Promoter-based isolation and assessment of differential gene expression by stage-defined glial tumor stem cells

We propose here to approach this issue from the standpoint of understanding the differences between tumor stem and progenitor cells, and the native stem and progenitor cells from which they likely arise in vivo. Over the past two decades, we and many others have reported that the mature brain continues to harbor a population of neural stem cells, multipotential and self-renewing cells that persist from early development 6,16,33-37. In the adult forebrain, these cells remain in a discrete layer, the subependyma, which lines the lateral ventricles. The adult brain also harbors a number of different types of more restricted progenitor cells, that can give rise to new neurons and glial cells, the latter including the two major glial cell types, oligodendrocytes and astrocytes. Whereas mature human neurons and oligodendrocytes are incapable of further cell division, the stem and progenitor cells that give rise to them can divide throughout life. These precursor cells thus appear likely candidates as sources for primary tumors of the central nervous system10. This may be especially true in children, in whom periventricular tumors predominate. But even in adults, in whom glial tumors are much more common, tumors may arise from resident glial progenitor cells of the tissue parenchyma, rather than from mature glial cells. In this proposal, we seek to use a genetic strategy of promoter-based selection to isolate stem and progenitor cells from different stage-defined adult glial tumors, in order to study the biology and genomics of the neoplastic progenitors from which these tumors arise.

In studies of the past 7 years, we have used fluorescent reporter genes placed under the control of progenitor cell-specific promoters to identify and then isolate neural stem cells24, neuronal progenitors2,3, as well as parenchymal glial progenitor cells4,5, from both fetal and adult human brain tissues. Recently we have extended this analysis to CNS tumors, for the purpose of isolating stem and progenitor cells from tumors, as a first step towards understanding how these cells differ in their biology and gene expression from normal, non-neoplastic adult progenitor cells. Our pilot studies thus far have included neurocytoma, oligodendroglioma, mixed oligo-astrocytoma and anaplastic astrocytoma, and have proven both encouraging and fundamentally exciting: Using promoter-based selection, we have now been able to extract neoplastic progenitors from each of these tumors, that correspond to ontogenetically-analogous progenitors in the normal brain. This has allowed us to begin comparing the gene expression patterns of these tumor stem cells to their native, non-transformed analogues.

In our first formal validation of this strategy, we used Affymetrix arrays to compare the gene expression profile of neurocytoma, a predominantly pro-neuronal tumor of the ventricular wall, to that of the normal adult subependyma, as well as to that of neural progenitor cells sorted from normal brain on the basis of nestin enhancer-specified, GFP-based FACS. We found that this analysis revealed a discrete and relatively small set of highly differentially expressed genes in the neurocytoma cells relative to normal ventricular zone and its nestin-selected progenitors22. Among the differentially expressed genes, the growth hormone IGF2 and its downstream signal intermediates were prominent; indeed, their selective overexpression was quantitatively remarkable: qPCR confirmed a >50-fold increase in IGF signal components in neurocytoma cells compared to native subependymal progenitors, despite substantially overlapping expression patterns otherwise. Immunocytochemistry and Western analysis confirmed high IGF2 expression levels by neurocytoma, and pathway analysis using Ingenuity confirmed the differential transcriptional activation of the IGF2 signaling pathway. We are now in the midst of testing IGF2 antagonists to assess their therapeutic potential in these tumors. Yet whether IGF2 signal inhibition is found to be a potential treatment strategy in neurocytoma or not, the value of this strategy of comparing the expression profiles of tumor progenitors to their sorted native homologues, as a means of rapidly and efficiently identifying potentially causal genes in neural tumor formation, and in identifying the causal stem or progenitor cell in a given heterogeneous cancer, now seems clear.

In this proposal we seek to follow this approach in assessing adult glial tumors, with the goal of identifying those genes associated with the transformation of a native glial progenitor into a glioma. Using progenitor cell isolates specifically extracted from human astrocytomas, oligodendroglioma, and mixed astrocytoma-oligodendrogliomas, we will first identify which are actually tumorigenic, by transplanting each promoter-defined isolate into naïve immunodeficient mice to establish which progenitor isolates are able to initiate tumors, and what types of tumors are generated by each purified phenotype. We will then test the possibility that by subtracting the gene expression profile of normal, native progenitors from that of their tumor-derived counterparts, we can identify those genes that are specifically dysregulated in tumor progenitors. In particular, for each of the glial progenitor cell types to be investigated, we expect to identify those genes overexpressed by tumorigenic vs. normal progenitors, and then use this information to predict those signaling pathways differentially active in the tumor progenitors. We thereby hope to identify a discrete cohort of genes and pathways that distinguish each tumor progenitor cell type from its counterpart in normal brain.

The importance of defining those genes and signaling pathways that distinguish the transformed progenitors of brain tumors from the native progenitor cells from which they derive is manifold. The different phenotypes of human brain tumors may comprise a hierarchy of neoplastic progenitor cells, with distinct tumors corresponding to the transformed derivatives of cells transformed at distinct points in their lineage progression. As a result, the daughter cells of transformed progenitor cells may be sufficiently distinct from their parents in both their expansion and growth control, that therapy directed at their derivative tumors may be neither appropriate nor effective against the parental transformed progenitor clone. Of note, this differs from the tumor stem cell hypothesis, which would argue that abolition of the parental progenitor, or tumor stem cell, would be sufficient to destroy a given tumor, whose derivative phenotypes would be incapable of self-renewal. Rather, we suggest that derivative phenotypes may well be capable of autonomous self-renewal once generated, but that cytotoxic therapy directed against them, without abolition of their underlying parental transformant, is destined for relapse and ultimate treatment failure. The therapeutic implication is that oncolytic therapy may need to be directed not solely at either the tumor stem cell or its derivatives, but rather at both, through fundamentally different mechanistic strategies. By the strategies outlined in this proposal, we hope to efficiently develop anti-neoplastic strategies directed specifically at genes critical to the growth and survival of tumor stem cells. By separately targeting tumor stem cells and their daughter cells with mechanistically distinct agents, we hope to minimize the likelihood of clinical relapse after initial treatment of malignant glioma. By so doing, we hope to provide clinical benefit to a patient population whose prognosis remains as dire today as it was decades ago, long before the advent of the technologies and approaches that we now hope to bring to bear to the treatment of this disease.

References
1. Wang, S. et al. Isolation of neuronal precursors by sorting embryonic forebrain transfected
with GFP regulated by the T alpha 1 tubulin promoter. Nature Biotechnol 16, 196-201.
(1998).
2. Roy, N.S. et al. Promoter-targeted selection and isolation of neural progenitor cells from the
adult human ventricular zone. J. Neurosci. Res. 59, 321-31. (2000).
3. Roy, N.S. et al. In vitro neurogenesis by progenitor cells isolated from the adult human
hippocampus. Nature Medicine 6, 271-7 (2000).
4. Roy, N.S. et al. Identification, isolation, and promoter-defined separation of mitotic
oligodendrocyte progenitor cells from the adult human subcortical white matter. J Neurosci
19, 9986-95. (1999).
5. Nunes, M.C. et al. Identification and isolation of multipotential neural progenitor cells from
the subcortical white matter of the adult human brain. Nature Medicine 9, 439-447 (2003).
6. Goldman, S. Glia as neural progenitor cells. Trends in Neurosci. 26, 590-596 (2003).
7. Goldman, S.A. Directed mobilization of endogenous neural progenitor cells: The
intersection of stem cell biology and gene therapy. Curr. Opin. Molec. Ther. 6, 466-472
(2004).
8. Roy, N.S. et al. Telomerase immortalization of neuronally restricted progenitor cells derived
from the human fetal spinal cord. Nature Biotechnology 22, 297-305 (2004).
9. Windrem, M.S. et al. Fetal and adult human oligodendrocyte progenitor cell isolates
myelinate the congenitally dysmyelinated brain. Nature Medicine 10, 93-97 (2004).
10. Hemmati, H. et al. Cancerous stem cells can arise from pediatric brain tumors. Proc. Natl.
Acad. Sci. 100, 15178-15183 (2003).
11. Sanai, N., Alvarez-Buylla, A. & Berger, M. Neural stem cells and the origin of gliomas.
New Engl. J. Med. 353, 811-822 (2005).
12. Kirschenbaum, B. et al. In vitro neuronal production and differentiation by precursor cells
derived from the adult human forebrain. Cerebral Cortex 4, 576-89 (1994).
13. Pincus, D.W. et al. FGF2/BDNF- associated maturation of new neurons generated from
adult human subependymal cells. Ann. Neurology 43, 576-585 (1998).
14. Pincus, D.W. et al. In vitro neurogenesis by adult human epileptic temporal neocortex. Clin
Neurosurg 44, 17-25 (1997).
15. Sanai, N. et al. Unique astrocyte ribbon in adult human brain contains neural stem cells but
lacks chain migration. Nature 427, 740-744 (2004).
16. Gage, F.H. Mammalian neural stem cells. Science 287, 1433-1438 (2000).
17. Alvarez-Buylla, A. & Garcia-Verdugo, J.M. Neurogenesis in adult subventricular zone. J
Neurosci 22, 629-34. (2002).
18. Scolding, N.J., Rayner, P.J. & Compston, D.A. Identification of A2B5-positive putative
oligodendrocyte progenitor cells and A2B5-positive astrocytes in adult human white matter.
Neuroscience 89, 1-4 (1999).
19. Nunes, M.C. et al. Identification and isolation of multipotential neural progenitor cells from
the subcortical white matter of the adult human brain. Nature Medicine 9, 439-447 (2003).
20. Sim, F. et al. Complementary patterns of gene expression by adult human oligodendrocyte
progenitor cells and their white matter environment. Ann. Neurology in press (2006).
21. Doetsch, F., Petreanu, L., Caille, I., Garcia-Verdugo, J. & Alvarez-Buylla, A. EGF converts
transit-amplifying neurogenic precursors in the adult brain into multipotent stem cells.
Neuron 36, 1021-34 (2002).
22. Sim, F., Keyoung, H., Goldman, J.E., Roy, N.S. & Goldman, S.A. Neurocytoma is a tumor
of neuronal progenitors of the adult human forebrain. J. Neuroscience, under revision
(2005).
23. Singh, S. et al. Identification of human brain tumor initiating cells. Nature 432, 396-401
(2004).
24. Keyoung, H.M. et al. High-yield selection and extraction of two promoter-defined
phenotypes of neural stem cells from the fetal human brain. Nat Biotechnol 19, 843-50
(2001).
25. Uchida, N. et al. Direct isolation of human central nervous system stem cells. Proc Natl
Acad Sci U S A 97, 14720-5. (2000).
26. Okano, H., Imai, T. & Okabe, M. Musashi: a translational regulator of cell fate. J Cell Sci
115, 1355-9 (2002).
27. Pincus, D.W. et al. Fibroblast growth factor-2/brain-derived neurotrophic factor-associated
maturation of new neurons generated from adult human subependymal cells. Ann. Neurol.
43, 576-85. (1998).
28. Zappone, M. & al., e. Sox2 regulatory sequences direct expression of a ß-geo transgene to
telencephalic neural stem cells and precursors of the mouse embryo, revealing
regionalization of gene expression in CNS stem cells. Development 127, 2367-2382 (2000).
29. Reya, T., Morrison, S., Clarke, M. & Weissman, I. Stem cells, cancer, and cncer stem cells.
Nature 414, 105-111 (2001).
30. Wichta, M., Liu, S. & Dontu, G. Cancer stem cells: An old idea-A paradigm shift. Cancer
Research 66, 1883-1890 (2006).
31. Ignatova, T. et al. Human cortical glial tumors contain neural stem-like cells expressing
astroglial and neuronal markers in vitro. Glia 39(2002).
32. Singh, S. et al. Identification of a cancer stem cell in human brain tumors. Cancer Res. 63,
5821-5828 (2003).
33. Goldman, S. & Sim, F. Neural progenitor cells of the adult brain. in Stem Cells: Nuclear
programming and therapeutic applications. Novartis Foundation Symposium 265 (ed.
Gearhart, J.) 66-92 (John Wiley, London, 2005).
34. Goldman, S.A. Stem and progenitor cell-based therapy of the human central nervous system.
Nature Biotech. 23, 862-871 (2005).
35. Doetsch, F. The glial identity of neural stem cells. 6, 1127-1134 (2003).
36. Gage, F.H. Neurogenesis in the adult brain. J Neuroscience 22, 612-3 (2002).
37. Goldman, S. et al. Neural precursors and neuronal production in the adult mammalian
forebrain. Ann. N.Y. Acad. Sci. 835, 30-55 (1997).