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Starving cancer cells of sugar -- does it work?

Date:
January 26, 2018
Source:
Duke-NUS Medical School
Summary:
Researchers from the Duke-NUS Medical School and collaborators from Austria have demonstrated for the first time a novel cell death pathway that describes how depletion of sugar causes cancer cell death.
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Previous research have shown that rapidly dividing cancer cells require higher levels of sugar than healthy cells. This dependency on sugar distinguishes cancer cells from normal cells and is often used as a treatment option to kill cancer cells. In reality, the results have not been encouraging. Not all cancer cell types are sensitive to the removal of sugar, and even for the cancers that are sensitive, sugar depletion only slows down the rate of cancer progression. The pathways that sensitise cancer cells to sugar deprivation remains poorly understood.

In the research led by Singapore team under Duke-NUS Associate Professor Koji Itahana, along with a team of collaborators led by Dr. Egon Ogris of the Max F. Perutz Laboratories (MFPL), in Austria, they have demonstrated for the first time a novel cell death pathway that describes how depletion of sugar caused cancer cell death. The article was published in Science Signaling's January issue.

Novel role of glucose

It was long believed that sugar served as one of the main energy sources for cancer cells. However, the team discovered that in some cancer cells, tiny levels of sugar that were incapable of providing sufficient energy ensured the survival of the cancer cells. This meant that there is a previously undiscovered role of sugar for survival, besides providing energy. The team subsequently found that sugar has a novel signalling function in cancer cells whereby its deprivation would trigger voltage differences across cancer cell membrane, leading to a flowing of calcium ions into the cells and subsequently cell death.

Novel therapeutic approach

The team speculated that this unique property of sugar in cancer cells could be manipulated for a novel therapeutic approach. By combining the inhibition of sugar intake and the increase of calcium levels in cancer cells, they managed to kill cancer cells while leaving healthy cells intact. Itahana and colleagues also found that certain cancer cells lost the ability to sustain intracellular sugar levels after sugar deprivation and speculated this to be the primary reason why not all cancer cells are sensitive to sugar deprivation. By applying the combination treatment to the suitable cancer cell types, this could be a novel treatment combination against cancer. The team aims to extend their results to develop a new cancer treatment in the future.

The new combination therapy based on this finding are on international patent application no. PCT/SG2017/050208 for "A potential combination therapy using an inhibitor of glucose transport and an intracellular calcium inducer to target cancer metabolism."


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Materials provided by Duke-NUS Medical School. Note: Content may be edited for style and length.


Journal Reference:

  1. Ha Yin Lee, Yoko Itahana, Stefan Schuechner, Masahiro Fukuda, H. Shawn Je, Egon Ogris, David M. Virshup, Koji Itahana. Ca2 -dependent demethylation of phosphatase PP2Ac promotes glucose deprivation–induced cell death independently of inhibiting glycolysis. Science Signaling, 2018; 11 (512): eaam7893 DOI: 10.1126/scisignal.aam7893

Cite This Page:

Duke-NUS Medical School. "Starving cancer cells of sugar -- does it work?." ScienceDaily. ScienceDaily, 26 January 2018. <www.sciencedaily.com/releases/2018/01/180126095312.htm>.
Duke-NUS Medical School. (2018, January 26). Starving cancer cells of sugar -- does it work?. ScienceDaily. Retrieved December 21, 2024 from www.sciencedaily.com/releases/2018/01/180126095312.htm
Duke-NUS Medical School. "Starving cancer cells of sugar -- does it work?." ScienceDaily. www.sciencedaily.com/releases/2018/01/180126095312.htm (accessed December 21, 2024).

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