Postmitotic regulation of sensory area patterning in the mammalian neocortex by Lhx2

Zembrzycki, Andreas; Pérez-García, Carlos G.; Wang, Chia-Fang; Chou, Shen-Ju; O’Leary, Dennis D.M.

doi:10.1073/pnas.1424440112

Cited by 50 publications

(51 citation statements)

References 41 publications

(73 reference statements)

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“…6A). Finally, when area patterning was examined using Serotonin (5-HT) immunostaining on tangential sections of the flattened cortex, which reveals terminations of thalamocortical axons in cortical layer 4 of the corresponding primary sensory areas (Fujimiya et al, 1986; Zembrzycki et al, 2015a), we found no differences in overall cortical or area sizes and their patterning between wild type and Foxg1-IRES-Cre heterozygous mice (Fig. 6B).…”

Section: Resultsmentioning

confidence: 91%

Generation and analysis of an improved Foxg1-IRES-Cre driver mouse line

Kawaguchi

Sahara

Zembrzycki

et al. 2016

Developmental Biology

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Foxg1 expression is highly restricted to the telencephalon and other head structures in the early embryo. This expression pattern has been exploited to generate conditional knockout mice, based on a widely used Foxg1-Cre knock-in line (Foxg1tm1(cre)Skm), in which the Foxg1 coding region was replaced by the Cre gene. The utility of this line, however, is severely hampered for two reasons: (1) Foxg1-Cre mice display ectopic and unpredictable Cre activity, and (2) Foxg1 haploinsufficiency can produce neurodevelopmental phenotypes. To overcome these issues, we have generated a new Foxg1-IRES-Cre knock-in mouse line, in which an IRES-Cre cassette was inserted in the 3′UTR of Foxg1 locus, thus preserving the endogenous Foxg1 coding region and un-translated gene regulatory sequences in the 3′UTR, including recently discovered microRNA targeting sites. We further demonstrate that the new Foxg1-IRES-Cre line displays consistent Cre activity patterns that recapitulated the endogenous Foxg1 expression at embryonic and postnatal stages without causing defects in cortical development. We conclude that the new Foxg1-IRES-Cre mouse line is a unique and advanced tool for studying genes involved in the development of the telencephalon and other Foxg1-expressing regions starting from early embryonic stages.

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Section: Resultsmentioning

confidence: 91%

Generation and analysis of an improved Foxg1-IRES-Cre driver mouse line

Kawaguchi

Sahara

Zembrzycki

et al. 2016

Developmental Biology

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“…A recent study combining serial analysis of gene expression and transcription factor binding site prediction identified 64 novel candidate target genes of NR2E1 involved in neocortical development (Schmouth et al, 2015). These include LHX2, which is involved in "post-mitotic regulation of sensory area patterning in the mammalian neocortex" (Zembrzycki, Perez-Garcia, Wang, Chou, & O'Leary, 2015) and its cofactor SOX9. It is also known that coordination and cooperation between NR2E1 and PAX6 is required for brain patterning during development (Stenman, Yu, Evans, & Campbell, 2003).…”

Section: Discussionmentioning

confidence: 99%

Aberrant transcriptomes and DNA methylomes define pathways that drive pathogenesis and loss of brain laterality/asymmetry in schizophrenia and bipolar disorder

Abdolmaleky

Gower

Wong

et al. 2018

American J of Med Genetics Pt B

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Although the loss of brain laterality is one of the most consistent modalities in schizophrenia (SCZ) and bipolar disorder (BD), its molecular basis remains elusive. Our limited previous studies indicated that epigenetic modifications are key to the asymmetric transcriptomes of brain hemispheres. We used whole-genome expression microarrays to profile postmortem brain samples from subjects with SCZ, psychotic BD [BD[+]] or non-psychotic BD [BD(−)], or matched controls (10/group) and performed whole-genome DNA methylation (DNAM) profiling of the same samples (3-4/group) to identify pathways associated with SCZ or BD[+] and genes/sites susceptible to epigenetic regulation. qRT-PCR and quantitative DNAM analysis were employed to validate findings in larger sample sets (35/group). Gene Set Enrichment Analysis (GSEA) demonstrated that BMP signaling and astrocyte and cerebral cortex development are significantly (FDR q < 0.25) coordinately upregulated in both SCZ and BD[+], and glutamate signaling and TGFβ signaling are significantly coordinately upregulated in SCZ. GSEA also indicated that collagens are downregulated in right versus left brain of controls, but not in SCZ or BD[+] patients. IngenuityPathway Analysis predicted that TGFB2 is an upstream regulator of these genes (p = .0012).While lateralized expression of TGFB2 in controls (p = .017) is associated with a corresponding change in DNAM (p ≤ .023), lateralized expression and DNAM of TGFB2 are absent in SCZ or BD. Loss of brain laterality in SCZ and BD corresponds to aberrant epigenetic regulation of TGFB2 and changes in TGFβ signaling, indicating potential avenues for disease prevention/ treatment. K E Y W O R D Sbrain asymmetry, DNA methylation, NR2E1, schizophrenia, TGFB2

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“…Therefore, an obvious question is whether the effects of LHX2 removal are relevant in the ventricular zone progenitors themselves, or in the newly postmitotic neurons they produce. A recent study that used NexCre to delete LHX2 specifically in postmitotic neurons starting from E11 offers clarity on this issue (Zembrzycki et al, 2015). This study elegantly demonstrated that NexCre action is not seen in proliferating progenitors in the ventricular zone but is seen in newly postmitotic cells (Zembrzycki et al, 2015, their Figure S2) and that molecular specification of the different cortical layers is not affected (Zembrzycki et al, 2015, their Fig.…”

Section: Discussionmentioning

confidence: 99%

LHX2 Interacts with the NuRD Complex and Regulates Cortical Neuron Subtype DeterminantsFezf2andSox11

et al. 2016

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In the developing cerebral cortex, sequential transcriptional programs take neuroepithelial cells from proliferating progenitors to differentiated neurons with unique molecular identities. The regulatory changes that occur in the chromatin of the progenitors are not well understood. During deep layer neurogenesis, we show that transcription factor LHX2 binds to distal regulatory elements of Fezf2 and Sox11, critical determinants of neuron subtype identity in the mouse neocortex. We demonstrate that LHX2 binds to the nucleosome remodeling and histone deacetylase histone remodeling complex subunits LSD1, HDAC2, and RBBP4, which are proximal regulators of the epigenetic state of chromatin. When LHX2 is absent, active histone marks at the Fezf2 and Sox11 loci are increased. Loss of LHX2 produces an increase, and overexpression of LHX2 causes a decrease, in layer 5 Fezf2 and CTIP2-expressing neurons. Our results provide mechanistic insight into how LHX2 acts as a necessary and sufficient regulator of genes that control cortical neuronal subtype identity.SIGNIFICANCE STATEMENT The functional complexity of the cerebral cortex arises from an array of distinct neuronal subtypes with unique connectivity patterns that are produced from common progenitors. This study reveals that transcription factor LHX2 regulates the numbers of specific cortical output neuron subtypes by controlling the genes that are required to produce them. Loss or increase in LHX2 during neurogenesis is sufficient to increase or decrease, respectively, a particular subcerebrally projecting population. Mechanistically, LHX2 interacts with chromatin modifying protein complexes to edit the chromatin landscape of its targets Fezf2 and Sox11, which regulates their expression and consequently the identities of the neurons produced. Thus, LHX2 is a key component of the control network for producing neurons that will participate in cortical circuitry.

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Postmitotic regulation of sensory area patterning in the mammalian neocortex by Lhx2

Cited by 50 publications

References 41 publications

Generation and analysis of an improved Foxg1-IRES-Cre driver mouse line

Generation and analysis of an improved Foxg1-IRES-Cre driver mouse line

Aberrant transcriptomes and DNA methylomes define pathways that drive pathogenesis and loss of brain laterality/asymmetry in schizophrenia and bipolar disorder

LHX2 Interacts with the NuRD Complex and Regulates Cortical Neuron Subtype DeterminantsFezf2andSox11

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