Claudia Mandl

Activity requires soluble amyloid precursor protein α to promote neurite outgrowth in neural stem cell‐derived neurons via activation of the MAPK pathway

It is known that activity modulates neuronal differentiation in the adult brain but the signalling mechanisms underlying this process remain to be identified. We show here that activity requires soluble amyloid precursor protein (sAPP) to enhance neurite outgrowth of young neurons differentiating from neural stem cells. Inhibition of sAPP secretion and anti‐APP antibodies both abolished the effect of depolarization on neurite outgrowth, whereas exogenous sAPPα, similar to depolarization, induced neurite elongation. Depolarization and sAPPα both required active N‐methyl‐d‐aspartic acid receptor (NMDAR) and mitogen‐activated protein kinase (MAPK)/extracellular signal‐regulated kinase (ERK) recruitment to induce neurite outgrowth. However, depolarization and sAPPα played different roles in modulating this signalling cascade. Depolarization induced ERK phosphorylation with fast kinetics via activation of NMDAR. By contrast, acute application of sAPPα did not lead to ERK activation. However, continuous generation of sAPPα was necessary for depolarization‐induced ERK phosphorylation, indicating that sAPPα promotes MAPK/ERK recruitment by an indirect mechanism. In addition, we found that blockade of NMDAR down‐regulated APP expression, whereas depolarization increased sAPPα, suggesting that activity may also act upstream of sAPP signalling by regulating the amount of cellular APP and extracellular sAPPα. Finally, we show that soluble amyloid precursor‐like protein 2 (sAPLP2), but not sAPLP1, is functionally redundant to sAPP in promoting neurite outgrowth and that soluble members of the APP family require membrane‐bound APP to enhance neurite outgrowth. In summary, these experiments indicate a novel role of APP family members in activity‐dependent neuronal differentiation.

Analysis of stem cell lineage progression in the neonatal subventricular zone identifies EGFR+/NG2- cells as transit-amplifying precursors.

In the adult subventricular zone (SVZ), astroglial stem cells generate transit‐amplifying precursors (TAPs). Both stem cells and TAPs form clones in response to epidermal growth factor (EGF). However, in vivo, in the absence of sustained EGF receptor (EGFR) activation, TAPs divide a few times before differentiating into neuroblasts. The lack of suitable markers has hampered the analysis of stem cell lineage progression and associated functional changes in the neonatal germinal epithelium. Here we purified neuroblasts and clone‐forming precursors from the neonatal SVZ using expression levels of EGFR and polysialylated neural cell adhesion molecule (PSANCAM). As in the adult SVZ, most neonatal clone‐forming precursors did not express the neuroglia proteoglycan 2 (NG2) but displayed characteristics of TAPs, and only a subset exhibited antigenic characteristics of astroglial stem cells. Both precursors and neuroblasts were PSANCAM+; however, neuroblasts also expressed doublecortin and functional voltage‐dependent Ca2+ channels. Neuroblasts and precursors had distinct outwardly rectifying K+ current densities and passive membrane properties, particularly in precursors contacting each other, because of the contribution of gap junction coupling. Confirming the hypothesis that most are TAPs, cell tracing in brain slices revealed that within 2 days the majority of EGFR+ cells had exited the cell cycle and differentiated into a progenitor displaying intermediate antigenic and functional properties between TAPs and neuroblasts. Thus, distinct functional and antigenic properties mark stem cell lineage progression in the neonatal SVZ. STEM CELLS 2009;27:1443–1454

Interaction between DLX2 and EGFR regulates proliferation and neurogenesis of SVZ precursors.

In the postnatal subventricular zone (SVZ) neural stem cells (NSCs) give rise to transit-amplifying precursors (TAPs) expressing high levels of epidermal growth factor receptor (EGFR) that in turn generate neuroblasts. Both TAPs and neuroblasts express distal-less (DLX)2 homeobox transcription factor but the latter proliferate less. Modulation of its expression in vivo has revealed that DLX2 affects both neurogenesis and proliferation in the postnatal SVZ. However, the mechanisms underlying these effects are not clear. To investigate this issue we have here forced the expression of DLX2 in SVZ isolated NSCs growing in defined in vitro conditions. This analysis revealed that DLX2 affects the proliferation of SVZ precursors by regulating two distinct steps of neural lineage progression. Firstly, it promotes the lineage transition from NSCs to TAPs. Secondly it enhances the proliferative response of neuronal progenitors to EGF. Thus DLX2 and EGFR signalling interact at multiple levels to coordinate proliferation in the postnatal SVZ.

Expression of DSD-1-PG in primary neural and glial-derived cell line cultures, upregulation by TGF-β, and implications for cell-substrate interactions of the glial cell line Oli-neu

DSD‐1‐PG is a chondroitin sulfate proteoglycan with neurite‐outgrowth promoting properties expressed during development and upon lesion of neural tissues which has been defined with the specific monoclonal antibody 473HD. Double immunofluorescence studies performed on primary cerebellar cultures document that the proteoglycan is expressed on the surface of immature glial cells and the neural cell line Oli‐neu, a model of mouse oligodendrocyte progenitors. Biochemical and immunoprecipitation studies performed with biosynthetically labelled Oli‐neu and primary neural cells demonstrated that DSD‐1‐PG is expressed in vitro as a proteoglycan of 1000 kD apparent Mr with two core glycoproteins of 250 kD and 400 kD. In order to study the regulation of DSD‐1‐PG expression, an in vitro enzyme‐linked immunosorbent assay based on Oli‐neu and mAb 473HD was established. TGF‐β1‐3 induced up‐regulation of the proteoglycan, while various growth factors and cytokines did not significantly affect DSD‐1‐PG expression in both the supernatant and the extract of the culture monolayer. FACSCAN analysis suggested that the proteoglycan is upregulated on the surface of Oli‐neu. Cell substrate adhesion assays revealed that this enhanced expression correlates with a selective reduction of adhesion to laminin, but not fibronectin or merosin, which could specifically be neutralized by antibodies to DSD‐1‐PG. We conclude that the proteoglycan contributes to the regulation of glial precursor interactions with the extracellular matrix. GLIA 23:99–119, 1998.

GABAA Receptor Signaling Induces Osmotic Swelling and Cell Cycle Activation of Neonatal Prominin+ Precursors

Signal‐regulated changes in cell size affect cell division and survival and therefore are central to tissue morphogenesis and homeostasis. In this respect, GABA receptors (GABAARs) are of particular interest because allowing anions flow across the cell membrane modulates the osmolyte flux and the cell volume. Therefore, we have here investigated the hypothesis that GABA may regulate neural stem cell proliferation by inducing cell size changes. We found that, besides neuroblasts, also neural precursors in the neonatal murine subependymal zone sense GABA via GABAARs. However, unlike in neuroblasts, where it induced depolarization‐mediated [Ca2+]i increase, GABAARs activation in precursors caused hyperpolarization. This resulted in osmotic swelling and increased surface expression of epidermal growth factor receptors (EGFRs). Furthermore, activation of GABAARs signaling in vitro in the presence of EGF modified the expression of the cell cycle regulators, phosphatase and tensin homolog and cyclin D1, increasing the pool of cycling precursors without modifying cell cycle length. A similar effect was observed on treatment with diazepam. We also demonstrate that GABA and diazepam responsive precursors represent prominin+ stem cells. Finally, we show that as in in vitro also in in vivo a short administration of diazepam promotes EGFR expression in prominin+ stem cells causing activation and cell cycle entry. Thus, our data indicate that endogenous GABA is a part of a regulatory mechanism of size and cell cycle entry of neonatal stem cells. Our results also have potential implications for the therapeutic practices that involve exposure to GABAARs modulators during neurodevelopment. STEM CELLS 2011;29:307–319

Expression of Tlx in Both Stem Cells and Transit Amplifying Progenitors Regulates Stem Cell Activation and Differentiation in the Neonatal Lateral Subependymal Zone

Niche homeostasis in the postnatal subependymal zone of the lateral ventricle (lSEZ) requires coordinated proliferation and differentiation of neural progenitor cells. The mechanisms regulating this balance are scarcely known. Recent observations indicate that the orphan nuclear receptor Tlx is an intrinsic factor essential in maintaining this balance. However, the effect of Tlx on gene expression depends on age and cell‐type cues. Therefore, it is essential to establish its expression pattern at different developmental ages. Here, we show for the first time that in the neonatal lSEZ activated neural stem cells (NSCs) and especially transit‐amplifying progenitors (TAPs) express Tlx and that its expression may be regulated at the posttranscriptional level. We also provide evidence that in both cell types Tlx affects gene expression in a positive and negative manner. In activated NSCs, but not in TAPs, absence of Tlx leads to overexpression of negative cell cycle regulators and impairment of proliferation. Moreover, in both cell types, the homeobox transcription factor Dlx2 is downregulated in the absence of Tlx. This is paralleled by increased expression of Olig2 in activated NSCs and glial fibrillary acidic protein in TAPs, indicating that in both populations Tlx decreases gliogenesis. Consistent with this, we found a higher proportion of cells expressing glial makers in the neonatal lSEZ of mutant mice than in the wild type counterpart. Thus, Tlx playing a dual role affects the expression of distinct genes in these two lSEZ cell types. STEM CELLS 2011; 29:1415–1426

Growth/differentiation factor 15 promotes EGFR signalling, and regulates proliferation and migration in the hippocampus of neonatal and young adult mice

The activation of epidermal growth factor receptor (EGFR) affects multiple aspects of neural precursor behaviour, including proliferation and migration. Telencephalic precursors acquire EGF responsiveness and upregulate EGFR expression at late stages of development. The events regulating this process and its significance are still unclear. We here show that in the developing and postnatal hippocampus (HP), growth/differentiation factor (GDF) 15 and EGFR are co-expressed in primitive precursors as well as in more differentiated cells. We also provide evidence that GDF15 promotes responsiveness to EGF and EGFR expression in hippocampal precursors through a mechanism that requires active CXC chemokine receptor (CXCR) 4. Besides EGFR expression, GDF15 ablation also leads to decreased proliferation and migration. In particular, lack of GDF15 impairs both processes in the cornu ammonis (CA) 1 and only proliferation in the dentate gyrus (DG). Importantly, migration and proliferation in the mutant HP were altered only perinatally, when EGFR expression was also affected. These data suggest that GDF15 regulates migration and proliferation by promoting EGFR signalling in the perinatal HP and represent a first description of a functional role for GDF15 in the developing telencephalon.

Proliferation and cilia dynamics in neural stem cells prospectively isolated from the SEZ.

Neural stem cells (NSCs) generate new neurons in vivo and in vitro throughout adulthood and therefore are physiologically and clinically relevant. Unveiling the mechanisms regulating the lineage progression from NSCs to newborn neurons is critical for the transition from basic research to clinical application. However, the direct analysis of NSCs and their progeny is still elusive due to the problematic identification of the cells. We here describe the isolation of highly purified genetically unaltered NSCs and transit-amplifying precursors (TAPs) from the adult subependymal zone (SEZ). Using this approach we show that a primary cilium and high levels of epidermal growth factor receptor (EGFR) at the cell membrane characterize quiescent and cycling NSCs, respectively. However, we also observed non-ciliated quiescent NSCs and NSCs progressing into the cell cycle without up-regulating EGFR expression. Thus, the existence of NSCs displaying distinct molecular and structural conformations provides more flexibility to the regulation of quiescence and cell cycle progression.

γ-Aminobutyric A Receptor (GABAAR) Regulates Aquaporin 4 Expression in the Subependymal Zone RELEVANCE TO NEURAL PRECURSORS AND WATER EXCHANGE

Activation of γ-aminobutyric A receptors (GABA(A)Rs) in the subependymal zone (SEZ) induces hyperpolarization and osmotic swelling in precursors, thereby promoting surface expression of the epidermal growth factor receptor (EGFR) and cell cycle entry. However, the mechanisms underlying the GABAergic modulation of cell swelling are unclear. Here, we show that GABA(A)Rs colocalize with the water channel aquaporin (AQP) 4 in prominin-1 immunopositive (P(+)) precursors in the postnatal SEZ, which include neural stem cells. GABA(A)R signaling promotes AQP4 expression by decreasing serine phosphorylation associated with the water channel. The modulation of AQP4 expression by GABA(A)R signaling is key to its effect on cell swelling and EGFR expression. In addition, GABA(A)R function also affects the ability of neural precursors to swell in response to an osmotic challenge in vitro and in vivo. Thus, the regulation of AQP4 by GABA(A)Rs is involved in controlling activation of neural stem cells and water exchange dynamics in the SEZ.Background: GABAARs regulate osmotic tension in prominin+ neural stem cells and ependymal cells. Results: GABAAR activation increases surface expression of AQP4, thereby affecting water exchange between the subependyma and the lateral ventricle. Conclusion: Modulation of AQP4 expression by GABA underlies the osmotic function of the neurotransmitter. Significance: GABAARs contribute to the regulation of water exchange between lateral ventricle and subependyma. Activation of γ-aminobutyric A receptors (GABAARs) in the subependymal zone (SEZ) induces hyperpolarization and osmotic swelling in precursors, thereby promoting surface expression of the epidermal growth factor receptor (EGFR) and cell cycle entry. However, the mechanisms underlying the GABAergic modulation of cell swelling are unclear. Here, we show that GABAARs colocalize with the water channel aquaporin (AQP) 4 in prominin-1 immunopositive (P+) precursors in the postnatal SEZ, which include neural stem cells. GABAAR signaling promotes AQP4 expression by decreasing serine phosphorylation associated with the water channel. The modulation of AQP4 expression by GABAAR signaling is key to its effect on cell swelling and EGFR expression. In addition, GABAAR function also affects the ability of neural precursors to swell in response to an osmotic challenge in vitro and in vivo. Thus, the regulation of AQP4 by GABAARs is involved in controlling activation of neural stem cells and water exchange dynamics in the SEZ.

Bone morphogenetic protein promotes LeX‐SSEA1 expression thereby interfering with neural precursor and stem cell proliferation

The glycoprotein Prominin‐1 and the carbohydrate Lewis X stage‐specific embryonic antigen 1 (LeX‐SSEA1) both have been extensively used as cell surface markers to purify neural stem cells (NSCs). While Prominin‐1 labels a specialized membrane region in NSCs and ependymal cells, the specificity of LeX‐SSEA1 expression and its biological significance are still unknown. To address these issues, we have here monitored the expression of the carbohydrate in neonatal and adult NSCs and in their progeny. Our results show that the percentage of immunopositive cells and the levels of LeX‐SSEA1 immunoreactivity both increase with postnatal age across all stages of the neural lineage. This is associated with decreased proliferation in precursors including NSCs, which accumulate the carbohydrate at the cell surface while remaining quiescent. Exposure of precursors to bone morphogenetic protein (BMP) increases LEX‐SSEA1 expression, which promotes cell cycle withdrawal by a mechanism involving LeX‐SSEA1‐mediated interaction at the cell surface. Conversely, interference with either BMP signaling or with LeX‐SSEA1 promotes proliferation to a similar degree. Thus, in the postnatal germinal niche, the expression of LeX‐SSEA1 increases with age and exposure to BMP signaling, thereby downregulating the proliferation of subependymal zone precursors including NSCs. Stem Cells 2017;35:2417–2429