Gregory P. Marshall

Microglia Instruct Subventricular Zone Neurogenesis

Microglia are increasingly implicated as a source of non‐neural regulation of postnatal neurogenesis and neuronal development. To evaluate better the contributions of microglia to neural stem cells (NSCs) of the subventricular neuraxis, we employed an adherent culture system that models the continuing proliferation and differentiation of the dissociated neuropoietic subventricular tissues. In this model, neuropoietic cells retain the ability to self‐renew and form multipotent neurospheres, but progressively lose the ability to generate committed neuroblasts with continued culture. Neurogenesis in highly expanded NSCs can be rescued by coculture with microglial cells or microglia‐conditioned medium, indicating that microglia provide secreted factor(s) essential for neurogenesis, but not NSC maintenance, self‐renewal, or propagation. Our findings suggest an instructive role for microglial cells in contributing to postnatal neurogenesis in the largest neurogenic niche of the mammalian brain.

Using the neurosphere assay to quantify neural stem cells in vivo.

Since their initial description in 1992, neurospheres have appeared in some aspect of more than a thousand published studies. Despite their ubiquitous presence in the scientific literature, there is little consensus regarding the fundamental defining characteristics of neurospheres; thus, there is little agreement about what, if anything, the neurosphere assay can tell us about the relative abundance or behavior of neural stem cells in vivo. In this review we will examine some of the common features of neurospheres, and ask if these features should be interpreted as a proxy for neural stem cells. In addition, we will discuss ways in which the neurosphere assay has been used to evaluate in vivo treatment/manipulation, and will suggest appropriate ways in which neurosphere data should be interpreted, vis-à-vis the neural stem cell. Finally, we will discuss a relatively new in vitro approach, the Neural-Colony Forming Cell Assay, which provides a more meaningful method of quantifying bona fide neural stem cells without conflating them with more growth-restricted progenitor cells.

Bromodeoxyuridine Induces Senescence in Neural Stem and Progenitor Cells

Bromodeoxyuridine (BrdU) is a halogenated pyrimidine that incorporates into newly synthesized DNA during the S phase. BrdU is used ubiquitously in cell birthdating studies and as a means of measuring the proliferative index of various cell populations. In the absence of secondary stressors, BrdU is thought to incorporate relatively benignly into replicating DNA chains. However, we report here that a single, low‐dose pulse of BrdU exerts a profound and sustained antiproliferative effect in cultured murine stem and progenitor cells. This is accompanied by altered terminal differentiation, cell morphology, and protein expression consistent with the induction of senescence. There is no evidence of a significant increase in spontaneous cell death; however, cells are rendered resistant to chemically induced apoptosis. Finally, we show that a brief in vivo BrdU regimen reduces the proliferative potential of subsequently isolated subependymal zone neurosphere‐forming cells. We conclude, therefore, that BrdU treatment induces a senescence pathway that causes a progressive decline in the replication of rapidly dividing stem/progenitor cells, suggesting a novel and uncharacterized effect of BrdU. This finding is significant in that BrdU‐incorporating neural stem/progenitor cells and their progeny should not be expected to behave normally with respect to proliferative potential and downstream functional parameters. This effect highlights the need for caution when results based on long‐term BrdU tracking over multiple rounds of replication are interpreted. Conversely, the reliable induction of senescence in stem/progenitor cells in vitro and in vivo may yield a novel platform for molecular studies designed to address multiple aspects of aging and neurogenesis.

Fusion of neural stem cells in culture.

An important issue in stem cell biology relates to mechanisms of cellular plasticity. Specifically, could any observed multipotency of, e.g., adult stem cells arise from true transdifferentiation or as a result of cell-cell fusion? We studied this issue using a culture paradigm of astrocyte monolayers and multipotent neurospheres generated from neonatal cerebellar cortex and the subventricular zone (SVZ). Based on fluorescence in situ hybridization (FISH), cells from these cultures were found to contain an abnormal number of sex chromosomes, suggesting that cellular fusion is a common in vitro occurrence. A Cre/lox recombination method was also exploited to further confirm the evidence of fusion. Next, we assessed the potential of fusogenic microglial involvement by combining CD11b immunolabeling with FISH sex chromosome analysis. Differentiating neurospheres were also studied from the PU.1 knockout mouse that lacks cells of myeloid origin, presumed to be a source of central nervous system microglia. Very few cells immunopositive for the microglial marker CD11b were found to be aneuploid, and there was no difference in fusion frequency between PU.1+/+ and PU.1-/- neurospheres. These results, together, suggest that stem and/or progenitor cells that generate neurons and glia in culture possess the ability to generate fused polyploidal cells, but microglial participation is not a requirement for fusion to occur. In addition to caution that should be exerted during the interpretation of in vitro neural cell plasticity, the data also suggest that novel therapeutic treatments could be designed that exploit cellular fusion in rescue paradigms for degenerating neuronal populations.

Subventricular zone microglia possess a unique capacity for massive in vitro expansion

Microglia, the resident immune cells of the brain, have recently been hypothesized to play a role both in neuronal diseases and age‐related neurogenic decline, and are theorized to be modulators of adult neurogenesis. Current methods for the isolation of microglia from cultured primary brain tissue result in relatively poor yield, requiring a large tissue sample or multiple specimens to obtain a sufficient number of microglia for cell and molecular analysis. We report here a method for the repetitive isolation of microglia from established glial monolayer cultures from which it is possible to expand the initial population of microglia roughly 10,000‐fold. The expanded population expresses appropriate microglial morphology and phenotype markers, and demonstrates functionally normal phagocytosis, thus providing a high‐yield assay for the investigation and analysis of microglia from a single initial dissection of primary tissue. Furthermore, this massive expansion is limited to microglia derived from the subventricular zone as the fold expansion of isolatable microglia was found to be up to 20 times greater than cultures from other brain regions, indicating unique properties for this persistently neurogenic region.

In Vitro–Derived “Neural Stem Cells” Function as Neural Progenitors Without the Capacity for Self‐Renewal

Hematopoietic stem cells have been defined by their ability to self‐renew and successfully reconstitute hematopoiesis throughout the life of a transplant recipient. Neural stem cells (NSCs) are believed to exist in the regenerating regions of the brain in adult mice: the subependymal zone (SEZ) of the lateral ventricles (LVs) and the hippocampal dentate gyrus. Cells from the SEZ can be cultured to generate neurospheres or multipotent astrocytic stem cells (MASCs), both of which demonstrate the stem cell qualities of multipotency and self‐renewal in vitro. Whether neurospheres and MASCs possess the true stem cell quality of functional self‐renewal in vivo is unknown. The definitive tests for this unique capability are long‐term engraftment and serial transplantation. Both neurospheres and MASCs transplanted into the LVs of C57BL/6 mice resulted in short‐term engraftment into the recipient brain, with donor‐derived migratory neuroblasts visible in the rostral migratory stream and olfactory bulb after transplantation. To test in vivo expansion/self‐renewal of the transplanted cells, we attempted to reisolate donor‐derived neurospheres and MASCs. Even when rigorous drug selection was used to select for rare events, no donor‐derived neurospheres or MASCs could be reisolated. Furthermore, donor‐derived migratory neuroblasts were not observed in the rostral migratory stream (RMS) for more than 1 month after transplantation, indicating a transient rather than long‐term engraftment. Therefore, in vitro‐derived neurospheres and MASCs do not function as NSCs with long‐term, self‐renewal capabilities in vivo but instead represent short‐term neural progenitor cells as defined by an in vivo functional assay.

Production of Neurospheres from CNS Tissue

The relatively recent discovery of persistent adult neurogenesis has led to the experimental isolation and characterization of central nervous system neural stem cell populations. Protocols for in vitro analysis and expansion of neural stem cells are crucial for understanding their properties and defining characteristics. The methods described here allow for cell and molecular analysis of individual clones of cells--neurospheres--derived from neural stem/progenitor cells. Neurospheres can be cultivated from a variety of normal, genetically altered, or pathological tissue specimens, even with protracted postmortem intervals, for studies of mechanisms underlying neurogenesis, cell fate decisions, and cell differentiation. Neurosphere-forming cells hold great promise for the development of cell and molecular therapeutics for a variety of neurological diseases.

Ionizing Radiation Enhances the Engraftment of Transplanted In Vitro–Derived Multipotent Astrocytic Stem Cells

The subependymal zone (SEZ) is a region of persistent neurogenesis in the adult mammalian brain containing a neural stem cell (NSC) pool that continuously generates migratory neuroblasts that travel in chains through the rostral migratory stream (RMS) to the olfactory bulb (OB), where they differentiate and functionally integrate into existing neural circuitry. NSCs can be isolated from the SEZ and cultured to generate either neurospheres (NSs) or multipotent astrocytic stem cells (MASCs), with both possessing the stem cell characteristics of multipotency and self‐renewal. NSs and MASCs home to the SEZ after transplantation into the lateral ventricle (LV) and contribute to neuroblast migration, with minimal engraftment into the OB observed in the adult mouse. Recent studies have compared the relatively uncharacterized NSC with the more established hematopoietic stem cell (HSC) in an effort to determine the level of stemness possessed by the NSC. Depletion of native HSCs in the bone marrow by lethal irradiation (LI) is necessary to maximize functional engraftment of donor HSCs. Our data show that the NSC pool and neuroblasts in the SEZ can be significantly and permanently depleted by exposure to LI. Attenuation of donor‐derived migratory neuroblast engraftment into the OB is observed after transplantation of gfp+ MASCs into the LV of LI animals, whereas engraftment is significantly enhanced after transplantation into animals exposed to sublethal levels of ionizing radiation. By increasing receptiveness of the NSC niche through depletion of indigenous cells, the adult SEZ‐RMS‐OB can be used as a model to further characterize the NSC.

Microglia from neurogenic and non-neurogenic regions display differential proliferative potential and neuroblast support

Microglia isolated from the neurogenic subependymal zone (SEZ) and hippocampus (HC) are capable of massive in vitro population expansion that is not possible with microglia isolated from non-neurogenic regions. We asked if this regional heterogeneity in microglial proliferative capacity is cell intrinsic, or is conferred by interaction with respective neurogenic or non-neurogenic niches. By combining SEZ and cerebral cortex (CTX) primary tissue dissociates to generate heterospatial cultures, we find that exposure to the SEZ environment does not enhance CTX microglia expansion; however, the CTX environment exerts a suppressive effect on SEZ microglia expansion. Furthermore, addition of purified donor SEZ microglia to either CTX- or SEZ-derived cultures suppresses the expansion of host microglia, while the addition of donor CTX microglia enhances the over-all microglia yield. These data suggest that SEZ and CTX microglia possess intrinsic, spatially restricted characteristics that are independent of their in vitro environment, and that they represent unique and functionally distinct populations. Finally, we determined that the repeated supplementation of neurogenic SEZ cultures with expanded SEZ microglia allows for sustained levels of inducible neurogenesis, provided that the ratio of microglia to total cells remains within a fairly narrow range.

Transplantation of Neural Stem/Progenitor Cells into Developing and Adult CNS

Neural transplantation has been a long-standing goal for the treatment of neurological injury and disease. The recent discovery of persistent pools of neural stem cells within the adult mammalian brain has re-ignited interest in transplant therapeutics. Since neural stem cells are self-renewing, it may be possible to culture and expand neural stem cells and their progenitor cell progeny to sufficient numbers for use in autologous, self-repair strategies. Such approaches will require optimized cultivation protocols, as well as extensive testing of candidate donor cells to assess their capacity for engraftment, survival, and integration. In this chapter, we describe the transplantation of neural stem/progenitor cells-cultivated as either neurospheres or neurogenic astrocyte monolayers-into the persistently neurogenic olfactory bulb system of the adult mouse forebrain, and into the cerebellum of neonatal mutant mice.