Neuronal Subtype Generation During Postnatal Olfactory Bulb Neurogenesis

Autor: Christophe Beclin, Alexandra Angelova, Marie-Catherine Tiveron, Harold Cremer
Přispěvatelé: Institut de Biologie du Développement de Marseille (IBDM), Aix Marseille Université (AMU)-Collège de France (CdF)-Centre National de la Recherche Scientifique (CNRS), Aix Marseille Université (AMU)-Collège de France (CdF (institution))-Centre National de la Recherche Scientifique (CNRS), Poulain, Sébastien
Jazyk: angličtina
Rok vydání: 2018
Předmět:
Zdroj: Journal of experimental neuroscience
Journal of experimental neuroscience, Libertas Academica, 2018, 12, pp.117906951875567. ⟨10.1177/1179069518755670⟩
Journal of experimental neuroscience, 2018, 12, pp.117906951875567. ⟨10.1177/1179069518755670⟩
Journal of Experimental Neuroscience, Vol 12 (2018)
Journal of experimental neuroscience, Libertas Academica, 2017, 12, pp.3888-3904
Journal of Experimental Neuroscience
Journal of experimental neuroscience, 2017, 12, pp.3888-3904
ISSN: 1179-0695
Popis: International audience; New neurons are generated throughout life in two specific regions of the mammalian brain: the hippocampus and the olfactory bulb (OB). In the OB, large numbers of interneurons are permanently issued from stem cells residing in the ven-tricular/subventricular zone (V/SVZ) lining the forebrain ven-tricles. From here, they migrate via the rostral migratory stream (RMS) into the OB where they differentiate as interneurons. These postnatal and adult generated interneurons exhibit considerable phenotypic diversity at several levels. First, they are heterogeneous at the neurotransmitter level. Indeed, it has been shown that neurons using exclusively GABA, neurons that use both GABA and dopamine, and also very few gluta-matergic neurons are generated and integrated. Second, they show varying final locations in the OB. Although most OB interneurons remain in the deep positioned granule cell layer, a substantial fraction integrates in the superficial glomerular layer. Finally, adult-born neurons show a wide spectrum of morphologies, projection patterns, and targets. 1 Lineage studies demonstrated that the diversity of OB interneurons is closely tied to their spatial origin in the stem cell compartment. For example, interneurons generated by progenitors of the dorsal part of the V/SVZ will predominantly integrate in the superficial layers of the OB and express sub-type markers such as calretinin (CR), tyrosine hydroxylase, or the transcription factors (TFs) TBR1/2. In contrast, OB neu-rons produced along the lateral aspect of the ventricle are purely GABAergic and integrate in deeper layers of the OB. The discovery that neuronal heterogeneity is determined by their site of origin led to the notion that the stem cell niche represents a cellular mosaic in which populations of stem cells in defined dorsoventral and anteroposterior positions are predetermined to produce specific neurons for the OB. 2 This, in turn, implies that molecular determinants, for example, differentially expressed TFs, underlie early fate specification and ultimately neuronal function and connectivity. Gene Expression in Space and Time Tiveron et al. 3 set out to systematically identify and functionally characterize such fate determinants based on high-resolution gene expression analyses. Up to now, gene expression analyses performed in the V/SVZ-RMS-OB neurogenic system relied either on microdissection of tissues 4 or on cell sorting based on expression of a limited set of membrane markers 5,6 that define specific differentiation stages. However, in this neurogenic system , such approaches present several limitations. Although the stem cell compartments of the dorsal and lateral lineages are physically separated, these regions harbor progenitors at different differentiation stages (neural stem cells [NSCs], transit amplifying progenitors and migrating neuroblasts). In addition, in the RMS and the OB, both lineages are intermingled and cannot be easily distinguished, let alone isolated. To overcome these limitations, Tiveron et al. performed a lineage tracing approach based on targeted brain electropora-tion. Previous work demonstrated that in vivo brain electropo-ration can be used to transfect DNA-based vectors, 7 or even messenger RNA, 8 into the different stem cell compartments ABSTRACT: In the perinatal and adult forebrain, regionalized neural stem cells lining the ventricular walls produce different types of olfactory bulb interneurons. Although these postnatal stem cells are lineage related to their embryonic counterparts that produce, for example, cortical, septal, and striatal neurons, their output at the level of neuronal phenotype changes dramatically. Tiveron et al. investigated the molecular determinants underlying stem cell regionalization and the gene expression changes inducing the shift from embryonic to adult neuron production. High-resolution gene expression analyses of different lineages revealed that the zinc finger proteins, Zic1 and Zic2, are postnatally induced in the dorsal olfactory bulb neuron lineage. Functional studies demonstrated that these factors confer a GABAergic and calretinin-positive phenotype to neural stem cells while repressing dopaminergic fate. Based on these findings, we discuss the molecular mechanisms that allow acquisition of new traits during the transition from embryonic to adult neurogenesis. We focus on the involvement of epigenetic marks and emphasize why the identification of master transcription factors, that instruct the fate of postnatally generated neurons, can help in deciphering the mechanisms driving fate transition from embryonic to adult neuron production.
Databáze: OpenAIRE
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