Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells

Sjors Middelkamp; S.A.A.C. van Heesch; Koen Braat; J de Ligt; Maarten van Iterson; Marieke Simonis; Markus J.  van Roosmalen; Martijn J E Kelder; Evelien Kruisselbrink; Ron Hochstenbach; Nienke Verbeek; Elly Ippel; Y. Adolfs; R. Jeroen Pasterkamp; Wigard P. Kloosterman; Ewart W. Kuijk; Edwin Cuppen

doi:10.1186/s13073-017-0399-z

Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells

Sjors Middelkamp, S.A.A.C. van Heesch, Koen Braat, J de Ligt, Maarten van Iterson, Marieke Simonis, Markus J. van Roosmalen, Martijn J E Kelder, Evelien Kruisselbrink, Ron Hochstenbach, Nienke Verbeek, Elly Ippel, Y. Adolfs, R. Jeroen Pasterkamp, Wigard P. Kloosterman, Ewart W. Kuijk^*, Edwin Cuppen

^*Corresponding author for this work

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Abstract

Background: Germline chromothripsis causes complex genomic rearrangements that are likely to affect multiple genes and their regulatory contexts. The contribution of individual rearrangements and affected genes to the phenotypes of patients with complex germline genomic rearrangements is generally unknown. Methods: To dissect the impact of germline chromothripsis in a relevant developmental context, we performed trio-based RNA expression analysis on blood cells, induced pluripotent stem cells (iPSCs), and iPSC-derived neuronal cells from a patient with de novo germline chromothripsis and both healthy parents. In addition, Hi-C and 4C-seq experiments were performed to determine the effects of the genomic rearrangements on transcription regulation of genes in the proximity of the breakpoint junctions. Results: Sixty-seven genes are located within 1 Mb of the complex chromothripsis rearrangements involving 17 breakpoints on four chromosomes. We find that three of these genes (FOXP1, DPYD, and TWIST1) are both associated with developmental disorders and differentially expressed in the patient. Interestingly, the effect on TWIST1 expression was exclusively detectable in the patient's iPSC-derived neuronal cells, stressing the need for studying developmental disorders in the biologically relevant context. Chromosome conformation capture analyses show that TWIST1 lost genomic interactions with several enhancers due to the chromothripsis event, which likely led to deregulation of TWIST1 expression and contributed to the patient's craniosynostosis phenotype. Conclusions: We demonstrate that a combination of patient-derived iPSC differentiation and trio-based molecular profiling is a powerful approach to improve the interpretation of pathogenic complex genomic rearrangements. Here we have applied this approach to identify misexpression of TWIST1, FOXP1, and DPYD as key contributors to the complex congenital phenotype resulting from germline chromothripsis rearrangements.

Original language	English
Article number	9
Journal	Genome Medicine
Volume	9
Issue number	1
DOIs	https://doi.org/10.1186/s13073-017-0399-z
Publication status	Published - 26 Jan 2017

Keywords

Chromosome conformation capture
Chromothripsis
Complex genomic rearrangements
Congenital disorders
Craniosynostosis
Induced pluripotent stem cells
Neuronal differentiation
Personal genomics
RNA-sequencing
TWIST1

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Middelkamp, S., van Heesch, S. A. A. C., Braat, K., de Ligt, J., van Iterson, M., Simonis, M., van Roosmalen, M. J., Kelder, M. J. E., Kruisselbrink, E., Hochstenbach, R., Verbeek, N., Ippel, E., Adolfs, Y., Pasterkamp, R. J., Kloosterman, W. P., Kuijk, E. W., & Cuppen, E. (2017). Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells. Genome Medicine, 9(1), Article 9. https://doi.org/10.1186/s13073-017-0399-z

@article{71887c66b4464c86970e6c35e88a8b16,

title = "Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells",

abstract = "Background: Germline chromothripsis causes complex genomic rearrangements that are likely to affect multiple genes and their regulatory contexts. The contribution of individual rearrangements and affected genes to the phenotypes of patients with complex germline genomic rearrangements is generally unknown. Methods: To dissect the impact of germline chromothripsis in a relevant developmental context, we performed trio-based RNA expression analysis on blood cells, induced pluripotent stem cells (iPSCs), and iPSC-derived neuronal cells from a patient with de novo germline chromothripsis and both healthy parents. In addition, Hi-C and 4C-seq experiments were performed to determine the effects of the genomic rearrangements on transcription regulation of genes in the proximity of the breakpoint junctions. Results: Sixty-seven genes are located within 1 Mb of the complex chromothripsis rearrangements involving 17 breakpoints on four chromosomes. We find that three of these genes (FOXP1, DPYD, and TWIST1) are both associated with developmental disorders and differentially expressed in the patient. Interestingly, the effect on TWIST1 expression was exclusively detectable in the patient's iPSC-derived neuronal cells, stressing the need for studying developmental disorders in the biologically relevant context. Chromosome conformation capture analyses show that TWIST1 lost genomic interactions with several enhancers due to the chromothripsis event, which likely led to deregulation of TWIST1 expression and contributed to the patient's craniosynostosis phenotype. Conclusions: We demonstrate that a combination of patient-derived iPSC differentiation and trio-based molecular profiling is a powerful approach to improve the interpretation of pathogenic complex genomic rearrangements. Here we have applied this approach to identify misexpression of TWIST1, FOXP1, and DPYD as key contributors to the complex congenital phenotype resulting from germline chromothripsis rearrangements.",

keywords = "Chromosome conformation capture, Chromothripsis, Complex genomic rearrangements, Congenital disorders, Craniosynostosis, Induced pluripotent stem cells, Neuronal differentiation, Personal genomics, RNA-sequencing, TWIST1",

author = "Sjors Middelkamp and {van Heesch}, S.A.A.C. and Koen Braat and {de Ligt}, J and {van Iterson}, Maarten and Marieke Simonis and {van Roosmalen}, {Markus J.} and Kelder, {Martijn J E} and Evelien Kruisselbrink and Ron Hochstenbach and Nienke Verbeek and Elly Ippel and Y. Adolfs and Pasterkamp, {R. Jeroen} and Kloosterman, {Wigard P.} and Kuijk, {Ewart W.} and Edwin Cuppen",

note = "Funding Information: This work was financially supported by a Vici grant (865.13.004) from the Netherlands Science Foundation (NWO) to EC. Publisher Copyright: {\textcopyright} 2017 The Author(s).",

year = "2017",

month = jan,

day = "26",

doi = "10.1186/s13073-017-0399-z",

language = "English",

volume = "9",

journal = "Genome Medicine",

issn = "1756-994x",

publisher = "BioMed Central",

number = "1",

}

Middelkamp, S, van Heesch, SAAC, Braat, K, de Ligt, J, van Iterson, M, Simonis, M, van Roosmalen, MJ, Kelder, MJE, Kruisselbrink, E, Hochstenbach, R, Verbeek, N, Ippel, E, Adolfs, Y, Pasterkamp, RJ, Kloosterman, WP, Kuijk, EW & Cuppen, E 2017, 'Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells', Genome Medicine, vol. 9, no. 1, 9. https://doi.org/10.1186/s13073-017-0399-z

TY - JOUR

T1 - Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells

AU - Middelkamp, Sjors

AU - van Heesch, S.A.A.C.

AU - Braat, Koen

AU - de Ligt, J

AU - van Iterson, Maarten

AU - Simonis, Marieke

AU - van Roosmalen, Markus J.

AU - Kelder, Martijn J E

AU - Kruisselbrink, Evelien

AU - Hochstenbach, Ron

AU - Verbeek, Nienke

AU - Ippel, Elly

AU - Adolfs, Y.

AU - Pasterkamp, R. Jeroen

AU - Kloosterman, Wigard P.

AU - Kuijk, Ewart W.

AU - Cuppen, Edwin

PY - 2017/1/26

Y1 - 2017/1/26

N2 - Background: Germline chromothripsis causes complex genomic rearrangements that are likely to affect multiple genes and their regulatory contexts. The contribution of individual rearrangements and affected genes to the phenotypes of patients with complex germline genomic rearrangements is generally unknown. Methods: To dissect the impact of germline chromothripsis in a relevant developmental context, we performed trio-based RNA expression analysis on blood cells, induced pluripotent stem cells (iPSCs), and iPSC-derived neuronal cells from a patient with de novo germline chromothripsis and both healthy parents. In addition, Hi-C and 4C-seq experiments were performed to determine the effects of the genomic rearrangements on transcription regulation of genes in the proximity of the breakpoint junctions. Results: Sixty-seven genes are located within 1 Mb of the complex chromothripsis rearrangements involving 17 breakpoints on four chromosomes. We find that three of these genes (FOXP1, DPYD, and TWIST1) are both associated with developmental disorders and differentially expressed in the patient. Interestingly, the effect on TWIST1 expression was exclusively detectable in the patient's iPSC-derived neuronal cells, stressing the need for studying developmental disorders in the biologically relevant context. Chromosome conformation capture analyses show that TWIST1 lost genomic interactions with several enhancers due to the chromothripsis event, which likely led to deregulation of TWIST1 expression and contributed to the patient's craniosynostosis phenotype. Conclusions: We demonstrate that a combination of patient-derived iPSC differentiation and trio-based molecular profiling is a powerful approach to improve the interpretation of pathogenic complex genomic rearrangements. Here we have applied this approach to identify misexpression of TWIST1, FOXP1, and DPYD as key contributors to the complex congenital phenotype resulting from germline chromothripsis rearrangements.

AB - Background: Germline chromothripsis causes complex genomic rearrangements that are likely to affect multiple genes and their regulatory contexts. The contribution of individual rearrangements and affected genes to the phenotypes of patients with complex germline genomic rearrangements is generally unknown. Methods: To dissect the impact of germline chromothripsis in a relevant developmental context, we performed trio-based RNA expression analysis on blood cells, induced pluripotent stem cells (iPSCs), and iPSC-derived neuronal cells from a patient with de novo germline chromothripsis and both healthy parents. In addition, Hi-C and 4C-seq experiments were performed to determine the effects of the genomic rearrangements on transcription regulation of genes in the proximity of the breakpoint junctions. Results: Sixty-seven genes are located within 1 Mb of the complex chromothripsis rearrangements involving 17 breakpoints on four chromosomes. We find that three of these genes (FOXP1, DPYD, and TWIST1) are both associated with developmental disorders and differentially expressed in the patient. Interestingly, the effect on TWIST1 expression was exclusively detectable in the patient's iPSC-derived neuronal cells, stressing the need for studying developmental disorders in the biologically relevant context. Chromosome conformation capture analyses show that TWIST1 lost genomic interactions with several enhancers due to the chromothripsis event, which likely led to deregulation of TWIST1 expression and contributed to the patient's craniosynostosis phenotype. Conclusions: We demonstrate that a combination of patient-derived iPSC differentiation and trio-based molecular profiling is a powerful approach to improve the interpretation of pathogenic complex genomic rearrangements. Here we have applied this approach to identify misexpression of TWIST1, FOXP1, and DPYD as key contributors to the complex congenital phenotype resulting from germline chromothripsis rearrangements.

KW - Chromosome conformation capture

KW - Chromothripsis

KW - Complex genomic rearrangements

KW - Congenital disorders

KW - Craniosynostosis

KW - Induced pluripotent stem cells

KW - Neuronal differentiation

KW - Personal genomics

KW - RNA-sequencing

KW - TWIST1

UR - http://www.scopus.com/inward/record.url?scp=85011031947&partnerID=8YFLogxK

U2 - 10.1186/s13073-017-0399-z

DO - 10.1186/s13073-017-0399-z

M3 - Article

C2 - 28126037

AN - SCOPUS:85011031947

SN - 1756-994x

VL - 9

JO - Genome Medicine

JF - Genome Medicine

IS - 1

M1 - 9

ER -

Molecular dissection of germline chromothripsis in a developmental context using patient-derived iPS cells

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