Conversion of differentiated cancer cells into cancer stem-like cells in a glioblastoma model after primary chemotherapy

Glioblastoma multiforme patients have a poor prognosis due to therapeutic resistance and tumor relapse. It has been suggested that gliomas are driven by a rare subset of tumor cells known as glioma stem cells (GSCs). This hypothesis states that only a few GSCs are able to divide, differentiate, and initiate a new tumor. It has also been shown that this subpopulation is more resistant to conventional therapies than its differentiated counterpart. In order to understand glioma recurrence post therapy, we investigated the behavior of GSCs after primary chemotherapy. We first show that exposure of patient-derived as well as established glioma cell lines to therapeutic doses of temozolomide (TMZ), the most commonly used antiglioma chemotherapy, consistently increases the GSC pool over time both in vitro and in vivo. Secondly, lineage-tracing analysis of the expanded GSC pool suggests that such amplification is a result of a phenotypic shift in the non-GSC population to a GSC-like state in the presence of TMZ. The newly converted GSC population expresses markers associated with pluripotency and stemness, such as CD133, SOX2, Oct4, and Nestin. Furthermore, we show that intracranial implantation of the newly converted GSCs in nude mice results in a more efficient grafting and invasive phenotype. Taken together, these findings provide the first evidence that glioma cells exposed to chemotherapeutic agents are able to interconvert between non-GSCs and GSCs, thereby replenishing the original tumor population, leading to a more infiltrative phenotype and enhanced chemoresistance. This may represent a potential mechanism for therapeutic relapse.Glioblastoma multiforme (GBM) is a heterogeneous, highly invasive brain tumor, which is treated with a multimodal approach that includes surgery followed by radio- and chemotherapy.¹ Temozolomide (TMZ) is currently the best chemotherapeutic drug available on the market against malignant glioma because of its ability to cross the blood–brain barrier (BBB). Even after such an aggressive therapeutic intervention, disease relapse is inevitable due to GBM''s infiltrative nature and ability to resist conventional therapies.^{2, 3} Thus, understanding the mechanisms of therapeutic escape and disease recurrence is crucial for developing more effective treatments against GBM.GBMs are among the first solid tumors in which the discovery of stem-like tumor-initiating cells has suggested the existence of a hierarchical model of tumorigenesis. Such a dogma proposes that a distinct population of tumor cells, referred to as glioma stem cells (GSCs), are not only responsible for driving tumor growth, but also represent a population that can survive intensive oncological therapies and give rise to recurrent malignancies.^{4, 5} In the clinical setting, the presence of CD133+ GSCs correlates with a shorter overall survival as well as reduced progression-free survival and is considered a critical target for successful antiglioma therapies.⁶The inability of conventional treatments, such as radio- and chemotherapies, to exterminate all infiltrative tumor foci is considered one of the main causes of therapeutic failure and malignant recurrence in GBM. Although the radio-resistance properties of glioma cells are fairly well established, the underlying molecular mechanisms of chemoresistance have been addressed only in a few studies.^{7, 8} On the basis of this, we set to investigate the biology of GSCs following TMZ therapy both in vitro and in vivo. We observed significant expansion of different GSC subpopulations after exposure to TMZ at the plasma (50 μM) and cerebral spinal fluid (CSF; 5 μM) concentrations detected in GBM patients.^{9, 10, 11, 12} This expansion arises from the high degree of plasticity that exists within glioma cell populations. After long-term exposure to therapeutic concentrations of TMZ, differentiated tumor cells convert into glioma stem-like cells. These newly formed GSCs acquire phenotypic and functional characteristics similar to those of native GSCs. Once implanted orthotopically in the animal brain, these newly converted GSCs demonstrate a very invasive characteristic similar to that of parental GSCs. In light of these findings, we propose that TMZ may induce specific changes in the tumor microenvironment, which facilitate a GSC-specific ‘niche'', thereby providing the necessary contextual signals to initiate the interconversion between differentiated tumor cells and GSCs. Therefore, such cellular plasticity represents a new mechanism for therapeutic resistance in GBM, and understanding this may allow us to optimize TMZ-based antiglioma chemotherapy.