• Profile
Close

Researcher studies incurable blood disease usually diagnosed in children

Newswise May 15, 2019

Treating a stubborn blood disease that strikes children may come down to tweaking energy production in stem cells, suggests research out of West Virginia University.

Wei Du, an assistant professor in the School of Pharmacy, is investigating the link between how stem cells make energy and how Fanconi anemia develops. The disease makes it harder for bone marrow to churn out the blood cells our bodies need to fight illnesses, stanch bleeding, and transport oxygen. It also makes repairing damaged DNA more difficult.

“Almost all of the kids with Fanconi anemia will develop leukemia eventually,” said Du, who co-leads the Alexander B. Osborn Hematopoietic Malignancy and Transplantation Program at the WVU Cancer Institute. According to St. Jude Children’s Research Hospital, the average lifespan for people with the disease is between 20 and 30 years.

Du and her research team discovered that, in animal models of Fanconi anemia, stem cells tended to use aerobic—or oxygen-based—processes to make energy. That’s unusual: normally stem cells found in bone marrow and blood prefer an anaerobic process that doesn’t rely on oxygen.

This metabolic distinction suggests that Fanconi anemia’s diverse symptoms—from fatigue and shortness of breath, to frequent bruising and nosebleeds—may hinge on cellular-level energy production.

In fact, a single step in the metabolic process seems crucial. The researchers identified a specific signaling pathway—called the p53-TIGAR axis—that was overexpressed in the anemic models. The overexpression correlated to the aerobic “rerouting” of the stem cells’ energy production.

The current standard of care for Fanconi anemia includes bone marrow transplant, but as Du explained, it works less than one-third of the time. “In people with Fanconi anemia, blood cells aren’t the only ones that have a mutation,” she said. “So do other cells in other parts of the body that support stem cell survival.” For that reason, the patients’ bodies can’t support the replication of healthy, transplanted normal cells properly, and their anemia persists.

But Du’s findings could lead to new and better treatments for Fanconi anemia. One promising option is a drug that inhibits the overactivation of the p53-TIGAR signal. Preventing p53-TIGAR from inordinate activation may guide the stem cells’ energy production back to the usual pathway.

Her insights might even deepen researchers’ understanding of gene-therapy techniques. “If you know more about diseases of the stem cell—how they regulate energy, and how they regulate differentiation and self-renewal—you probably can improve gene therapy as well,” Du said. “If you can manually balance the energy production of the diseased stem cells then maybe this can be a benefit when you harvest those gene-delivery cells and transplant them into the patient.”

Go to Original
Only Doctors with an M3 India account can read this article. Sign up for free or login with your existing account.
4 reasons why Doctors love M3 India
  • Exclusive Write-ups & Webinars by KOLs

  • Nonloggedininfinity icon
    Daily Quiz by specialty
  • Nonloggedinlock icon
    Paid Market Research Surveys
  • Case discussions, News & Journals' summaries
Sign-up / Log In
x
M3 app logo
Choose easy access to M3 India from your mobile!


M3 instruc arrow
Add M3 India to your Home screen
Tap  Chrome menu  and select "Add to Home screen" to pin the M3 India App to your Home screen
Okay