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Expanding access to new tools to study childhood cancers

30 Aug 2017
Expanding access to new tools to study childhood cancers

Scientists from Howard Hughes Medical Institute at St. Jude Children's Research Hospital have created an extensive resource for studying paediatric cancers, which they are sharing widely to help accelerate research.

Led by HHMI Investigator Michael Dyer at St. Jude Children's Research Hospital, the team grew cells from patient tumours in laboratory mice, and created nearly 100 models of 12 types of paediatric cancer.

The researchers implanted the tumour cells into their organ of origin in the mice and carefully characterised them to ensure clinical relevance.

Now, Dyer and his colleagues are making samples freely available to the scientific community through the Childhood Solid Tumour Network.

Researchers worldwide will also have access to data about the tumours' sensitivity to drugs, molecular profiles, and other features.

"We want this data at the fingertips of clinicians, translational researchers, and basic scientists," Dyer says. "It's a great resource for people interested in moving new therapies forward."

Dyer's team has already used the models to identify a new drug combo that may benefit patients with recurrent rhabdomyosarcoma, an aggressive childhood cancer that begins in muscles or other soft tissue.

The team describes the new models and reports its findings in the journal Nature.

According to the American Cancer Society, paediatric cancers represent less than one percent of all cancers diagnosed each year in the United States.

Until now, scientists have had few resources available to study how they develop.

Five years ago, Dyer and his colleagues set out to create laboratory models that would give researchers new tools to study these cancers.

Their goal was to broadly represent the diversity of tumours that develop in children.

"I knew I wanted to start with all paediatric solid tumours, not just pick one or two," Dyer says.

Over the last five years, he and his colleagues obtained tumour samples from 168 patients, including tumours that arose when a patient's disease recurred after initial treatment. Cells from the tumour samples, which represented 15 types of paediatric cancers, were injected into mice and allowed to grow.

A human tumour that is grown in a mouse or other animal is called a xenograft.

It is most commonly implanted by injecting tumour cells just under the animal's skin.

Instead, Dyer's team wanted to grow their tumours in the relevant tissues; these tumours are called orthotopic xenografts.

The researchers knew that a tumour's development is influenced significantly by its microenvironment in the body.

They figured out how to get tumour cells to their tissues of origin, and then implanted each patient tumour sample into multiple mice.

Not all the tumours grew in the animals, but the team was able to establish 97 patient-derived xenografts representing 12 types of paediatric tumours.

Dyer's team then compared the molecular and cellular features of the mouse tumours to those of the patient tumours from which they were derived.

Many of the mouse tumours retained the complex makeup of the patient tumours, the researchers found.

"We know that cancer isn't a homogeneous population of tumour cells. It's a mixture of different cells," Dyer says. "For at least some of the patients, we're able to capture that complexity."

This is important, because a tumour's cellular composition can change dramatically after treatment, and the cells that persist largely determine whether a patient's cancer recurs, he says.

"With the xenografts, we can for the first time model this complexity in the laboratory."

Once the models were established, Dyer's team grew cells from 30 of the xenograft tumours in culture dishes and used them for large-scale drug screens.

They determined each tumour's sensitivity to 156 drugs, producing more than a half million data points.

The team discovered that the muscle cancer rhabdomyosarcoma is sensitive to a combination of three drugs, two of which - irinotecan and vincristine - are already widely used treatments for the disease.

The third drug, AZD1775, is an inhibitor of the enzyme WEE1, a key regulator of cell cycle progression.

Its safety when used in combination with irinotecan has recently been evaluated in paediatric patients in a phase I clinical trial.

In tests in mice with rhabdomyosarcoma xenografts, the three-drug combo had a greater effect on tumour size and growth than the standard drug regimen.

"There was a dramatic response pretty much across the board for these aggressive rhabdomyosarcoma patient-derived tumour samples," Dyer says.

He is optimistic that the new drug combination will move into clinical trials quickly, and that it may bring real benefit to patients with this difficult-to-treat disease.

Dyer's team has made the drug sensitivity data from the lab's screens available in a free, easy-to-use online database.

"The faster and easier the data is to use, the easier it is for people to test hypotheses," he says.

Likewise, Dyer is eager for the research community to use the new xenografts.

Cells from each patient-derived tumour have been preserved for future studies and the team has already distributed samples to more than 130 labs worldwide.

All the data that Dyer's team has collected with the models is available upon request including unpublished data.

The team will continue to expand the resource, developing new xenografts and incorporating more tumours that represent rare subsets of paediatric cancers.

Source: Howard Hughes Medical Institute