The study, published today (3 March 2021) in Nature Communications, found that MRT arises from developmental cells in the neural crest* whose maturation is blocked by a genetic defect. The team also identified two drugs that could be used to overcome this block and resume normal development, bringing hope of new treatments for the disease.
Malignant rhabdoid tumour (MRT) is a rare soft tissue cancer that predominantly affects infants. Although these tumours may arise in any part of the body, they usually form in the kidney and the brain. MRT is one of the childhood cancers with the poorest outcomes.
The rarity of MRT, with only 4-5 cases per year in the UK, combined with its aggressiveness, make clinical trials extremely difficult. Until now, the origin of MRT has not been known and no reliably effective treatment currently exists. This new study sought to discover the root of MRT in the hope of identifying new treatments for the disease.
For this study, two cases of MRT were whole genome sequenced at the Wellcome Sanger Institute, alongside corresponding normal tissues. The researchers then conducted phylogenetic analyses of the somatic mutations in the diseased and healthy tissue, in order to 'reconstruct' the timeline of normal and abnormal development.
The analyses confirmed that MRT develops from progenitor cells on their way to becoming Schwann cells, a cell type found in the neural crest, due to a mutation in the SMARCB1 gene. This mutation blocks the normal development of these cells, which can then go on to form MRT.
Researchers at the Princess Máxima Center for Pediatric Oncology then inserted the intact SMARCB1 gene into patient-derived MRT organoids**, artificial tumours grown in the laboratory from the patients' original tumours, to successfully overcome the maturation block that had prevented normal development and led to cancer. Based on single-cell mRNA analyses and predictions made from these experiments, the researchers then identified two existing medicines that overcome the maturation block and could thus be used to treat children with MRT.
Dr Jarno Drost, co-lead author of the study from the Princess Máxima Center for Pediatric Oncology, said: "To be able to identify where malignant rhabdoid tumour (MRT) comes from for the first time is an important step in being able to treat this disease, but to confirm that it is possible to overcome the genetic flaw that can cause these tumours is incredibly exciting. The fact that two drugs already exist that we think can be used to treat the disease gives us hope that we can improve outcomes for children diagnosed with MRT."
Professor Richard Grundy, Chair of the Children's Cancer and Leukaemia Group, said: "It is fantastic to see this collaborative research bearing highly translatable outcomes in a childhood cancer with a currently poor prognosis. It emphasises the significant benefit of a National Tumour banking system, that allows collection of rarer tumours and in turn, the best use of such precious tissue through agreement of the CCLG Biological Studies committee that oversees this resource. For this to result in such a meaningful outcome gives new hope to children with malignant rhabdoid tumour (MRT)."
MRT remains a cancer with very poor outcomes for which few new treatments are on the horizon. This study harnesses cutting edge quantitative and experimental methods, to identify a potential new treatment for MRT.
Dr Sam Behjati, co-lead author of the study from the Wellcome Sanger Institute, said: "We began our enquiry into the origins of malignant rhabdoid tumours in late 2019, so we have gone from hypothesis to discovery of origin to possible treatments for the disease in just over a year. This was possible due to all the leading-edge tools available to us, from organoid technology to single-cell mRNA sequencing to drug screen databases. I hope this study will serve as the blueprint for discovering the origin of other childhood cancers and, ultimately, lead to better outcomes for children affected by these awful diseases."
INFORMATION:
Contact details:
Dr Matthew Midgley
Press Office
Wellcome Sanger Institute
Cambridge, CB10 1SA
Phone: 01223 494856
Email: press.office@sanger.ac.uk
Notes to Editors:
* The neural crest is a temporary group of stem cells from which many other cell types, including bone, cartilage and certain types of neural cell, arise during development.
** More information on organoids and how they are being used to fight cancer is available here: https://www.broadinstitute.org/news/organoids-emerge-powerful-tools-disease-modeling-and-drug-discovery
Publication:
Lars Custers, Eleonora Khabirova and Tim H.H. Coorens et al. (2021). Somatic mutations and single cell transcriptomes reveal the root of malignant rhabdoid tumours. Nature Commnications. DOI: https://doi.org/10.1038/s41467-021-21675-6
Funding:
This research was supported by the Dutch Cancer Society, the European Research Council (ERC), Children Cancer-free foundation (KiKa), the St. Baldrick's Foundation and Wellcome.
Selected websites:
About the Princess Máxima Center
Every year some 600 children in the Netherlands are diagnosed with cancer. One in four children with cancer still dies from the disease.
In order to cure children from cancer, all care and research in the Netherlands is concentrated in the Princess Máxima Center for pediatric oncology in Utrecht. More than ten years ago, parents and healthcare professionals took the initiative. The new pediatric oncology center was opened by Queen Máxima of the Netherlands on 5 June 2018.
The mission of the Princess Máxima Center is to cure every child with cancer, with optimal quality of life. The Princess Máxima Center is the largest pediatric oncology center in Europe where care and research are closely intertwined. Approximately 400 scientists and more than 800 healthcare professionals work closely together. Read more at https://www.prinsesmaximacentrum.nl/en
The Wellcome Sanger Institute
The Wellcome Sanger Institute is a world leading genomics research centre. We undertake large-scale research that forms the foundations of knowledge in biology and medicine. We are open and collaborative; our data, results, tools and technologies are shared across the globe to advance science. Our ambition is vast - we take on projects that are not possible anywhere else. We use the power of genome sequencing to understand and harness the information in DNA. Funded by Wellcome, we have the freedom and support to push the boundaries of genomics. Our findings are used to improve health and to understand life on Earth. Find out more at http://www.sanger.ac.uk or follow us on Twitter, Facebook, LinkedIn and on our Blog.
About Wellcome
Wellcome exists to improve health by helping great ideas to thrive. We support researchers, we take on big health challenges, we campaign for better science, and we help everyone get involved with science and health research. We are a politically and financially independent foundation. https://wellcome.org/
