Mitochondrial DNA mutations are established in human colonic stem cells, and mutated clones expand by crypt fission
Author(s) -
Laura C. Greaves,
Sean Preston,
Paul Tadrous,
Robert W. Taylor,
Martin Barron,
Dahmane Oukrif,
Simon J. Leedham,
Maesha Deheragoda,
Peter Sasieni,
Marco Novelli,
Janusz Jankowski,
Douglass M. Turnbull,
Nicholas A. Wright,
Stuart A.C. McDonald
Publication year - 2006
Publication title -
proceedings of the national academy of sciences
Language(s) - English
Resource type - Journals
SCImago Journal Rank - 5.011
H-Index - 771
eISSN - 1091-6490
pISSN - 0027-8424
DOI - 10.1073/pnas.0505903103
Subject(s) - crypt , biology , mitochondrial dna , cytochrome c oxidase , genetics , microbiology and biotechnology , stem cell , mitochondrial fission , mitochondrion , gene , endocrinology
The understanding of the fixation of mutations within human tissues and their subsequent clonal expansion is a considerable problem, of which little is known. We have previously shown that nononcogenic mutations in the mitochondrial genome occur in one of a number of morphologically normal colonic crypt stem cells, the progeny of which later occupy the whole crypt. We propose that these wholly mutated crypts then clonally expand by crypt fission, where each crypt divides into two mutated daughter crypts. Here we show that (i) mutated crypts in the process of fission share the same mutated mitochondrial genotype not present in neighboring cytochrome c oxidase-positive crypts (the odds of this being a random event are >or=2.48 x 10(9):1); (ii) neighboring mutated crypts have the same genotype, which is different from adjacent cytochrome c oxidase-positive crypts; (iii) mutated crypts are clustered together throughout the colon; and (iv) patches of cytochrome c oxidase-deficient crypts increase in size with age. We thus demonstrate definitively that crypt fission is the mechanism by which mutations spread in the normal human colon. This has important implications for the biology of the normal adult human colon and possibly for the growth and spread of colorectal neoplasms.
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