Detailed analysis of two brain tumour subtypes has revealed that they may originate from the same type of neural progenitor cells and be distinguished by gene mutation patterns and by the composition of their microenvironments.

The results of a study led by investigators at Massachusetts General Hospital (MGH) and the Broad Institute of MIT and Harvard are being published in the March 31 issue of Science.

"Our study redefines the cellular composition of two closely related gliomas characterised by mutations in the IDH gene - astrocytomas and oligodendrogliomas," says Mario Suvà, MD, PhD, of the MGH Department of Pathology and the Center for Cancer Research, co-senior author of the Science paper. "While we know these are genetically distinct tumour types, we did not know whether they had similar cells of origin or if their expression differences could be explained by genetics, by the cells from which they developed, or by the tumour microenvironment."

Several recent studies, including The Cancer Genome Atlas, have identified mutations driving tumour growth and defined tumour subtypes based on analysing gene expression in tissue samples that include both tumour cells and cells from the surrounding microenvironment.

But the fact that these analyses are done in bulk pieces of tumours masks many critical pieces of information.

Single-cell RNA sequencing, which measures RNA transcription on a cell-by-cell basis, offers detailed insights into tumour biology but can only be done in a limited number of tumours due to financial and logistic constraints.

The MGH team hypothesised that combining single-cell RNA data from a limited number of tumours with existing bulk expression data from large study groups could reveal many key aspects of brain tumour biology.

Both astrocytomas and oligodendrogliomas are considered incurable, but surgery and radio/chemotherapy can significantly extend survival.

The tumours are believed to develop from subtypes of the glial cells that support and protect neurons and are known to differ in terms of genetics, appearance and gene expression.

While both types of tumour contain cells similar to the glial cells for which they are named -- astrocytes and oligodendrocytes - they also each contain markers of both cell types, calling into question the common belief that they originate in those distinct cell types.

Combining RNA sequencing results from more than 9,800 cells from 10 astrocytomas and more than 4,300 cells from 6 oligodendrogliomas with 165 bulk expression profiles from The Cancer Genome Atlas revealed that both types of tumour contained three different types of cancer cells: nonproliferating cells that have differentiated into either astrocyte- or oligodendrocyte-like cells as well as cells that resemble neural stem or progenitor cells and drive tumor growth.

Differences between the two types of tumour appear to be determined primarily by genetic differences and in the composition of the tumour microenvironment, such as the abundance of specific immune cells.

"We were surprised to find that cancer cells from these two tumour subtypes share similar stem cell programs and glial lineages of differentiation," says Suvà. "Additionally, we observed that cancer cells that become more differentiated do not proliferate, even in more advanced tumours. That suggests that pushing cells towards differentiation -- something we currently do not know how to do in patients -- could significantly halt tumour growth. As these tumours share stem cell programs that drive their growth, an alternative approach could be to target specific cell types with immunotherapies. We now plan to use similar approaches to study other types of adult and paediatric gliomas to get additional insight into their origins and the programs driving their aggressiveness."