Glioblastomas are the most common malignant brain tumours. Because of their rapid growth, the prognosis for those affected is usually dismal. Many patients hold out hopes for novel therapeutic approaches, which utilise drug-bound antibodies directed against specific markers present on the surface of a subpopulation of immature glioblastoma cells. These antibody-drug conjugates bind to the surface, are then internalised and kill the cancer stem cells.

However, results published in April 2019 in the journal Nature Communications suggest that this approach may be misdirected. Cancer stem cells, including their progeny, are able to adapt to environmental conditions and undergo reversible transformations into various cell types, thereby altering their surface structures. The results imply that novel therapeutic approaches, which target specific surface structures of cancer stem cells, will be of limited utility.

Remarkable cell state transitions

 “We exposed cancer cells in the laboratory to certain stressors, such as drug treatment or oxygen deficiency,” explains Dr Anna Golebiewska, Junior Principal Investigator at the NORLUX Neuro-Oncology Laboratory in LIH’s Department of Oncology and co-first author of the study. “We were able to show that glioblastoma cells react flexibly to such stress factors and simply transform themselves at any time into cell types with a different set of surface markers.” This plasticity allows the cells to adapt to their microenvironment and reach a favourable environment-specific heterogeneity that enables them to sustain and grow, and mostly likely to escape also therapeutic attacks.

The team of scientists from Luxembourg, Norway and Germany, led by Prof Simone P. Niclou at LIH, proposes that neoplastic cells of other tumour types may be also less constrained by defined hierarchical principles, but rather can adapt their characteristics to the prevailing environmental conditions. “The same phenomenon has been observed in breast and skin cancer,” says Dr Golebiewska. “This observation predicts that cancer therapies specifically directed against cancer stem cell markers may not be successful in patients.”

The new findings could help to optimise future standard treatments. In laboratory experiments, the researchers were able to show that environmental factors, such as lack of oxygen in combination with signals from the tumour microenvironment can induce cancer cells to modify their characteristics. This microenvironment, the immediate surrounding of the cancer, comprises cells and molecules that influence the growth of the tumour. “Once we understand exactly what causes the plasticity of tumor cells, we can devise combination therapies which target the signals underlying plasticity and thereby improve the therapeutic impact,” underlines Dr Golebiewska.

Collaboration and funding

The study is a collaborative work between the NORLUX Neuro-Oncology Laboratory and other research units and platforms at LIH. The researchers from LIH also worked in close collaboration with their long-term national partners to whom they are tightly connected through transversal research programmes: the Luxembourg Centre for Systems Biomedicine (LCSB) at the University of Luxembourg and the Department of Neurosurgery of the Centre Hospitalier de Luxembourg. Moreover, the project was carried out with international partners from the Technische Universität Dresden, Germany, the University of Heidelberg, Germany, and the University of Bergen, Norway. This joint undertaking of different research and clinical players gives a truly interdisciplinary dimension to the study.

The study is a major part of the PhD thesis of Dr Anne Dirkse, co-first author on the publication, who was supported by an AFR PhD grant (#5778172 – PhD2013-1/BM) from the Luxembourg National Research Fund (FNR) and a training grant from the Fondation du Pélican de Mie et Pierre Hippert-Faber (Fondation de Luxembourg). Furthermore, the work was supported by funding from LIH, Sächsisches Staatsministerium für Wissenschaft und Kunst (SMWK), Deutsche Krebshilfe and Deutsche Forschungsgemeinschaft (DFG).

Link to publication: Stem cell-associated heterogeneity in Glioblastoma results from intrinsic tumor plasticity shaped by the microenvironment