Disease-Associated Short Tandem Repeats Co-localize with Chromatin Domain Boundaries

Sun, James; Zhou, Linda; Emerson, Daniel; Phyo, Sai Aung; Titus, Katelyn R.; Gong, Wanfeng; Gilgenast, Thomas G.; Beagan, Jonathan A.; Davidson, Beverly L.; Tassone, Flora; Phillips-Cremins, Jennifer E.

doi:10.1016/j.cell.2018.08.005

Cited by 179 publications

(151 citation statements)

References 65 publications

(100 reference statements)

Supporting

Mentioning

141

Contrasting

Unclassified

Order By: Relevance

“…For example, a 20bp eSTR was associated with nine eGenes (seven lead) connected via distal loops ( Figure 6E) and was in strong LD with a UKBB variant linked to 19 distinct traits including asthma and body fat percentage; two of the genes associated with this variant (TCF20 and POLR3H) have also been previously linked to autism (Babbs et al, 2014;Kong et al, 2012). We observed that this variant appears to overlap a chromatin subdomain boundary visible in Hi-C data from iPSCORE which is notable given that disease causing STRs, such as the causal variant for Fragile X syndrome, have been reported to localize to subdomain boundaries (Sun et al, 2018). Additionally, we found a 13kb deletion on chromosome 7 linked to five eGenes via looping that was also linked to 14 traits ( Figure 6F).…”

Section: Ld Tagging and Gwas Associations Differ Between Variant Classessupporting

confidence: 49%

Genomic properties of structural variants and short tandem repeats that impact gene expression and complex traits in humans

Jakubosky

D’Antonio

Bonder

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

Section: Ld Tagging and Gwas Associations Differ Between Variant Classessupporting

confidence: 49%

Genomic properties of structural variants and short tandem repeats that impact gene expression and complex traits in humans

Jakubosky

D’Antonio

Bonder

et al. 2019

Preprint

View full text Add to dashboard Cite

show abstract

“…This is complemented by evidence for insulator function of specific TE families (Wang et al 2015;Schmidt et al 2012). More recently, an association between the expansion of disease-associated tandem repeats and three-dimensional chromatin topology has been reported, highlighting the role of these elements for healthy cellular function (Sun et al 2018). However, despite their functional relevance, the establishment of a causal relationship between TE genomic location and three-dimensional chromatin organisation has been hindered by the lack of observations in a dynamic system that would allow the examination of changes in chromatin conformation related to TEs.…”

Section: Introductionmentioning

confidence: 87%

Transposable elements drive reorganisation of 3D chromatin during early embryogenesis

Kruse

Díaz

Enriquez-Gasca

et al. 2019

Preprint

View full text Add to dashboard Cite

Transposable elements are abundant genetic components of eukaryotic genomes with important regulatory features affecting transcription, splicing, and recombination, among others. Here we demonstrate that the Murine Endogenous Retroviral Element (MuERV-L/MERVL) family of transposable elements drives the 3D reorganisation of the genome in the early mouse embryo. By generating Hi-C data in 2-cell-like cells, we show that MERLV elements promote the formation of insulating domain boundaries throughout the genome in vivo and in vitro. The formation of these boundaries is coupled to the upregulation of directional transcription from MERVL, which results in the activation of a subset of the gene expression programme of the 2-cell stage embryo. Domain boundaries in the 2-cell stage embryo are transient and can be remodelled without undergoing cell division. Remarkably, we find extensive inter-strain MERVL variation, suggesting multiple non-overlapping rounds of recent genome invasion and a high regulatory plasticity of genome organisation. Our results demonstrate that MERVL drive chromatin organisation during early embryonic development shedding light into how nuclear organisation emerges during zygotic genome activation in mammals.

show abstract

“…lead to partial ATM activation [48]. A recent study has shown that repeat expansion disease genes, including HTT, localize to boundaries of chromatin domains associated with defined chromatin topology [57]. The study provided evidence in Fragile X syndrome, a disease caused by CGG expansions in the FMR1 gene, that pathological repeat expansions are associated with disrupted chromatin boundaries and, by extension, genomic topography [57].…”

Section: Increased Asymmetric Divisionmentioning

confidence: 97%

“…A recent study has shown that repeat expansion disease genes, including HTT, localize to boundaries of chromatin domains associated with defined chromatin topology [57]. The study provided evidence in Fragile X syndrome, a disease caused by CGG expansions in the FMR1 gene, that pathological repeat expansions are associated with disrupted chromatin boundaries and, by extension, genomic topography [57]. Thus, it is conceivable that the HTT CAG repeat expansion in HD also leads to altered chromatin structure, triggering partial ATM activation and elevated genome integrity signaling.…”

Section: Increased Asymmetric Divisionmentioning

confidence: 99%

Expanded huntingtin CAG repeats disrupt the balance between neural progenitor expansion and differentiation in human cerebral organoids

Zhang

Ooi

Utami

et al. 2019

Preprint

View full text Add to dashboard Cite

Huntington disease (HD) manifests in both adult and juvenile forms. Mutant HTT gene carriers are thought to undergo normal brain development followed by a degenerative phase, resulting in progressive clinical manifestations. However, recent studies in children and prodromal individuals at risk for HD have raised the possibility of abnormal neurodevelopment.Although key findings in rodent models support this notion, direct evidence in the context of human physiology remains lacking. Using a panel of isogenic HD human embryonic pluripotent stem cells and cerebral organoids, we investigated the impact of mutant HTT on early neurodevelopment. We find that ventricular zone-like neuroepithelial progenitor layer expansion is blunted in an HTT CAG repeat length-dependent manner due to premature neurogenesis in HD cerebral organoids, driven by cell intrinsic processes. Transcriptional profiling and imaging analysis revealed impaired cell cycle regulatory processes, increased G1 length, and increased asymmetric division of apical progenitors, collectively contributing to premature neuronal differentiation. We demonstrate increased activity of the ATM-p53 pathway, an up-stream regulator of cell cycle processes, and show that treatment with ATM antagonists partially rescues the blunted neuroepithelial progenitor expansion in HD organoids. Our findings suggest that CAG repeat length regulates the balance between neural progenitor expansion and differentiation during early neurodevelopment. Our results 1/26further support the view that HD, at least in its early-onset forms, may not be a purely neurodegenerative disorder, and that abnormal neurodevelopment may be a component of HD pathophysiology.

show abstract

Disease-Associated Short Tandem Repeats Co-localize with Chromatin Domain Boundaries

Cited by 179 publications

References 65 publications

Genomic properties of structural variants and short tandem repeats that impact gene expression and complex traits in humans

Genomic properties of structural variants and short tandem repeats that impact gene expression and complex traits in humans

Transposable elements drive reorganisation of 3D chromatin during early embryogenesis

Expanded huntingtin CAG repeats disrupt the balance between neural progenitor expansion and differentiation in human cerebral organoids

Contact Info

Product

Resources

About