Project description:Microglia are brain-resident immune cells and regulate mechanisms essential for cognitive functions. Down syndrome (DS), the most frequent cause of genetic intellectual disability, is caused by a supernumerary chromosome 21, containing also genes related to the immune system. In the hippocampus of the Dp(16) mouse model of DS and DS individuals, we found activated microglia, as assessed by their morphology; activation markers; and, for DS mice, electrophysiological profile. Accordingly, we found increased pro-inflammatory cytokine levels and altered interferon signaling in Dp(16) hippocampi. DS mice also showed decreased spine density and activity of hippocampal neurons and hippocampus-dependent cognitive behavioral deficits. Depletion of defective microglia or treatment with a commonly used anti-inflammatory drug rescued the neuronal spine and activity impairments and cognitive deficits in juvenile Dp(16) mice. Our results suggest an involvement of microglia in Dp(16)-mouse cognitive deficits and identify a new potential therapeutic approach for cognitive disabilities in DS individuals.

Project description:Down syndrome, the leading genetic cause of intellectual disability, results from an extra-copy of chromosome 21. Mice engineered to model this aneuploidy exhibit Down syndrome-like memory deficits in spatial and contextual tasks. While abnormal neuronal function has been identified in these models, most studies have relied on in vitro measures. Here, using in vivo recording in the Dp(16)1Yey model, we find alterations in the organization of spiking of hippocampal CA1 pyramidal neurons, including deficits in the generation of complex spikes. These changes lead to poorer spatial coding during exploration and less coordinated activity during sharp-wave ripples, events involved in memory consolidation. Further, the density of CA1 inhibitory neurons expressing neuropeptide Y, a population key for the generation of pyramidal cell bursts, were significantly increased in Dp(16)1Yey mice. Our data refine the 'over-suppression' theory of Down syndrome pathophysiology and suggest specific neuronal subtypes involved in hippocampal dysfunction in these model mice.

Project description:ImportancePatients with Down syndrome have a high incidence of persistent obstructive sleep apnea (OSA) and limited treatment options. Upper airway hypoglossal stimulation has been shown to be effective for adults with OSA but has not yet been evaluated for pediatric populations.ObjectiveTo evaluate the safety and effectiveness of upper airway stimulation for adolescent patients with Down syndrome and severe OSA.Design, setting, and participantsThis prospective single-group multicenter cohort study with 1-year follow-up was conducted between April 1, 2015, and July 31, 2021, among a referred sample of 42 consecutive adolescent patients with Down syndrome and persistent severe OSA after adenotonsillectomy.InterventionUpper airway stimulation.Main outcomes and measuresThe prespecified primary outcomes were safety and the change in apnea-hypopnea index (AHI) from baseline to 12 months postoperatively. Polysomnographic and quality of life outcomes were assessed at 1, 2, 6, and 12 months postoperatively.ResultsAmong the 42 patients (28 male patients [66.7%]; mean [SD] age, 15.1 [3.0] years), there was a mean (SD) decrease in AHI of 12.9 (13.2) events/h (95% CI, -17.0 to -8.7 events/h). With the use of a therapy response definition of a 50% decrease in AHI, the 12-month response rate was 65.9% (27 of 41), and 73.2% of patients (30 of 41) had a 12-month AHI of less than 10 events/h. The most common complication was temporary tongue or oral discomfort, which occurred in 5 patients (11.9%). The reoperation rate was 4.8% (n = 2). The mean (SD) improvement in the OSA-18 total score was 34.8 (20.3) (95% CI, -42.1 to -27.5), and the mean (SD) improvement in the Epworth Sleepiness Scale score was 5.1 (6.9) (95% CI, -7.4 to -2.8). The mean (SD) duration of nightly therapy was 9.0 (1.8) hours, with 40 patients (95.2%) using the device at least 4 hours a night.Conclusions and relevanceUpper airway stimulation was able to be safely performed for 42 adolescents who had Down syndrome and persistent severe OSA after adenotonsillectomy with positive airway pressure intolerance. There was an acceptable adverse event profile with high rates of therapy response and quality of life improvement.Trial registrationClinicalTrials.gov Identifier: NCT02344108.

Project description:Microglia are the resident immune cells of the brain and have been implicated in mechanisms essential for cognitive functions. Down syndrome (DS), the most frequent cause of genetic intellectual disability, is caused by the presence of a supernumerary chromosome 21, which contains genes essential for the function of the immune system. Here, we investigated the presence of microglial alterations and their implication for cognitive impairment in the Dp(16) mouse model of DS. In the hippocampus of Dp(16) mice and individuals with DS, we found microglial morphology indicative of an activated state. Accordingly, we found increased levels of pro-inflammatory cytokines and altered interferon signaling in Dp(16) mice. In addition, Dp(16) mice showed decreased dendritic spine density and cognitive deficits. Remarkably, depletion of defective microglia by PLX3397 treatment or rescue of the microglia activated state by the commonly used anti-inflammatory drug acetaminophen fully rescued dendritic-spine density and cognitive deficits in Dp(16) mice. Our data suggest an involvement of microglia in the cognitive impairment of DS animals and identify a new therapeutic approach for the potential rescue of cognitive disabilities in individuals with DS.

Project description:Microglia are the resident immune cells of the brain and have been implicated in mechanisms essential for cognitive functions. Down syndrome (DS), the most frequent cause of genetic intellectual disability, is caused by the presence of a supernumerary chromosome 21, which contains genes essential for the function of the immune system. Here, we investigated the presence of microglial alterations and their implication for cognitive impairment in the Dp(16) mouse model of DS. In the hippocampus of Dp(16) mice and individuals with DS, we found microglial morphology indicative of an activated state. Accordingly, we found increased levels of pro-inflammatory cytokines and altered interferon signaling in Dp(16) mice. In addition, Dp(16) mice showed decreased dendritic spine density and cognitive deficits. Remarkably, depletion of defective microglia by PLX3397 treatment or rescue of the microglia activated state by the commonly used anti-inflammatory drug acetaminophen fully rescued dendritic-spine density and cognitive deficits in Dp(16) mice. Our data suggest an involvement of microglia in the cognitive impairment of DS animals and identify a new therapeutic approach for the potential rescue of cognitive disabilities in individuals with DS.

Project description:Microglia are the resident immune cells of the brain and have been implicated in mechanisms essential for cognitive functions. Down syndrome (DS), the most frequent cause of genetic intellectual disability, is caused by the presence of a supernumerary chromosome 21, which contains genes essential for the function of the immune system. Here, we investigated the presence of microglial alterations and their implication for cognitive impairment in the Dp(16) mouse model of DS. In the hippocampus of Dp(16) mice and individuals with DS, we found microglial morphology indicative of an activated state. Accordingly, we found an electrophysiological profile typical of activated microglia, increased levels of pro-inflammatory cytokines, and altered interferon signaling in Dp(16) mice. In addition, DS mice showed decreased neuronal spine density and neuronal activity, as well as cognitive behavioral deficits. Remarkably, depletion of defective microglia by PLX3397 treatment or rescue of the microglia activated state by the commonly used anti-inflammatory drug acetaminophen rescued the neuronal deficits and cognitive impairment in Dp(16) mice. Our data suggest an involvement of microglia in the cognitive impairment of DS animals and identify a new therapeutic approach for the potential rescue of cognitive disabilities in individuals with DS.

Project description:Down syndrome (DS), the most common human chromosomal disorder, is caused by trisomy 21. Recent studies show that the trisomic genes Dyrk1a and Kcnj6 play critical causative roles in DS cognitive deficits. Interestingly, an unexpected lack of improvement of hippocampal-dependent learning and memory deficits was observed when both Dyrk1a and Kcnj6 were normalized to diploidy in the DS mouse model, Dp(16)1/Yey (Dp16). In this study, we explored the molecular mechanisms underlying this phenomenon by using whole genome-wide hippocampal transcriptome analysis. In total, 142, 142, and 112 genes were found significantly differentially expressed in the Dp16, Dp16/Dyrk1aKO (Dyrk1a normalized) and Dp16;Dyrk1aKO/Kcnj6KO (Both Dyrk1a and Kcnj6 normalized) hippocampus, respectively, compared with the WT hippocampus. The majority of the common significantly differentially expressed genes (DEGs) were trisomic genes. Dyrk1a and Kcnj6 normalization mainly altered the expression of diploid genes. Normalizing Dyrk1a in the Dp16 hippocampus caused an overall downregulation of genes, whereas further Kcnj6 normalization caused an overall upregulation of genes. Both further rescuing effects and neutralizing effects were observed in Kcnj6 and Dyrk1a double-normalized mice compared with mice with Dyrk1a normalization alone.

Project description:Down syndrome (DS) results from triplication of human chromosome 21. Neuropathological hallmarks of DS include atypical central nervous system development that manifests prenatally and extends throughout life. As a result, individuals with DS exhibit cognitive and motor deficits, and have delays in achieving developmental milestones. To determine whether different mouse models of DS recapitulate the human prenatal and postnatal phenotypes, here, we directly compared brain histogenesis, gene expression and behavior over the lifespan of three cytogenetically distinct mouse models of DS: Ts1Cje, Ts65Dn and Dp(16)1/Yey. Histological data indicated that Ts65Dn mice were the most consistently affected with respect to somatic growth, neurogenesis and brain morphogenesis. Embryonic and adult gene expression results showed that Ts1Cje and Ts65Dn brains had considerably more differentially expressed (DEX) genes compared with Dp(16)1/Yey mice, despite the larger number of triplicated genes in the latter model. In addition, DEX genes showed little overlap in identity and chromosomal distribution in the three models, leading to dissimilarities in affected functional pathways. Perinatal and adult behavioral testing also highlighted differences among the models in their abilities to achieve various developmental milestones and perform hippocampal- and motor-based tasks. Interestingly, Dp(16)1/Yey mice showed no abnormalities in prenatal brain phenotypes, yet they manifested behavioral deficits starting at postnatal day 15 that continued through adulthood. In contrast, Ts1Cje mice showed mildly abnormal embryonic brain phenotypes, but only select behavioral deficits as neonates and adults. Altogether, our data showed widespread and unexpected fundamental differences in behavioral, gene expression and brain development phenotypes between these three mouse models. Our findings illustrate unique limitations of each model when studying aspects of brain development and function in DS. This work helps to inform model selection in future studies investigating how observed neurodevelopmental abnormalities arise, how they contribute to cognitive impairment, and when testing therapeutic molecules to ameliorate the intellectual disability associated with DS.This article has an associated First Person interview with the first author of the paper.

Project description:The Dp(10)2Yey mouse carries a ~2.3 Mb intra-chromosomal duplication of mouse chromosome 10 (Mmu10) that makes it an essential model for aspects of Down syndrome (DS, trisomy 21). Specifically, these animals carry extra copies of Mmu10 genes that are homologous to those on human chromosome 21 (Hsa21). Here, we report spatial memory impairment and anxiety-like behaviour in this model alongside altered neural activity in the medial prefrontal cortex (mPFC) and hippocampus (HPC). Specifically, Dp(10)2Yey DS mice showed impaired spatial alternation associated with increased ripple activity in mPFC during the period of memory consolidation, and reduced mobility in a novel environment accompanied by reduced theta-gamma phase-amplitude coupling in HPC. Finally, we found alterations in the number of interneuron subtypes in mPFC and HPC that may contribute to the observed phenotypes and highlight potential approaches to ameliorate the effects of human trisomy 21.

Project description:The assessment of pharyngeal collapsibility is difficult to perform in children under normal sleep. An alternative is to perform the assessment under an anesthetic, such as dexmedetomidine (DEX), that induces non-rapid eye movement (NREM) sleep. The objectives of this study were to compare critical closing airway pressure (Pcrit) obtained during natural sleep to that obtained under DEX in patients with Down syndrome (DS) and persistent obstructive sleep apnea (OSA) and determine whether Pcrit measured under sedation predicts the severity of OSA.The passive and active Pcrit, which represent airway passive mechanical properties and active dynamic responses to airway obstruction, respectively, were measured. Upper airway reflex activity was estimated by calculating the difference between active and passive Pcrit. Subjects underwent overnight polysomnography during which Pcrit was measured during normal sleep. Pcrit was also measured during DEX sedation at a dose of 2 ?g/kg/h.The study included 50 patients with median age of 11.4 years (interquartile range: 7.0-13.9) and median body mass index of 23.0 kg/m2 (interquartile range: 18.4-29.1), 66% male and 80% Caucasian. Passive Pcrit was significantly higher than active Pcrit when measured during normal sleep and DEX-induced sleep. There was a positive association between apnea-hypopnea index and passive Pcrit (Spearman r = 0.53, P = .0001) and active Pcrit (r = 0.55, P = .0002) under DEX-induced sleep. There were no significant differences between the Pcrit measurements during natural sleep and during DEX sedation.Patients with OSA can compensate for airway obstruction under DEX-induced sleep. The close association between Pcrit and apnea-hypopnea index suggests that airway responses with DEX sedation parallel those seen during natural sleep.ClinicalTrials.gov identifier: NCT01902407.