3D genome mapping identifies subgroup-specific chromosome conformations and tumor-dependency genes in ependymoma.
Konstantin OkonechnikovAylin CamgözOwen ChapmanSameena WaniDonglim Esther ParkJens-Martin HübnerAbhijit ChakrabortyMeghana PagadalaRosalind BumpSahaana ChandranKaterina KraftRocio Acuna-HidalgoDerek ReidKristin L SikkinkMonika MauermannEdwin F JuarezAnne JenseitJames T RobinsonKristian W PajtlerTill MildeNatalie JägerPetra FieselLing MorganSunita SridharNicole G CoufalMichael L LevyDenise MalickiCharlotte HobbsStephen F KingsmoreShareef NahasMatija SnuderlJohn CrawfordRobert J Wechsler-ReyaTom Belle DavidsonJennifer A CotterGeorge MichaielGudrun FleischhackStefan MundlosAnthony SchmittHannah CarterKulandaimanuvel Antony MichealrajSachin A KumarMichael D TaylorJeremy RichFrank BuchholzJill P MesirovStefan M PfisterFerhat AyJesse R DixonMarcel KoolLukas ChavezPublished in: Nature communications (2023)
Ependymoma is a tumor of the brain or spinal cord. The two most common and aggressive molecular groups of ependymoma are the supratentorial ZFTA-fusion associated and the posterior fossa ependymoma group A. In both groups, tumors occur mainly in young children and frequently recur after treatment. Although molecular mechanisms underlying these diseases have recently been uncovered, they remain difficult to target and innovative therapeutic approaches are urgently needed. Here, we use genome-wide chromosome conformation capture (Hi-C), complemented with CTCF and H3K27ac ChIP-seq, as well as gene expression and DNA methylation analysis in primary and relapsed ependymoma tumors, to identify chromosomal conformations and regulatory mechanisms associated with aberrant gene expression. In particular, we observe the formation of new topologically associating domains ('neo-TADs') caused by structural variants, group-specific 3D chromatin loops, and the replacement of CTCF insulators by DNA hyper-methylation. Through inhibition experiments, we validate that genes implicated by these 3D genome conformations are essential for the survival of patient-derived ependymoma models in a group-specific manner. Thus, this study extends our ability to reveal tumor-dependency genes by 3D genome conformations even in tumors that lack targetable genetic alterations.
Keyphrases
- genome wide
- dna methylation
- copy number
- gene expression
- spinal cord
- single molecule
- circulating tumor
- high resolution
- acute lymphoblastic leukemia
- acute myeloid leukemia
- white matter
- circulating tumor cells
- multiple myeloma
- multiple sclerosis
- high throughput
- single cell
- molecular dynamics simulations
- diffuse large b cell lymphoma
- clinical trial
- resting state