Within the basal ganglia circuit, the external globus pallidus (GPe) is critically involved in motor control. Aside from Foxp2+ neurons and ChAT+ neurons that have been established as unique neuron types, there is little consensus on the classification of GPe neurons. Properties of the remaining neuron types are poorly-defined. In this study, we leverage new mouse lines, viral tools, and molecular markers to better define GPe neuron subtypes. We found that Sox6 represents a novel, defining marker for GPe neuron subtypes. Lhx6+ neurons that lack the expression of Sox6 were devoid of both parvalbumin and Npas1. This result confirms previous assertions of the existence of a unique Lhx6+ population. Neurons that arise from the Dbx1+ lineage were similarly abundant in the GPe and displayed a heterogeneous makeup. Importantly, tracing experiments revealed that Npas1+-Nkx2.1+ neurons represent the principal non-cholinergic, cortically-projecting neurons. In other words, they form the pallido-cortical arm of the cortico-pallido-cortical loop. Our data further described that pyramidal-tract neurons in the cortex collateralized within the GPe, forming a closed-loop system between the two brain structures. Overall, our findings reconcile some of the discrepancies that arose from differences in techniques or the reliance on pre-existing tools. While spatial distribution and electrophysiological properties of GPe neurons reaffirm the diversification of GPe subtypes, statistical analyses strongly support the notion that these neuron subtypes can be categorized under the two principal neuron classes—i.e., PV+ neurons and Npas1+ neurons.Significance statementThe poor understanding of the neuronal composition in the GPe undermines our ability to interrogate its precise behavioral and disease involvements. In this study, twelve different genetic crosses were used, hundreds of neurons were electrophysiologically-characterized, and over 100,000 neurons were histologically- and/or anatomically-profiled. Our current study further establishes the segregation of GPe neuron classes and illustrates the complexity of GPe neurons in adult mice. Our results support the idea that Npas1+-Nkx2.1+ neurons are a distinct GPe neuron subclass. By providing a detailed analysis of the organization of the cortico-pallidal-cortical projection, our findings establish the cellular and circuit substrates that can be important for motor function and dysfunction.
Highlights d The hypothalamic clock network aligns hunger and metabolism with sleep and wakefulness d The AgRP neuron clock remodels transcription in response to energy state d AgRP RiboTag profiling uncovers post-transcriptional control of bioenergetics d The transcriptional response to leptin requires an intact molecular clock
Within the basal ganglia circuit, the external globus pallidus (GPe) is critically involved in motor control. Aside from Foxp2 ϩ neurons and ChAT ϩ neurons that have been established as unique neuron types, there is little consensus on the classification of GPe neurons. Properties of theremainingneurontypesarepoorlydefined.Inthisstudy,weleveragenewmouselines,viraltools,andmolecularmarkerstobetterdefineGPe neuron subtypes. We found that Sox6 represents a novel, defining marker for GPe neuron subtypes. Lhx6 ϩ neurons that lack the expression of Sox6 were devoid of both parvalbumin and Npas1. This result confirms previous assertions of the existence of a unique Lhx6 ϩ population. Neurons that arise from the Dbx1 ϩ lineage were similarly abundant in the GPe and displayed a heterogeneous makeup. Importantly, tracing experiments revealed that Npas1 ϩ-Nkx2.1 ϩ neurons represent the principal noncholinergic, cortically-projecting neurons. In other words, they form the pallido-cortical arm of the cortico-pallido-cortical loop. Our data further show that pyramidal-tract neurons in the cortex collateralized within the GPe, forming a closed-loop system between the two brain structures. Overall, our findings reconcile some of the discrepancies that arose from differences in techniques or the reliance on preexisting tools. Although spatial distribution and electrophysiological properties of GPe neurons reaffirm the diversification of GPe subtypes, statistical analyses strongly support the notion that these neuron subtypes can be categorized under the two principal neuron classes: PV ϩ neurons and Npas1 ϩ neurons.
We have investigated the patterns of postnatal brain expression and DNA binding of Gtx, a homeodomain transcription factor. Gtx mRNA accumulates in parallel with the RNAs encoding the major structural proteins of myelin, myelin basic protein (MBP), and proteolipid protein (PLP) during postnatal brain development; Gtx mRNA decreases in parallel with MBP and PLP mRNAs in the brains of myelin-deficient rats, which have a point mutation in the PLP gene. Gtx mRNA is expressed in differentiated, postmitotic oligodendrocytes but is not found in oligodendrocyte precursors or astrocytes. These data thus demonstrate that Gtx is expressed uniquely in differentiated oligodendrocytes in postnatal rodent brain and that its expression is regulated in parallel with the major myelin protein mRNAs, encoding MBP and PLP, under a variety of physiologically relevant circumstances.Using a Gtx fusion protein produced in bacteria, we have confirmed that Gtx is a sequence-specific DNA-binding protein, which binds DNA sequences containing a core AT-rich homeodomain binding site. Immunoprecipitation of labeled DNA fragments encoding either the MBP or PLP promoter regions with this fusion protein has identified several Gtx-binding fragments, and we have confirmed these data using an electrophoretic mobility shift assay. In this way we have identified four Gtx binding sites within the first 750 bp of the MBP promoter and four Gtx binding sites within the first 1.3 kb of the PLP promoter. In addition, inspection of the PLP promoter sequence demonstrates the presence of six additional Gtx binding sites. These data, taken together, strongly suggest that Gtx is important for the function of differentiated oligodendrocytes and may be involved in the regulation of myelin-specific gene expression.
Previous studies, both in vitro and in vivo, suggest that small portions of the mouse myelin basic protein (MBP) promoter are sufficient to activate regulated expression of MBP. To confirm our previous in vitro studies, we prepared transgenic mice with short regions of the human MBP promoter fused to the lacZ reporter gene. We found that 750 nucleotides of the proximal human MBP promoter is sufficient to activate oligodendrocyte‐specific, developmentally regulated expression of lacZ in three independent lines. This promoter, however, does not activate expression of lacZ in Schwann cells in peripheral nerve or in adult mouse brain. The relative levels of β‐galactosidase specific activity, mRNA, and transcription parallel those of MBP mRNA during myelinogenesis. Thus, we exploited this transgene as a quantitative tool to evaluate the response to stimuli known to affect myelination. Transgene expression is reduced 75% after optic enucleation, as previously reported for levels of MBP mRNA, indicating that axons signal to this portion of the proximal MBP promoter to fully activate MBP expression during myelinogenesis. Instead, in adult shiverer mice, another setting in which MBP transcription is modulated, transgene expression is not increased, in contrast to the increased transcriptional activation of MBP previously reported in these mice. These data suggest that the regulatory region that mediates transcriptional activation of the MBP gene is modular, since discrete subregions are required for activation in Schwann cells, during myelinogenesis in oligodendrocytes, during maintenance myelination in adult brain, and in the dysmyelinating mutant shiverer mouse. © 1998 John Wiley & Sons, Inc. J Neurobiol 34: 10–26, 1998
In Parkinson's disease, the most vulnerable neurons are found in the ventral tier of the substantia nigra (SN), while the adjacent dopamine (DA) neurons of the ventral tegmental area (VTA) are mostly spared. Although a significant subset of adult VTA DA neurons expresses Vglut2, a vesicular glutamate transporter, and release glutamate as a second neurotransmitter in the striatum, only very few adult SN DA neurons have this capacity. Previous work has demonstrated that lesions created by neurotoxins such as MPTP and 6-hydroxydopamine (6-OHDA) can upregulate the expression of Vglut2 in surviving DA neurons.Currently, the molecular mechanisms explaining the plasticity of Vglut2 expression in DA neurons are unknown, as are the physiological consequences for DA neuron function and survival. Here we aimed to characterize the developmental expression pattern of Vglut2 in DA neurons and the role of this transporter in post-lesional plasticity in these neurons. Using an intersectional genetic lineage-mapping approach, based on Vglut2-Cre and TH-Flpo drivers, we first found that more than 98% of DA neurons expressed Vglut2 at some point in their embryonic development. Expression of this transporter was detectable in most DA neurons until E11.5 and was found to be localized in developing axons. Moderate enhancement of VGLUT2 expression in primary DA neurons caused an increase in axonal arborization length. Compatible with a developmental role, constitutive deletion of Vglut2 caused a regional defect in TH-innervation of the dorsal striatum in E18.5 embryos. Moreover, using an in vitro neurotoxin model, we demonstrate that Vglut2 expression can be upregulated in post-lesional DA neurons by 2.5-fold, arguing that the developmental expression of Vglut2 in DA neurons can be reactivated at postnatal stages and contribute to post-lesional plasticity of dopaminergic axons. In support of this hypothesis, we find fewer mesostriatial dopaminergic projections in the striatum of conditional Vglut2 KO mice 7 weeks after a neurotoxic lesion, compared to control animals. Thus, we propose here that one of the functions of Vglut2 in adult DA neurons is to promote post-lesional recovery of meso-striatal axons.
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