Prdm12 specifies V1 interneurons through cross-repressive interactions with Dbx1 and Nkx6 genes in Xenopus

Thélie, Aurore; Desiderio, Simon; Hanotel, Julie; Quigley, Ian K.; Driessche, Benoît Van; Rodari, Anthony; Borromeo, Mark D.; Kricha, Sadia; Lahaye, François; Croce, Jenifer C.; Cerda-Moya, Gustavo; Fernandez, Jesús Ordoño; Bolle, Barbara; Lewis, Katharine E.; Sander, Maike; Pierani, Alessandra; Schubert, Michael; Johnson, Jane E.; Kintner, Christopher R.; Pieler, Tomas; Lint, Carine Van; Henningfeld, Kristine A.; Bellefroid, Éric; Campenhout, Claude Van

doi:10.1242/dev.121871

Cited by 46 publications

(81 citation statements)

References 53 publications

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“…Among them, zic and her genes promote neural progenitor identity and inhibit differentation (Bae et al, 2005; Coolen et al, 2012; Nyholm et al, 2007; Scholpp et al, 2009), id genes encode negative regulators of proneural bHLH proteins (Ellis et al, 1990; Garrell and Modolell, 1990; Ling et al, 2014) and zbtb16a (plzfa) inhibits neurogenesis (Sobieszczuk et al, 2010). The following group of genes (G3) with shifting expression in pseudotime are: sox3 which has initial constant expression followed by a drop in differentiated cells; neurog1 (reviewed by Bertrand et al, 2002); prdm12b, a regulator of V1 interneuron fate decision (Thélie et al, 2015; Zannino et al, 2014); and foxp4 that is promotes detachment of differentiating cells from the neuroepithelium (Rousso et al, 2012). atoh1b and neurod4 are in the next step of the cascade (G4) together with ebf2, a factor that acts downstream of proneural genes and necessary for initiation of migration and neuronal differentiation (Garcia-Dominguez et al, 2003).…”

Section: Resultsmentioning

confidence: 99%

A single cell transcriptome atlas of the developing zebrafish hindbrain

Tambalo

Mitter

Wilkinson

2019

Preprint

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Segmentation of the vertebrate hindbrain leads to the formation of rhombomeres, each with a distinct anteroposterior identity. Specialised boundary cells form at segment borders that act as a source or regulator of neuronal differentiation. In zebrafish, there is spatial patterning of neurogenesis in which non-neurogenic zones form at bounderies and segment centres, in part mediated by Fgf20 signaling. To further understand the control of neurogenesis, we have carried out single cell RNA sequencing of the zebrafish hindbrain at three different stages of patterning. Analyses of the data reveal known and novel markers of distinct hindbrain segments, of cell types along the dorsoventral axis, and of the transition of progenitors to neuronal differentiation. We find major shifts in the transcriptome of progenitors and of differentiating cells between the different stages analysed. Supervised clustering with markers of boundary cells and segment centres, together with RNA-seq analysis of Fgf-regulated genes, has revealed new candidate regulators of cell differentiation in the hindbrain. These data provide a valuable resource for functional investigations of the patterning of neurogenesis and the transition of progenitors to neuronal differentiation.

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Section: Resultsmentioning

confidence: 99%

A single cell transcriptome atlas of the developing zebrafish hindbrain

Tambalo

Mitter

Wilkinson

2019

Preprint

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“…Posterior CNS development in ascidians and amphioxus therefor differs from all vertebrates (including lampreys) in three key ways: (i) neither has a medial proliferative progenitor pool, (ii) in both lineages Notch signalling is maintained only through early development, and (iii) the expression of neuronal HLH genes is confined to scattered individual cells. To this we can add the observation that many of the genes that define vertebrate DV progenitor zones, and the pools of neurons that develop from them, are also only expressed in scattered individual cells in amphioxus, including members of the Olig , Prdm12 , Evx , Engrailed and Isl/Lhx gene families (Albuixech-Crespo et al, 2017b; Beaster-Jones et al, 2008; Ferrier et al, 2001; Holland et al, 1997; Jackman and Kimmel, 2002; Thelie et al, 2015). Furthermore, when Notch signalling is blocked in lamprey development, aspects of the resultant pattern of differentiating cells resemble what is observed in amphioxus, with scattered cells rather than clearly-defined DV zones.…”

Section: Discussionmentioning

confidence: 99%

A Notch-regulated proliferative stem cell zone in the developing spinal cord is an ancestral vertebrate trait

Lara-Ramírez¹,

Pérez‐González

Anselmi

et al. 2018

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statementVertebrates develop nervous systems with numerous cells. Study of cell proliferation in the lamprey nervous system links this to a medial proliferation zone regulated by Notch signalling, a vertebrate innovation. AbstractVertebrates have evolved the most sophisticated nervous systems we know. These differ from the nervous systems of invertebrates in several ways, including the evolution of new cell types, and the emergence and elaboration of patterning mechanisms to organise cells in time and space. Vertebrates also generally have many more cells in their central nervous systems than invertebrates, and an increase in neural cell number may have contributed to the sophisticated anatomy of the brain and spinal cord. Here we study how increased cell number evolved in the vertebrate central nervous system, investigating the regulation of cell proliferation in lampreys as basally-diverging vertebrate, and focusing on the spinal cord because of its relatively simple anatomy. Markers of proliferating cells show that a medial proliferative progenitor zone is found throughout the lamprey spinal cord. We show that inhibition of Notch signalling disrupts the maintenance of this proliferative zone. When Notch signalling is blocked progenitor cells differentiate precociously, the proliferative medial zone is lost, and differentiation markers activate throughout the medial-lateral axis of the spinal cord. Comparison to other chordates suggests that the emergence of a persistent Notchregulated proliferative progenitor zone in the medial spinal cord of vertebrate ancestors was a critical step for the evolution of the vertebrate spinal cord and its complexity.the -secretase enzyme complex (Bray, 2006; Kopan and Ilagan, 2009). This releases the Notch intracellular domain (NICD), which translocates to the nucleus to promote transcription of target genes in combination with the transcription factor CSL (Bray, 2006; Fischer and Gessler, 2007). The best known direct targets of NICD/CSL are the basic Helix Loop Helix (bHLH) transcription factors of the Hes family, which exert an inhibitory role on neuronal differentiation and act as antagonists to neural differentiation-promoting bHLH genes including the neurogenin, atonal, ASCL and COE families. Experimental manipulation of Notch signalling in mice, Xenopus and zebrafish has shown that loss of Notch signalling causes cells to differentiate prematurely, depleting the progenitor pool (Appel et al., 2001; Wettstein et al., 1997). Thus, continued Notch signalling seems necessary to keep a progenitor pool over developmental time, and hence for spinal cords to develop their characteristic large number of cells. These progenitor cell populations may also be the source of adult neural stem cell populations (reviewed by (Grandel and Brand, 2013)). A long-standing question in evolutionary biology is explaining how the complex central nervous system (CNS) of vertebrates evolved. Many studies have approached this by asking how neural patterning is regulated in vertebrates and in their ...

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“…ARMS signature was composed of TFs which are not normally co-expressed in vertebrate embryos. For instance, during early/late somitogenesis in the caudal part of amniotes, LMO4 [49], MEOX1 [50], MYOD1 [51], PITX2 [52] label embryonic muscle cells, FOXF1 [53] is in the sclerotome and PAX2 [54], PRDM12 [55], TFAP2 mark neurons of the peripheral and/or central nervous system. This suggests that ARMS cells are not simply undifferentiated muscle cells, but rather as cells with their own transcriptional status.…”

Section: Paxfoxo1 Tfs Convert Chick Neural Cells Into Arms Like-cellsmentioning

confidence: 99%

The PAXFOXO1s trigger fast trans-differentiation of chick embryonic neural cells into alveolar rhabdomyosarcoma with tissue invasive properties limited by S phase entry inhibition

Curto

Vartanian

Frarma

et al. 2020

Preprint

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The chromosome translocations generating PAX3FOXO1 and PAX7FOXO1 chimeric proteins are the primary hallmarks of the paediatric cancer, Alveolar Rhabdomyosarcoma (ARMS).Despite the ability of these transcription factors to remodel chromatin landscapes and promote the expression of tumour driver genes, they only inefficiently promote malignant transformation in vivo. The reason for this is unclear. To address this, we developed an in ovo model to follow the response of spinal cord progenitors to PAXFOXO1s. Our data demonstrate that PAXFOXO1s, but not wild-type PAX3 and PAX7, trigger the trans-differentiation of neural cells into ARMS-like cells with myogenic characteristics. In parallel expression of PAXFOXO1s remodels the neural pseudo-stratified epithelium into a cohesive mesenchyme capable of tissue invasion. Surprisingly, gain for PAXFOXO1s, as for wild-type PAX3/7, reduces the levels of CDK-CYCLIN activity and arrests cells in G1. Introduction of CYCLIN D1 or MYCN overcomes PAXFOXO1s mediated cell cycle inhibition and promotes tumour growth. Together, our findings reveal a mechanism underpinning the apparent limited oncogenicity of PAXFOXO1 fusion transcription factors and support a neural origin for ARMS.We deeply thank the ImagoSeine core facility of Institut Jacques Monod, a member of France-BioImaging (ANR-10-INBS-04) and certified IBiSA. We thank Griselda Wentzinger and Magali Fradet for performing cell sorting at ImagoSeine Institut Jacques Monod platform. We are grateful to the people who have provided us with useful tools. We received plasmids from

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Prdm12 specifies V1 interneurons through cross-repressive interactions with Dbx1 and Nkx6 genes in Xenopus

Cited by 46 publications

References 53 publications

A single cell transcriptome atlas of the developing zebrafish hindbrain

A single cell transcriptome atlas of the developing zebrafish hindbrain

A Notch-regulated proliferative stem cell zone in the developing spinal cord is an ancestral vertebrate trait

The PAXFOXO1s trigger fast trans-differentiation of chick embryonic neural cells into alveolar rhabdomyosarcoma with tissue invasive properties limited by S phase entry inhibition

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