Structural variations in cancer and the 3D genome

Frank Dubois; Nikos Sidiropoulos; Joachim Weischenfeldt; Rameen Beroukhim

doi:10.1038/s41568-022-00488-9

Structural variations in cancer and the 3D genome

Frank Dubois, Nikos Sidiropoulos, Joachim Weischenfeldt^*, Rameen Beroukhim^*

^*Corresponding author for this work

The Finsen Laboratory

71 Citations (Scopus)

Abstract

Structural variations (SVs) affect more of the cancer genome than any other type of somatic genetic alteration but difficulties in detecting and interpreting them have limited our understanding. Clinical cancer sequencing also increasingly aims to detect SVs, leading to a widespread necessity to interpret their biological and clinical relevance. Recently, analyses of large whole-genome sequencing data sets revealed features that impact rates of SVs across the genome in different cancers. A striking feature has been the extent to which, in both their generation and their influence on the selective fitness of cancer cells, SVs are more specific to individual cancer types than other genetic alterations such as single-nucleotide variants. This Perspective discusses how the folding of the 3D genome, and differences in its folding across cell types, affect observed SV rates in different cancer types as well as how SVs can impact cancer cell fitness.

Original language	English
Journal	Nature Reviews Cancer
Volume	22
Issue number	9
Pages (from-to)	533-546
Number of pages	14
ISSN	1474-175X
DOIs	https://doi.org/10.1038/s41568-022-00488-9
Publication status	Published - Sept 2022

Keywords

Genome, Human
Genomics
Humans
Neoplasms/genetics

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10.1038/s41568-022-00488-9

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title = "Structural variations in cancer and the 3D genome",

abstract = "Structural variations (SVs) affect more of the cancer genome than any other type of somatic genetic alteration but difficulties in detecting and interpreting them have limited our understanding. Clinical cancer sequencing also increasingly aims to detect SVs, leading to a widespread necessity to interpret their biological and clinical relevance. Recently, analyses of large whole-genome sequencing data sets revealed features that impact rates of SVs across the genome in different cancers. A striking feature has been the extent to which, in both their generation and their influence on the selective fitness of cancer cells, SVs are more specific to individual cancer types than other genetic alterations such as single-nucleotide variants. This Perspective discusses how the folding of the 3D genome, and differences in its folding across cell types, affect observed SV rates in different cancer types as well as how SVs can impact cancer cell fitness.",

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T1 - Structural variations in cancer and the 3D genome

AU - Dubois, Frank

AU - Sidiropoulos, Nikos

AU - Weischenfeldt, Joachim

AU - Beroukhim, Rameen

PY - 2022/9

Y1 - 2022/9

N2 - Structural variations (SVs) affect more of the cancer genome than any other type of somatic genetic alteration but difficulties in detecting and interpreting them have limited our understanding. Clinical cancer sequencing also increasingly aims to detect SVs, leading to a widespread necessity to interpret their biological and clinical relevance. Recently, analyses of large whole-genome sequencing data sets revealed features that impact rates of SVs across the genome in different cancers. A striking feature has been the extent to which, in both their generation and their influence on the selective fitness of cancer cells, SVs are more specific to individual cancer types than other genetic alterations such as single-nucleotide variants. This Perspective discusses how the folding of the 3D genome, and differences in its folding across cell types, affect observed SV rates in different cancer types as well as how SVs can impact cancer cell fitness.

AB - Structural variations (SVs) affect more of the cancer genome than any other type of somatic genetic alteration but difficulties in detecting and interpreting them have limited our understanding. Clinical cancer sequencing also increasingly aims to detect SVs, leading to a widespread necessity to interpret their biological and clinical relevance. Recently, analyses of large whole-genome sequencing data sets revealed features that impact rates of SVs across the genome in different cancers. A striking feature has been the extent to which, in both their generation and their influence on the selective fitness of cancer cells, SVs are more specific to individual cancer types than other genetic alterations such as single-nucleotide variants. This Perspective discusses how the folding of the 3D genome, and differences in its folding across cell types, affect observed SV rates in different cancer types as well as how SVs can impact cancer cell fitness.

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KW - Humans

KW - Neoplasms/genetics

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Structural variations in cancer and the 3D genome

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