Lifelong multilineage contribution by embryonic-born blood progenitors
Sachin PatelConstantina ChristodoulouCaleb WeinrebQi YuEdroaldo Lummertz da RochaBrian J. Pepe-MooneySarah BowlingLi LiFernando G. OsorioGeorge Q. DaleyFernando D. Camargo
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Abstract Neural progenitor cells must be maintained during development in order to produce the full complement of neuronal and glial derivatives. While molecular pathways have been identified that inhibit progenitor differentiation, it is unclear whether the progenitor state itself is actively maintained. In this study, we have investigated the role of Tcf7l1 (formerly named Tcf3) in maintaining spinal progenitor characteristics and allowing the continued production of neurons and glia following primary neurogenesis. We find that spinal cord progenitor markers are progressively lost in embryos lacking Tcf7l1, and that the number of proliferative progenitors decreases accordingly. Furthermore, we show that the production of both neuronal and glial secondary derivatives of the pMN progenitor pool requires Tcf7l1. Together, these results indicate that Tcf7l1 plays an important role in spinal cord progenitor maintenance, indicating that this core function is conserved throughout multiple epithelial cell populations. Developmental Dynamics 240:2256–2264, 2011. © 2011 Wiley‐Liss, Inc.
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Summary The expansion of the neocortex during mammalian evolution has been linked to an enlargement of the subventricular zone during cortical development and an increase in the proliferation of the basal progenitors residing therein. Here, we explored a potential role of YAP, the major downstream effector of the Hippo signaling pathway, in proliferation of basal progenitors. We show that YAP expression and activity are high in ferret and human basal progenitors, which are known to exhibit high proliferative capacity, but low in mouse basal progenitors, which lack such capacity. To induce YAP activity in mouse basal progenitors, we expressed a constitutively active YAP (CA-YAP). This resulted in an increase in proliferation of basal progenitor. In addition, CA-YAP expressing mouse basal progenitors promoted the production of upper-layer neurons. To investigate if YAP is required for the proliferation of basal progenitors, we pharmacologically interfered with the function of YAP in the developing ferret and human neocortex. This resulted in a decrease of cycling basal progenitors. In concert, genetical interference with the function of YAP in ferret developing neocortex resulted in decreased abundance of basal progenitors. Together, our data indicate that YAP promotes the proliferation of basal progenitors and suggest that changes in YAP activity levels contributed to the evolutionary expansion of the neocortex.
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Neocortex expansion during mammalian evolution has been linked to an increase in proliferation of basal progenitors in the subventricular zone. Here, we explored a potential role of YAP, the major downstream effector of the Hippo pathway, in proliferation of basal progenitors. YAP expression and activity are high in ferret and human basal progenitors, which exhibit high proliferative capacity, but low in mouse basal progenitors, which lack such capacity. Conditional expression of a constitutively active YAP in mouse basal progenitors resulted in increased proliferation of basal progenitor and promoted production of upper-layer neurons. Pharmacological and genetic interference with YAP function in ferret and human developing neocortex resulted in decreased abundance of cycling basal progenitors. Together, our data indicate that YAP is necessary and sufficient to promote the proliferation of basal progenitors and suggest that increases in YAP levels and presumably activity contributed to the evolutionary expansion of the neocortex.
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Past studies of pancreatic progenitor cell biology relied mostly on histological analyses. Recent studies, using genetic labeling and tracing of progenitors, direct single cell analyses, colony assays, and enrichment of the minor population of progenitor cells through the use of cell surface markers, have strongly suggested that pancreatic progenitor cells with various frequency and lineage potentials, including the multipotent progenitors that give rise to endocrine, exocrine, and duct cells, exist in the developing and adult pancreas. In this review, it is therefore proposed that pancreatic progenitor cells may be organized in a hierarchy, in which the most primitive pan-pancreatic multipotent progenitors are at the top and rare, and the monopotent progenitors are at the bottom and abundant. This model may explain why only drastic injuries lead to effective activation of the progenitor cell compartment of the higher hierarchy, whereas under steady state, pregnancy, and milder injuries, recruitment of preexisting mature cells or their immediate monopotent progenitors could be sufficient to restore metabolic homeostasis. It is also proposed that the morphologically defined ductal cells are likely to be functionally heterogeneous and that endocrine progenitor cell activity should be determined based on functional analyses rather than histological locations.
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Intermediate progenitor cells constitute a second proliferative cell type in the developing mammalian cerebral cortex. Little is known about the factors that govern the production of intermediate progenitors. Although persistent expression of stabilized β-catenin was found to delay the maturation of radial glial progenitors into intermediate progenitors, the relationship between β-catenin signaling and intermediate progenitors remains poorly understood. Using a transgenic reporter mouse for Axin2, a direct target of Wnt/β-catenin signaling, we observed that β-catenin signaling is decreased in intermediate progenitor cells relative to radial glial progenitors. Conditional deletion of β-catenin from mouse cortical neural progenitors increased intermediate progenitor numbers, while conditional expression of stabilized β-catenin reduced the intermediate progenitor population. Together, these findings provide evidence that β-catenin signaling in radial progenitors negatively regulates intermediate progenitor cell number during cortical development.
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The adult human heart is unable to regenerate after various forms of injury, suggesting that this organ lacks a biologically meaningful endogenous stem cell pool. However, injecting the infarcted area of the adult mammalian heart with exogenously prepared progenitor cells of various types has been reported to create new myocardium by the direct conversion of these progenitor cells into cardiomyocytes. These reports remain controversial because follow-up studies from independent laboratories failed to observe such an effect. Also, the exact nature of various putative myocyte-producing progenitor cells remains elusive and undefined across laboratories. By comparison, the field has gradually worked toward a consensus viewpoint that proposes that the adult mammalian myocardium can undergo a low level of new cardiomyocyte renewal of ≈1% per year, which is primarily because of proliferation of existing cardiomyocytes but not from the differentiation of putative progenitor cells. This review will weigh the emerging evidence, suggesting that the adult mammalian heart lacks a definable myocyte-generating progenitor cell of biological significance.
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Development requires tissue growth as well as cell diversification. To address how these processes are coordinated, we analyzed the development of molecularly distinct domains of neural progenitors in the mouse and chick neural tube. We show that during development, these domains undergo changes in size that do not scale with changes in overall tissue size. Our data show that domain proportions are first established by opposing morphogen gradients and subsequently controlled by domain-specific regulation of differentiation rate but not differences in proliferation rate. Regulation of differentiation rate is key to maintaining domain proportions while accommodating both intra- and interspecies variations in size. Thus, the sequential control of progenitor specification and differentiation elaborates pattern without requiring that signaling gradients grow as tissues expand.
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