TY - JOUR
T1 - Reconstruction of cell lineage trees in mice
AU - Wasserstrom, Adam
AU - Adar, Rivka
AU - Shefer, Gabi
AU - Frumkin, Dan
AU - Itzkovitz, Shalev
AU - Stern, Tomer
AU - Shur, Irena
AU - Zangi, Lior
AU - Kaplan, Shai
AU - Harmelin, Alon
AU - Reisner, Yair
AU - Benayahu, Dafna
AU - Tzahor, Eldad
AU - Segal, Eran
AU - Shapiro, Ehud
PY - 2008/4/9
Y1 - 2008/4/9
N2 - The cell lineage tree of a multicellular organism represents its history of cell divisions from the very first cell, the zygote. A new method for high-resolution reconstruction of parts of such cell lineage trees was recently developed based on phylogenetic analysis of somatic mutations accumulated during normal development of an organism. In this study we apply this method in mice to reconstruct the lineage trees of distinct cell types. We adress for the first time basic questions in developmental biology of higher organisms, namely what is the correlation between the lineage relation among cells and their (1) function, (2) physical proximity and (3) anatomical proximity. We analyzed B-cells, kidney-, mesenchymal- and hematopoietic-stem cells, as well as satellite cells, which are adult skeletal muscle stem cells isolated from their niche on the muscle fibers (myofibers) from various skeletal muscles. Our results demonstrate that all analyzed cell types are intermingled in the lineage tree, indicating that none of these cell types are single exclusive clones. We also show a significant correlation between the physical proximity of satellite cells within muscles and their lineage. Furthermore, we show that satellite cells obtained from a single myofiber are significantly clustered in the lineage tree, reflecting their common developmental origin. Lineage analysis based on somatic mutations enables performing high resolution reconstruction of lineage trees in mice and humans, which can provide fundamental insights to many aspects of their development and tissue maintenance.
AB - The cell lineage tree of a multicellular organism represents its history of cell divisions from the very first cell, the zygote. A new method for high-resolution reconstruction of parts of such cell lineage trees was recently developed based on phylogenetic analysis of somatic mutations accumulated during normal development of an organism. In this study we apply this method in mice to reconstruct the lineage trees of distinct cell types. We adress for the first time basic questions in developmental biology of higher organisms, namely what is the correlation between the lineage relation among cells and their (1) function, (2) physical proximity and (3) anatomical proximity. We analyzed B-cells, kidney-, mesenchymal- and hematopoietic-stem cells, as well as satellite cells, which are adult skeletal muscle stem cells isolated from their niche on the muscle fibers (myofibers) from various skeletal muscles. Our results demonstrate that all analyzed cell types are intermingled in the lineage tree, indicating that none of these cell types are single exclusive clones. We also show a significant correlation between the physical proximity of satellite cells within muscles and their lineage. Furthermore, we show that satellite cells obtained from a single myofiber are significantly clustered in the lineage tree, reflecting their common developmental origin. Lineage analysis based on somatic mutations enables performing high resolution reconstruction of lineage trees in mice and humans, which can provide fundamental insights to many aspects of their development and tissue maintenance.
UR - http://www.scopus.com/inward/record.url?scp=44849092648&partnerID=8YFLogxK
U2 - 10.1371/journal.pone.0001939
DO - 10.1371/journal.pone.0001939
M3 - Article
C2 - 18398465
AN - SCOPUS:44849092648
SN - 1932-6203
VL - 3
JO - PLoS ONE
JF - PLoS ONE
IS - 4
M1 - e1939
ER -