Project description:Using Huntington’s disease (HD) mouse models that quantitatively replicate the reduction of striatal Phoshodiesterase 10 (PDE10) levels in manifest Huntington’s disease patients, we demonstrate the potential therapeutic benefit of PDE10 inhibition on correcting basal ganglia circuitry deficits thought to drive disease symptomology in patients. PDE10 inhibition acutely restored corticostriatal input and boosted cortically driven indirect pathway activity in HD models with compromised PDE10 levels. We show that cyclic nucleotide signaling processes are impaired in the models, and that elevation of both the cAMP and cGMP nucleotides afforded by PDE10 inhibition are required for this rescue. Global phosphoproteomic profiling of striatal proteins in response to PDE10 inhibition provide novel information on the plausible neural substrates responsible for the improvement. Finally, we show that long-term chronic treatment of the Q175 knock-in mouse model with PDE10A inhibitors, starting at a presymptomatic age, showed improvements, above and beyond those seen during acute administration, including a partial reversal of striatal deregulated transcripts predominantly driven through activation of the AP-1 and CREB transcription factor complexes, and a prevention of the emergence of some cardinal HD neurophysiological deficits.

Project description:Deficiency of the astrocytic excitatory amino acid transporter type 2 (EAAT2) and, consequently, inefficient glutamate clearance at corticostriatal synapses may contribute to the depression of self-initiated movements in HuntingtonÕs disease (HD). Here we report that the removal of the last 68 amino-acids in the C-terminal of EAAT2 increases the levels of native EAAT2 in striatal lysates and counteracts some of the HD-related changes in the interactor spectrum of mYFP-tagged EAAT2. Using the Q175 mouse model of HD, we explored the functional consequences of C-terminal modifications. It was found that astrocytic expression of EAAT2-S506X or -4KR alleviates the HD-related decrease in the incidence and velocity of exploratory movements. It also stimulates astrocytic glutamate uptake, increases the level of synaptic EAAT2 and improves glutamate clearance at single corticostriatal synapse. The experiments illuminate a link between the intracellular regulation of astrocytic glutamate transport in the striatum and symptoms of hypokinesia in HD mice.

Project description:We recently identified heterozygous deletions of the gene TSHZ3, which encodes a Zn-finger transcription factor, in patients with a syndrome including autistic features and provided evidence in mice for a link between Tshz3 haploinsufficiency, defects in cortical projection neurons (CPNs) and autism spectrum disorder (ASD)-like abnormalities. To get more insight into when and where TSHZ3 is required for the proper development of the brain, we generated and characterized a novel mouse model of conditional Tshz3 deletion in projection neurons from postnatal day 2-3 onward. These mice exhibit altered striatal expression of genes encoding for synaptic components, electrophysiological and synaptic changes in striatal cholinergic interneurons, , as well as  ASD-relevant behavioral deficits. These data, by revealing a crucial postnatal role of TSHZ3 in the development and function of the corticostriatal circuitry that might be determinant for ASD pathogenesis, offer a novel ASD model and further open the possibility for an early postnatal therapeutic window for the syndrome linked to TSHZ3 haploinsufficiency.

Project description:The molecular mechanisms that underlie striatal development and organization remain largely unknown. Here, we show that Foxp1, a transcription factor strongly linked to autism and intellectual disability, regulates organizational features of striatal circuitry in a cell-type dependent fashion. Using single-cell RNA-sequencing, we examine the cellular diversity of the early postnatal striatum and demonstrate that Foxp1 specifies a subpopulation of indirect pathway spiny projection neurons (iSPNs) while maintaining the striosome-matrix architecture through molecular mechanisms mediated by direct pathway spiny projection neurons (dSPNs). Functionally, Foxp1 alters striatal projection patterns both cell-autonomously and non-autonomously. We connect these changes in striatal circuitry to distinct behavioral deficits relevant to phenotypes described in patients with FOXP1 loss-of-function mutations. These data reveal novel cell-type specific transcriptional mechanisms underlying distinct features of striatal circuitry and identify Foxp1 as a key regulator of striatal development

Project description:Transcriptional dysregulation in Huntington’s disease (HD) causes functional deficits in striatal neurons. Here, we performed Patch-seq in an in vitro HD model to investigate the effects of mutant huntingtin (Htt) on synaptic transmission and gene transcription in single striatal neurons. We found that expression of mutant Htt decreased the synaptic output of striatal neurons in a cell autonomous fashion and identified a number of genes, whose dysregulation was correlated with physiological deficiencies in mutant Htt neurons. In support of a pivotal role for epigenetic mechanisms in HD pathophysiology, we found that inhibiting histone deacetylase 1/3 activities rectified several functional and morphological deficits and alleviated the aberrant transcriptional profiles in mutant Htt neurons. With this study, we demonstrate that Patch-seq technology can be applied both to better understand molecular mechanisms underlying a complex neurological disease at single-cell level and to provide a platform for screening for therapeutics for the disease.

Project description:Alterations to corticostriatal glutamatergic function are early pathophysiological changes associated with Huntington?s disease (HD). The factors that regulate the maintenance of corticostriatal glutamatergic synapses post-developmentally are not well understood. Recently, the striatum-enriched transcription factor Foxp2 was implicated in the development of these synapses. Here we show that, in mice, overexpression of Foxp2 in the adult striatum of two models of HD leads to rescue of HD-associated behaviors, while knockdown of Foxp2 in wild-type mice leads to development of HD-associated behaviors. We note that Foxp2 encodes the longest polyglutamine repeat protein in the human reference genome, and we show that it can be sequestered into aggregates with polyglutamine-expanded mutant Huntingtin protein (mHTT). Foxp2 overexpression in HD model mice leads to altered expression of several genes associated with synaptic function, genes which present new targets for normalization of corticostriatal dysfunction in HD.

Project description:Huntington Disease (HD) is a dominantly inherited, relentlessly progressive neurodegenerative disease. Caused by a polyglutamine expansion in the mutant huntingtin protein (mhtt), HD pathogenesis impairs function in the cerebral cortex and in medium spiny neurons of the striatum and involves transcriptional dysregulation of a number of genes. Of these genes, silencing of genes related to mitochondrial function is believed to explain metabolic dysfunction in rodent models of HD. Here we show that transglutaminase 2 (TG2), which is upregulated in HD, exacerbates transcriptional dysregulation by acting as a selective corepressor of nuclear genes. TG2 inhibition by RNA knockdown, genetic deletion, or administration of a novel irreversible, peptide-based TG2 inhibitor (ZDON) de-repressed two established regulators of mitochondrial function, PGC-1? and cytochrome c in a cell model of HD. TG2 must localize to non-coding or coding regions of these mitochondrial metabolic genes to silence their transcription. As expected, TG2 inhibition reversed the increased susceptibility of HD mouse cells and human HD myoblasts to the mitochondrial toxin, 3-nitroproprionic acid (3-NP); however, protection mediated by TG2 inhibition was not associated with improved mitochondrial bioenergetics. Indeed, an unbiased array analysis indicated that TG2 inhibition leads to normalization of not only mitochondrial genes but of nearly 40% of genes that are dysregulated in HD mouse striatal neurons, including chaperone and histone genes. Indeed, TG2 interacts directly with Histone 3 in the nucleus. Moreover, TG2 inhibition significantly attenuated photoreceptor degeneration in a Drosophila model of HD and protected mouse HD striatal neurons (YAC128) from NMDA- induced toxicity. Altogether these findings demonstrate that TG2 mediates its deleterious effects in HD by contributing to broad transcriptional dysregulation of genes representing many cellular functions. These studies define a novel HDAC-independent epigenetic strategy for treating neurodegeneration. To evaluate the effect of TG2 inhibition (treatment with ZDON, Boc-DON, CystamineA, and Control) in striatal cell lines from a transgenic model of Huntington disease (Q111) vs. control (Q7). One sample (WT.boc.3, 4068264015_G) failed the QC test and was excluded from further analyses.

Project description:The Yeast Artificial Chomosome (YAC) 128 model of Huntington's disease shows substantial deficits in motor, learning and memory tasks and alterations in its transcriptional profile. We examined the changes in the transcriptional profile in the YAC 128 mouse model of HD at 6, 12, and 18 weeks Brain striatal tissue from Wild Type and YAC 128 mice were sampled at the three age groups

Project description:Production of learned vocalizations requires precise selection and accurate sequencing of appropriate vocal-motor actions. The basal ganglia are essential for the selection and sequencing of motor actions, but the cellular specializations and circuit mechanisms governing accurate sequencing of vocalizations are unknown. Here, we use single-nucleus RNA sequencing and genetic manipulations to map basal ganglia cell types and circuits involved in the production of songbird vocal sequences. We identify cell-type specializations in direct-like and indirect-like basal ganglia pathways, including evolutionary expansion of striatal and arkypallidal cell-types that could facilitate vocal sequencing. We also reversibly reduced the expression of FoxP2 with a viral knockdown. For birds in which FoxP2 was knocked down, striatal neurons exhibited decreased expression of Drd1 and showed an increased ratio of Drd2/Drd1 expression. These findings identify key evolutionary specializations and circuits essential for selection and sequencing of vocal-motor actions necessary for vocal communication.

Project description:Aberrant localization of proteins to mitochondria disturbs mitochondrial function and contributes to the pathogenesis of Huntington’s disease (HD). However, the crucial factors and the molecular mechanisms remain elusive. Here, we found that heat shock transcription factor 1 (HSF1) accumulates in the mitochondria of HD cell cultures, a YAC128 mouse model, and human striatal organoids derived from HD induced pluripotent stem cells (iPSCs). Overexpression of mitochondria-targeting HSF1 (mtHSF1) in the striatum causes neurodegeneration and HD-like behavior. Mechanistically, mtHSF1 facilitates mitochondrial fission by activating dynamin-related protein 1 (Drp1) phosphorylation at S616. Moreover, mtHSF1 suppresses single-stranded DNA binding protein 1 (SSBP1) oligomer formation, which results in mitochondrial DNA (mtDNA) deletion. Suppression of HSF1 mitochondrial localization by DH1, a unique peptide inhibitor, abolishes HSF1-induced mitochondrial abnormalities and ameliorates deficits in an HD animal model and human striatal organoids. Altogether, our findings describe an unsuspected role of HSF1 in contributing to mitochondrial dysfunction, which may provide a promising therapeutic target for HD.