Novel Insights into Embryonic Stem Cell Self‐Renewal Revealed Through Comparative Human and Mouse Systems Biology Networks

Dowell, Karen G.; Simons, Allen K.; Bai, Hao; Kell, Braden; Wang, Zack Z.; Yun, Kyuson; Hibbs, Matthew A.

doi:10.1002/stem.1612

Cited by 16 publications

(18 citation statements)

References 79 publications

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“…Live cell imaging and single cell RNA-seq methods have recently revealed unexpected heterogeneity of the TF network associated with pluripotency (Filipczyk et al, 2015, Kolodziejczyk et al, 2015), suggesting we still do not fully understand this TF network state. Consistent with this, several pluripotency TF network models recently built from detailed knowledge of the key TFs regulating pluripotency (Xu et al, 2014, Dunn et al, 2014, Dowell et al, 2014) were unable to fully predict cellular behavior.…”

Section: Introductionmentioning

confidence: 94%

“…To date, most network models are relatively simple, often consisting of simple diagrams of TF sub-networks annotated with nodes and edges. However, Boolean (Xu et al, 2014, Dunn et al, 2014, Moignard et al, 2015) and Bayesian (Dowell et al, 2014) modeling approaches have been built from such information to provide dynamic and executable network models. PetriNets, a mathematical modeling approach to graphically model networks, have also been successfully used to computationally encode TF networks (Bonzanni et al, 2013).…”

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Mammalian Transcription Factor Networks: Recent Advances in Interrogating Biological Complexity

2017

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Transcription factor (TF) networks are a key determinant of cell fate decisions in mammalian development and adult tissue homeostasis, and are frequently corrupted in disease. However, our inability to experimentally resolve and interrogate the complexity of mammalian TF networks has hampered the progress in this field. Recent technological advances, in particular large-scale genome-wide approaches, single-cell methodologies, live-cell imaging, and genome editing, are emerging as important technologies in TF network biology. Several recent studies even suggest a need to re-evaluate established models of mammalian TF networks. Here, we provide a brief overview of current and emerging methods to define mammalian TF networks. We also discuss how these emerging technologies facilitate new ways to interrogate complex TF networks, consider the current open questions in the field, and comment on potential future directions and biomedical applications.

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Section: Introductionmentioning

confidence: 94%

Section: Introductionmentioning

confidence: 99%

Mammalian Transcription Factor Networks: Recent Advances in Interrogating Biological Complexity

2017

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“…Regulation of stem cell pluripotency and differentiation has been studied at the transcriptional and epigenetic level in ESCs, particularly mouse ESCs [216–223]. High-throughput sequencing methodologies are now used to characterize whole networks of regulation in ESCs [224,225] and analyze the roles of overlapping and interactive regulatory networks in determining stem cell fate, including the role of microRNAs [226] and epigenetic marks (reviewed in [227]).…”

Section: Mechanisms Of Stem Cell Aging: Lessons From Transcriptionmentioning

confidence: 99%

Adult Stem Cells and Diseases of Aging

Boyette

Tuan

2014

JCM

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Preservation of adult stem cells pools is critical for maintaining tissue homeostasis into old age. Exhaustion of adult stem cell pools as a result of deranged metabolic signaling, premature senescence as a response to oncogenic insults to the somatic genome, and other causes contribute to tissue degeneration with age. Both progeria, an extreme example of early-onset aging, and heritable longevity have provided avenues to study regulation of the aging program and its impact on adult stem cell compartments. In this review, we discuss recent findings concerning the effects of aging on stem cells, contributions of stem cells to age-related pathologies, examples of signaling pathways at work in these processes, and lessons about cellular aging gleaned from the development and refinement of cellular reprogramming technologies. We highlight emerging therapeutic approaches to manipulation of key signaling pathways corrupting or exhausting adult stem cells, as well as other approaches targeted at maintaining robust stem cell pools to extend not only lifespan but healthspan.

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“…Novel biological insights gained using our network analysis approach include: 1) differences in ESC aggregate spatiotemporal pattern kinetics can be explained by a combined paracrine signaling methodology, and 2) gastrulation in cichlid fishes can be partitioned into a set of discrete stages. In the case of ESCs, a large body of literature exists that suggests differentiation is heavily influenced by ESC aggregate size 26,27,41–43 ; soluble gp130 proteins have been identified as a paracrine mechanism which modulate of differentiation 44,45 The two paracrine process proposed here can explain these differences (one in a secreted factor is responsible for maintain pluripotency, and the other where more differentiated cells secrete a factor which induces differentiation), and mirrors the known properties of soluble LIF and FGF4 signaling respectively 24,46–48 . Surprisingly but interestingly, the lack of local neighbor-to-neighbor regulation of phenotypic state, as analyzed by our methodology, suggests that transmission of cell state information by intercellular cues, such as Notch, may impact later stages of differentiation than the time period examined here.…”

Section: Discussionmentioning

confidence: 73%

Quantitative multivariate analysis of dynamic multicellular morphogenic trajectories

et al. 2015

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Interrogating fundamental cell biology principles that govern tissue morphogenesis is critical to better understanding of developmental biology and engineering novel multicellular systems. Recently, functional micro-tissues derived from pluripotent embryonic stem cell (ESC) aggregates have provided novel platforms for experimental investigation; however elucidating the factors directing emergent spatial phenotypic patterns remains a significant challenge. Computational modelling techniques offer a unique complementary approach to probe mechanisms regulating morphogenic processes and provide a wealth of spatio-temporal data, but quantitative analysis of simulations and comparison to experimental data is extremely difficult. Quantitative descriptions of spatial phenomena across multiple systems and scales would enable unprecedented comparisons of computational simulations with experimental systems, thereby leveraging the inherent power of computational methods to interrogate the mechanisms governing emergent properties of multicellular biology. To address these challenges, we developed a portable pattern recognition pipeline consisting of: the conversion of cellular images into networks, extraction of novel features via network analysis, and generation of morphogenic trajectories. This novel methodology enabled the quantitative description of morphogenic pattern trajectories that could be compared across diverse systems: computational modelling of multicellular structures, differentiation of stem cell aggregates, and gastrulation of cichlid fish. Moreover, this method identified novel spatio-temporal features associated with different stages of embryo gastrulation, and elucidated a complex paracrine mechanism capable of explaining spatiotemporal pattern kinetic differences in ESC aggregates of different sizes.

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Novel Insights into Embryonic Stem Cell Self‐Renewal Revealed Through Comparative Human and Mouse Systems Biology Networks

Cited by 16 publications

References 79 publications

Mammalian Transcription Factor Networks: Recent Advances in Interrogating Biological Complexity

Mammalian Transcription Factor Networks: Recent Advances in Interrogating Biological Complexity

Adult Stem Cells and Diseases of Aging

Quantitative multivariate analysis of dynamic multicellular morphogenic trajectories

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