Ikaros promotes early-born neuronal fates in the cerebral cortex

Alsiö, Jessica; Tarchini, Basile; Cayouette, Michel; Livesey, Frederick J.

doi:10.1073/pnas.1215707110

Cited by 110 publications

(103 citation statements)

References 71 publications

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“…Thus Tbr1 is expressed ectopically in both Neurog2;Ascl1 and Neurog2-Tg animals, and, accordingly, Foxg1, which is required to repress Tbr1 (17), is down-regulated. Conversely, the expression of Ikaros, which promotes an early identity (18), is upregulated in both loss-and gain-of-function models.…”

Section: ;Ascl1mentioning

confidence: 99%

“…8E). Conversely, expression of Ikaros, the overexpression of which promotes an early deep-layer identity (18), was elevated 1.23-fold in E12.5 Neurog2…”

Section: Neurog2 and Ascl1 Regulate The Expression Of Known Temporal mentioning

confidence: 99%

“…The subsequent switch from deep-to upper-layer cell fates also involves the repression of Tbr1 by Foxg1 (17). In addition, Ikaros/Ikzf1, a homolog of the temporal regulator hunchback in Drosophila, confers an early identity when overexpressed in the cortex (18). Finally, loss of Ezh2, part of polycomb repressive complex 2 (PRC2), confers an early identity to cortical progenitors (19).…”

Section: Significancementioning

confidence: 99%

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Neurog2 and Ascl1 together regulate a postmitotic derepression circuit to govern laminar fate specification in the murine neocortex

Dennis

Wilkinson

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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A derepression mode of cell-fate specification involving the transcriptional repressors Tbr1, Fezf2, Satb2, and Ctip2 operates in neocortical projection neurons to specify six layer identities in sequence. Less well understood is how laminar fate transitions are regulated in cortical progenitors. The proneural genes Neurog2 and Ascl1 cooperate in progenitors to control the temporal switch from neurogenesis to gliogenesis. Here we asked whether these proneural genes also regulate laminar fate transitions. Several defects were observed in the derepression circuit in Neurog2−/− mutants: an inability to repress expression of Tbr1 (a deep layer VI marker) during upper-layer neurogenesis, a loss of Fezf2+ layer V neurons, and precocious differentiation of normally late-born, Satb2 + layer II-IV neurons. Conversely, in stable gain-of-function transgenics, Neurog2 promoted differentiative divisions and extended the period of Tbr1 deep-layer neurogenesis while reducing Satb2+ upper-layer neurogenesis. Similarly, acute misexpression of Neurog2 in early cortical progenitors promoted Tbr1 expression, whereas both Neurog2 and Ascl1 induced Ctip2. However, Neurog2 was unable to influence the derepression circuit when misexpressed in late cortical progenitors, and Ascl1 repressed only Satb2. Nevertheless, neurons derived from late misexpression of Neurog2 and, to a lesser extent, Ascl1, extended aberrant subcortical axon projections characteristic of early-born neurons. Finally, Neurog2 and Ascl1 altered the expression of Ikaros and Foxg1, known temporal regulators. Proneural genes thus act in a context-dependent fashion as early determinants, promoting deeplayer neurogenesis in early cortical progenitors via input into the derepression circuit while also influencing other temporal regulators.neocortex | laminar fate specification | derepression circuit | proneural genes | temporal identity N eocortical neurons project to nearby or distant targets, depending on their molecular identity and correlating with laminar position. Deep-layer corticofugal neurons project subcortically and include layer VI corticothalamic neurons, which target the thalamus, and layer V subcerebral neurons, which project to the spinal cord, basal ganglia, and other distant targets (1). Conversely, layer IV granular neurons are the major site of thalamic input, whereas layer II/III callosal neurons form corticocortical connections. A cross-repressive gene-regulatory network operates in postmitotic projection neurons to specify laminar fates and to repress competing laminar identities (Fig. 1A) (2). Tbr1, a T-box transcription factor expressed in layer VI, specifies a corticothalamic neuronal fate (3) and also represses the expression of Fezf2, a zinc finger transcription factor that specifies a layer V subcerebral identity (4, 5). Fezf2 represses Tbr1 expression and a corticothalamic fate in layer V neurons (6, 7) and also represses the expression of Satb2 (8), an AT-rich DNA-binding protein that specifies a layer II-IV callosal identity (9, 10). In laye...

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Section: ;Ascl1mentioning

confidence: 99%

“…8E). Conversely, expression of Ikaros, the overexpression of which promotes an early deep-layer identity (18), was elevated 1.23-fold in E12.5 Neurog2…”

Section: Neurog2 and Ascl1 Regulate The Expression Of Known Temporal mentioning

confidence: 99%

Section: Significancementioning

confidence: 99%

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Neurog2 and Ascl1 together regulate a postmitotic derepression circuit to govern laminar fate specification in the murine neocortex

Dennis

Wilkinson

et al. 2017

Proc. Natl. Acad. Sci. U.S.A.

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“…IKAROS is expressed in neuro-epithelial progenitors of the developing striatum, cortical and retinal progenitors, and the developing pituitary (Georgopoulos et al 1992;Ezzat et al 2006;Agoston et al 2007;MartinIbanez et al 2010;Alsio et al 2013). In addition to neuroepithelial cells, HELIOS is also expressed in epidermal keratinocytes (Kelley et al 1998).…”

Section: Expression and Immune Cell Phenotypesmentioning

confidence: 99%

“…HUNCHBACK maintains competence of neural progenitor cells and contributes to specification of early born neuronal cell fates (Isshiki et al 2001;Novotny et al 2002), much as IKAROS acts at multiple stages of immune cell development. IKAROS also regulates progenitor competence and early born cell fates in the mammalian nervous system (Elliott et al 2008;Tran et al 2010;Alsio et al 2013). Like IKAROS, HUNCHBACK uses the N-terminal zinc fingers to bind DNA and its C-terminal zinc fingers to dimerize (McCarty et al 2003).…”

Section: Structure and Function Of The Ikaros Gene Familymentioning

confidence: 99%

The making of a lymphocyte: the choice among disparate cell fates and the IKAROS enigma

Georgopoulos

2017

Genes Dev.

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Lymphocyte differentiation is set to produce myriad immune effector cells with the ability to respond to multitudinous foreign substances. The uniqueness of this developmental system lies in not only the great diversity of cellular functions that it can generate but also the ability of its differentiation intermediates and mature effector cells to expand upon demand, thereby providing lifelong immunity. Surprisingly, the goals of this developmental system are met by a relatively small group of DNA-binding transcription factors that work in concert to control the timing and magnitude of gene expression and fulfill the demands for cellular specialization, expansion, and maintenance. The cellular and molecular mechanisms through which these lineage-promoting transcription factors operate have been a focus of basic research in immunology. The mechanisms of development discerned in this effort are guiding clinical research on disorders with an immune cell base. Here, I focus on IKAROS, one of the earliest regulators of lymphoid lineage identity and a guardian of lymphocyte homeostasis.

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Retinal Ganglion Cell Replacement: Current Status and Challenges Ahead

Miltner

Torre

2018

Developmental Dynamics

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The neurons of the retina can be affected by a wide variety of inherited or environmental degenerations that can lead to vision loss and even blindness. Retinal ganglion cell (RGC) degeneration is the hallmark of glaucoma and other optic neuropathies that affect millions of people worldwide. Numerous strategies are being trialed to replace lost neurons in different degeneration models, and in recent years, stem cell technologies have opened promising avenues to obtain donor cells for retinal repair. Stem cell–based transplantation has been most frequently used for the replacement of rod photoreceptors, but the same tools could potentially be used for other retinal cell types, including RGCs. However, RGCs are not abundant in stem cell–derived cultures, and in contrast to the short‐distance wiring of photoreceptors, RGC axons take a long and intricate journey to connect with numerous brain nuclei. Hence, a number of challenges still remain, such as the ability to scale up the production of RGCs and a reliable and functional integration into the adult diseased retina upon transplantation. In this review, we discuss the recent advancements in the development of replacement therapies for RGC degenerations and the challenges that we need to overcome before these technologies can be applied to the clinic. Developmental Dynamics 248:118–128, 2019. © 2018 Wiley Periodicals, Inc.

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Ikaros promotes early-born neuronal fates in the cerebral cortex

Cited by 110 publications

References 71 publications

Neurog2 and Ascl1 together regulate a postmitotic derepression circuit to govern laminar fate specification in the murine neocortex

Neurog2 and Ascl1 together regulate a postmitotic derepression circuit to govern laminar fate specification in the murine neocortex

The making of a lymphocyte: the choice among disparate cell fates and the IKAROS enigma

Retinal Ganglion Cell Replacement: Current Status and Challenges Ahead

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