Epigenetic dysregulation in the developing Down syndrome cortex

Hajj, Nady El; Dittrich, Marcus; Böck, Julia; Kraus, Theo; Nanda, Indrajit; Müller, Tobias; Seidmann, Larissa; Tralau, Tim; Galetzka, Danuta; Schneider, Eberhard; Haaf, Thomas

doi:10.1080/15592294.2016.1192736

Cited by 77 publications

(87 citation statements)

References 75 publications

(98 reference statements)

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“…4,5 The phenotype in Down syndrome is thought to arise from the overexpression and dysregulation of these genes and their associated pathways, together with global cellular stress responses and compensatory mechanisms early in development. 6 Epigenetic changes have also been observed in the fetal brain and blood from newborn infants with Down syndrome 7,8 which may further impact development and contribute to the range of observed cognitive outcomes. The neurological phenotype constantly changes over the life span of Down syndrome, 9 with differences continuing into adulthood.…”

Section: Chdmentioning

confidence: 99%

New approaches to studying early brain development in Down syndrome

Baburamani

Patkee

Arichi

et al. 2019

Develop Med Child Neuro

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Down syndrome is the most common genetic developmental disorder in humans and is caused by partial or complete triplication of human chromosome 21 (trisomy 21). It is a complex condition which results in multiple lifelong health problems, including varying degrees of intellectual disability and delays in speech, memory, and learning. As both length and quality of life are improving for individuals with Down syndrome, attention is now being directed to understanding and potentially treating the associated cognitive difficulties and their underlying biological substrates. These have included imaging and postmortem studies which have identified decreased regional brain volumes and histological anomalies that accompany early onset dementia. In addition, advances in genome‐wide analysis and Down syndrome mouse models are providing valuable insight into potential targets for intervention that could improve neurogenesis and long‐term cognition. As little is known about early brain development in human Down syndrome, we review recent advances in magnetic resonance imaging that allow non‐invasive visualization of brain macro‐ and microstructure, even in utero. It is hoped that together these advances may enable Down syndrome to become one of the first genetic disorders to be targeted by antenatal treatments designed to ‘normalize’ brain development. What this paper adds Magnetic resonance imaging can provide non‐invasive characterization of early brain development in Down syndrome. Down syndrome mouse models enable study of underlying pathology and potential intervention strategies. Potential therapies could modify brain structure and improve early cognitive levels. Down syndrome may be the first genetic disorder to have targeted therapies which alter antenatal brain development.

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Section: Chdmentioning

confidence: 99%

New approaches to studying early brain development in Down syndrome

Baburamani

Patkee

Arichi

et al. 2019

Develop Med Child Neuro

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“…Both of these neurodevelopmental disorders are characterized by defective dendritic arborization, abnormal synaptic formation, and disrupted dendritic spine morphology [163-165]. Microarray studies have uncovered hypermethylation of Pcdhg genes and promoters at multiple developmental stages in DS tissues including several brain regions [166,167]. Bisulfite pyrosequencing confirmed that multiple Pcdhg A and B subfamily gene promoters were hypermethylated in DS samples, and targeted RNA sequencing showed that this hypermethylation was, indeed, correlated with lower Pcdhg gene expression [167].…”

Section: Roles In Behavior and Neurological Or Neurodevelopmental Dismentioning

confidence: 99%

“…Microarray studies have uncovered hypermethylation of Pcdhg genes and promoters at multiple developmental stages in DS tissues including several brain regions [166,167]. Bisulfite pyrosequencing confirmed that multiple Pcdhg A and B subfamily gene promoters were hypermethylated in DS samples, and targeted RNA sequencing showed that this hypermethylation was, indeed, correlated with lower Pcdhg gene expression [167]. Though it remains to be demonstrated that reduced γ-Pcdh protein levels are causal for any of the dendritic or synaptic defects seen in DS, the phenotypes observed in Pcdhg null cortex (as discussed above, decreased dendrite arborization and altered dendritic spine number and morphology) are certainly consistent with such a possibility [54,82].…”

Section: Roles In Behavior and Neurological Or Neurodevelopmental Dismentioning

confidence: 99%

Regulation of neural circuit formation by protocadherins

Peek

Mah

Weiner

2017

Cell. Mol. Life Sci.

110

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The Protocadherins (Pcdhs), which make up the most diverse group within the cadherin superfamily, were first discovered in the early 1990's. Data implicating the Pcdhs, including ∼60 proteins encoded by the tandem Pcdha, Pcdhb, and Pcdhg gene clusters and another ∼10 non-clustered Pcdhs, in the regulation of neural development has continually accumulated, with a significant expansion of the field over the past decade. Here, we review the many roles played by clustered and non-clustered Pcdhs in multiple steps important for the formation and function of neural circuits, including dendrite arborization, axon outgrowth and targeting, synaptogenesis, and synapse elimination. We further discuss studies implicating mutation or epigenetic dysregulation of Pcdh genes in a variety of human neurodevelopmental and neurological disorders. With recent structural modeling of Pcdh proteins, the prospects for uncovering molecular mechanisms of Pcdh extracellular and intracellular interactions, and their role in normal and disrupted neural circuit formation, are bright.

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“…Another examination of DS fetal brain tissue (frontal and temporal cortex) observed a trend of modest global hypermethylation (0.3%) as well as hypermethylation of the clustered protocadherins, which are critical to neurodevelopment. 21 Interestingly, two separate studies of DS fetal frontal cortex have found that while significant DS-differential CpGs located on HSA21 displayed a balance of hypermethylation and hypomethylation, the significant CpGs across all other chromosomes were predominantly hypermethylated. 21,22 The DS differentially methylated CpGs belonged to genes involved in ubiquitin mediated proteolysis and Alzheimer's disease pathways.…”

Section: Introductionmentioning

confidence: 99%

“…21 Interestingly, two separate studies of DS fetal frontal cortex have found that while significant DS-differential CpGs located on HSA21 displayed a balance of hypermethylation and hypomethylation, the significant CpGs across all other chromosomes were predominantly hypermethylated. 21,22 The DS differentially methylated CpGs belonged to genes involved in ubiquitin mediated proteolysis and Alzheimer's disease pathways. 22 Taken together, the differences in CpG methylation observed across a variety of DS cells/tissues are not only relevant to early developmental events but also appear to be maintained into adulthood.…”

Section: Introductionmentioning

confidence: 99%

Whole genome bisulfite sequencing of Down syndrome brain reveals regional DNA hypermethylation and novel disorder insights

Laufer¹,

Hwang²,

Ciernia³

et al. 2018

Preprint

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Down Syndrome (DS) is the most common genetic cause of intellectual disability, in which an extra copy of human chromosome 21 (HSA21) affects regional DNA methylation profiles across the genome. Although DNA methylation has been previously examined at select regulatory regions across the genome in a variety of DS tissues and cells, differentially methylated regions (DMRs) have yet to be examined in an unbiased sequencing-based approach. Here, we present the first analysis of DMRs from whole genome bisulfite sequencing (WGBS) data of human DS and matched control brain, specifically frontal cortex. While no global differences in DNA methylation were observed, we identified 3,152 DS-DMRs across the entire genome, the majority of which were hypermethylated in DS. DS-DMRs were significantly enriched at CpG islands and de-enriched at specific gene body and regulatory regions. Functionally, the hypermethylated DS-DMRs were enriched for one-carbon metabolism, membrane transport, and glutamatergic synaptic signaling, while the hypomethylated DMRs were enriched for proline isomerization, glial immune response, and apoptosis. Furthermore, in a cross-tissue comparison to previous studies of DNA methylation from diverse DS tissues and reference epigenomes, hypermethylated DS-DMRs showed a strong cross-tissue concordance, while a more tissuespecific pattern was observed for the hypomethylated DS-DMRs. Overall, this approach highlights that low-coverage WGBS of clinical samples can identify epigenetic alterations to known biological pathways, which are potentially relevant to therapeutic treatments and include metabolic pathways. These results also provide new insights into the genome-wide effects of genetic alterations on DNA methylation profiles indicative of altered neurodevelopment and brain function.

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Epigenetic dysregulation in the developing Down syndrome cortex

Cited by 77 publications

References 75 publications

New approaches to studying early brain development in Down syndrome

New approaches to studying early brain development in Down syndrome

Regulation of neural circuit formation by protocadherins

Whole genome bisulfite sequencing of Down syndrome brain reveals regional DNA hypermethylation and novel disorder insights

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