Control of Ribosomal RNA Transcription by Nutrients

Tanaka, Yuji; Tsuneoka, Makoto

doi:10.5772/intechopen.71866

Cited by 7 publications

(7 citation statements)

References 115 publications

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“…The ribosome is the cellular protein translation machine that controls growth across the whole organism and throughout life. Whilst there are several hundreds of rDNA gene copies available per cell, many are inactive physiologically through epigenetic mechanisms, and thus, the rate of transcription can be modulated by nutrient availability and other factors such as ageing [90][91][92]. rDNA silencing includes epigenetic regulation through hypermethylation of the rDNA promotor restricting Pol 1 binding and transcription, working alongside ribosome-associated proteins that coordinate Pol 1 activity and sense cellular environment [91,93].…”

Section: Blastocyst Nutrient Sensing Coordinates the Foetal Growth Trajectorymentioning

confidence: 99%

“…Lastly, we need to consider how environmental nutrient availability is perceived to regulate RRN3 expression and ribosome biogenesis. RRN3 expression is regulated by environmental factors, reduced by caloric and other nutrient restriction and sensitive to AA availability and mTORC1 signalling [91,92,102]. Indeed, PTEN, the negative regulator of mTORC1, has been proposed as a thrifty gene to drive metabolic storage when nutrients are plentiful [103].…”

Section: Blastocyst Nutrient Sensing Coordinates the Foetal Growth Trajectorymentioning

confidence: 99%

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Environmental Exposures around Conception: Developmental Pathways Leading to Lifetime Disease Risk

Fleming

Sun

Denisenko

et al. 2021

IJERPH

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Environment around conception can influence the developmental programme with lasting effects on gestational and postnatal phenotype and with consequences for adult health and disease risk. Peri-conception exposure comprises a crucial part of the ‘Developmental Origins of Health and Disease’ (DOHaD) concept. In this review, we consider the effects of maternal undernutrition experienced during the peri-conception period in select human models and in a mouse experimental model of protein restriction. Human datasets indicate that macronutrient deprivation around conception affect the epigenome, with enduring effects on cardiometabolic and neurological health. The mouse model, comprising maternal low protein diet exclusively during the peri-conception period, has revealed a stepwise progression in altered developmental programming following induction through maternal metabolite deficiency. This progression includes differential effects in extra-embryonic and embryonic cell lineages and tissues, leading to maladaptation in the growth trajectory and increased chronic disease comorbidities. The timeline embraces an array of mechanisms across nutrient sensing and signalling, cellular, metabolic, epigenetic and physiological processes with a coordinating role for mTORC1 signalling proposed. Early embryos appear active participants in environmental sensing to optimise the developmental programme for survival but with the trade-off of later disease. Similar adverse health outcomes may derive from other peri-conception environmental experiences, including maternal overnutrition, micronutrient availability, pollutant exposure and assisted reproductive treatments (ART) and support the need for preconception health before pregnancy.

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Section: Blastocyst Nutrient Sensing Coordinates the Foetal Growth Trajectorymentioning

confidence: 99%

Section: Blastocyst Nutrient Sensing Coordinates the Foetal Growth Trajectorymentioning

confidence: 99%

Environmental Exposures around Conception: Developmental Pathways Leading to Lifetime Disease Risk

Fleming

Sun

Denisenko

et al. 2021

IJERPH

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“…rRNA is the most abundant transcript of the cell and, as such, its transcription is highly energy consuming. In line with what is discussed above, rDNA transcription is modulated according to different environmental factors, like the regulators of cell cycle, growth factors, stressors, and nutrients, to guarantee energy homeostasis [26]. In particular, several studies reported that amino acid/glucose starvation and CR reduce rDNA transcription in yeast and mammal cells [26][27][28][29][30].…”

Section: Introductionmentioning

confidence: 52%

Aging and Caloric Restriction Modulate the DNA Methylation Profile of the Ribosomal RNA Locus in Human and Rat Liver

Gensous¹,

Ravaioli²,

Pirazzini

et al. 2020

Nutrients

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A growing amount of evidence suggests that the downregulation of protein synthesis is an adaptive response during physiological aging, which positively contributes to longevity and can be modulated by nutritional interventions like caloric restriction (CR). The expression of ribosomal RNA (rRNA) is one of the main determinants of translational rate, and epigenetic modifications finely contribute to its regulation. Previous reports suggest that hypermethylation of ribosomal DNA (rDNA) locus occurs with aging, although with some species- and tissue- specificity. In the present study, we experimentally measured DNA methylation of three regions (the promoter, the 5′ of the 18S and the 5′ of 28S sequences) in the rDNA locus in liver tissues from rats at two, four, 10, and 18 months. We confirm previous findings, showing age-related hypermethylation, and describe, for the first time, that this gain in methylation also occurs in human hepatocytes. Furthermore, we show that age-related hypermethylation is enhanced in livers of rat upon CR at two and 10 months, and that at two months a trend towards the reduction of rRNA expression occurs. Collectively, our results suggest that CR modulates age-related regulation of methylation at the rDNA locus, thus providing an epigenetic readout of the pro-longevity effects of CR.

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“…The ribosome is a unique machine to synthesize proteins in organisms 13,14 , and the control of ribosome biogenesis is a critical factor in the regulation of cellular activities 15–18 . Because the level of rRNA transcription is a major factor determining the production of ribosomes, the regulation of rRNA transcription affects multiple cellular activities, including cell proliferation 13,14,16,18–23 . Recently, increasing numbers of studies have shown that epigenetic regulators control rRNA transcription 13,14,23–27 .…”

Section: Introductionmentioning

confidence: 99%

“…Because the level of rRNA transcription is a major factor determining the production of ribosomes, the regulation of rRNA transcription affects multiple cellular activities, including cell proliferation 13,14,16,18–23 . Recently, increasing numbers of studies have shown that epigenetic regulators control rRNA transcription 13,14,23–27 . We previously showed that a JmjC histone demethylase, lysine-demethylase 2 A (KDM2A), decreases the dimethylated lysine 36 of histone H3 (H3K36me2) in the ribosome RNA gene (rDNA) promoter and represses rRNA transcription under starvation in breast cancer cells 28,29 .…”

Section: Introductionmentioning

confidence: 99%

Metformin activates KDM2A to reduce rRNA transcription and cell proliferation by dual regulation of AMPK activity and intracellular succinate level

Tanaka

Konishi

Obinata

et al. 2019

Sci Rep

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Metformin is used to treat type 2 diabetes. Metformin activates AMP-activated kinase (AMPK), which may contribute to the action of metformin. Metformin also shows anti-proliferation activity. However, the mechanism is remained unknown. We found that treatment of MCF-7 cells with metformin induced the demethylase activity of KDM2A in the rDNA promoter, which resulted in reductions of rRNA transcription and cell proliferation. AMPK activity was required for activation of KDM2A by metformin. Because demethylase activities of JmjC-type enzymes require a side reaction converting α-ketoglutarate to succinate, these organic acids may affect their demethylase activities. We found that metformin did not induce KDM2A demethylase activity in conditions of a reduced level of α-ketoglutarate. A four-hour treatment of metformin specifically reduced succinate, and the replenishment of succinate inhibited the activation of KDM2A by metformin, but did not inhibit the activation of AMPK. Metformin reduced succinate even in the conditions suppressing AMPK activity. These results indicate that metformin activates AMPK and reduces the intracellular succinate level, both of which are required for the activation of KDM2A to reduce rRNA transcription. The results presented here uncover a novel factor of metformin actions, reduction of the intracellular succinate, which contributes to the anti-proliferation activity of metformin.

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Control of Ribosomal RNA Transcription by Nutrients

Cited by 7 publications

References 115 publications

Environmental Exposures around Conception: Developmental Pathways Leading to Lifetime Disease Risk

Environmental Exposures around Conception: Developmental Pathways Leading to Lifetime Disease Risk

Aging and Caloric Restriction Modulate the DNA Methylation Profile of the Ribosomal RNA Locus in Human and Rat Liver

Metformin activates KDM2A to reduce rRNA transcription and cell proliferation by dual regulation of AMPK activity and intracellular succinate level

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