can influence cellular function, metabolism, and disease risk.

In his most recent paper, published in Nature Cell Biology, Burkewitz describes a new way by which cells adapt to the aging process: by actively remodeling the endoplasmic reticulum, one of the cell’s largest and most complex organelles. His team found that aging cells remodel their ER through a process called ER-phagy, which selectively targets specific ER subdomains for breakdown. The discovery that ER-phagy is involved in aging highlights this process as a possible drug target for age-related chronic conditions such as neurodegenerative diseases and various metabolic disease contexts.

Ferroptosis: a promising therapeutic strategy in glioblastoma👇

✅Glioblastoma multiforme (GBM) is an aggressive brain tumor characterized by rapid growth and resistance to conventional therapies. Recent research highlights ferroptosis, a regulated form of cell death driven by iron-dependent lipid peroxidation, as a novel and promising approach for GBM treatment.

✅One key mechanism underlying ferroptosis in GBM is glutathione depletion. Inhibition of the cystine/glutamate antiporter system (xCT) limits cystine uptake, leading to reduced glutathione synthesis. As a consequence, the antioxidant enzyme GPX4 becomes inactivated, impairing the cell’s ability to detoxify lipid peroxides.

✅Lipid peroxidation is a central event in ferroptosis. Polyunsaturated fatty acids (PUFAs) incorporated into membrane phospholipids are highly susceptible to oxidative damage. Their conversion into peroxidized phospholipids (PL-PUFA-PE) disrupts membrane integrity and drives lethal oxidative stress.

✅Iron metabolism further amplifies ferroptotic signaling in GBM cells. Elevated intracellular iron, particularly the Fe²⁺ pool, catalyzes redox reactions that generate reactive oxygen species (ROS). This iron-driven ROS production accelerates lipid peroxidation and pushes tumor cells toward ferroptotic death.

✅Collectively, glutathione depletion, GPX4 inactivation, uncontrolled lipid peroxidation, and dysregulated iron metabolism converge to induce ferroptosis. Targeting these interconnected pathways offers a potential strategy to overcome therapy resistance and selectively eliminate GBM cells.