Researchers have found the 'bad seeds' of liver cancer and believe they could one day reprogram them to remain responsive to cancer treatment, a new study has found.
The key to disrupting chemo-resistant stem cells that become liver tumours from multiplying is to target the stem cell marker NANOG, said Keigo Machida, senior author and associate professor of molecular microbiology and immunology at the Keck School of Medicine of USC.
NANOG is scarce in early-stage cancer but abounds in Stage III liver cancer.
It promotes the cancer's spread by rewiring metabolism in the mitochondria -- a cell's energy factory.
"We identified the Achilles heel in cancer therapy," Machida said.
"There are bad seeds in cancer. Even though we treat patients with chemotherapy, those bad seeds survive and force relapse. That's why we would like to target the bad seeds in cancer to eradicate recurrence problems and metastasis, which is when the cancer spreads to other parts of the body."
The study is published in the journal Cell Metabolism.
Eliminating resistance
The study included patient-derived stem cells and hundreds of mice with liver tumours.
Researchers believe it is the first scientific article to identify the carcinogenic pathway of stem cell marker NANOG and to posit NANOG as a target that will eliminate patient resistance to Sorafenib, the most common chemotherapy used on liver cancer patients.
Liver cancer is on the rise.
An estimated 24,550 people died of the disease in 2015, according to the National Cancer Institute.
Only 17.2 percent of people diagnosed with liver cancer survive for five years or more.
A new cancer treatment target
To learn how NANOG reprograms stem cells that foster tumour growth, researchers examined proteins, messenger RNA and cell metabolism in the liver, said Vasu Punj, a co-author and lead bioinformatician at the USC Epigenome Center.
"Mitochondria-metabolism targeted therapy in cancer is being increasingly recognised as a promising area for future development of new, personalised treatment strategies," said Punj, an associate professor of research medicine at Keck Medicine of USC.
"If you reduce the cellular response to mitochondrial oxidative phosphorylation-fatty acid oxidation molecules, NANOG will not be able to promote cancer progression. This will enable researchers to develop novel therapeutic strategies for that cancer."
What NANOG does
NANOG controls the expression of genes that form 'mitochondrial metabolic pathways' -- energy sources -- for stem cells that turn into tumours.
It reprograms cells: Instead of using glucose as gasoline, they are ordered to use fatty acid.
"If we shut down this alternative pathway, the liver cancer will become sensitised to chemotherapy again," Machida said.
"In the future, we might be able to give liver cancer patients a shot that will infuse NANOG-targeted therapy into the blood stream. Wherever blood circulates, we will be able to deliver new instructions to the bad seeds of cancer."