Staying alive

Valcourt, James R.; Lemons, Johanna M. S.; Haley, Erin M.; Kojima, Mina; Demuren, Olukunle O.; Coller, Hilary A.

doi:10.4161/cc.19879

Cited by 195 publications

(146 citation statements)

References 278 publications

(354 reference statements)

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“…This non-dividing state is induced when yeast exhausts nutrients from the media and involves a marked downregulation in metabolism, histone acetylation, and transcriptional output. Interestingly, quiescence in yeast as in B cells relies on PI3K and TOR signaling (Valcourt et al, 2012). The immune system therefore appears to activate naïve lymphocytes through an ancient regulatory pathway.…”

Section: Discussionmentioning

confidence: 99%

Myc Regulates Chromatin Decompaction and Nuclear Architecture during B Cell Activation

et al. 2017

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50 years ago, Vincent Allfrey and colleagues discovered that lymphocyte activation triggers massive acetylation of chromatin. However, the molecular mechanisms driving epigenetic accessibility are still unknown. We here show that stimulated lymphocytes decondense chromatin by three differentially-regulated steps. First, chromatin is repositioned away from the nuclear periphery in response to global acetylation. Second, histone nanodomain clusters decompact into mononucleosome fibers through a mechanism that requires Myc and continual energy input. Single-molecule imaging shows that this step lowers transcription factor residence time and non-specific collisions during sampling for DNA targets. Third, chromatin interactions shift from long-range to predominantly short-range, and CTCF-mediated loops and contact domains double in numbers. This architectural change facilitates cognate promoter-enhancer contacts and also requires Myc and continual ATP production. Our results thus define the nature and transcriptional impact of chromatin decondensation and reveal an unexpected role for Myc in the establishment of nuclear topology in mammalian cells.

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Section: Discussionmentioning

confidence: 99%

Myc Regulates Chromatin Decompaction and Nuclear Architecture during B Cell Activation

et al. 2017

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“…Quiescent cells are particularly hardy and able to survive long periods of nutrient starvation; entry into quiescence is often associated with metabolic changes (reviewed in ref. 60). While proliferating cells devote much of their metabolic capacity to biosynthesis in order to create the material necessary to form a new cell, quiescent cells are relieved of this expensive metabolic requirement.…”

Section: Role Of Autophagy In Hematopoietic Stem Cellsmentioning

confidence: 99%

Autophagy in stem cells

et al. 2013

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Autophagy is a highly conserved cellular process by which cytoplasmic components are sequestered in autophagosomes and delivered to lysosomes for degradation. As a major intracellular degradation and recycling pathway, autophagy is crucial for maintaining cellular homeostasis as well as remodeling during normal development, and dysfunctions in autophagy have been associated with a variety of pathologies including cancer, inflammatory bowel disease and neurodegenerative disease. Stem cells are unique in their ability to self-renew and differentiate into various cells in the body, which are important in development, tissue renewal and a range of disease processes. Therefore, it is predicted that autophagy would be crucial for the quality control mechanisms and maintenance of cellular homeostasis in various stem cells given their relatively long life in the organisms. in contrast to the extensive body of knowledge available for somatic cells, the role of autophagy in the maintenance and function of stem cells is only beginning to be revealed as a result of recent studies. Here we provide a comprehensive review of the current understanding of the mechanisms and regulation of autophagy in embryonic stem cells, several tissue stem cells (particularly hematopoietic stem cells), as well as a number of cancer stem cells. we discuss how recent studies of different knockout mice models have defined the roles of various autophagy genes and related pathways in the regulation of the maintenance, expansion and differentiation of various stem cells. we also highlight the many unanswered questions that will help to drive further research at the intersection of autophagy and stem cell biology in the near future.

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“…Cellular activities such as those of the FOXO [106,107] and ATM-BID [108] pathways protect quiescent cells from the oxidative stress caused by the accumulation of reactive oxygen species (ROS); depletion of these cellular activities leads to quiescence exit in HSCs and an increase in their proliferation and apoptosis. Quiescent cells often exhibit low metabolic activities characterized by a decrease in glucose uptake and glycolysis, reduced translation rates, as well as reduced PI3K and mTOR pathway activities [9]. The PI3K-Akt pathway crosstalks with the Rb-E2F pathway by inhibiting p21 activity through phosphorylation [109,110].…”

Section: Stress and Metabolic Response Pathwaysmentioning

confidence: 99%

Modelling mammalian cellular quiescence

2014

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One contribution of 10 to a Theme Issue 'Computational cell biology: from the past to the future'. Cellular quiescence is a reversible non-proliferating state. The reactivation of 'sleep-like' quiescent cells (e.g. fibroblasts, lymphocytes and stem cells) into proliferation is crucial for tissue repair and regeneration and a key to the growth, development and health of higher multicellular organisms, such as mammals. Quiescence has been a primarily phenotypic description (i.e. non-permanent cell cycle arrest) and poorly studied. However, contrary to the earlier thinking that quiescence is simply a passive and dormant state lacking proliferating activities, recent studies have revealed that cellular quiescence is actively maintained in the cell and that it corresponds to a collection of heterogeneous states. Recent modelling and experimental work have suggested that an Rb-E2F bistable switch plays a pivotal role in controlling the quiescence-proliferation balance and the heterogeneous quiescent states. Other quiescence regulatory activities may crosstalk with and impinge upon the Rb-E2F bistable switch, forming a gene network that controls the cells' quiescent states and their dynamic transitions to proliferation in response to noisy environmental signals. Elucidating the dynamic control mechanisms underlying quiescence may lead to novel therapeutic strategies that re-establish normal quiescent states, in a variety of hyper-and hypo-proliferative diseases, including cancer and ageing.

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Staying alive

Cited by 195 publications

References 278 publications

Myc Regulates Chromatin Decompaction and Nuclear Architecture during B Cell Activation

Myc Regulates Chromatin Decompaction and Nuclear Architecture during B Cell Activation

Autophagy in stem cells

Modelling mammalian cellular quiescence

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