Epigenetic setting and reprogramming for neural cell fate determination and differentiation

Imamura, Takuya; Uesaka, Masahiro; Nakashima, Kinichi

doi:10.1098/rstb.2013.0511

Cited by 31 publications

(15 citation statements)

References 102 publications

(135 reference statements)

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“…In addition, it has been proposed that pancRNAs might bind epigenetic factors, promoting the fold of the chromatin into a transcriptionally competent ternary structure, named R-Loop and composed by the nascent RNA annealed with its complementary ssDNA and the nontemplate ssDNA. Another possibility was that pancRNAs may perhaps stabilize the active state of chromatin through the association with small dsRNAs, which in turn, could cover the catalytic site of methyl transferases [38].…”

Section: Pancrnas: Regulators Of Transcription In Developmental Procementioning

confidence: 99%

Dissecting the transcriptional regulatory networks of promoter-associated noncoding RNAs in development and cancer

Chellini

Frezza

Paronetto

2020

J Exp Clin Cancer Res

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In-depth analysis of global RNA sequencing has enabled a comprehensive overview of cellular transcriptomes and revealed the pervasive transcription of divergent RNAs from promoter regions across eukaryotic genomes. These studies disclosed that genomes encode a vast repertoire of RNAs beyond the well-known protein-coding messenger RNAs. Furthermore, they have provided novel insights into the regulation of eukaryotic epigenomes, and transcriptomes, including the identification of novel classes of noncoding transcripts, such as the promoterassociated noncoding RNAs (pancRNAs). PancRNAs are defined as transcripts transcribed within few hundred bases from the transcription start sites (TSSs) of protein-coding or non-coding genes. Unlike the long transacting ncRNAs that regulate expression of target genes located in different chromosomal domains and displaying their function both in the nucleus and in the cytoplasm, the pancRNAs operate as cis-acting elements in the transcriptional regulation of neighboring genes. PancRNAs are very recently emerging as key players in the epigenetic regulation of gene expression programs in development and diseases. Herein, we review the complex epigenetic network driven by pancRNAs in eukaryotic cells, their impact on physiological and pathological states, which render them promising targets for novel therapeutic strategies.

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Section: Pancrnas: Regulators Of Transcription In Developmental Procementioning

confidence: 99%

Dissecting the transcriptional regulatory networks of promoter-associated noncoding RNAs in development and cancer

Chellini

Frezza

Paronetto

2020

J Exp Clin Cancer Res

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“…There is a growing body of evidence of the importance of epigenetic regulation in behavioral and cognitive processes [71]. Epigenetic influence has been observed in brain development and neuroplasticity [2,49,50,154,163,173], neuron differentiation [86], also learning and memory formation [24,28,37,51,54,90,144], including fear memory formation [77,89,131]. Epigenetic mechanisms are also involved in aging, neurological diseases, mood and psychotic disorders, cognitive impairments or response to trauma [19,50,83,144,163,169,173].…”

Section: Epigenetic Revolutionmentioning

confidence: 99%

Nature or Nurture – Will Epigenomics Solve the Dilemma?

Plonka

2016

Studia Humana

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The concept of "nature and nurture" is used to distinguish between genetic and environmental influences on the formation of individual, mainly behavioral, traits. Different approaches that interpret nature and nurture as completely opposite or complementary aspects of human development have been discussed for decades. The paper addresses the most important points of nature vs nurture debate from the perspective of biological research, especially in the light of the recent findings in the field of epigenetics. The most important biological concepts, such as the trait, phenotype and genotype, as well as the evolution of other crucial notions are presented. Various attempts to find the main source of human variation are discussedmainly the search for structural variants and the genome-wide association studies (GWAS). A new approach resulting from the discovery of "missing heritability", as well as the current knowledge about the possible influence of epigenetic mechanisms on human traits are analyzed. Finally, the impact of epigenetic revolution on the society (public attitude, health policy, human rights etc.) is discussed.

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“…Nestin is a neural stem/progenitor cell marker (Michalczyk and Ziman, 2005). NeuN is a specific marker of postmitotic neurons (Lavezzi et al, 2013), and NEFL is abundantly found in mature neurons (Imamura et al, 2014). Synaptophysin is an integral membrane protein of small synaptic vesicles, which is present in mature terminals and outgrowing axons (Bergmann et al, 1991(Bergmann et al, , 1993Grabs et al, 1994).…”

Section: Cpf Altered the Expression Of Several Neuron-specific Genesmentioning

confidence: 99%

Study of the chlorpyrifos neurotoxicity using neural differentiation of adipose tissue‐derived stem cells

Zarei

Soodi

Qasemian-Lemraski

et al. 2015

Environmental Toxicology

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Chlorpyrifos (CPF) is the most commonly used organophosphorus insecticide which causes neurodevelopmental toxicity. So far, animals have been used as ideal models for neurotoxicity studies, but working with animals is very expensive, laborious, and ethically challenging. This has encouraged researchers to seek alternatives. During recent years, several studies have reported successful differentiation of embryonic and adult stem cells to neurons. This has provided an excellent model for neurotoxicologic studies. In this study, neural differentiation of mouse adipose tissue-derived stem cells (ADSCs) was used as an in vitro model for investigation of CPF neurotoxicity. For this purpose, mouse ADSCs were cultured in a medium containing knockout serum replacement and were treated with different concentrations of CPF at several stages of differentiation. Cytotoxic effect of CPF and the expression of neuron-specific genes and proteins were studied in the differentiating ADSCs. Furthermore, the activity of acetylcholinesterase was assessed by Ellman assay at different stages of differentiation. This study showed that up to 500 μM CPF did not alter viability of the undifferentiated ADSCs, whereas viability of the differentiating cells decreased with 500 μM CPF. CPF upregulated the expression of some neuron-specific genes and seemed to decrease the number of β-tubulin III and MAP2 proteins-expressing cells. There was no detectable acetylcholine esterase activity in differentiated ADSCs. In summary, it was shown that CPF treatment can decrease the viability of ADSC-derived neurons and dysregulate the expression of some neuronal markers through acetylcholinesterase-independent mechanisms. © 2015 Wiley Periodicals, Inc. Environ Toxicol 31: 1510-1519, 2016.

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Epigenetic setting and reprogramming for neural cell fate determination and differentiation

Cited by 31 publications

References 102 publications

Dissecting the transcriptional regulatory networks of promoter-associated noncoding RNAs in development and cancer

Dissecting the transcriptional regulatory networks of promoter-associated noncoding RNAs in development and cancer

Nature or Nurture – Will Epigenomics Solve the Dilemma?

Study of the chlorpyrifos neurotoxicity using neural differentiation of adipose tissue‐derived stem cells

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