Characterization of the Dlx Enhancers in the Developing Mouse

Esau, Crystal

25 November 2013

The Distal-less homeobox (Dlx) genes encode homeodomain transcription factors found in all animals of the phylum Chordata. These genes are involved in early vertebrate development of limbs, sensory organs, branchial arches and the forebrain (telencephalon and diencephalon). The mouse and human genomes each have six Dlx genes organized into convergently transcribed bigene clusters (Dlx1/2, Dlx3/4 and Dlx5/6). In the forebrain, Dlx1/2 and Dlx5/6 genes play essential roles in GABAergic neuron proliferation, migration and survival. Each bigene cluster includes a short intergenic region (~3.5-16kb) harboring cis-regulatory elements (CREs) that control expression of the Dlx genes. The Dlx1/2 intergenic region harbors the I12b/I12a CREs, while Dlx5/6 includes I56i/I56ii. In determining the regulatory roles of the CREs on Dlx activity and forebrain development, I have characterized the phenotypic changes that occur in mice that have an I56i enhancer deletion. I have also characterized mice with double deletions of I56i and I12b as well as mice that harbored an I12b deletion and have a SNP in the I56i enhancer (vI56i). Mutant mice with a single targeted deletion of I56i are viable, fertile and do not show obvious developmental defects. These mice have significant decreases in Dlx5/6, Gad1/Gad2 and Evf-2 expression in the forebrain and have defects related to GABAergic neuron development. The ΔI56i mutants demonstrate a behavioral phenotype related to anxiety and learning deficits. Mice that lack the I12b enhancer and have the vI56i do not show morphological abnormalities but have severely disrupted Dlx expression. When mice are homozygous for the I56i and I12b enhancer deletion, they do not survive past post natal day 5 and exhibit a dwarfed body size. These mice look weak and seem to have limited motor ability. In characterizing mice with targeted deletions of highly conserved Dlx enhancers, we will have a better understanding of forebrain development.

Development

Dlx genes

GABAergic neurons

Forebrain

Characterization of the Dlx Enhancers in the Developing Mouse

Esau, Crystal

January 2013

The Distal-less homeobox (Dlx) genes encode homeodomain transcription factors found in all animals of the phylum Chordata. These genes are involved in early vertebrate development of limbs, sensory organs, branchial arches and the forebrain (telencephalon and diencephalon). The mouse and human genomes each have six Dlx genes organized into convergently transcribed bigene clusters (Dlx1/2, Dlx3/4 and Dlx5/6). In the forebrain, Dlx1/2 and Dlx5/6 genes play essential roles in GABAergic neuron proliferation, migration and survival. Each bigene cluster includes a short intergenic region (~3.5-16kb) harboring cis-regulatory elements (CREs) that control expression of the Dlx genes. The Dlx1/2 intergenic region harbors the I12b/I12a CREs, while Dlx5/6 includes I56i/I56ii. In determining the regulatory roles of the CREs on Dlx activity and forebrain development, I have characterized the phenotypic changes that occur in mice that have an I56i enhancer deletion. I have also characterized mice with double deletions of I56i and I12b as well as mice that harbored an I12b deletion and have a SNP in the I56i enhancer (vI56i). Mutant mice with a single targeted deletion of I56i are viable, fertile and do not show obvious developmental defects. These mice have significant decreases in Dlx5/6, Gad1/Gad2 and Evf-2 expression in the forebrain and have defects related to GABAergic neuron development. The ΔI56i mutants demonstrate a behavioral phenotype related to anxiety and learning deficits. Mice that lack the I12b enhancer and have the vI56i do not show morphological abnormalities but have severely disrupted Dlx expression. When mice are homozygous for the I56i and I12b enhancer deletion, they do not survive past post natal day 5 and exhibit a dwarfed body size. These mice look weak and seem to have limited motor ability. In characterizing mice with targeted deletions of highly conserved Dlx enhancers, we will have a better understanding of forebrain development.

Development

Dlx genes

GABAergic neurons

Forebrain

Origine embryonnaire et propriétés morpho-physiologiques des neurones hubs de l'hippocampe en développement / Embryonic origin and morpho physiological properties of hub neurons in the developing hippocampus

Picardo, Michel

19 October 2012

Nous avons récemment mis en évidence des neurones GABAergiques jouant un rôle de « hub » dans l'hippocampe immature, orchestrant la synchronisation neuronale via une arborisation axonale dense. Dans ma thèse, j'ai d'abord montré, grâce à des enregistrements électrophysiologiques par paires, que les hubs étaient connectés à de nombreux neurones par des synapses GABAergiques fonctionnelles (Bonifazi et al. 2009). Puis, en utilisant des souris mutantes conditionnelles où les neurones sont marqués en fonction de leur origine embryonnaire, j'ai démontré que les neurones GABAergiques générés le plus tôt formaient une famille de hubs. Ces neurones sont toujours présents chez l'adulte et deviennent des neurones GABAergiques de projection extrahippocampique. Ceci suggère que la fonction de ces neurones serait maintenue, du moins anatomiquement, au stade adulte. / We have recently demonstrated the existence of functional hubs driving network synchronizations in the developing hippocampus. Hubs are a subpopulation of GABAergic neurons displaying widespread axonal projections. During my PhD, using paired electrophysiological recordings, I have shown that hub cells are synaptically connected to a large number of neurons (Bonifazi et al. 2009). Next, using genetic fate mapping approaches, I have demonstrated that early born GABAergic neurons constitute a subpopulation of hub cells. These pioneer hub cells remain into adulthood and develop into GABAergic neurons with an extrahippocampal projection (Picardo et al. 2011). This suggests that hub function may to retained into adulthood, at least structurally.

Neurone GABAergiques

Activité neuronales coordonnées

Gdp

Hippocampe

Développement

Réseaux

Hubs

Gabaergic neurons

GDPs

Network

Hubs

Development

Functional Analysis of the Cis-Regulatory Elements I56i, I56ii and I12b that Control Dlx Gene Expression in the Developing Forebrain of Mouse and Zebrafish

Yu, Man

22 August 2011

The vertebrate Dlx gene family consists of multiple convergently transcribed bigene clusters and encodes a group of homeodomain-containing transcription factors crucial for the development of forebrain, branchial arches, sensory organs and limbs. At least four cis-regulatory elements (CREs) are responsible for Dlx expression in the forebrain: URE2 and I12b in the Dlx1/Dlx2 (zebrafish dlx1a/dlx2a) locus, and, I56i and I56ii in the Dlx5/Dlx6 (zebrafish dlx5a/dlx6a) locus. Here, we first show that unlike the other three enhancers, mouse I56ii CRE targets a group of GABAergic projection neurons expressing striatal markers Meis2 and Islet1. Meis2 and Islet1 proteins can activate reporter gene transcription via the I56ii CRE, suggesting that they may be potential upstream regulators of Dlx genes in vivo. To determine whether there exists a dlx-mediated regulatory pathway during zebrafish GABAergic neuron formation, we establish two independent lines of transgenic fish in which the GFP reporter gene is controlled by a 1.4kb dlx5a/dlx6a intergenic sequence (encompassing zebrafish I56i and I56ii) and a 1.1kb fragment containing only I56i CRE, respectively. Our observations reveal that dlx5a/dlx6a regulatory elements exhibit a fairly specific activity in the zebrafish forebrain and may be essential for GABAergic neuron generation, while I56i and I56ii are likely to play distinct roles in modulating this process in different subpopulations of cells. Disruption of dlx1a/dlx2a or dlx5a/dlx6a function leads to a marked decrease of enhancer activity in the diencephalon and midbrain as well as a comparatively lesser extent of reduction in the telencephalon. In order to define the specific contribution of various individual CREs to overall Dlx regulation, we also generate a mutant mouse model in which I12b CRE is selectively deleted. Despite that mice homozygous for I12b loss develop normally and harbor no overt morphological defects in the forebrain, targeted deletion of this enhancer results in a significant reduction of Dlx1/Dlx2 transcript levels and seemingly perturbs cell proliferation in the subpallial telencephalon, particularly in the ventricular and subventricular zones of ganglionic eminences. Taken together, these data illustrate a complex and dynamic Dlx regulation in the early developing forebrain through the implications of multiple Dlx CREs with overlapping and diverse functions.

Dlx genes

enhancers

GABAergic neurons

mice

zebrafish

forebrain

gene regulation

transgenesis

Functional Analysis of the Cis-Regulatory Elements I56i, I56ii and I12b that Control Dlx Gene Expression in the Developing Forebrain of Mouse and Zebrafish

Yu, Man

22 August 2011

The vertebrate Dlx gene family consists of multiple convergently transcribed bigene clusters and encodes a group of homeodomain-containing transcription factors crucial for the development of forebrain, branchial arches, sensory organs and limbs. At least four cis-regulatory elements (CREs) are responsible for Dlx expression in the forebrain: URE2 and I12b in the Dlx1/Dlx2 (zebrafish dlx1a/dlx2a) locus, and, I56i and I56ii in the Dlx5/Dlx6 (zebrafish dlx5a/dlx6a) locus. Here, we first show that unlike the other three enhancers, mouse I56ii CRE targets a group of GABAergic projection neurons expressing striatal markers Meis2 and Islet1. Meis2 and Islet1 proteins can activate reporter gene transcription via the I56ii CRE, suggesting that they may be potential upstream regulators of Dlx genes in vivo. To determine whether there exists a dlx-mediated regulatory pathway during zebrafish GABAergic neuron formation, we establish two independent lines of transgenic fish in which the GFP reporter gene is controlled by a 1.4kb dlx5a/dlx6a intergenic sequence (encompassing zebrafish I56i and I56ii) and a 1.1kb fragment containing only I56i CRE, respectively. Our observations reveal that dlx5a/dlx6a regulatory elements exhibit a fairly specific activity in the zebrafish forebrain and may be essential for GABAergic neuron generation, while I56i and I56ii are likely to play distinct roles in modulating this process in different subpopulations of cells. Disruption of dlx1a/dlx2a or dlx5a/dlx6a function leads to a marked decrease of enhancer activity in the diencephalon and midbrain as well as a comparatively lesser extent of reduction in the telencephalon. In order to define the specific contribution of various individual CREs to overall Dlx regulation, we also generate a mutant mouse model in which I12b CRE is selectively deleted. Despite that mice homozygous for I12b loss develop normally and harbor no overt morphological defects in the forebrain, targeted deletion of this enhancer results in a significant reduction of Dlx1/Dlx2 transcript levels and seemingly perturbs cell proliferation in the subpallial telencephalon, particularly in the ventricular and subventricular zones of ganglionic eminences. Taken together, these data illustrate a complex and dynamic Dlx regulation in the early developing forebrain through the implications of multiple Dlx CREs with overlapping and diverse functions.

Dlx genes

enhancers

GABAergic neurons

mice

zebrafish

forebrain

gene regulation

transgenesis

Recurrent inhibitory network among cholinergic inerneurons of the striatum

Sullivan, Matthew Alexander

08 November 2012

The striatum is the initial input nuclei of the basal ganglia, and it serves as an integral processing center for action selection and sensorimotor learning. Glutamatergic projections from the cortex and thalamus converge with dense dopaminergic axons from the midbrain to provide the primary inputs to the striatum. Striatal output is then relayed to downstream basal ganglia nuclei by GABAergic medium – sized spiny neurons, which comprise at least 95% of the population of neurons in the striatum. The remaining population of local circuit neurons is dedicated to regulating the activity of spiny projection neurons, and although spiny neurons form a weak lateral inhibitory network among themselves via local axon collaterals, feedforward modulation exerts more powerful control over spiny neuron excitability. Of the striatal interneurons, only one class is not GABAergic. These neurons are cholinergic and correspond to the tonically active neurons (TANs) recorded in vivo, which respond to specific environmental stimuli with a transient depression, or pause, of tonic firing. Striatal cholinergic interneurons account for less than 2 % of the striatal neuronal population, yet their axons form an extensive and complex network that permeates the entire striatum and significantly shapes striatal output by acting at numerous targets via varied receptor types. Indeed, the persistent level of ambient striatal acetylcholine as well as changes to that basal acetylcholine level underlie the major mechanisms of cholinergic signaling in the striatum, however regulation of this system by the local striatal microcircuitry is not well understood. This dissertation finds that activation of intrastriatal cholinergic fibers elicits polysynaptic GABAA inhibitory postsynaptic currents (IPSCs) in cholinergic interneurons recorded in brain slices. Excitation of striatal GABAergic neurons via nicotinic acetylcholine receptors (nAChRs) mediates this polysynaptic inhibition in a manner independent of dopamine. Moreover, activation of a single cholinergic interneuron is capable of eliciting polysynaptic GABAA IPSCs onto itself and nearby cholinergic interneurons. These findings provide an important insight into the striatal microcircuitry controlling cholinergic neuron excitability. / text

Intrastriatal cholinergic fibers

Inhibitory postsynaptic currents

Cholinergic interneurons

Striatal GABAergic neurons

Nicotinic acetylcholine receptors

Polysynaptic inhibition

Functional Analysis of the Cis-Regulatory Elements I56i, I56ii and I12b that Control Dlx Gene Expression in the Developing Forebrain of Mouse and Zebrafish

Yu, Man

22 August 2011

The vertebrate Dlx gene family consists of multiple convergently transcribed bigene clusters and encodes a group of homeodomain-containing transcription factors crucial for the development of forebrain, branchial arches, sensory organs and limbs. At least four cis-regulatory elements (CREs) are responsible for Dlx expression in the forebrain: URE2 and I12b in the Dlx1/Dlx2 (zebrafish dlx1a/dlx2a) locus, and, I56i and I56ii in the Dlx5/Dlx6 (zebrafish dlx5a/dlx6a) locus. Here, we first show that unlike the other three enhancers, mouse I56ii CRE targets a group of GABAergic projection neurons expressing striatal markers Meis2 and Islet1. Meis2 and Islet1 proteins can activate reporter gene transcription via the I56ii CRE, suggesting that they may be potential upstream regulators of Dlx genes in vivo. To determine whether there exists a dlx-mediated regulatory pathway during zebrafish GABAergic neuron formation, we establish two independent lines of transgenic fish in which the GFP reporter gene is controlled by a 1.4kb dlx5a/dlx6a intergenic sequence (encompassing zebrafish I56i and I56ii) and a 1.1kb fragment containing only I56i CRE, respectively. Our observations reveal that dlx5a/dlx6a regulatory elements exhibit a fairly specific activity in the zebrafish forebrain and may be essential for GABAergic neuron generation, while I56i and I56ii are likely to play distinct roles in modulating this process in different subpopulations of cells. Disruption of dlx1a/dlx2a or dlx5a/dlx6a function leads to a marked decrease of enhancer activity in the diencephalon and midbrain as well as a comparatively lesser extent of reduction in the telencephalon. In order to define the specific contribution of various individual CREs to overall Dlx regulation, we also generate a mutant mouse model in which I12b CRE is selectively deleted. Despite that mice homozygous for I12b loss develop normally and harbor no overt morphological defects in the forebrain, targeted deletion of this enhancer results in a significant reduction of Dlx1/Dlx2 transcript levels and seemingly perturbs cell proliferation in the subpallial telencephalon, particularly in the ventricular and subventricular zones of ganglionic eminences. Taken together, these data illustrate a complex and dynamic Dlx regulation in the early developing forebrain through the implications of multiple Dlx CREs with overlapping and diverse functions.

Dlx genes

enhancers

GABAergic neurons

mice

zebrafish

forebrain

gene regulation

transgenesis

Functional Analysis of the Cis-Regulatory Elements I56i, I56ii and I12b that Control Dlx Gene Expression in the Developing Forebrain of Mouse and Zebrafish

Yu, Man

January 2011

The vertebrate Dlx gene family consists of multiple convergently transcribed bigene clusters and encodes a group of homeodomain-containing transcription factors crucial for the development of forebrain, branchial arches, sensory organs and limbs. At least four cis-regulatory elements (CREs) are responsible for Dlx expression in the forebrain: URE2 and I12b in the Dlx1/Dlx2 (zebrafish dlx1a/dlx2a) locus, and, I56i and I56ii in the Dlx5/Dlx6 (zebrafish dlx5a/dlx6a) locus. Here, we first show that unlike the other three enhancers, mouse I56ii CRE targets a group of GABAergic projection neurons expressing striatal markers Meis2 and Islet1. Meis2 and Islet1 proteins can activate reporter gene transcription via the I56ii CRE, suggesting that they may be potential upstream regulators of Dlx genes in vivo. To determine whether there exists a dlx-mediated regulatory pathway during zebrafish GABAergic neuron formation, we establish two independent lines of transgenic fish in which the GFP reporter gene is controlled by a 1.4kb dlx5a/dlx6a intergenic sequence (encompassing zebrafish I56i and I56ii) and a 1.1kb fragment containing only I56i CRE, respectively. Our observations reveal that dlx5a/dlx6a regulatory elements exhibit a fairly specific activity in the zebrafish forebrain and may be essential for GABAergic neuron generation, while I56i and I56ii are likely to play distinct roles in modulating this process in different subpopulations of cells. Disruption of dlx1a/dlx2a or dlx5a/dlx6a function leads to a marked decrease of enhancer activity in the diencephalon and midbrain as well as a comparatively lesser extent of reduction in the telencephalon. In order to define the specific contribution of various individual CREs to overall Dlx regulation, we also generate a mutant mouse model in which I12b CRE is selectively deleted. Despite that mice homozygous for I12b loss develop normally and harbor no overt morphological defects in the forebrain, targeted deletion of this enhancer results in a significant reduction of Dlx1/Dlx2 transcript levels and seemingly perturbs cell proliferation in the subpallial telencephalon, particularly in the ventricular and subventricular zones of ganglionic eminences. Taken together, these data illustrate a complex and dynamic Dlx regulation in the early developing forebrain through the implications of multiple Dlx CREs with overlapping and diverse functions.

Dlx genes

enhancers

GABAergic neurons

mice

zebrafish

forebrain

gene regulation

transgenesis

Immunocytochemical techniques identify Na⁺-coupled HCO₃^– transporters (NCBTs) in chemosensitive neurons of the medullary raphé

Coley, Austin A.

January 2011

No description available.

Biophysics

Neurosciences

Physiology

nNCBTs

NBCn1

NBCn2

NDCBE

Serotonergic neurons

GABAergic neurons

pHi

Immunocytochemistry

Image processing

Antidepressant response and stress resilience are promoted by CART peptides in GABAergic neurons of the anterior cingulate cortex / 抗うつ薬への反応とストレスレジリエンスは前帯状皮質のGABA作動性ニューロンでのCARTペプチドによって促される

Funayama, Yuki

23 May 2022

京都大学 / 新制・課程博士 / 博士(医学) / 甲第24088号 / 医博第4864号 / 新制||医||1059(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 林 康紀, 教授 渡邉 大, 教授 髙橋 良輔 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Antidepressant response

Stress resilience

Depression

Transcriptome

Anterior cingulate cortex

GABAergic neurons

490