A new scientific study identified taurine, which is made naturally in the body and consumed through some foods, as a key regulator of myeloid cancers such as leukaemia, according to a paper published in the journal Nature.
The preclinical research shows that scientists are a step closer to finding new ways to target leukaemia, which is one of the most aggressive blood cancers. The Wilmot Cancer Institute investigators at the University of Rochester were able to block the growth of leukaemia in mouse models and in human leukaemia cell samples by using genetic tools to prevent taurine from entering cancer cells.
Led by Jeevisha Bajaj, PhD, the research team discovered that taurine is produced by a subset of normal cells in the bone marrow microenvironment, the tissue inside bones where myeloid cancers begin and expand. Leukaemia cells are unable to make taurine themselves, so they rely on a taurine transporter (encoded by the SLC6A6 gene) to grab taurine from the bone marrow environment and deliver it to the cancer cells.
The discovery occurred as scientists were mapping what happens within the bone marrow and its ecosystem—a longtime focus among Wilmot researchers, who have advanced the science around the microenvironment with the goal of improving blood cancer treatments.
“We are very excited about these studies because they demonstrate that targeting uptake by myeloid leukaemia cells may be a possible new avenue for treatment of these aggressive diseases,” said Bajaj, an assistant professor in the Department of Biomedical Genetics and a member of Wilmot’s Cancer Microenvironment research program.
Researchers also discovered that as leukaemia cells drink up taurine, it promotes glycolysis (a breakdown of glucose to produce energy) to feed cancer growth. Prior to this, the authors said, it was not known that taurine might have a cancer-promoting role.
Leukaemia has several subtypes and survival rates vary. This study finds that taurine transporter expression is essential for the growth of multiple subtypes including acute myeloid leukaemia (AML), chronic myeloid leukaemia (CML), and myelodysplastic syndromes (MDS), which all originate from blood stem cells in the bone marrow. Future studies will investigate signals from the microenvironment that promote the transition of MDS, a precursor to leukaemia, to acute leukaemia.
