New cancer research targets ‘trunk’ of cancer
A cancer breakthrough may pave the way for personalized cancer treatments.
Cancer growth can be illustrated by how a tree grows. It grows quickly and grows branches. These branches allow the cancer to adapt, and make it resist treatment. But, like the tree, it has a common trunk, which will be a more effective target.
Researchers discovered that even if cancer cells mutate to different forms over time, they also have common mutations—or the ‘trunk of the cancer’— that can be isolated and targeted by the immune system.
Study co-author Dr Sergio Quezada compares the process to cops and robbers. ““The body’s immune system acts as the police trying to tackle cancer, the criminals. Genetically diverse tumours are like a gang of hoodlums involved in different crimes – from robbery to smuggling. And the immune system struggles to keep on top of the cancer – just as it’s difficult for police when there’s so much going on.”
“Our research shows that instead of aimlessly chasing crimes in different neighbourhoods, we can give the police the information they need to get to the kingpin at the root of all organised crime – or the weak spot in a patient’s tumour – to wipe out the problem for good.” Continued Quezada who is a Cancer Research UK scientist and head of the Immune Regulation and Cancer Immunotherapy lab at University College London (UCL) Cancer Institute
Instead of cops and robbers, we have the immune system and antigens.
UCL Researchers found that all cancer cells in a tumour share a common genetic fault. These faults, called antigens, can be targeted to take a tumour down.
After finding the common antigen, it’s just a matter of finding an immune system cell, called T-cells, that can destroy it.
This research, published in Science, paves the way for therapies that specifically activate these T cells to target all the tumour cells at once based on the disease’s genetic signature. In the future, scientists could exploit this by developing a therapeutic vaccine to activate T-cells, or harvesting, growing and administering T-cells back into the patient that recognise the antigens common to every cancer cell.
Professor Charles Swanton, co-author from the UCL Cancer Institute and a Francis Crick Institute scientist, said: “This is exciting. There was evidence that complex tumours with many mutations could increase the chance of the immune system spotting them; now we can prioritise and target tumour antigens that are present in every cell, the Achilles heel of these highly complex cancers.
“This opens up a way to look at individual patients’ tumours and profile all the antigen variations to figure out the best ways for immunotherapy treatments to work, prioritising antigens present in every tumour cell and identifying the body’s immune T cells that recognise them. This is really fascinating, and takes personalised medicine to its absolute limit where each patient would have a unique, bespoke treatment.”
Dr Quezada added: “For many years we have studied how the immune response to cancer is regulated without a clear understanding of what it is that immune cells recognise on cancerous cells. Based on these new findings, we will be able to tell the immune system how to specifically recognise and attack tumours.”
Professor Peter Johnson, Cancer Research UK’s chief clinician, said: “This fascinating research gives us vital clues about how to specifically tailor treatment for a patient using their immune system.
“It gets us closer to knowing why some patients respond to immunotherapy treatment and others don’t, and how we might select which patients will benefit the most.
“As well as suggesting a new way to treat cancer, the research fills key gaps in our knowledge about the effects of the immune system on tumours. This gives us hope of developing better treatments for some of the cancers we have previously found hardest to treat.”
Sam Howard, Chief Executive of Rosetrees Trust, said: “Rosetrees Trust is delighted to be able to support such cutting edge research carried out by outstanding researchers, which potentially has a direct human impact.”