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Open Access 01-12-2017 | Research

Exome sequencing characterizes the somatic mutation spectrum of early serrated lesions in a patient with serrated polyposis syndrome (SPS)

Authors: Sukanya Horpaopan, Jutta Kirfel, Sophia Peters, Michael Kloth, Robert Hüneburg, Janine Altmüller, Dmitriy Drichel, Margarete Odenthal, Glen Kristiansen, Christian Strassburg, Jacob Nattermann, Per Hoffmann, Peter Nürnberg, Reinhard Büttner, Holger Thiele, Philip Kahl, Isabel Spier, Stefan Aretz

Published in: Hereditary Cancer in Clinical Practice | Issue 1/2017

Abstract

Background

Serrated or Hyperplastic Polyposis Syndrome (SPS, HPS) is a yet poorly defined colorectal cancer (CRC) predisposition characterised by the occurrence of multiple and/or large serrated polyps throughout the colon. A serrated polyp-CRC sequence (serrated pathway) of CRC formation has been postulated, however, to date only few molecular signatures of serrated neoplasia (BRAF, KRAS, RNF43 mutations, CpG Island Methylation, MSI) have been described in a subset of SPS patients and neither the etiology of the syndrome nor the distinct genetic alterations during tumorigenesis have been identified.

Methods

To identify somatic point mutations in potential novel candidate genes of SPS-associated lesions and the involved pathways we performed exome sequencing of eleven early serrated polyps obtained from a 41 year-old female patient with clinically confirmed SPS. For data filtering and analysis, standard pipelines were used. Somatic mutations were identified by comparison with leukocyte DNA and were validated by Sanger sequencing.

Results

The BRAF p.V600E or KRAS p.G12D mutation was identified in six polyps (~50%) and not found in polyps from the distal colon. In addition, we found seven unique rare somatic alterations of seven different genes in four serrated tumours, all of which are missense variants. The variant in ABI3BP and CATSPERB are predicted to be deleterious. No established cancer gene or candidate genes related to serrated tumorigenesis were affected.

Conclusions

Somatic mutations seem to be rare events in early hyperplastic and serrated lesions of SPS patients. Neither frequently affected genes nor enrichment of specific pathways were observed. Thus, other alterations such as non-coding variants or epigenetic changes might be the major driving force of tumour progression in SPS.

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Title: Exome sequencing characterizes the somatic mutation spectrum of early serrated lesions in a patient with serrated polyposis syndrome (SPS)
Authors: Sukanya Horpaopan
Jutta Kirfel
Sophia Peters
Michael Kloth
Robert Hüneburg
Janine Altmüller
Dmitriy Drichel
Margarete Odenthal
Glen Kristiansen
Christian Strassburg
Jacob Nattermann
Per Hoffmann
Peter Nürnberg
Reinhard Büttner
Holger Thiele
Philip Kahl
Isabel Spier
Stefan Aretz
Publication date: 01-12-2017
Publisher: BioMed Central
Published in: Hereditary Cancer in Clinical Practice / Issue 1/2017
Electronic ISSN: 1897-4287
DOI: https://doi.org/10.1186/s13053-017-0082-9

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