Genetic Discovery Helps Determine the Difference Between Aggressive & Benign Bone Tumors
Osteosarcoma cell with DNA in blue, energy factories (mitochondria) in yellow and actin filaments, part of the cellular skeleton, in purple. Credit: Dylan Burnette and Jennifer Lippincott-Schwartz, NIH
The first genetic marker for the bone tumor, osteoblastoma, has been discovered by scientists at the Wellcome Sanger Institute and their collaborators. Whole-genome and transcriptome sequencing of human bone tumors revealed that a genetic change that affects the transcription factor, FOS, is a hallmark mutation of osteoblastoma.
The results, published in Nature Communications, will help clinicians correctly distinguish benign osteoblastoma tumors from aggressive osteosarcoma tumors and direct the correct treatment.
Osteoblastoma is the most common benign tumor of the bone, mainly affecting children and adults between the ages of 10 and 25. It is treated by surgical removal of the tumor, however the diagnosis of osteoblastoma can be challenging. Under the microscope, osteoblastoma tumors can look very similar to osteosarcoma, an aggressive form of bone cancer that requires extensive treatment, sometimes including amputation or significant surgery and chemotherapy.
In this new study, scientists from the Wellcome Sanger Institute and their collaborators at the UCL Cancer Institute and Francis Crick Institute discovered a genetic mutation that distinguishes osteoblastoma from osteosarcoma.
The team carried out whole genome and whole transcriptome* sequencing on five osteoblastoma tumors and one osteoid osteoma tumor.
Researchers discovered a mutation that affects FOS, a transcription factor that turns on and off genes to ensure they are expressed in the right cell at the right time, as well as its relative, FOSB.
When the team extended their results in a study of 55 cases they found that mutations in FOS and FOSB are ubiquitous across osteoblastoma and osteoid osteoma.
To explore whether their result could be useful as diagnostic markers for osteoblastoma, scientists examined the whole genome sequences of 55 osteosarcoma cases, and found none of the samples harboured mutations in FOS or FOSB. When the team analysed over 2,500 non-osteoblastoma tumors, they again did not find similar mutations, meaning the FOS and FOSB mutations are specific to osteoblastoma.
Dr Sam Behjati, co-lead author from the Wellcome Sanger Institute and University of Cambridge, said: “The main clinical challenge when diagnosing osteoblastoma can be to reliably distinguish these tumors from osteosarcoma. These two forms of bone tumor require very different treatments: osteoblastoma tumors just need removing to ease symptoms, whereas osteosarcomas is treated aggressively with surgery and intensive chemotherapy. For the first time, we have discovered a specific mutation that defines osteoblastoma.”
Dr Matthew Fittall, co-first author from the Francis Crick Institute, UCL Cancer Institute and Wellcome Sanger Institute, said: “We have known for a while that FOS is involved in the progression of bone tumors, however we have not found mutations of FOS in human bone-forming tumors before. Using genomic sequencing we have shown that mutations in FOS and its relative FOSB are diagnostic markers of osteoblastoma.”
Professor Adrienne Flanagan, co-lead author from the UCL Cancer Institute and Royal National Orthopaedic Hospital NHS Trust, said: “Genomics is transforming our understanding of cancers. Our discovery of the genetic mutation that characterizes osteoblastoma will help clinicians diagnose it with more confidence and direct the correct treatment.”
This article has been republished from materials provided by the Sanger Institute. Note: material may have been edited for length and content. For further information, please contact the cited source.
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