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Regulatory Mechanisms in Stem Cell Biology

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Presentation on theme: "Regulatory Mechanisms in Stem Cell Biology"— Presentation transcript:

1 Regulatory Mechanisms in Stem Cell Biology
Sean J Morrison, Nirao M Shah, David J Anderson  Cell  Volume 88, Issue 3, Pages (February 1997) DOI: /S (00)81867-X

2 Figure 1 Possible Patterns of Cell Division in Stem Cell Lineages
“S” indicates stem cell; “P” indicates a committed or restricted progenitor cell. (A) All divisions are obligatorily asymmetric and controlled by a cell-intrinsic mechanism. Note that no amplification of the size of the stem cell population is possible in this type of lineage. (B) A population of four stem cells is shown in which all divisions are symmetric, but half the time are self-renewing. The steady-state behavior of this population is indistinguishable from that of a population of stem cells like that shown in (A). However, the probabilities of self-renewing versus differentiative divisions could in principle be different than 0.5 (seePotten and Loeffler 1990, for further discussion). (C) A lineage in which individual stem cell divisions are asymmetric with respect to daughter cell fate, but not intrinsically so, as in (A). The daughters behave differently owing to different local environments (shaded ovals). Examples of all of the patterns in (A)–(C) are found in nature, including combinations of (B) and (C). Cell  , DOI: ( /S (00)81867-X)

3 Figure 2 The Difference Between Selective and Instructive Mechanisms of Growth Factor Influences on Stem Cell Fate Decisions (A and B) Selective mechanism in which two different factors (F1 and F2) allow the survival and maturation of lineage-committed progenitors generated by a cell-autonomous mechanism; “X” indicates death of the other progenitors. Erythryopoietin appears to work in this manner (Wu et al. 1995). (C and D) Instructive mechanism in which the factors cause the stem cell to adopt one fate at the expense of others. Glial growth factor and BMP2 appear to work in this manner on neural crest cells (Shah et al. 1994; Shah et al. 1996). Cell  , DOI: ( /S (00)81867-X)

4 Figure 3 Phylogenetic Variation in the Control of a Binary Cell Fate Decision in Nematodes In each case (A–E), a choice between ventral uterine (VU) and gonadal anchor cell (AC) fates is made by adjacent precursors (called “Z1.ppp” and “Z4.aaa”). In C. elegans (A), the decision is stochastic with a 50:50 probability and nonautonomously controlled by lateral signaling. In Acrobeloides (B), lateral signaling exerts a partial bias on a stochastic decision, so that the probability is about 80:20. In Cephalobus (C), the decision is deterministic yet nonautonomously controlled, while in Panagrolaimus PS1732 (E) it is both deterministic and autonomously controlled. (D) represents an intermediate case between (C) and (E) where the decision is deterministic, but displays autonomy only some of the time in laser-ablation experiments. Although the precursor cells involved do not meet our criteria for a stem cell, they illustrate how the same cell fate decision can be either stochastic or deterministic and controlled by autonomous or nonautonomous mechanisms. Reprinted with permission (fromFelix and Sternberg 1996). Cell  , DOI: ( /S (00)81867-X)

5 Figure 4 Alternative Modes of Differentiation by Multipotent Stem Cells In each panel, two equivalent stem cells in a population are shown. In a “direct” mode (A and B), the immediate progeny of stem cell divisions are committed to a single fate. This mode frequently operates in invertebrates. In an “indirect” mode (C and D), stem cell progeny are partially restricted to a subset of potential fates. This mode operates in hematopoiesis. In either case, the segregation of different lineages can exhibit no perceptible order or pattern (“stochastic;” A and C), or can occur according to a defined sequence or hierarchy (“deterministic;” B and D). For convenience, all examples are shown with asymmetric stem cell divisions; however, symmetrically dividing stem cells could operate with each mode as well. Furthermore, hierarchical restrictions, as shown in (B) and (D), could occur by progressive loss of developmental potentials from partially restricted intermediates, rather than by sequential production from a self-renewing stem cell. Finally, all four modes could be controlled either cell-autonomously or nonautonomously. (For an example of a stochastic decision that is nonautonomously controlled, see Figure 3A and Figure 3B.) Cell  , DOI: ( /S (00)81867-X)

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