A drug molecule targeting RNA modifications suppresses neuroblastoma

 9
A drug molecule targeting RNA modifications suppresses neuroblastoma
Neuroblastoma is a common pediatric cancer that originates in developing nerve cells outside the brain. While increasingly intensive treatments have improved the survival of patients with high-risk neuroblastoma, currently more than 40% of patients do not survive.
 
New research shows the potential for a promising new approach to treating neuroblastoma by targeting RNA modifications associated with the disease. In a new study published in Cell Reports, scientists show that a drug molecule designed to inhibit proteins that add modifications to RNA transcripts reduced the growth of neuroblastoma cells. The treatment also suppressed the growth of neuroblastoma tumors in mouse models, suggesting that it could be an effective strategy for treatment.
 
“High risk neuroblastoma remains very difficult to cure with current approaches, and survivors are at high-risk for treatment-related toxicities, including severe chronic health conditions and second cancers,” said the senior author of the new study. “We are testing a completely different therapeutic strategy using drugs that change gene expression by inhibiting RNA modifying proteins. If future studies validate our findings, this strategy may transform our approach for treating neuroblastoma patients.”
 
Advances in genetic sequencing, data analysis, and chemical biology have identified countless genetic links to cancer, yet DNA doesn’t tell the whole story. Sometimes, molecules are added to DNA bases and RNA transcripts, affecting the way genes are expressed or how they get translated into proteins. These modifications to DNA and RNA act as molecular switches, determining whether a gene is turned on or off, thus influencing cellular processes, tissue development, and disease progression.
 
One of the most common messenger RNA modifications is N6-methyladenosine (m6A), which gets added to an RNA transcript by “writer” proteins, including a complex formed between methyltransferase-like 3 (METTL3) and methyltransferase-like 14 (METTL14). High levels of METTL3 and METTL14 are known to drive the growth of many adult cancers, so the authors wanted to look at its effects in neuroblastoma.
 
The team showed that high levels of METTL3 expression in neuroblastoma tumors were associated with significantly lower survival rates in patients. This suggests that METTL3 may drive tumor growth.
 
To investigate how METTL3 affects neuroblastoma, the team created a genetically modified version of neuroblastoma cells in which METTL3 expression was knocked down, or diminished. They also tested an inhibitor called STM2457 that inhibits the function of METTL3, synthesized by He’s team based on a published molecule structure.
 
Both approaches decreased neuroblastoma cell growth. METTL3 inhibition also increased the expression of genes that regulate the differentiation of neurons, or development into mature cells. They even saw this increased the extension of neurites, which eventually develop into axons and dendrites, a hallmark of neuroblastoma differentiation. The team also tested the STM2457 inhibitor in mouse models with neuroblastoma and found that it decreased tumor growth there as well.
 
Recently, inhibitors of METTL3 have been shown to enhance the anti-tumor effects of immunotherapy in adult cancers by promoting tumor infiltration of immune cells. When tumors are infiltrated with immune cells, they become inflamed, or “hot.” Neuroblastoma is a non-T cell inflamed, or “cold,” tumor that is resistant to immunotherapy like check point blockade drugs.
 
The teams are currently conducting studies to determine if METTL3 inhibition will modify the composition of immune cells in neuroblastoma tumors, making them “hot,” with improved response to immunotherapy. If successful, the combination of METTL3 inhibitors and immunotherapy may offer a new approach for treating neuroblastoma.