The sweet side of AMPK signaling: regulation of GFAT1

Maintaining a steady balance between nutrient supply and energy demand is essential for all living organisms and is achieved through the dynamic control of metabolic processes that produce and consume adenosine-5′-triphosphate (ATP), the universal currency of energy in all cells. A key sensor of cellular energy is the adenosine-5′-monophosphate (AMP)-activated protein kinase (AMPK), which is the core component of a signaling network that regulates energy and nutrient metabolism. AMPK is activated by metabolic stresses that decrease cellular ATP, and functions to restore energy balance by orchestrating a switch in metabolism away from anabolic pathways toward energy-generating catabolic processes. A new study published in a recent issue of Biochemical Journal by Zibrova et al. shows that glutamine:fructose-6-phosphate amidotransferase-1 (GFAT1), the rate-limiting enzyme of the hexosamine biosynthesis pathway (HBP), is a physiological substrate of AMPK. The HBP is an offshoot of the glycolytic pathway that drives the synthesis of uridine-5′-diphospho-N-acetylglucosamine, the requisite donor metabolite needed for dynamic β-N-acetylglucosamine (O-GlcNAc) modification (O-GlcNAcylation) of cellular proteins. O-GlcNAcylation is a nutrient-sensitive post-translational modification that, like phosphorylation, regulates numerous intracellular processes. Zibrova et al. show that inhibitory phosphorylation of the GFAT1 residue Ser243 by AMPK in response to physiological or small-molecule activators leads to a reduction in cellular protein O-GlcNAcylation. Further work revealed that AMPK-dependent phosphorylation of GFAT1 promotes angiogenesis in endothelial cells. This elegant study demonstrates that the AMPK–GFAT1 signaling axis serves as an important communication point between two nutrient-sensitive signaling pathways and is likely to play a significant role in controlling physiological processes in many other tissues.

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AMPK in Health and Disease

Physiological Reviews ◽

10.1152/physrev.00011.2008 ◽

2009 ◽

Vol 89 (3) ◽

pp. 1025-1078 ◽

Cited By ~ 1050

Author(s):

Gregory R. Steinberg ◽

Bruce E. Kemp

Keyword(s):

Energy Balance ◽

Stress Responses ◽

Energy Demand ◽

Dynamic Control ◽

Cellular Level ◽

Whole Body ◽

Α Subunit ◽

Ampk Signaling ◽

Control Food Intake

The function and survival of all organisms is dependent on the dynamic control of energy metabolism, when energy demand is matched to energy supply. The AMP-activated protein kinase (AMPK) αβγ heterotrimer has emerged as an important integrator of signals that control energy balance through the regulation of multiple biochemical pathways in all eukaryotes. In this review, we begin with the discovery of the AMPK family and discuss the recent structural studies that have revealed the molecular basis for AMP binding to the enzyme's γ subunit. AMPK's regulation involves autoinhibitory features and phosphorylation of both the catalytic α subunit and the β-targeting subunit. We review the role of AMPK at the cellular level through examination of its many substrates and discuss how it controls cellular energy balance. We look at how AMPK integrates stress responses such as exercise as well as nutrient and hormonal signals to control food intake, energy expenditure, and substrate utilization at the whole body level. Lastly, we review the possible role of AMPK in multiple common diseases and the role of the new age of drugs targeting AMPK signaling.

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Assessing energy demand in living organisms: the influence of environmental temperature

Endocrine Abstracts ◽

10.1530/endoabs.34.apw1.1 ◽

2014 ◽

Author(s):

Jan Nedergaard ◽

Barbara Cannon

Keyword(s):

Energy Demand ◽

Environmental Temperature ◽

Living Organisms

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Androgen signaling uses a writer and a reader of ADP-ribosylation to regulate protein complex assembly

Nature Communications ◽

10.1038/s41467-021-23055-6 ◽

2021 ◽

Vol 12 (1) ◽

Author(s):

Chun-Song Yang ◽

Kasey Jividen ◽

Teddy Kamata ◽

Natalia Dworak ◽

Luke Oostdyk ◽

...

Keyword(s):

Gene Expression ◽

Protein Interactions ◽

Prostate Cancer Cells ◽

Protein Protein Interactions ◽

Post Translational Modification ◽

Complex Assembly ◽

Adp Ribosylation ◽

Signaling Axis ◽

Regulate Protein ◽

Protein Complex Assembly

AbstractAndrogen signaling through the androgen receptor (AR) directs gene expression in both normal and prostate cancer cells. Androgen regulates multiple aspects of the AR life cycle, including its localization and post-translational modification, but understanding how modifications are read and integrated with AR activity has been difficult. Here, we show that ADP-ribosylation regulates AR through a nuclear pathway mediated by Parp7. We show that Parp7 mono-ADP-ribosylates agonist-bound AR, and that ADP-ribosyl-cysteines within the N-terminal domain mediate recruitment of the E3 ligase Dtx3L/Parp9. Molecular recognition of ADP-ribosyl-cysteine is provided by tandem macrodomains in Parp9, and Dtx3L/Parp9 modulates expression of a subset of AR-regulated genes. Parp7, ADP-ribosylation of AR, and AR-Dtx3L/Parp9 complex assembly are inhibited by Olaparib, a compound used clinically to inhibit poly-ADP-ribosyltransferases Parp1/2. Our study reveals the components of an androgen signaling axis that uses a writer and reader of ADP-ribosylation to regulate protein-protein interactions and AR activity.

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The phytochemical hyperforin triggers thermogenesis in adipose tissue via a Dlat-AMPK signaling axis to curb obesity

Cell Metabolism ◽

10.1016/j.cmet.2021.02.007 ◽

2021 ◽

Vol 33 (3) ◽

pp. 565-580.e7

Author(s):

Suzhen Chen ◽

Xiaoxiao Liu ◽

Chao Peng ◽

Chang Tan ◽

Honglin Sun ◽

...

Keyword(s):

Adipose Tissue ◽

Ampk Signaling ◽

Signaling Axis

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Responses of hypertrophied myocytes to reactive species: implications for glycolysis and electrophile metabolism

Biochemical Journal ◽

10.1042/bj20101390 ◽

2011 ◽

Vol 435 (2) ◽

pp. 519-528 ◽

Cited By ~ 20

Author(s):

Brian E. Sansbury ◽

Daniel W. Riggs ◽

Robert E. Brainard ◽

Joshua K. Salabei ◽

Steven P. Jones ◽

...

Keyword(s):

Oxidative Stress ◽

Oxygen Consumption ◽

Energy Demand ◽

Lactate Production ◽

Fold Increase ◽

Cellular Protein ◽

Reactive Species ◽

Neonatal Rat ◽

Glycolytic Flux ◽

Rat Cardiomyocytes

During cardiac remodelling, the heart generates higher levels of reactive species; yet an intermediate ‘compensatory’ stage of hypertrophy is associated with a greater ability to withstand oxidative stress. The mechanisms underlying this protected myocardial phenotype are poorly understood. We examined how a cellular model of hypertrophy deals with electrophilic insults, such as would occur upon ischaemia or in the failing heart. For this, we measured energetics in control and PE (phenylephrine)-treated NRCMs (neonatal rat cardiomyocytes) under basal conditions and when stressed with HNE (4-hydroxynonenal). PE treatment caused hypertrophy as indicated by augmented atrial natriuretic peptide and increased cellular protein content. Hypertrophied myocytes demonstrated a 2.5-fold increase in ATP-linked oxygen consumption and a robust augmentation of oligomycin-stimulated glycolytic flux and lactate production. Hypertrophied myocytes displayed a protected phenotype that was resistant to HNE-induced cell death and a unique bioenergetic response characterized by a delayed and abrogated rate of oxygen consumption and a 2-fold increase in glycolysis upon HNE exposure. This augmentation of glycolytic flux was not due to increased glucose uptake, suggesting that electrophile stress results in utilization of intracellular glycogen stores to support the increased energy demand. Hypertrophied myocytes also had an increased propensity to oxidize HNE to 4-hydroxynonenoic acid and sustained less protein damage due to acute HNE insults. Inhibition of aldehyde dehydrogenase resulted in bioenergetic collapse when myocytes were challenged with HNE. The integration of electrophile metabolism with glycolytic and mitochondrial energy production appears to be important for maintaining myocyte homoeostasis under conditions of increased oxidative stress.

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Substrate-Specific Effects of Natural Genetic Variation on Proteasome Activity

10.1101/2021.11.23.469794 ◽

2021 ◽

Author(s):

Mahlon Collins ◽

Randi R. Avery ◽

Frank W Albert

Keyword(s):

Genetic Variation ◽

Protein Degradation ◽

Dynamic Control ◽

Cellular Protein ◽

Proteasome Activity ◽

Heritable Variation ◽

Natural Genetic Variation ◽

Specific Effects ◽

Regulatory Particle

The bulk of targeted cellular protein degradation is performed by the proteasome, a multi-subunit complex consisting of the 19S regulatory particle, which binds, unfolds, and translocates substrate proteins, and the 20S core particle, which degrades them. Protein homeostasis requires precise, dynamic control of proteasome activity. To what extent genetic variation creates differences in proteasome activity is almost entirely unknown. Using the ubiquitin-independent degrons of the ornithine decarboxylase and Rpn4 proteins, we developed reporters that provide high-throughput, quantitative measurements of proteasome activity in vivo in genetically diverse cell populations. We used these reporters to characterize the genetic basis of variation in proteasome activity in the yeast Saccharomyces cerevisiae. We found that proteasome activity is a complex, polygenic trait, shaped by variation throughout the genome. Genetic influences on proteasome activity were predominantly substrate-specific, suggesting that they primarily affect the function or activity of the 19S regulatory particle. Our results demonstrate that individual genetic differences create heritable variation in proteasome activity and suggest that genetic effects on proteasomal protein degradation may be an important source of variation in cellular and organismal traits.

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Wnt signalling at the crossroads of nutritional regulation

Biochemical Journal ◽

10.1042/bj20082074 ◽

2008 ◽

Vol 416 (2) ◽

pp. e11-e13 ◽

Cited By ~ 9

Author(s):

Jaswinder K. Sethi ◽

Antonio J. Vidal-Puig

Keyword(s):

Protein Kinase ◽

Glucose Sensing ◽

Cellular Level ◽

Wnt Signalling ◽

Nutritional Regulation ◽

Biochemical Journal ◽

Hexosamine Pathway ◽

Attractive Therapeutic Target ◽

Sense And Respond ◽

Living Organisms

The ability to sense and respond to nutritional cues is among the most fundamental processes that support life in living organisms. At the cellular level, a number of biochemical mechanisms have been proposed to mediate cellular glucose sensing. These include ATP-sensitive potassium channels, AMP-activated protein kinase, activation of PKC (protein kinase C), and flux through the hexosamine pathway. Less well known is how cellularly heterogenous organs couple nutrient availability to prioritization of cell autonomous functions and appropriate growth of the entire organ. Yet what is clear is that when such mechanisms fail or become inappropriately active they can lead to dire consequences such as diabetes, metabolic syndromes, cardiovascular diseases and cancer. In this issue of the Biochemical Journal, Anagnostou and Shepherd report the identification of an important link between cellular glucose sensing and the Wnt/β-catenin signalling pathway in macrophages. Their data strongly indicate that the Wnt/β-catenin pathway of Wnt signalling is responsive to physiological concentrations of nutrients but also suggests that that this system could be inappropriately activated in the diabetic (hyperglycaemic) or other metabolically compromised pathological states. This opens the exciting possibility that organ-selective modulation of Wnt signalling may become an attractive therapeutic target to treat these diseases.

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The DNA Sensor cGAS is Decorated by Acetylation and Phosphorylation Modifications in the Context of Immune Signaling

Molecular & Cellular Proteomics ◽

10.1074/mcp.ra120.001981 ◽

2020 ◽

Vol 19 (7) ◽

pp. 1193-1208 ◽

Cited By ~ 5

Author(s):

Bokai Song ◽

Todd M. Greco ◽

Krystal K. Lum ◽

Caroline E. Taber ◽

Ileana M. Cristea

Keyword(s):

Cyclic Gmp ◽

Single Point ◽

Cell Types ◽

Post Translational Modification ◽

Immune Signaling ◽

Signaling Axis ◽

Primary Fibroblasts ◽

Elevated Surface ◽

Simplex Virus ◽

Hsv 1

The cyclic GMP-AMP synthase (cGAS) protein is a pattern-recognition receptor of the mammalian innate immune system that is recognized as a main cytosolic sensor of pathogenic or damaged DNA. cGAS DNA binding initiates catalytic production of the second messenger, cyclic GMP-AMP, which activates the STING-TBK1-IRF3 signaling axis to induce cytokine expression. Post-translational modification (PTM) has started to be recognized as a critical component of cGAS regulation, yet the extent of these modifications remains unclear. Here, we report the identification and functional analysis of cGAS phosphorylations and acetylations in several cell types under basal and immune-stimulated conditions. cGAS was enriched by immunoaffinity purification from human primary fibroblasts prior to and after infection with herpes simplex virus type 1 (HSV-1), as well as from immune-stimulated STING-HEK293T cells. Six phosphorylations and eight acetylations were detected, of which eight PTMs were not previously documented. PTMs were validated by parallel reaction monitoring (PRM) mass spectrometry in fibroblasts, HEK293T cells, and THP-1 macrophage-like cells. Primary sequence and structural analysis of cGAS highlighted a subset of PTM sites with elevated surface accessibility and high evolutionary sequence conservation. To assess the functional relevance of each PTM, we generated a series of single-point cGAS mutations. Stable cell lines were constructed to express cGAS with amino acid substitutions that prevented phosphorylation (Ser-to-Ala) and acetylation (Lys-to-Arg) or that mimicked the modification state (Ser-to-Asp and Lys-to-Gln). cGAS-dependent apoptotic and immune signaling activities were then assessed for each mutation. Our results show that acetyl-mimic mutations at Lys384 and Lys414 inhibit the ability of cGAS to induce apoptosis. In contrast, the Lys198 acetyl-mimic mutation increased cGAS-dependent interferon signaling when compared with the unmodified charge-mimic. Moreover, targeted PRM quantification showed that Lys198 acetylation is decreased upon infections with two herpesviruses—HSV-1 and human cytomegalovirus (HCMV), highlighting this residue as a regulatory point during virus infection.

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Uncovering miRNAs involved in crosstalk between nutrient deficiencies in Arabidopsis

Scientific Reports ◽

10.1038/srep11813 ◽

2015 ◽

Vol 5 (1) ◽

Cited By ~ 46

Author(s):

Gang Liang ◽

Qin Ai ◽

Diqiu Yu

Keyword(s):

Metabolic Pathways ◽

Nutrient Deficiency ◽

Differentially Expressed ◽

Nutrient Deficiencies ◽

Nutrient Metabolism ◽

S Deficiency ◽

Differentially Expressed Mirnas ◽

Living Organisms ◽

Nutrient Homeostasis ◽

Mirna Abundance

Abstract Integrating carbon (C), nitrogen (N) and sulfur (S) metabolism is essential for the growth and development of living organisms. MicroRNAs (miRNAs) play key roles in regulating nutrient metabolism in plants. However, how plant miRNAs mediate crosstalk between different nutrient metabolic pathways is unclear. In this study, deep sequencing of Arabidopsis thaliana small RNAs was used to reveal miRNAs that were differentially expressed in response to C, N, or S deficiency. Comparative analysis revealed that the targets of the differentially expressed miRNAs are involved in different cellular responses and metabolic processes, including transcriptional regulation, auxin signal transduction, nutrient homeostasis and regulation of development. C, N and S deficiency specifically induced miR169b/c, miR826 and miR395, respectively. In contrast, miR167, miR172, miR397, miR398, miR399, miR408, miR775, miR827, miR841, miR857 and miR2111 are commonly suppressed by C, N and S deficiency. In particular, the miRNAs that are induced specifically by a certain nutrient deficiency are often suppressed by other nutrient deficiencies. Further investigation indicated that the modulation of nutrient-responsive miRNA abundance affects the adaptation of plants to nutrient starvation conditions. This study revealed that miRNAs function as important regulatory nodes of different nutrient metabolic pathways.

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