During animal development, cells become progressively more restricted in the cell types to which they can give rise. In the central nervous system (CNS), for example, multipotential stem cells produce various kinds of specified precursors that divide a limited number of times before they terminally differentiate into either neurons or glial cells. We show here that certain extracellular signals can induce oligodendrocyte precursor cells to revert to multipotential neural stem cells, which can self-renew and give rise to neurons and astrocytes, as well as to oligodendrocytes. Thus, these precursor cells have greater developmental potential than previously thought.

https://science.sciencemag.org/content/sci/289/5485/1754.full.pdf

Oligodendrocyte Precursor Cells Reprogrammed to Become Multipotential CNS Stem Cells

Bone morphogenetic proteins promote astroglial lineage commitment by mammalian subventricular zone progenitor cells.

Tumors of the central nervous system (CNS) can be devastating because they often affect children, are difficult to treat, and frequently cause mental impairment or death. New insights into the causes and potential treatment of CNS tumors have come from discovering connections with genes that control cell growth, differentiation, and death during normal development. Links between tumorigenesis and normal development are illustrated by three common CNS tumors: retinoblastoma, glioblastoma, and medulloblastoma. For example, the retinoblastoma (Rb) tumor suppressor protein is crucial for control of normal neuronal differentiation and apoptosis. Excessive activity of the epidermal growth factor receptor and loss of the phosphatase PTEN are associated with glioblastoma, and both genes are required for normal growth and development. The membrane protein Patched1 (Ptc1), which controls cell fate in many tissues, regulates cell growth in the cerebellum, and reduced Ptc1 function contributes to medulloblastoma. Just as elucidating the mechanisms that control normal development can lead to the identification of new cancer-related genes and signaling pathways, studies of tumor biology can increase our understanding of normal development. Learning that Ptc1 is a medulloblastoma tumor suppressor led directly to the identification of the Ptc1 ligand, Sonic hedgehog, as a powerful mitogen for cerebellar granule cell precursors. Much remains to be learned about the genetic events that lead to brain tumors and how each event regulates cell cycle progression, apoptosis, and differentiation. The prospects for beneficial work at the boundary between oncology and developmental biology are great.

The developmental biology of brain tumors.

The immune system and developmental programming of brain and behavior

We recently showed that defined sets of transcription factors are sufficient to convert mouse and human fibroblasts directly into cells resembling functional neurons, referred to as “induced neuronal” (iN) cells. For some applications however, it would be desirable to convert fibroblasts into proliferative neural precursor cells (NPCs) instead of neurons. We hypothesized that NPC-like cells may be induced using the same principal approach used for generating iN cells. Toward this goal, we infected mouse embryonic fibroblasts derived from Sox2-EGFP mice with a set of 11 transcription factors highly expressed in NPCs. Twenty-four days after transgene induction, Sox2-EGFP+ colonies emerged that expressed NPC-specific genes and differentiated into neuronal and astrocytic cells. Using stepwise elimination, we found that Sox2 and FoxG1 are capable of generating clonal self-renewing, bipotent induced NPCs that gave rise to astrocytes and functional neurons. When we added the Pou and Homeobox domain-containing transcription factor Brn2 to Sox2 and FoxG1, we were able to induce tripotent NPCs that could be differentiated not only into neurons and astrocytes but also into oligodendrocytes. The transcription factors FoxG1 and Brn2 alone also were capable of inducing NPC-like cells; however, these cells generated less mature neurons, although they did produce astrocytes and even oligodendrocytes capable of integration into dysmyelinated Shiverer brain. Our data demonstrate that direct lineage reprogramming using target cell-type–specific transcription factors can be used to induce NPC-like cells that potentially could be used for autologous cell transplantation-based therapies in the brain or spinal cord.

https://www.pnas.org/content/pnas/109/7/2527.full.pdf

Direct conversion of mouse fibroblasts to self-renewing, tripotent neural precursor cells

We have used bipotent postnatal cortical oligodendroglial-astroglial progenitor cells (O-2As) to examine the role of inductive signals in astroglial lineage commitment. O-2A progenitor cells undergo progressive oligodendroglial differentiation when cultured in serum-free medium, but differentiate into astrocytes in medium supplemented with FBS. We now report that the bone morphogenetic proteins (BMPs), a major subclass of the transforming growth factor beta (TGFbeta) superfamily, promote the selective, dose-dependent differentiation of O-2As into astrocytes with concurrent suppression of oligodendroglial differentiation. This astroglial-inductive action is not sanctioned by other members of the TGFbeta superfamily. Astroglial differentiation requires only very brief initial exposure to the BMPs and is accompanied by increased cellular survival and accelerated exit from cell cycle. Dual-label immunofluorescence microscopy documents that O-2A progenitor cells express a complement of BMP type I and type II receptor subunits required for signal transduction. Furthermore, expression of BMP2 in vivo reaches maximal levels during the period of gliogenesis. These results suggest that the BMPs act as potent inductive factors in postnatal glial lineage commitment that initiate a stable program of astroglial differentiation.

https://www.jneurosci.org/content/jneuro/17/11/4112.full.pdf

Bone Morphogenetic Proteins Induce Astroglial Differentiation of Oligodendroglial–Astroglial Progenitor Cells

Cytokines regulate the cellular phenotype of developing neural lineage species.

The epigenetic signals and progenitor cell species involved in progressive neural maturation in the mammalian brain are poorly understood. Although these complex developmental issues can be examined in cultures of generative zone progenitor cells, analysis of signaling relationships in complex progenitor cell systems requires the meticulous definition of the cellular complement at each developmental stage. The presence of microglia within the generative zone cultures would further complicate these developmental analyses. Utilizing the microglial markers Griffonia simplicifolia B4 isolectin, carbocyanine dye-acetylated low density lipoprotein, F4/80, and Mac-1 we now report the presence of microglia within cultures of late embryonic murine epidermal growth factor-derived generative zone progenitor cells. Cytokine treatment of serially passaged epidermal growth factor-generated neurospheres altered the phenotype of the microglia in culture. Macrophage colony-stimulating factor treatment promoted the expression of spindle-shaped microglia, whereas granulocytemacrophage colony-stimulating factor treatment promoted the elaboration of flat and amoeboid microglia. Treatment with microglial-conditioned medium or 10% non-heat inactivated fetal calf serum led to an increased complement of both phenotypes. Microglia could be generated from single isolated neurospheres, and there were differences in the number of microglial lineage species obtained from distinct oligopotent progenitor cells, raising the possibility that a complement of this cellular lineage may be derived from a progenitor cell present within the generative zones. These observations indicate that microglia are present within the generative zone progenitor cell system, and this system thus represents an important experimental resource to examine the progenitor cell maturation and the origin of the microglial lineage.

Microglial lineage species are expressed in mammalian epidermal growth factor-generated embryonic neurospheres.

OBJECTIVE: Colony-stimulating factor (CSF)-1, a chemotactic and mitogenic factor for macrophages and microglia, is expressed in a variety of nervous system tumors and when present in nonneural malignancies, is associated with marked inflammatory infiltrates, dissemination, and poorer prognosis. This study investigated the paracrine effects of CSF-1 production by medulloblastoma cells on the macrophage/microglial lineage. METHODS: A recurrent metastatic desmoplastic medulloblastoma was isolated from a 26-year-old man and propagated in tissue culture. Cellular phenotype and proliferation were assessed by immunocytochemical techniques; transcript expression for CSF-1, granulocyte macrophage-CSF, interleukin-3, and c-fms (the receptor for CSF-1) was examined with reverse transcriptase-polymerase chain reaction; and conditioned media and coculture paradigms were used to study cytokine effects on cellular proliferation. RESULTS: Serially passaged cells were uniformly immunoreactive for two lineage-independent neuroepithelial markers, nestin and vimentin. A subpopulation of cells with morphological characteristics of early differentiation stained for neurofilament 66 (7%) and microtubule-associated protein (5%) (markers of early neuronal precursors and postmitotic neurons, respectively) and for the Yp subunit of glutathione-S-transferase (3%) (a marker of early oligodendroglial progenitors). Tumor cells expressed transcripts for CSF-1, but not for granulocyte macrophage-CSF, interleukin-3, or c-fms. Treatment of microglia with serum-free medulloblastoma-conditioned media significantly increased proliferation (P < 0.001), suggesting the secretion of CSF-1. Coculture of medulloblastoma cells and microglia significantly increased proliferation of both cell types (each condition, P < 0.01). CONCLUSION: These observations suggest that CSF-1 mediates important paracrine interactions between transformed cells and the immune system, resulting in increased growth rate and metastatic potential. Future therapeutic goals need to include immunotherapeutic protocols to modulate this interaction.

Achilles K. Papavasiliou

Papers

Bone Morphogenetic Proteins Induce Astroglial Differentiation of Oligodendroglial–Astroglial Progenitor Cells

Cytokines regulate the cellular phenotype of developing neural lineage species.

Microglial lineage species are expressed in mammalian epidermal growth factor-generated embryonic neurospheres.

Paracrine regulation of colony-stimulating factor-1 in medulloblastoma: implications for pathogenesis and therapeutic interventions.