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New drug triggers tissue regeneration: Faster regrowth and healing of damaged tissues
Last updated: Friday 12 June 2015 at 2am PST
Adapted media release
Research focuses on select tissues injured through disease, surgery and transplants, but early findings indicate potential for broad applications
The concept sounds like the stuff of science fiction: take a pill, and suddenly new tissues grow to replace damaged ones.
Researchers at Case Western Reserve and UT Southwestern Medical Center this week announced that they have taken significant steps toward turning this once-improbable idea into a vivid reality. In a study published in the June 12 edition of Science, they detail how a new drug repaired damage to the colon, liver and bone marrow in animal models -- even going so far as to save the lives of mice who otherwise would have died in a bone marrow transplantation model.
"We are very excited," said Sanford Markowitz, MD, PhD, the Ingalls Professor of Cancer Genetics at the university's School of Medicine and a medical oncologist at University Hospitals Case Medical Center's Seidman Cancer Center. "We have developed a drug that acts like a vitamin for tissue stem cells, stimulating their ability to repair tissues more quickly. The drug heals damage in multiple tissues, which suggests to us that it may have applications in treating many diseases."
The institutions collaborating on this work next hope to develop the drug -- now known as "SW033291" -- for use in human patients. Because of the areas of initial success, they first would focus on individuals who are receiving bone marrow transplants, individuals with ulcerative colitis, and individuals having liver surgery. The goal for each is the same: to increase dramatically the chances of a more rapid and successful recovery.
The key to the drug's potential involves a molecule the body produces that is known as prostaglandin E2, or PGE2. It is well established that PGE2 supports proliferation of many types of tissue stem cells. Markowitz and University of Kentucky Professor Hsin-Hsiung Tai earlier had demonstrated that a gene product found in all humans, 15-hydroxyprostaglandin dehydrogenase (15-PGDH), degrades and reduces the amount of PGE2 in the body.
Markowitz, also a Harrington Discovery Institute Scholar-Innovator, and James K.V. Willson, MD, a former Case Western Reserve colleague now at UT-Southwestern, hypothesized that inhibiting 15-PGDH would increase PGE2 in tissues. In so doing, it would promote and speed tissue healing. When experiments on mice genetically engineered to lack 15-PGDH proved them correct, the pair began searching for a way to inactivate 15-PGDH on a short-term basis.
The preliminary work began in test tubes. Yongyou Zhang, PhD, a Case Western Reserve research associate in Markowitz's lab and a lead author on the study, developed a test where cells glowed when 15-PGDH levels changed. Zhang then traveled to UT Southwestern's Harold C. Simmons Comprehensive Cancer Center, where Willson serves as director. Zhang and UT Southwestern researchers Bruce Posner, PhD, and Joseph Ready, PhD, collaborated to comb through the center's library of 230,000 different chemicals. Ultimately they identified one chemical that they found inactivated 15-PGDH.
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