Signaling epigenetics: Novel insights on cell signaling and epigenetic regulation

Arzate-Mejía, Rodrigo G.; Valle-García, David; Recillas‐Targa, Félix

doi:10.1002/iub.557

Cited by 43 publications

(25 citation statements)

References 115 publications

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“…It is becoming an accepted paradigm that an intimate and dynamic relationship exists between signaling mediators and the epigenetic machinery (42). Within this framework, eHsp90 is emerging as an effector of epigenetic cross-talk, linking ERK activation with EZH2 activation.…”

Section: Discussionmentioning

confidence: 99%

Tumor-secreted Hsp90 Subverts Polycomb Function to Drive Prostate Tumor Growth and Invasion

Nolan

Franco

Hance

et al. 2015

Journal of Biological Chemistry

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Background: Extracellular Hsp90 (eHsp90) is implicated in cancer cell motility and invasion. Results: Tumor eHsp90 regulates ERK signaling, EZH2 expression, and histone methylation to facilitate prostate tumor growth and invasion. Conclusion: Newly characterized epigenetic functions of eHsp90 contribute to prostate tumorigenesis. Significance: Epigenetic modulation by eHsp90 may be a key facilitator in the transition of indolent to aggressive disease, highlighting a novel molecular effector of disease progression.

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Section: Discussionmentioning

confidence: 99%

Tumor-secreted Hsp90 Subverts Polycomb Function to Drive Prostate Tumor Growth and Invasion

Nolan

Franco

Hance

et al. 2015

Journal of Biological Chemistry

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“…Although scarce, current pioneering studies have clearly shown the epigenetics-signal transduction crosstalk (Arzate-Mejıa et al 2011) and the role of signal transduction pathways in the maintenance of genetic variation by balancing selection (Penn and Siemens 2010). Recent reports in mammals describe a direct link between balancing selection and epigenetic variation (Arzate-Mejía et al 2011;Okhovat et al 2014;Renn and Siemens 2010).…”

Section: Kruskalwallismentioning

confidence: 99%

Beyond population genetics: natural epigenetic variation in wild cherry (Prunus avium)

Avramidou

Ganopoulos

Doulis

et al. 2015

Tree Genetics & Genomes

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The epigenetic structure in wild plant populations remains largely unknown despite the substantial interest in evaluating epigenetic diversity in non-model organisms living in nature. The forces that shape natural epigenetic variation continue to be elusive and the potential challenge of neo-Darwinian evolutionary theory is still an open question. In this work, we estimated epigenetic diversity and differentiation within and between five natural wild cherry (Prunus avium L.) populations in northern Greece. By using a combination of either EcoRI/HpaII, or EcoRI/MspI restriction enzymes, we found low epigenetic polymorphism and weak epigenetic structure. In total, 324 methylation-sensitive amplified polymorphic (MSAP) marker bands were detected across 93 wild cherry individuals examined. They represented 272 methylation-susceptible and 52 nonmethylated epiloci. The total 5′-CCGG-methylation level, ranged from 37.05 to 59.39 %, presenting an overall mean of 49.67 % and the difference among populations was significant. The relative levels of full-methylation (m-subepiloci), hemimethylation (h-subepiloci), and non-methylation (n-subepiloci), presented an overall mean of 47.07, 30.99, and 21.92 % respectively. Most of the epigenetic variation (97 %) resided within populations (Φ ST =0.017; p<0.001). Epigenetic and genetic diversity did not differ significantly and were not significantly correlated. Epigenetic variation was not congruent to genetic variation that was assessed in the same populations and individuals by inter simple sequence repeat (ISSR) markers and by the S-locus. This study supports the thesis that epigenetic variation is uncoupled from genetic variation. It presents a first insight into the partitioning of epigenetic diversity within and among natural wild cherry populations.

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“…MAPK, Wnt, Notch, JAK-STAT, JNK, NFkB, and PKA signaling pathways all have intrinsic links to epigenetic regulation. 12,13 Current evidence indicates that such regulation may be critical. EZH2, the primary histone methyltransferase for H3K27, is phosphorylated by AKT and CDK1/CDK2 at serine 21, threonine 345 (threonine 350 in humans), and threonine 487 (threonine 492 in humans).…”

Section: Introductionmentioning

confidence: 99%

Ubp-M serine 552 phosphorylation by cyclin-dependent kinase 1 regulates cell cycle progression

Yang

Joo

et al. 2013

Cell Cycle

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Signaling epigenetics: Novel insights on cell signaling and epigenetic regulation

Cited by 43 publications

References 115 publications

Tumor-secreted Hsp90 Subverts Polycomb Function to Drive Prostate Tumor Growth and Invasion

Tumor-secreted Hsp90 Subverts Polycomb Function to Drive Prostate Tumor Growth and Invasion

Beyond population genetics: natural epigenetic variation in wild cherry (Prunus avium)

Ubp-M serine 552 phosphorylation by cyclin-dependent kinase 1 regulates cell cycle progression

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