A new drug may offer improved treatment options for a type of childhood cancer down the track, a study in animal models has shown.
Research by Australian scientists could pave the way to a new treatment for a currently incurable brain cancer in children called Diffuse Intrinsic Pontine Glioma, or DIPG. Affecting about 20 children in Australia each year, DIPG is a devastating disease with an average survival time of just nine months after diagnosis.
The research in mice models, led by scientists at Children’s Cancer Institute and UNSW and published this week in Cell Reports, offers a new therapeutic approach for the treatment of DIPG by using a new anti-cancer drug.
The new drug, CBL0137, is an anti-cancer compound developed from the antimalarial drug quinacrine. The researchers found that CBL0137 directly reverses the effects of the key genetic drivers in DIPG in mice, and has a profound effect against DIPG tumour models. They also found CBL0137 is even more effective when combined with a second drug, panobinostat, a new type of drug known as a histone deacetylase (HDAC) inhibitor. When used in combination, the two drugs were found to work synergistically, each enhancing the other’s effects against DIPG.
UNSW Conjoint Associate Professor David Ziegler, Group Leader at Children’s Cancer Institute and paediatric oncologist at the Kids Cancer Centre, Sydney Children’s Hospital, said there was a desperate need for a new and more effective way to treat DIPG.
“Over the years, many different types of treatments have been tried for DIPG, but none so far have proven effective in clinical trials of children with the disease,” he said. “Part of the problem is that the genetic driver in DIPG is a master gene that controls thousands of other genes. Until now, we have not known how to switch it off. Our data shows that CBL0137 acts to reverse the effects of this master gene, and then switch off the growth of the DIPG tumour cells.”
In the newly published study, A/Professor Ziegler and his colleagues at the Children’s Cancer Institute built on earlier research carried out by the Institute, which found that CLB037 was effective against neuroblastoma. Taking a similar approach with DIPG, the group confirmed that CBL0137 interferes with the growth of DIPG tumours by inhibiting an important molecule known as FACT (needed for DNA transcription, replication and repair). They found that FACT binds with the key genetic driver in DIPG – a mutation called K27M. By treating DIPG cells with CBL0137 they were able to target this gene and stop tumour cells from growing. Next, they tested CBL0137 in ‘patient-derived xenografts’ − mice specially bred to grow DIPG cells taken directly from children with the disease − showing it effectively penetrated the blood-brain barrier and increased survival time.
When the researchers added panobinostat to the mix, they found that the CBL0137-panobinostat combination was even more effective at killing DIPG cells and further improved the survival time of mice with DIPG.
"K27M is the Achilles heel of DIPG tumour cells,” said Associate Professor Ziegler. “The finding that CBL0137 indirectly acts against this genetic driver is very exciting, and gives us great hope for this treatment strategy.”
A/Prof Ziegler will lead an international clinical trial of CBL0137 for children with DIPG that will open in the top children’s hospitals in the US and Australia. Plans to launch the trial are boosted by the fact that CBL0137 has recently successfully completed testing in phase I clinical trials in adults with solid tumours.
This work was supported by grants from the National Health and Medical Research Council, Cancer Institute NSW, the DIPG Collaborative, The Cure Starts Now, Kid’s Cancer Project, Cure Brain Cancer Foundation, Levi’s Project and the Benny Wills Brain Tumour Research Fund.