Diversity of Clinically Relevant Outcomes Resulting from Hypofractionated Radiation in Human Glioma Stem Cells Mirrors Distinct Patterns of Transcriptomic Changes.

Darius Kalasauskas,Sven Reiner Kantelhardt,Margret Rave-Fraenk,Gabriela Salinas,Alf Giese,Maxim Sorokin,Lennart Opitz,Sina Viehweg,Alhassan Elmasri,Ella L Kim,Anton Buzdin,Walter Schulz-Schaeffer,Bettina Sprang

doi:10.3390/cancers12030570

Abstract

Hypofractionated radiotherapy is the mainstay of the current treatment for glioblastoma. However, the efficacy of radiotherapy is hindered by the high degree of radioresistance associated with glioma stem cells comprising a heterogeneous compartment of cell lineages differing in their phenotypic characteristics, molecular signatures, and biological responses to external signals. Reconstruction of radiation responses in glioma stem cells is necessary for understanding the biological and molecular determinants of glioblastoma radioresistance. To date, there is a paucity of information on the longitudinal outcomes of hypofractionated radiation in glioma stem cells. This study addresses long-term outcomes of hypofractionated radiation in human glioma stem cells by using a combinatorial approach integrating parallel assessments of the tumor-propagating capacity, stemness-associated properties, and array-based profiling of gene expression. The study reveals a broad spectrum of changes in the tumor-propagating capacity of glioma stem cells after radiation and finds association with proliferative changes at the onset of differentiation. Evidence is provided that parallel transcriptomic patterns and a cumulative impact of pathways involved in the regulation of apoptosis, neural differentiation, and cell proliferation underly similarities in tumorigenicity changes after radiation.

Highlights

Glioblastoma (GB) is the most malignant form of astrocytic tumors in adults with dismal prognosis [1]
In agreement with the general hypothesis that glioma stem cells (GSCs) are primarily responsible for maintaining tumor growth after radiochemotherapy, our data reveal that the tumor-promoting capacity in some types of GSCs can be significantly augmented by fractionated radiation (fr-IR) treatment
While it is inarguable that propensity to self-renew is the fundamental characteristic of GSCs, there are divergent views on the role of self-renewal as the primary factor in determining the degree of tumor-propagating capacity or radioresistance in GSCs

Summary

Introduction

Glioblastoma (GB) is the most malignant form of astrocytic tumors in adults with dismal prognosis [1]. The current paradigm of gliomagenesis and malignant progression is centered on so-called glioma stem cells (GSCs) implicated as the most tumorigenic type of glioma cells driving GBs growth before and after therapy [6,7,8,9]. Owing to their unique biological properties such as an unlimited capacity to self-renew and inherent plasticity, GSCs are capable of maintaining the tumor homeostasis and perpetuating intratumoral heterogeneity, which is as an important factor contributing to GBs resistance to cytotoxic and targeted therapies [10,11,12]

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