Decreasing glioma recurrence through adjuvant cancer stem cell inhibition

Biologics: Targets and Therapy, Jun 2010

Decreasing glioma recurrence through adjuvant cancer stem cell inhibition Josh Neman, Rahul JandialDivision of Neurosurgery, City of Hope National Cancer Center, Duarte, CA, USAAbstract: Gliomas remain one of the most challenging solid organ tumors to treat and are marked clinically by invariable recurrence despite multimodal intervention (surgery, chemotherapy, radiation). This recurrence perhaps, is as a consequence of the failure to eradicate a tumor cell subpopulation, termed cancer stem cells. Isolating, characterizing, and understanding these tumor-initiating cells through cellular and molecular markers, along with genetic and epigenetic understanding will allow for selective targeting through therapeutic agents and holds promise for decreasing glioma recurrence.Keywords: glioma, cancer stem cells, epigenetic

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Decreasing glioma recurrence through adjuvant cancer stem cell inhibition

Biologics:Targets and Therapy Decreasing glioma recurrence through adjuvant cancer stem cell inhibition Josh Neman Rahul Jandial 0 0 Division of Neurosurgery, City of Hope National Cancer Center , Duarte, CA , USA Gliomas remain one of the most challenging solid organ tumors to treat and are marked clinically by invariable recurrence despite multimodal intervention (surgery, chemotherapy, radiation). This recurrence perhaps, is as a consequence of the failure to eradicate a tumor cell subpopulation, termed cancer stem cells. Isolating, characterizing, and understanding these tumor-initiating cells through cellular and molecular markers, along with genetic and epigenetic understanding will allow for selective targeting through therapeutic agents and holds promise for decreasing glioma recurrence. Introduction Malignant gliomas are the most frequent cancers of the central nervous system and remain the most clinically challenging solid organ tumor.1 The median survival for glioblastoma multiform patients has been a dismal 12 months, even with surgery, radiation, and chemotherapy.2 With the recent use of the DNA alkylating agent temozolomide, the median survival has increased by two months to approximately 14 months.3 This small yet significant increase in survival represents the greatest advancement in malignant glioma treatment over the last four decades. Recurrences occur almost exclusively in the brain, both at the site of initial tumor presentation and at distance, for example, the opposite hemisphere, illustrating the tumor’s infiltrative nature. The cancer stem cell (CSC) hypothesis proposes that tumors contain a small subset of cells with stem-like properties, which retain the exclusive ability to self-renew and sustain the growth of the tumor; essentially malignant cells that have stem cell like characteristics. Tumor stem cells were first identified in leukemia,4 and more recently also discovered in various solid tumors, including cancers of the brain such as glioblastomas, medulloblastomas and ependymomas.1 Brain CSCs, also known as brain tumor stem cells (BTSCs), are defined by (i) the capacity to self-renew, (ii) the ability to initiate brain tumors upon orthotopic implantation in xenografts and (iii) multipotency, that is, the capacity to differentiate into cells with a neuronal, astrocytic or oligodendroglial phenotype.5 In addition, BTSCs are characterized by the expression of neural stem cell antigens and the ability to grow as nonadherent three dimensional aggregates termed neurospheres when cultured in the presence of epidermal growth factor (EGF) and fibroblast growth factor (FGF) under serum-free conditions. BTSCs possess many molecular and functional similarities with normal neural stem cells (NSCs), supporting the hypothesis that brain tumors could arise from neural stem or progenitor cells.6,7 Regardless of whether BTSCs arise from normal NSCs, it is known that once brain tumors develop these BTSCs evince properties fundamentally unique from the majority of malignant cells that comprise the bulk of the tumor. BTSCs are resistant to current radiotherapy and chemotherapy and as such are being investigated for their role in tumor recurrence.8,9 8 1 0 2 l u J 3 1 n o 8 4 . 6 9 . 7 3 1 . 9 7 y b / m o c . s s e r BTSC cell of origin In the nascent field of CSCs, many fundamental questions remain unanswered. One critical question is whether these cells arise from NSCs or from more differentiated cells that acquire the capacity of self-renewal. Evidence for the latter exists in the hematopoietic field in blast crisis chronic myelogenous leukemia, in which a committed granulocyte-macrophage progenitor may acquire self-renewal capacity and thus ‘‘reacquire’’ stem-like properties due to the effects of later mutations.13 The term CSC is not meant to suggest a stem cell origin, but rather a cancerous cell that has stem cell-like properties, namely extensive self renewal and capacity for differentiation. However, which cells give rise to CSCs remains unknown. isolation and characterization of BTSCs Expanding on seminal work performed identifying CSCs in the hematopoietic system,14 CSCs in breast cancer were assayed and identified to provide the first evidence of CSCs in solid organ tumors.15 Subsequently, it was demonstrated that a subpopulation of cells from glioma could recapitulate the primary glioma with xenograft transplantation of as submit your manuscript | Dovepress few as 100 cells.5 Currently, CSCs can be best defined experimentally by their ability to perpetuate tumors in serial transplantation xenotransplantation assays in vivo.13 An ideal in vitro BTSC assay would employ a highly specific and quantitative guideline, only measuring the cells of interest. In addition, this assay should be sufficiently sensitive so as to be able to measure candidate BTSCs when present at very low frequency. A few examples of in vitro assays currently in use to enrich for CSCs include: sphere, serial colony-forming unit (CFU) and label-retention (BrdU) assays.16 Another technique, the side population (SP) phenotype (defined by its ability to efflux the nucleic acid-staining dye Hoechst) has been used to enrich for BTSCs.16–18 Flow sorting (fluorescence-activated cell sorting) techniques to prospectively isolate BTSCs on the basis of cell surface markers that characterize and define bona fide CSCs would be ideal for cellular, molecular, and clinical investigation. Presently, the BTSC subpopulation can be enriched for by sorting for the cell surface marker CD133+ (Prominin-1).19,20 However, this marker is not an unequivocal marker that can be used for prospective isolation of BTSCs in the brain. In fact, recent studies suggest that CD133− cells may also give rise to brain tumors.21,22 Recently, the contributions of the microenvironment have shown that BTSCs exist in a perivascular niche by providing evidence that the microvasculature forms scaffolding that may be necessary for maintaining or promoting the CSCs. Also, it has been shown that in the Patched mutant mouse (model of medulloblastoma), are not propagated by CD133+ cells but by cells expressing the progenitor markers Math1 and CD15/SSEA-1.23 These cells have a distinct expression profile that suggests increased proliferative capacity and decreased tendency to undergo apoptosis and differentiation. CD15 was also found in a subset of human medulloblastomas, and tumors expressing genes similar to those found in murine CD15+ cells have a poorer prognosis. Therefore, CD15 may represent an important marker for CSCs in medulloblastoma.24,25 However, it clearly does not suffice to define CSCs solely on surface markers. To further understand and characterize these aberrant stem cells, it would be prudent to link marker expression and self-renewal capacity with underlying molecular changes. BTSCs as the source of glioma recurrence Unlike other solid organ tumors, gliomas do not metastasize and patients succumb to this disease from invariable tumor 8 1 0 2 l u J 3 1 n o 8 4 . 6 9 . 7 3 1 . 9 7 y b / m o c . s s e r frodm ropF recurrence. This has been thought to result from insufficient cell surface marker CD133+. Although CD133 is not an reduction of tumor cell number, with most malignant cells unequivocal marker useful for prospective isolation, it is considered competent for tumor formation.26 a highly reliable marker of malignant glioma CSCs with Glioma recurrence is now being understood to arise robust capacity to initiate tumors upon xenotransplantafrom a subset of tumor cells that exhibit stem cell-like tion and can be used to enrich for CSCs as a starting point features, CSCs. Consequently, while cur rent cancer for investigation.21 Our preliminary evidence using human treatments are cytotoxic to the bulk of tumor cells, they CSCs in the xenotransplantation assay shows that the CSC fail to eliminate CSCs, thereby making them the leading fraction (CD133+ cells) increases in recurrent gliomas candidates for the origin of glioma recurrence. To elucidate (unpublished). Moreover, recent work by Bao et al and the biology of recurrent gliomas, we investigated the fraction Piccirillo et al provide new in vitro and in vivo evidence of CSCs in primary vs recurrent (post treatment) gliomas. supporting the involvement of CSCs in tumors of the brain Human and mouse CSCs can be isolated by sorting for the (Figure 1).20,27 Working with mouse models of glioblastoma, A Treatment with ionizing radiation Glioblastoma Tumour shirinks but CD133+ cells persist Glioblastoma regrowth in vitro and in vivo Radiation Checkpoint blockers B Treatment with BMPs Glioblastoma CD133+ cells Glioblastoma progenitor cells Tumour astrocytes Isolated CD133+ cells Differentiation of CD133+ cells Graft into mouse brains Graft into mouse brains BMPs BMPs Reduced tumorigenicity submit your manuscript | Dovepress 159 the two groups described mechanisms by which BTSC cells escape antitumor treatment and approaches for forcing CSCs to mature to differentiated cells, with consequent loss of self renewal. epigenetic instability in gliomas that create CSC competition and clonal diversity Along with genetic and molecular mutations, epigenetic alterations also affect the expression of cancer genes and in gliomas multiple microRNAs are aberrantly expressed or repressed in both primary tumors and cell lines.28 Overall, microRNAs appear to play multiple roles in gliomas with respect to self renewal and clonal evolution of CSCs.12 Moreover, in gliomas, hundreds of genes are subject to DNA hypermethylation at their CpG island promoters.29 A subset of gliomas is also characterized by locus-specific 8 1 0 2 l u J 3 1 n o 8 4 . 6 9 . 7 3 1 . 9 7 y b / m o c . s s e r .voepd l.yon ahnydpogmeneothmyela-wtioidne.28deOctrheearseepinigDenNeAticmaelttheyralatitoionns,, osrucDhNaAs //www lsue changes in the position of histone variants and changes in :s na histone modifications are also likely to be important in the tp so th re molecular pathology of gliomas. These epigenetic contribufrodm ropF tions must also be considered in the successful elucidation of ed BTSC biology and the possibility that in tumor recurrence laon BTSCs most likely compete with other BTSCs for domiodw nance in creating tumor recurrence. This possibility is one ryap that would require molecular lineage techniques to follow heT the clonal evolution and diversity of BTSCs in primary vs and recurrent gliomas. s t e g r a T : s c i g o il o B Targeting elusive CSCs Insights from other disciplines have led to unanticipated links between CSC biology, neurosciences, and epidemiology. Mutations in neurotransmission pathways including sodium, potassium, and calcium channels have recently been shown to be a common occurrence in gliomas.30 These include mutations in all five of the major neurotransmission classes, serotonin, dopamine, acetylcholine, glutamate and GABA.26 Interestingly, this suggests that neuromodulatory mutations could confer selective advantage rather than just representing genetic alteration. Furthermore, unlike other mutations (ie, PTEN, P53) discovered in other cancers (ie, pancreases, breast, colon) mutations in neurotransmission pathways appear to be a feature unique to gliomas.31 These mutually exclusive cancer driving mutations may thus be a consequence of the unique mechanism these pathways play in regulating CSCs and neural precursor pool size and tendency to differentiate. submit your manuscript | Dovepress Such perturbations in basal neurotransmission inputs from the surrounding NSC niche may be enough to change the dynamics of the CSCs and NSCs pool. This activation of normal lineage-specific signaling pathways in neural precursor derived cancer cells may provide a means of depleting the undifferentiated pool of cells that initiate and maintain brain tumor growth (Figure 2). For example, it has recently been demonstrated that pro-differentiating agents such as bone morphogenic proteins (BMPs) can promote the differentiation of gliomas CSCs and prolong the life of mice xenotransplanted with human tumors. Moreover, in vivo neuromodulation of the metabotropic glutamate receptor 4 (mGlu4), a candidate target for the treatment of Parkinson’s disease, has also been shown to attenuate medulloblastoma formation in mice. Similarly, mGlu2/3 antagonism also suppresses both the in vitro and in vivo growth of human glioma cells.30 The generality of this phenomenon is suggested by the finding that a broad spectrum of drugs that act on diverse neurotransmission pathways inhibit both normal and cancerous neural precursor cell proliferation in vitro. Based on a high through put screening of 1257 potential agents, the most potent NSCs and potentially anti-CSCs agents identified in these in vitro screens included the clinically prescribed dopamine agonist apomorphine and the glutamate antagonist ifenprodil.32 Thus, chronic administration of neuromodulatory agents may deplete CSCs pools in the neuropsychiatric patient and thereby protect against cancer initiation, perpetuation, or recurrence. This group of well tolerated neuropharmacological agents used in standard clinical practice may offer the prospect of rapid new clinical application following clinical trials in patients with brain cancer. Conclusion The immediate goal at hand should be a consensus identification of the elusive CSCs. This objective is achieved through the integration and analysis of multiple methods including functional assays, marker analysis, and analysis of genetic and epigenetic signatures. Subsequently, this will allow for the isolation and characterization of these cells and a comparison to their normal stem cells counterparts. In understanding CSCs development and biology, we have the possibility of generating novel targets that could overcome issues of drug resistance, improve therapeutic efficacy, and decrease tumor recurrence. Disclosures The authors report no conflicts of interest in this work. 8 1 0 2 l u J 3 1 n o 8 4 . 6 9 . 7 3 1 . 9 7 y b / m o c . s s e r Relative risk of brain tumors size of precursor compartment Self renewal NMDA Ca2+ Excitation Ca2+ Neurogenesis Ca2+ Neuromodulation Neurogenesis Symmetric self renewal i. C GABAergic Dopaminergic Cholinergic Serotonergic E GABAergic Dopaminergic Cholinergic Serotonergic NSC Neuromodulation Differentiation BTSC Neuromodulation Differentiation Symmetric self renewal Asymmetric self renewal Symmetric differentiation ii. 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Josh Neman, Rahul Jandial. Decreasing glioma recurrence through adjuvant cancer stem cell inhibition, Biologics: Targets and Therapy, 2010, 157-162, DOI: 10.2147/BTT.S9497