Project description:Trisomy of chromosome 21, the cause of Down syndrome (DS), is the most commonly occurring genetic cause of Alzheimer’s disease (AD). Here we compare the proteome of the frontal cortex of people who have Down syndrome-Alzheimer’s disease (DSAD) with demographically matched cases of early-onset AD and healthy ageing controls from the general population. We find the abundance of several chromosome 21 encoded proteins are increased in DSAD compared to both comparative groups. Moreover, wider dysregulation of the proteome occurs beyond proteins encoded by chromosome 21, including an increase in the abundance of the key AD protein APOE, in people with DSAD compared to matched cases of early-onset AD.

Project description:The presence of an extra whole or part of chromosome 21 in people with Down syndrome (DS) is associated with multiple neurological changes, including pathological aging that often meets the criteria for Alzheimer’s Disease (AD). While the mechanism underlying these changes is unknown, it has been hypothesized that the presence of the amyloid precursor protein (APP) on chromosome 21 may contribute to the phenotype. Genome-wide DNA methylation abnormalities have been shown in neural tissue of patients with AD, and cells may respond to changes in gene dosage with altered DNA methylation. We therefore examined whole-genome DNA methylation in buccal epithelial cells of adults with DS to determine whether patterns of DNA methylation correlated with DS and/or cognitive impairment. In addition we examined DNA methylation at the APP gene itself, to see whether there were changes in DNA methylation in this population. Using the Illumina 450K Human Methylation Array, we examined more than 485,000 CpG sites distributed across the genome in buccal epithelial cells. We found 297 CpGs to be differentially methylated between the groups, including 26 genes that were represented by more than one CpG. In addition, we found 331 probes that were correlated with cognitive function including 23 genes represented by more than one probe. We found no enrichment on chromosome 21 and targeted analysis of the APP gene revealed weak evidence for epigenetic impacts related to the AD phenotype. Overall, our results indicate that both Trisomy 21 and cognitive impairment are associated with distinct patterns of DNA methylation. This cohort consist of genomic DNA extracted from 20 buccal swabs, bisulphite converted and hybridized to the Illumina Infinium HumanMethylation450 Beadchip for genome wide DNA methylation profiling.

Project description:The presence of an extra whole or part of chromosome 21 in people with Down syndrome (DS) is associated with multiple neurological changes, including pathological aging that often meets the criteria for Alzheimer’s Disease (AD). While the mechanism underlying these changes is unknown, it has been hypothesized that the presence of the amyloid precursor protein (APP) on chromosome 21 may contribute to the phenotype. Genome-wide DNA methylation abnormalities have been shown in neural tissue of patients with AD, and cells may respond to changes in gene dosage with altered DNA methylation. We therefore examined whole-genome DNA methylation in buccal epithelial cells of adults with DS to determine whether patterns of DNA methylation correlated with DS and/or cognitive impairment. In addition we examined DNA methylation at the APP gene itself, to see whether there were changes in DNA methylation in this population. Using the Illumina 450K Human Methylation Array, we examined more than 485,000 CpG sites distributed across the genome in buccal epithelial cells. We found 297 CpGs to be differentially methylated between the groups, including 26 genes that were represented by more than one CpG. In addition, we found 331 probes that were correlated with cognitive function including 23 genes represented by more than one probe. We found no enrichment on chromosome 21 and targeted analysis of the APP gene revealed weak evidence for epigenetic impacts related to the AD phenotype. Overall, our results indicate that both Trisomy 21 and cognitive impairment are associated with distinct patterns of DNA methylation.

Project description:Trisomy 21, a form of aneuploidy, is one of the few viable forms of trisomy. The goal of this study was to assess the effect of an additional chromosome 21 on gene expression in two different human aneuploid model cell lines.

Project description:Alzheimer’s disease (AD) is characterized by neuroinflammation, accumulation of amyloid-β (Aβ) plaques and neuronal degeneration in the brain. The APOE4 variant of apolipoprotein E (apoE) is the most prevalent genetic risk allele associated with late-onset AD. ApoE interacts with complement regulator factor H (FH) but the role of this interaction in AD pathogenesis is unknown.

Project description:Down syndrome, caused by trisomy 21, is a complex developmental disorder associated with intellectual disability and reduced growth of multiple organs. Structural pathologies are present at birth, reflecting embryonic origins. A fundamental unanswered question is how an extra copy of human chromosome 21 contributes to organ-specific pathologies that characterize individuals with Down syndrome. Relevant to the hallmark intellectual disability in Down syndrome, how does trisomy 21 affect neural development? We tested the hypothesis that trisomy 21 exerts effects on human neural development as early as neural induction. Bulk RNA sequencing was performed on isogenic trisomy 21 and euploid human induced pluripotent stem cells (iPSCs) at successive stages of neural induction: embryoid bodies at Day 6, early neuroectoderm at Day 10, and differentiated neuroectoderm at Day 17. Gene expression analysis revealed over 1,300 differentially expressed genes in trisomy 21 cells along the differentiation pathway compared to euploid controls. Less than 5% of the gene expression changes included upregulated chromosome 21 encoded genes at every timepoint. Genes involved in specific growth factor signaling pathways (Wnt and Notch), metabolism (including interferon response and oxidative stress), and extracellular matrix were altered in trisomy 21 cells. Further analysis revealed heterochronic expression of genes. This comprehensive analysis reveals that trisomy 21 impacts discrete developmental pathways at the earliest stages of neural development. Further, the results suggest that metabolic dysfunction arises early in embryogenesis in trisomy 21 and may thus affect development and function more broadly.

Project description:Induced pluripotent stem cells (iPSCs) from patients are an attractive disease model to study tissues with poor accessibility such as the brain. Using this approach, we and others have shown that trisomy 21 results in genome-wide transcriptional dysregulations. The effects of loss of genes on chromosome 21 is much less characterized. Here, we use patient-derived neural cells from an individual with neurodevelopmental delay and a ring chromosome 21 with two deletions spanning 3.8 Mb at the terminal end of 21q22.3, containing 60 protein-coding genes. To investigate the molecular perturbations of the partial monosomy on neural cells, we established patient-derived iPSCs from fibroblasts retaining the ring chromosome 21, and we then induced iPSCs into neuroepithelial stem cells (NESCs). RNA-Seq analysis of NESCs with the ring chromosome revealed downregulation of 18 genes within the deleted region together with global transcriptomic dysregulations when compared to euploid NESCs. Since the deletions on chromosome 21 represent a genetic “contrary” to trisomy of the corresponding region, we further compared the dysregulated transcriptomic profile in with that of two NESC lines with trisomy 21. The analysis revealed opposed expression changes for 23 genes on chromosome 21 as well as 149 non-chromosome 21 genes. Taken together, our results bring insights into the effects on the global and chromosome 21 specific gene expression from a partial monosomy of chromosome 21qter during early neuronal differentiation.

Project description:Trisomy of chromosome 21, the genetic cause of Down syndrome, has the potential to alter expression of genes on chromosome 21, as well as other locations throughout the genome. These transcriptome changes are likely to underlie the Down syndrome clinical phenotypes. We have employed RNA-seq to undertake an in-depth analysis of transcriptome changes resulting from trisomy of chromosome 21, using induced pluripotent stem cells (iPSCs) derived from a single individual with Down syndrome. These cells were originally derived by Li et al, who genetically targeted chromosome 21 in trisomic iPSCs, allowing selection of disomic sibling iPSC clones. Analyses were conducted on trisomic/disomic cell pairs maintained as iPSCs or differentiated into cortical neuronal cultures.

Project description:Apolipoprotein E (APOE) is a lipid and cholesterol transport molecule known to influence Alzheimer's disease (AD) risk in an isoform-specific manner. In particular, the APOE E4 allele is the largest genetic risk factor for late-onset sporadic AD. Our recent findings uncovered activated, clonally expanded T cells in AD cerebrospinal fluid (CSF). This T cell phenotype occurred concomitantly with altered expression of APOE in CSF monocytes. Yet, whether APOE variants differentially affect peripheral immunity systems remains unknown. In this study, we performed targeted immune profiling using single-cell epigenetic and transcriptomic analysis of peripheral blood mononuclear cells (PBMC). We analyzed 55 age-matched healthy control (HC) and AD patients with equal distribution of APOE E3/E3, E3/E4, and E4/E4 genotypes. We reveal dysregulation in monocytes and clonally expanded T cells that are distinct to AD patients carrying the APOE E4/E4 genotype. Additionally, we find APOE isoform-dependent chromatin accessibility differences that correspond to RNA expression changes. Cumulatively, these results uncover APOE isoform-dependent changes to peripheral immunity in AD.

Project description:Congenital development disorders with variable severity occur in trisomy 21. However, how these phenotypic abnormalities develop with variations remains elusive. We hypothesize that the difference in euploidy gene expression variation among trisomy 21 tissues are perturbed by the presence of an extra copy of chromosome 21 and this may contribute to the phenotypic variations in Down syndrome. Keywords: Disease state analysis