Neuroblasts of the postnatal mammalian forebrain: Their phenotype and fate

The subventricular zone (SVZ) is the only germinal zone of the developing mammalian forebrain to persist postnatally. Although the SVZ has been known to give rise to most of the glial cells of the forebrain, several studies over the past few years have shown that the cells of the neonatal and adult SVZ can also generate neurons. Recent studies have demonstrated that a discrete region of the anterior part of the neonatal SVZ is composed exclusively of neuronal progenitor cells, whose progeny become interneurons of the olfactory bulb. This review will explore the properties that distinguish this anterior segment of the neonatal subventricular zone (SVZa) from the more posterior, gliogenic region. The cells of the SVZa, as well as its anterior extension forming the rostral migratory stream that enters the middle of the olfactory bulb, have antigenic characteristics of a neuronal phenotype, yet continue to divide during migration. In vitro, SVZa progenitor cells also retain a neuronal phenotype despite persistent division. Intriguingly, SVZa cells and their progeny migrate long distances along a highly stereotypical pathway. To better understand the guidance cues used by SVZa-derived cells during migration, both homotopic and heterotopic transplantation experiments have been conducted. SVZa cells homotopically transplanted into another animal's SVZa migrate with the recipient's endogenous SVZa cells in an indistinguishable manner, whereas those from the embryonic telencephalic ventricular zone, normally destined to follow radial glia to the cerebral cortex, fail to migrate following transplantation to the SVZa. SVZa cells transplanted heterotopically into the neonatal and adult striatum were able to disperse from their site of implantation. Thus, SVZa cells are special proliferating cells for which the rostral migratory stream is a particularly permissive pathway. © 1998 John Wiley & Sons, Inc. J Neurobiol 36: 221–233, 1998     

Neurogenesis and neuronal migration in the neonatal rat forebrain anterior subventricular zone do not require GFAP-positive astrocytes

A prolific neuronal progenitor cell population in the anterior portion of the neonatal rat forebrain subventricular zone, the SVZa, is specialized for the production of olfactory bulb interneurons. At all ages, SVZa-derived cells traverse a tangential migratory pathway, the rostral migratory stream (RMS), while en route to the olfactory bulb. Unlike other neuronal progenitor cells of the forebrain, migrating progeny of SVZa progenitors express neuronal-specific proteins and continue to divide into adulthood. Recent studies indicate that in the adult, migrating SVZa-derived cells are ensheathed by astrocytes, although the function of these astrocytes has not been determined. To explore the possible role(s) of astrocytes in the rat SVZa and RMS, we examined the expression of astroglial-specific genes in the postnatal SVZa and RMS using RT-PCR, in situ hybridization, and immunohistochemistry during (Postnatal Days 1-10) and after the period of peak olfactory bulb interneuron generation. We also examined the expression of neuronal-specific genes throughout the rostral-caudal extent of the postnatal subventricular zone to determine if differential cell type-specific gene expression could distinguish the neurogenic SVZa as a region distinct from the remainder of the SVZ. We found little to no astrocyte-specific gene expression in the P0-P7 SVZa, although the neuron-specific isoforms of tubulin (T alpha 1 and beta-III tubulin) were expressed abundantly in the SVZa and RMS. In contrast, astrocyte-specific genes were strongly expressed in the SVZ posterior to the SVZa. GFAP expressions begins to appear in some restricted areas of the rostral migratory stream after the first postnatal week. These data suggest that astroglia are not involved in the generation or migration of most olfactory bulb interneurons. Moreover, the scarcity of glial markers in the neonatal SVZa indicates that the forebrain subventricular zone includes a distinct neurogenic anterior region containing predominantly committed neuronal progenitor cells.     

The neuronal progenitor cells of the forebrain subventricular zone: intrinsic properties in vitro and following transplantation

During the development of the central nervous system, progenitor cells, located within distinct germinal zones, produce presumptive neurons that migrate to their destinations and differentiate. Recent studies have demonstrated that a discrete region of the anterior part of the postnatal subventricular zone (SVZa) comprises neuronal progenitor cells whose progeny are fated to become the interneurons of the olfactory bulb. The SVZa is of particular interest because it is one of few germinal zones to persist postnatally and may be the only postnatal germinal zone to give rise exclusively to neurons. To the extent that the SVZa is unique among proliferative zones, the SVZa progeny are unique among neurons. First, unlike most cortical neurons, the SVZa-derived cells do not rely on radial glia-assisted migration when traveling to their target region. Second, the SVZa progeny continue to proliferate as they migrate to their target region. And third, the SVZa progeny express early neuron-specific antigens prior to their final division and, therefore, prior to reaching their destination where they will terminally differentiate. To better understand the capacity of the SVZa progeny to concurrently proliferate, migrate, and differentiate, we studied the cells in vitro and following transplantation into the neonatal SVZa and adult striatum. In each setting, we found that the SVZa cells continue both to proliferate and to differentiate into neurons. In addition, after homotopic and heterotopic transplantation, we found that the SVZa cells maintain their ability to migrate. These results suggest that the unique features of the SVZa progeny are specified intrinsically rather than by their extrinsic environment.     

Visualization of Rostral Migratory Stream in the Developing Rat Brain by In Vivo Electroporation

Interneurons in the olfactory bulb (OB) are generated from neuronal precursor cells migrating from anterior subventricular zone (SVZa) not only in the developing embryo but also throughout the postnatal life of mammals. In the present study, we established an in vivo electroporation assay to label SVZa cells of rat both at embryonic and postnatal ages, and traced SVZa progenitors and followed their migration pathway and differentiation. We found that labeled cells displayed high motility. Interestingly, the postnatal cells migrated faster than the embryonic cells after applying this assay at different ages of brain development. Furthermore, based on brain slice culture and time-lapse imaging, we analyzed the detail migratory properties of these labeled precursor neurons. Finally, tissue transplantation experiments revealed that cells already migrated in subependymal zone of OB were transplanted back into rostral migratory stream (RMS), and these cells could still migrate out tangentially along RMS to OB. Taken together, these findings provide an in vivo labeling assay to follow and trace migrating cells in the RMS, their maturation and integration into OB neuron network, and unrecognized phenomena that postnatal SVZa progenitor cells with higher motility than embryonic cells, and their migration was affected by extrinsic environments.     

Rate and pattern of migration of lineally-related olfactory bulb interneurons generated postnatally in the subventricular zone of the rat

A spatially discrete region of the anterior part of the postnataltelescephalic subventricular zone, referred to as the SVZa generatesvast numbers of lineally-related neurons destined for the olfactorybulb (Luskin, 1993). The cells originating in the SVZa migrateto the olfactory bulb along a highly restricted pathway whichis in a direction orthogonal to the orientation of radial glialfibers. In this study we analysed the number, distribution,orientation and rate of migration of SVZa-derived cells as theyapproach the olfactory bulb. In order to track the SVZa-derivedcells, a retroviral lineage tracer, encoding the reporter geneE.coli ß-galactosidase (lacZ) was injected preciselyinto the rat SVZa at postnatal day 1 (Pl). The lacZ-positivecells were visualized 1, 2 and 3 days later by X-Gal histochemistryin cryostat sections. As the number of SVZa-derived cells inthe pathway increased with survival time, their distributionchanged systematically. The distribution pattern of lacZ-positivecells by 2 and 3 days postinjection suggested that some of theprogeny of infected progenitor cells were undergoing neurogenesisas they proceeded to the olfactory bulb; a large percentageof the lacZ-positive cells were substantially displaced fromthe SVZa injection site. To investigate whether lacZ-positivecells migrate in a directed fashion, their orientation preferencewas scored. For the majority of lacZ-positive cells (>94%),their leading process was directed toward the olfactory bulb,possibly reflecting a response to migratory cues present alongthe pathway. The estimated average rate of cell migration tothe olfactory bulb was 23 µm/h, which is approximatelytwice the speed of radially directed neuronal migration fromthe telencephalic ventricular zone to the cortical plate (O'Rourkeet al, 1992). Collectively, these results suggest that SVZa-derivedintemeurons en route to the olfactory bulb may employ a novelmode of tangential migration.     

Fractone‐heparan sulphates mediate FGF‐2 stimulation of cell proliferation in the adult subventricular zone

Objectives: Fractones are extracellular matrix structures that form a niche for neural stem cells and their immediate progeny in the subventricular zone of the lateral ventricle (SVZa), the primary neurogenic zone in the adult brain. We have previously shown that heparan sulphates (HS) associated with fractones bind fibroblast growth factor‐2 (FGF‐2), a powerful mitotic growth factor in the SVZa. Here, our objective was to determine whether the binding of FGF‐2 to fractone‐HS is implicated in the mechanism leading to cell proliferation in the SVZa. Materials and methods: Heparitinase‐1 was intracerebroventricularly injected with FGF‐2 to N‐desulfate HS proteoglycans and determine whether the loss of HS and of FGF‐2 binding to fractones modifies FGF‐2 effect on cell proliferation. We also examined in vivo the binding of Alexa‐Fluor‐FGF‐2 in relationship with the location of HS immunoreactivity in the SVZa. Results: Heparatinase‐1 drastically reduced the stimulatory effect of FGF‐2 on cell proliferation in the SVZa. Alexa‐Fluor‐FGF‐2 binding was strictly co‐localized with HS immunoreactivity in fractones and adjacent vascular basement membranes in the SVZa. Conclusions: Our results demonstrate that FGF‐2 requires HS to stimulate cell proliferation in the SVZa and suggest that HS associated with fractones and vascular basement membranes are responsible for activating FGF‐2. Therefore, fractones and vascular basement membranes may function as a HS niche to drive cell proliferation in the adult neurogenic zone.     

Increased number of BrdU-labeled neurons in the rostral migratory stream of the estrous prairie vole

In the mammalian forebrain, most neurons originate from proliferating cells in the ventricular zone lining the lateral ventricles, including a discrete area of the subventricular zone in which neurogenesis continues into adulthood. The majority of the cells generated in the anterior portion of the subventricular zone (SVZa) are neuronal precursors with progeny that migrate to the olfactory bulb (OB) along a pathway known as the rostral migratory stream (RMS). The list of factors that influence the proliferation and survival of neurons in the adult brain remains incomplete, but previous studies have implicated neurotrophins in mammals and estrogen in birds. This study examined the effect of estrus induction on the proliferation of SVZa neurons in female prairie voles. Prairie voles, unlike many other rodents, are induced into estrus by chemosensory cues from a male. This olfactory-mediated process results in an increase in serum estrogen levels and the consequent induction of behavioral estrus (sexual receptivity). Female prairie voles induced into estrus by male exposure had a 92% increase in BrdU-labeled cells in the SVZa compared to females exposed to a female. Double-label immunocytochemical studies demonstrated that 80% of the BrdU-labeled cells in the RMS displayed a neuronal phenotype. Ovariectomized females exposed to a male did not show an increase in serum estrogen or BrdU labeling in the RMS. Conversely, ovariectomized females injected with estrogen were sexually receptive and had more BrdU-labeled cells in the RMS than oil-injected females. These data suggest that, in female prairie voles, estrus induction is associated with increased numbers of dividing cells in the RMS, possibly via an estrogen-mediated process.     

Mash-1在大鼠SVZa神经干细胞迁移流的发育学表达

目的了解在大鼠脑发育过程中,mash-1在SVZa神经干细胞迁移流通路中三个不同脑区内的表达模式。方法用RT-PCR和免疫荧光染色的方法观察在胚胎14d(E14),出生后0d(P0),生后7d(P7)3个不同发育阶段大鼠SVZa、RMS、OB3个区域mash-1的表达情况。结果RT-PCR显示在大鼠脑发育过程中SVZa、RMS、OB三个区域mash-1的mRNA均有不同程度的表达,在出生前后(P0)表达最高;免疫组化显示在大鼠脑发育成熟过程中,mash-1表达水平呈现复杂的时空表达模式,在胚胎期SVZa神经干细胞迁移流通路中表达密集,P0时期在嗅球有较高的表达,P7以后mash-1的表达水平普遍下降。结论mash-1可能主要参与调节大鼠SVZa神经干细胞分化过程,对其迁移和增殖也可能具有积极影响。     

Wnt2b controls retinal cell differentiation at the ciliary marginal zone

The ciliary marginal zone of the vertebrate retina contains undifferentiated progenitor cells that continue to proliferate and add new neurons and glia peripherally during the embryonic stages - even after the formation of a functional retina. To understand the molecular mechanism that controls the prolonged progenitor cell proliferation in the ciliary marginal zone, we employed a candidate molecule approach, focusing on Wnt2b (formerly know as Wnt13), which is expressed in the marginal most tip of the retina. Frizzled 4 and 5, seven-pass transmembrane Wnt receptors, were expressed in the peripheral and central part of the retina, respectively. LEF1, a downstream Wnt signaling component, was expressed at high levels in the ciliary marginal zone with expression gradually decreasing towards the central retina. The LEF1-expressing region, which is where Wnt signaling is supposedly activated, expressed a set of molecular markers that are characteristic of the progenitor cells in the ciliary marginal zone. Overexpression of Wnt2b by use of in ovo electroporation in the central retina inhibited neuronal differentiation and induced the progenitor cell markers. Blocking of the Wnt downstream signaling pathway by a dominant-negative LEF1 inhibited proliferation of the cells in the marginal area, which resulted in their premature neuronal differentiation. The progenitor cells in the ciliary marginal zone differentiated into all the neuronal and glial cell types when cultured in vitro, and they proliferated for a longer period than did centrally located progenitor cells that underwent a limited number of cell divisions. In addition, the proliferation of these progenitor cells was promoted in the presence of Wnt2b. These results suggest that Wnt2b functions to maintain undifferentiated progenitor cells in the ciliary marginal zone, and thus serves as a putative stem cell factor in the retina.     

Signal transduction in neuronal migration: roles of GTPase activating proteins and the small GTPase Cdc42 in the Slit-Robo pathway.

The Slit protein guides neuronal and leukocyte migration through the transmembrane receptor Roundabout (Robo). We report here that the intracellular domain of Robo interacts with a novel family of Rho GTPase activating proteins (GAPs). Two of the Slit-Robo GAPs (srGAPs) are expressed in regions responsive to Slit. Slit increased srGAP1-Robo1 interaction and inactivated Cdc42. A dominant negative srGAP1 blocked Slit inactivation of Cdc42 and Slit repulsion of migratory cells from the anterior subventricular zone (SVZa) of the forebrain. A constitutively active Cdc42 blocked the repulsive effect of Slit. These results have demonstrated important roles for GAPs and Cdc42 in neuronal migration. We propose a signal transduction pathway from the extracellular guidance cue to intracellular actin polymerization.     

Gene profiles within the adult subventricular zone niche: proliferation, differentiation and migration of neural progenitor cells in the ischemic brain

Focal cerebral ischemia induces neurogenesis in the subventricular zone (SVZ) of the adult human brain. Neurogenesis is controlled by proliferation, differentiation, and migration of neural progenitor cells. This article reviews emerging data that changes of cell cycle kinetics of neural progenitor cells induced by stroke contribute to increased neural progenitor cell proliferation and that gene profiles control proliferation, differentiation, and migration of neural progenitor cells within the SVZ niche. A better understanding of gene profiles that control the biological function of adult SVZ neural progenitor cells could lead to more selective and effective treatments to enhance neurogenesis during stroke recovery.     

A Wnt5a pathway underlies outgrowth of multiple structures in the vertebrate embryo

Morphogenesis depends on the precise control of basic cellular processes such as cell proliferation and differentiation. Wnt5a may regulate these processes since it is expressed in a gradient at the caudal end of the growing embryo during gastrulation, and later in the distal-most aspect of several structures that extend from the body. A loss-of-function mutation of Wnt5a leads to an inability to extend the A-P axis due to a progressive reduction in the size of caudal structures. In the limbs, truncation of the proximal skeleton and absence of distal digits correlates with reduced proliferation of putative progenitor cells within the progress zone. However, expression of progress zone markers, and several genes implicated in distal outgrowth and patterning including Distalless, Hoxd and Fgf family members was not altered. Taken together with the outgrowth defects observed in the developing face, ears and genitals, our data indicates that Wnt5a regulates a pathway common to many structures whose development requires extension from the primary body axis. The reduced number of proliferating cells in both the progress zone and the primitive streak mesoderm suggests that one function of Wnt5a is to regulate the proliferation of progenitor cells.     

Antagonistic cross-regulation between Wnt and Hedgehog signalling pathways controls post-embryonic retinal proliferation

Continuous neurogenesis in the adult nervous system requires a delicate balance between proliferation and differentiation. Although Wnt/β-catenin and Hedgehog signalling pathways are thought to share a mitogenic function in adult neural stem/progenitor cells, it remains unclear how they interact in this process. Adult amphibians produce retinal neurons from a pool of neural stem cells localised in the ciliary marginal zone (CMZ). Surprisingly, we found that perturbations of the Wnt and Hedgehog pathways result in opposite proliferative outcomes of neural stem/progenitor cells in the CMZ. Additionally, our study revealed that Wnt and Hedgehog morphogens are produced in mutually exclusive territories of the post-embryonic retina. Using genetic and pharmacological tools, we found that the Wnt and Hedgehog pathways exhibit reciprocal inhibition. Our data suggest that Sfrp-1 and Gli3 contribute to this negative cross-regulation. Altogether, our results reveal an unexpected antagonistic interplay of Wnt and Hedgehog signals that may tightly regulate the extent of neural stem/progenitor cell proliferation in the Xenopus retina.     

LIF and BMP signaling generate separate and discrete types of GFAP-expressing cells

Bone morphogenetic protein (BMP) and leukemia inhibitory factor (LIF) signaling both promote the differentiation of neural stem/progenitor cells into glial fibrillary acidic protein (GFAP) immunoreactive cells. This study compares the cellular and molecular characteristics, and the potentiality, of GFAP(+) cells generated by these different signaling pathways. Treatment of cultured embryonic subventricular zone (SVZ) progenitor cells with LIF generates GFAP(+) cells that have a bipolar/tripolar morphology, remain in cell cycle, contain progenitor cell markers and demonstrate self-renewal with enhanced neurogenesis - characteristics that are typical of adult SVZ and subgranular zone (SGZ) stem cells/astrocytes. By contrast, BMP-induced GFAP(+) cells are stellate, exit the cell cycle, and lack progenitor traits and self-renewal--characteristics that are typical of astrocytes in the non-neurogenic adult cortex. In vivo, transgenic overexpression of BMP4 increases the number of GFAP(+) astrocytes but depletes the GFAP(+) progenitor cell pool, whereas transgenic inhibition of BMP signaling increases the size of the GFAP(+) progenitor cell pool but reduces the overall numbers of astrocytes. We conclude that LIF and BMP signaling generate different astrocytic cell types, and propose that these cells are, respectively, adult progenitor cells and mature astrocytes.     

Widespread tangential dispersion and extensive cell death during early neurogenesis in the mouse neocortex

The development of the mammalian neocortex requires radial and tangential migration of cells. Radial migration of differentiated neurons from the ventricular zone (VZ) is well established. It is hypothesised that an earlier phase of tangential migration of mitotically active cells lays down a widespread periodically spaced set of progenitors that generate radial arrays of postmitotic neurons. We use a transgenic cell lineage marker to label and observe the behaviour of progenitors before and during the early stages of neurogenesis. Using optical projection tomography (OPT), we show that individual progenitor cells generate many radially arrayed columns of periodically spaced cells. Column positions indicate the paths taken by these progenitor cells as they migrate, often over long distances, through the proliferative zone. Clonally related cells can be distributed in both hemispheres, suggesting progenitor cells cross the midline in the anterior neural plate. We observe a dramatic and rapid decline in the number of labelled clones after E13.5, indicating that there is extensive cell death at this time.