University of Pittsburgh scientists are unlocking the complexities of a recently discovered cell death process that plays a key role in health and disease, and new findings link their discovery to asthma, kidney injury and brain trauma.
The results, reported today in the journal Cell, are the early steps toward drug development that could transform emergency and critical care treatment.
Damaged or malfunctioning cells can wreak havoc on the body, so it’s essential to destroy and recycle them safely and efficiently. One way this is accomplished is through ferroptosis, a highly regulated cell death program that uses iron (“ferro” means iron), and was first discovered in 2012, explained senior author Valerian Kagan, Ph.D., D.Sc., professor in the Pitt Graduate School of Public Health’s Department of Environmental and Occupational Health. The work also was led by Sally Wenzel, M.D., director of the University of Pittsburgh Asthma Institute at UPMC, and Hülya Bay?r, M.D., research director of Pediatric Critical Care Medicine at Children’s Hospital of Pittsburgh of UPMC.
To function harmoniously, the billions of cells in the body use a sophisticated and coordinated language to communicate. Last year, the team published two papers that uncovered the signaling language that cells use to initiate ferroptosis. The communication process they found requires a group of naturally occurring oxidized phospholipids called OOH-phosphatidylethanolamines (OOH-PEs). Phospholipids are the basic building blocks that make up cell membranes, which separate what’s inside a cell from everything else outside.
However, if too many of these phospholipid signals are generated and too many cells die, the organs and tissues of the body cannot function normally.
“Discovering ferroptosis was just the tip of the iceberg – it’s essential that we learn how to keep it under control. If we want to do that, we must understand how it works,” said Kagan. “And, by discovering how several key proteins interact with the phospholipid molecules to cause ferroptosis, that is what we did. Now we can move forward with the translational work of finding ways to limit ferroptosis and prevent the massive cell death that leads to catastrophic organ and tissue failure.”
In the new work, the team used a variety of methods, including a new technique called lipodomics, to discover that the production of OOH-PE is a major crossroads at which a cell decides whether to initiate ferroptosis.
Previous research had shown that OOH-PEs were made by a group of enzymes known as 15-lipoxygenases (15LOs). In the course of its study, the team discovered that a protein called PEBP1 was acting as a “warden” controlling whether the 15LO enzymes made either OOH-PEs or another type of membrane building block. When the cell made increasing amounts of OOH-PEs, it initiated ferroptosis.
The researchers also used several cell culture experiments to demonstrate that PEBP1 and other key players in this pathway play a role in driving ferroptosis in several diseases, such as in kidney cells during renal failure, neurons in brain trauma and airway cells in asthma. Preventing PEBP1 from binding to 15LOs might be a way to prevent ferroptosis, says Kagan.
“Better treatments for traumatic brain injury and acute kidney injuries are desperately needed,” said Bay?r, co-senior author of the new work. “Gaining insight into these conditions at the molecular level is extremely crucial to developing new therapies.”
In traumatic brain and acute kidney injuries, there is typically an ever-widening area of cell death, indicating that ferroptosis is continuing unabated, even after cells involved in the initial injury have been cleared, said Bay?r, also a professor in Pitt’s departments of Critical Care Medicine and Environmental and Occupational Health. This points to a longer therapeutic window of opportunity during which the ferroptotic pathway could be targeted with drugs to halt these devastating injuries.
A future therapy targeting ferroptosis could work differently for asthma, noted Wenzel, the lead author.
“Asthma is not just about stopping an attack, it’s also about prevention – and both are a major unmet need among patients,” said Wenzel, also a professor of medicine in Pitt’s School of Medicine. “Our study identified how ferroptotic death signals can damage the cells lining the airway. Targeting these pathways could lead to both preventative and treatment options for asthma exacerbations.”
Learn more: Tracing Cell Death Pathway Points to Drug Targets for Brain Damage, Kidney Injury and Asthma
The Latest on: Ferroptosis
[google_news title=”” keyword=”ferroptosis” num_posts=”10″ blurb_length=”0″ show_thumb=”left”]- Multi-omic analysis of bat versus human fibroblasts reveals altered central metabolismon July 22, 2024 at 8:59 am
To investigate why bats are long-lived and cancer-resistant, multi-omic data from bat and human cells was analyzed using computational flux modeling, suggesting dysregulation of succinate-fumarate ...
- Cardiac Consequences: New Research Explores Alcohol’s Influence on Heart Healthon July 22, 2024 at 6:00 am
Two new, basic research studies in rodents (mice and rats) analyzed the impacts that alcohol may have on the heart. In a mouse study, abnormal heart rhythms that can occur after a pattern of repeated ...
- Major step towards a treatment for metastasison July 19, 2024 at 11:12 pm
A treatment for metastatic cancer – researchers at Friedrich-Alexander-Universität Erlangen-Nürnberg (FAU), the University of Innsbruck, the Massachusetts Institute of Technology (MIT) and Universität ...
- Reverse liver damage? Duke researchers gain ground on getting us thereon July 19, 2024 at 2:30 am
To slow or maybe even reverse organ damage linked to aging, scientists must first figure out what goes wrong at the cellular level. Duke University researchers are gaining ground on that quest with ...
- UTSW Says Experimental Compound Kills Cancer, Spares Immune Cellson July 18, 2024 at 1:40 pm
Researchers at UT Southwestern Medical Center in Dallas have identified a compound that selectively eliminates cancer cells while sparing immune cells in a form of cell death known as ferroptosis, ...
- Massive cell death study can aid cancer researchon July 18, 2024 at 9:01 am
A research team at Academia Sinica’s Institute of Molecular Biology has published findings on large-scale cell death during embryonic development, which it said can contribute to studies on cancer ...
- Targeting LILRB1 disrupts cholesterol homeostasis and promotes MM cell ferroptosison July 16, 2024 at 5:01 pm
Previous studies have suggested the importance of cholesterol metabolism in multiple myeloma (MM) cells. Since ferroptosis is closely related to lipid metabolism, researchers from Houston Methodist ...
- A treatment for metastasis? Using ferroptosis to attack migrating cancer cellson July 16, 2024 at 8:12 am
Alexander-Universität Erlangen-Nürnberg (FAU), the University of Innsbruck, the Massachusetts Institute of Technology (MIT) and Universität Würzburg have now come a major step closer to this ambitious ...
- Review highlights unique characteristics and mechanisms of ferroptosison July 14, 2024 at 8:42 pm
Junxia Min, Fudi Wang, et al., at Zhejiang University School of Medicine, China, provided an in-depth review on the programmed cell death known as ferroptosis, which is driven by iron-dependent lipid ...
- Researchers successfully rejuvenate aging livers in preclinical studyon July 7, 2024 at 5:00 pm
The study homes in on ferroptosis — a form of iron-dependent cell death — as an age-related process affecting a set of key cells in the liver, called ‘hepatocytes.’ Its authors found gene clusters ...
via Google News and Bing News