Two specific populations of GABAergic neurons originating from the medial and the caudal ganglionic eminences aid in proper navigation of callosal axons

Niquille, Mathieu; Minocha, Shilpi; Hornung, Jean‐Pierre; Rufer, Nathalie; Valloton, Delphine; Kessaris, Nicoletta; Alfonsi, Fabienne; Vitalis, Tania; Yanagawa, Yuchio; Devenoges, Christiane; Dayer, Alexandre; Lebrand, Cécile

doi:10.1002/dneu.22075

Cited by 23 publications

(24 citation statements)

References 105 publications

(164 reference statements)

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“…Our data support a role for commissural axons in neurophilic migration and, to the best of our knowledge, provide the first experimental evidence that commissural axonal fascicles act as border landmarks delimiting neuronal migration named 'axon-restricted migration'. Several studies have shown that conversely, appropriate clustering of cell bodies can influence the axon to be guided appropriately [7][8][9] . Furthermore, it is well established that both axons and neuronal cell bodies are influenced by direct chemotactic mechanisms 5 .…”

Section: Discussionmentioning

confidence: 99%

“…As axons and neuronal cell bodies from different populations are guided simultaneously during development and are in close apposition, it seems plausible that forming axonal fascicles and cell bodies physically influence each other's behaviour. A small number of studies have shown that the position of cell bodies influence the guidance of axons by the production of chemotactic cues [7][8][9] . Conversely, there is also evidence to support the idea that pioneer axons provide a growth substrate for newly migrating axons and cell bodies [10][11][12] .…”

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confidence: 99%

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Commissural axonal corridors instruct neuronal migration in the mouse spinal cord

et al. 2015

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Unravelling how neurons are guided during vertebrate embryonic development has wide implications for understanding the assembly of the nervous system. During embryogenesis, migration of neuronal cell bodies and axons occurs simultaneously, but to what degree they influence each other's development remains obscure. We show here that within the mouse embryonic spinal cord, commissural axons bisect, delimit or preconfigure ventral interneuron cell body position. Furthermore, genetic disruption of commissural axons results in abnormal ventral interneuron cell body positioning. These data suggest that commissural axonal fascicles instruct cell body position by acting either as border landmarks (axon-restricted migration), which to our knowledge has not been previously addressed, or acting as cellular guides. This study in the developing spinal cord highlights an important function for the interaction of cell bodies and axons, and provides a conceptual proof of principle that is likely to have overarching implications for the development of neuronal architecture.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

Commissural axonal corridors instruct neuronal migration in the mouse spinal cord

et al. 2015

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“…Rather, transient neurons have been described during embryonic development and early postnatal stages (Niquille et al, 2009;Teissier et al, 2012) and, at least in the neocortex, it has been suggested that their death is regulated by intrinsically defined mechanisms (Southwell et al, 2012). Interestingly, these cells are often directed to white matter tracts, where they contribute to the guidance of growing axons (López-Bendito et al, 2006;Niquille et al, 2009Niquille et al, , 2013Sato et al, 1998). Moreover, these cells originate, in part, from the caudal ganglionic eminence, a major source of Sp8 + interneurons (Ma et al, 2012;Niquille et al, 2013).…”

Section: Fate Of the Newly Generated Neuroblastsmentioning

confidence: 99%

“…Interestingly, these cells are often directed to white matter tracts, where they contribute to the guidance of growing axons (López-Bendito et al, 2006;Niquille et al, 2009Niquille et al, , 2013Sato et al, 1998). Moreover, these cells originate, in part, from the caudal ganglionic eminence, a major source of Sp8 + interneurons (Ma et al, 2012;Niquille et al, 2013). These observations raise the possibility that the transient EC-LS neuroblasts belong to a broader population of cells involved in transient forms of plasticity, possibly related to the remodeling of long-range connections.…”

Section: Fate Of the Newly Generated Neuroblastsmentioning

confidence: 99%

Quiescent neuronal progenitors are activated in the juvenile guinea pig lateral striatum and give rise to transient neurons

et al. 2014

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In the adult brain, active stem cells are a subset of astrocytes residing in the subventricular zone (SVZ) and the dentate gyrus (DG) of the hippocampus. Whether quiescent neuronal progenitors occur in other brain regions is unclear. Here, we describe a novel neurogenic system in the external capsule and lateral striatum (EC-LS) of the juvenile guinea pig that is quiescent at birth but becomes active around weaning. Activation of neurogenesis in this region was accompanied by the emergence of a neurogenic-like niche in the ventral EC characterized by chains of neuroblasts, intermediate-like progenitors and glial cells expressing markers of immature astrocytes. Like neurogenic astrocytes of the SVZ and DG, these latter cells showed a slow rate of proliferation and retained BrdU labeling for up to 65 days, suggesting that they are the primary progenitors of the EC-LS neurogenic system. Injections of GFPtagged lentiviral vectors into the SVZ and the EC-LS of newborn animals confirmed that new LS neuroblasts originate from the activation of local progenitors and further supported their astroglial nature. Newborn EC-LS neurons existed transiently and did not contribute to neuronal addition or replacement. Nevertheless, they expressed Sp8 and showed strong tropism for white matter tracts, wherein they acquired complex morphologies. For these reasons, we propose that EC-LS neuroblasts represent a novel striatal cell type, possibly related to those populations of transient interneurons that regulate the development of fiber tracts during embryonic life.

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“…Sources of these guidance cues include populations of guidepost cells (of both glial and neuronal identity) situated at various stages along the callosal tract. Examples of such populations are the indusium griseum at the midline dorsal border of the corpus callosum (Shu and Richards, 2001), the glial wedge ventral to the corpus callosum and medial to the lateral ventricles (Shu and Richards, 2001;Shu et al, 2003c), and the midline corridor, which lies ventral and dorsal to the corpus callosum at the midline (Silver et al, 1982;Shu et al, 2003b;Niquille et al, 2009;Niquille et al, 2013).…”

Section: Midline Crossingmentioning

confidence: 99%

Contralateral targeting of the corpus callosum

Fenlon¹

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During development, the brain establishes billions of precise connections in order to perform its myriad functions. The largest of these connections in placental mammals is the corpus callosum, which is a large bundle of axons linking the two cortical hemispheres of the brain. Absence or gross malformation of this structure is a relatively common developmental disorder in humans, producing symptoms ranging from severe to mild cognitive, emotional and motor deficits. However, recent evidence suggests that the corpus callosum can also display subtle malformations that are not visible with traditional magnetic resonance imaging methods, and that these may be involved in neurodevelopmental disorders such as autism and schizophrenia. The possibility of callosal misconnectivity arising independently of the widely-studied process of midline crossing highlights the need to investigate other less well-understood stages of callosal development. One such process that may be disrupted after normal midline crossing of the corpus callosum is contralateral targeting, where axons must locate, innervate and stabilize in their appropriate contralateral cortical targets.This thesis focuses on understanding the normal process of contralateral targeting, as well as the nature of its dependence on neuronal activity and the molecular mechanisms that regulate it. To investigate these topics, diverse approaches including in utero electroporation, stereotaxic brain injection, sensory deprivation paradigms, tissuespecific RNA extraction and RNA sequencing were used in the mouse somatosensory cortex model system of callosal connectivity. Novel patterns and processes of normal contralateral targeting were identified, as well as distinct periods of region-specific activitydependent and -independent axonal exuberance. Contralateral callosal targeting was also shown to be not just dependent on neuronal activity, but rather a balance of spatially symmetric activity between the two cortical hemispheres. The molecular mechanisms underlying activity-dependent and -independent stages of contralateral callosal targeting were also investigated, and a novel technique to extract RNA from an electroporated population of cell bodies and/or their callosal axons was developed to facilitate this study in the future.These results constitute fundamental insights into the process of contralateral callosal targeting, as well as some of the mechanisms that may lead to its disruption. This work provides solid foundations for future studies to build upon, and may ultimately help us to better understand subtle human disorders of neuronal connectivity.3

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Two specific populations of GABAergic neurons originating from the medial and the caudal ganglionic eminences aid in proper navigation of callosal axons

Cited by 23 publications

References 105 publications

Commissural axonal corridors instruct neuronal migration in the mouse spinal cord

Commissural axonal corridors instruct neuronal migration in the mouse spinal cord

Quiescent neuronal progenitors are activated in the juvenile guinea pig lateral striatum and give rise to transient neurons

Contralateral targeting of the corpus callosum

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