Differentiation imbalance in single oesophageal progenitor cells causes clonal immortalization and field change
Differentiation imbalance in single oesophageal progenitor cells causes clonal immortalization and field change
Multiple cancers may arise from within a clonal region of preneoplastic epithelium, a phenomenon termed ‘field change’. However, it is not known how field change develops. Here we investigate this question using lineage tracing to track the behaviour of scattered single oesophageal epithelial progenitor cells expressing a mutation that inhibits the Notch signalling pathway. Notch is frequently subject to inactivating mutation in squamous cancers3–6. Quantitative analysis reveals that cell divisions that produce two differentiated daughters are absent from mutant progenitors. As a result, mutant clones are no longer lost by differentiation and become functionally immortal. Furthermore, mutant cells promote the differentiation of neighbouring wild-type cells, which are then lost from the tissue. These effects lead to clonal expansion, with mutant cells eventually replacing the entire epithelium. Notch inhibition in progenitors carrying p53 stabilizing mutations creates large confluent regions of doubly mutant epithelium. Field change is thus a consequence of imbalanced differentiation in individual progenitor cells.
612-619
Alcolea, Maria P.
710c4b43-40e3-4a9e-adfe-0f65a76fd978
Greulich, Philip
65da32ad-a73a-435a-86e0-e171437430a9
Wabik, Agnieska
e51effe3-183b-4bef-a0c2-adf8c4408736
Frede, Julia
45a1abf2-49bc-4301-9bf2-39798fdb8dc1
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
Jones, Philip H.
f263e68c-4612-4e26-884c-0ff65f824611
2014
Alcolea, Maria P.
710c4b43-40e3-4a9e-adfe-0f65a76fd978
Greulich, Philip
65da32ad-a73a-435a-86e0-e171437430a9
Wabik, Agnieska
e51effe3-183b-4bef-a0c2-adf8c4408736
Frede, Julia
45a1abf2-49bc-4301-9bf2-39798fdb8dc1
Simons, Benjamin D.
02e0ea52-9b7f-4b80-a856-a22cc1991ba3
Jones, Philip H.
f263e68c-4612-4e26-884c-0ff65f824611
Alcolea, Maria P., Greulich, Philip, Wabik, Agnieska, Frede, Julia, Simons, Benjamin D. and Jones, Philip H.
(2014)
Differentiation imbalance in single oesophageal progenitor cells causes clonal immortalization and field change.
Nature Cell Biology, 16, .
(doi:10.1038/ncb2963).
Abstract
Multiple cancers may arise from within a clonal region of preneoplastic epithelium, a phenomenon termed ‘field change’. However, it is not known how field change develops. Here we investigate this question using lineage tracing to track the behaviour of scattered single oesophageal epithelial progenitor cells expressing a mutation that inhibits the Notch signalling pathway. Notch is frequently subject to inactivating mutation in squamous cancers3–6. Quantitative analysis reveals that cell divisions that produce two differentiated daughters are absent from mutant progenitors. As a result, mutant clones are no longer lost by differentiation and become functionally immortal. Furthermore, mutant cells promote the differentiation of neighbouring wild-type cells, which are then lost from the tissue. These effects lead to clonal expansion, with mutant cells eventually replacing the entire epithelium. Notch inhibition in progenitors carrying p53 stabilizing mutations creates large confluent regions of doubly mutant epithelium. Field change is thus a consequence of imbalanced differentiation in individual progenitor cells.
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Accepted/In Press date: 4 April 2014
e-pub ahead of print date: 11 May 2014
Published date: 2014
Organisations:
Applied Mathematics
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Local EPrints ID: 408815
URI: http://eprints.soton.ac.uk/id/eprint/408815
ISSN: 1465-7392
PURE UUID: 280bdf37-fd39-48a1-93f7-9e6384e3d1fb
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Date deposited: 28 May 2017 04:01
Last modified: 16 Mar 2024 04:17
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Author:
Maria P. Alcolea
Author:
Agnieska Wabik
Author:
Julia Frede
Author:
Benjamin D. Simons
Author:
Philip H. Jones
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