Your search keyword '"Futile cycle"' showing total 22 results

1. The 6-phosphofructokinase reaction in Acetivibrio thermocellus is both ATP- and pyrophosphate-dependent.

Author

Koendjbiharie JG, Kuil T, Nurminen CMK, and van Maris AJA

Abstract

Acetivibrio thermocellus (formerly Clostridium thermocellum) is a potential platform for lignocellulosic ethanol production. Its industrial application is hampered by low product titres, resulting from a low thermodynamic driving force of its central metabolism. It possesses both a functional ATP- and a functional PP i -dependent 6-phosphofructokinase (PP i -Pfk), of which only the latter is held responsible for the low driving force. Here we show that, following the replacement of PP i -Pfk by cytosolic pyrophosphatase and transaldolase, the native ATP-Pfk is able to carry the full glycolytic flux. Interestingly, the barely-detectable in vitro ATP-Pfk activities are only a fraction of what would be required, indicating its contribution to glycolysis has consistently been underestimated. A kinetic model demonstrated that the strong inhibition of ATP-Pfk by PP i can prevent futile cycling that would arise when both enzymes are active simultaneously. As such, there seems to be no need for a long-sought-after PP i -generating mechanism to drive glycolysis, as PP i -Pfk can simply use whatever PP i is available, and ATP-Pfk complements the rest of the PFK-flux. Laboratory evolution of the ΔPP i -Pfk strain, unable to valorize PP i , resulted in a mutation in the GreA transcription elongation factor. This mutation likely results in reduced RNA-turnover, hinting at transcription as a significant (and underestimated) source of anabolic PP i . Together with other mutations, this resulted in an A. thermocellus strain with the hitherto highest biomass-specific cellobiose uptake rate of 2.2 g/g x /h. These findings are both relevant for fundamental insight into dual ATP/PP i Pfk-nodes, which are not uncommon in other microorganisms, as well as for further engineering of A. thermocellus for consolidated bioprocessing., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

2. Futile cycles: Emerging utility from apparent futility.

Author

Sharma AK, Khandelwal R, and Wolfrum C

Subjects

Humans, Animals, Thermogenesis, Homeostasis, Energy Metabolism

Abstract

Futile cycles are biological phenomena where two opposing biochemical reactions run simultaneously, resulting in a net energy loss without appreciable productivity. Such a state was presumed to be a biological aberration and thus deemed an energy-wasting "futile" cycle. However, multiple pieces of evidence suggest that biological utilities emerge from futile cycles. A few established functions of futile cycles are to control metabolic sensitivity, modulate energy homeostasis, and drive adaptive thermogenesis. Yet, the physiological regulation, implication, and pathological relevance of most futile cycles remain poorly studied. In this review, we highlight the abundance and versatility of futile cycles and propose a classification scheme. We further discuss the energetic implications of various futile cycles and their impact on basal metabolic rate, their bona fide and tentative pathophysiological implications, and putative drug interactions., Competing Interests: Declaration of interests The authors declare no competing interests., (Copyright © 2024 The Authors. Published by Elsevier Inc. All rights reserved.)

Published

2024

3. Purinergic ligands induce extracellular acidification and increased ATP turnover in HepG2 cells.

Author

Chen H, Han Y, Hearne A, Monarchino A, and Wiseman JS

Subjects

Humans, Hep G2 Cells, Adenosine pharmacology, Ligands, Hydrogen-Ion Concentration, Adenosine Triphosphate, Lactic Acid, Nucleotides

Abstract

Nucleosides and nucleotides at μM concentrations stimulated a 300% increase in acid secretion in HepG2 cells, which was quantitatively accounted for as increased export of lactate generated by glycogenolysis. Agonist selectivity encompassed nucleosides and nucleotides for all 5 natural nucleobases and, along with antagonist profiles, was inconsistent with a role for purinergic receptors in mediating this activity. Agonist catabolism did not contribute significantly to either low selectivity or lactate production. Lactate production was driven by an increase in ATP turnover of as much as 56%. For some agonists, especially adenosine, ATP turnover decreased precipitously at mM concentrations, correlating with known adenosine-stimulated apoptosis. We propose that nucleoside/nucleotide agonists induce a futile energy cycle via a novel mechanism, which results in increased ATP turnover and initiates a continuum of events that for some agonists culminates in apoptosis., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2024 Elsevier Ltd. All rights reserved.)

Published

2024

4. Bifunctional enzyme provides absolute concentration robustness in multisite covalent modification networks.

Author

Joshi B and Nguyen TD

Abstract

Biochemical covalent modification networks exhibit a remarkable suite of steady state and dynamical properties such as multistationarity, oscillations, ultrasensitivity and absolute concentration robustness. This paper focuses on conditions required for a network of this type to have a species with absolute concentration robustness. We find that the robustness in a substrate is endowed by its interaction with a bifunctional enzyme, which is an enzyme that has different roles when isolated versus when bound as a substrate-enzyme complex. When isolated, the bifunctional enzyme promotes production of more molecules of the robust species while when bound, the same enzyme facilitates degradation of the robust species. These dual actions produce robustness in the large class of covalent modification networks. For each network of this type, we find the network conditions for the presence of robustness, the species that has robustness, and its robustness value. The unified approach of simultaneously analyzing a large class of networks for a single property, i.e. absolute concentration robustness, reveals the underlying mechanism of the action of bifunctional enzyme while simultaneously providing a precise mathematical description of bifunctionality., (© 2024. The Author(s), under exclusive licence to Springer-Verlag GmbH Germany, part of Springer Nature.)

Published

2024

5. A new mathematical model of folate homeostasis in E. coli highlights the potential importance of the folinic acid futile cycle in cell growth.

Author

Morgan AE, Salcedo-Sora JE, and Mc Auley MT

Subjects

Leucovorin metabolism, Substrate Cycling, Homeostasis, Models, Theoretical, Carbon metabolism, Folic Acid analysis, Folic Acid metabolism, Escherichia coli metabolism

Abstract

Folate (vitamin B9) plays a central role in one-carbon metabolism in prokaryotes and eukaryotes. This pathway mediates the transfer of one-carbon units, playing a crucial role in nucleotide synthesis, methylation, and amino acid homeostasis. The folinic acid futile cycle adds a layer of intrigue to this pathway, due to its associations with metabolism, cell growth, and dormancy. It also introduces additional complexity to folate metabolism. A logical way to deal with such complexity is to examine it by using mathematical modelling. This work describes the construction and analysis of a model of folate metabolism, which includes the folinic acid futile cycle. This model was tested under three in silico growth conditions. Model simulations revealed: 1) the folate cycle behaved as a stable biochemical system in three growth states (slow, standard, and rapid); 2) the initial concentration of serine had the greatest impact on metabolite concentrations; 3) 5-formyltetrahydrofolate cyclo-ligase (5-FCL) activity had a significant impact on the levels of the 7 products that carry the one-carbon donated from folates, and the redox couple NADP/NADPH; this was particularly evident in the rapid growth state; 4) 5-FCL may be vital to the survival of the cells by maintaining low levels of homocysteine, as high levels can induce toxicity; and 5) the antifolate therapeutic trimethoprim had a greater impact on folate metabolism with higher nutrient availability. These results highlight the important role of 5-FCL in intracellular folate homeostasis and mass generation under different metabolic scenarios., Competing Interests: Declaration of competing interest The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper., (Copyright © 2023 The Authors. Published by Elsevier B.V. All rights reserved.)

Published

2024

6. Hypermetabolism in mice carrying a near-complete human chromosome 21.

Author

Sarver DC, Xu C, Rodriguez S, Aja S, Jaffe AE, Gao FJ, Delannoy M, Periasamy M, Kazuki Y, Oshimura M, Reeves RH, and Wong GW

Subjects

Mice, Humans, Animals, Energy Metabolism physiology, Proteolipids metabolism, Cytoplasm metabolism, Chromosomes, Human metabolism, Calcium metabolism, Muscle, Skeletal metabolism, Thermogenesis genetics

Abstract

The consequences of aneuploidy have traditionally been studied in cell and animal models in which the extrachromosomal DNA is from the same species. Here, we explore a fundamental question concerning the impact of aneuploidy on systemic metabolism using a non-mosaic transchromosomic mouse model (TcMAC21) carrying a near-complete human chromosome 21. Independent of diets and housing temperatures, TcMAC21 mice consume more calories, are hyperactive and hypermetabolic, remain consistently lean and profoundly insulin sensitive, and have a higher body temperature. The hypermetabolism and elevated thermogenesis are likely due to a combination of increased activity level and sarcolipin overexpression in the skeletal muscle, resulting in futile sarco(endo)plasmic reticulum Ca 2+ ATPase (SERCA) activity and energy dissipation. Mitochondrial respiration is also markedly increased in skeletal muscle to meet the high ATP demand created by the futile cycle and hyperactivity. This serendipitous discovery provides proof-of-concept that sarcolipin-mediated thermogenesis via uncoupling of the SERCA pump can be harnessed to promote energy expenditure and metabolic health., Competing Interests: DS, CX, SR, SA, AJ, FG, MD, MP, YK, RR, GW No competing interests declared, MO M.O. is CEO, employee, and shareholder of Trans Chromosomics, Inc which manages commercial use of the TcMAC21 mouse. We declare that none of the authors has a conflict of interest, (© 2023, Sarver et al.)

Published

2023

7. What makes a reaction network "chemical"?

Author

Müller S, Flamm C, and Stadler PF

Abstract

Background: Reaction networks (RNs) comprise a set X of species and a set [Formula: see text] of reactions [Formula: see text], each converting a multiset of educts [Formula: see text] into a multiset [Formula: see text] of products. RNs are equivalent to directed hypergraphs. However, not all RNs necessarily admit a chemical interpretation. Instead, they might contradict fundamental principles of physics such as the conservation of energy and mass or the reversibility of chemical reactions. The consequences of these necessary conditions for the stoichiometric matrix [Formula: see text] have been discussed extensively in the chemical literature. Here, we provide sufficient conditions for [Formula: see text] that guarantee the interpretation of RNs in terms of balanced sum formulas and structural formulas, respectively., Results: Chemically plausible RNs allow neither a perpetuum mobile, i.e., a "futile cycle" of reactions with non-vanishing energy production, nor the creation or annihilation of mass. Such RNs are said to be thermodynamically sound and conservative. For finite RNs, both conditions can be expressed equivalently as properties of the stoichiometric matrix [Formula: see text]. The first condition is vacuous for reversible networks, but it excludes irreversible futile cycles and-in a stricter sense-futile cycles that even contain an irreversible reaction. The second condition is equivalent to the existence of a strictly positive reaction invariant. It is also sufficient for the existence of a realization in terms of sum formulas, obeying conservation of "atoms". In particular, these realizations can be chosen such that any two species have distinct sum formulas, unless [Formula: see text] implies that they are "obligatory isomers". In terms of structural formulas, every compound is a labeled multigraph, in essence a Lewis formula, and reactions comprise only a rearrangement of bonds such that the total bond order is preserved. In particular, for every conservative RN, there exists a Lewis realization, in which any two compounds are realized by pairwisely distinct multigraphs. Finally, we show that, in general, there are infinitely many realizations for a given conservative RN., Conclusions: "Chemical" RNs are directed hypergraphs with a stoichiometric matrix [Formula: see text] whose left kernel contains a strictly positive vector and whose right kernel does not contain a futile cycle involving an irreversible reaction. This simple characterization also provides a concise specification of random models for chemical RNs that additionally constrain [Formula: see text] by rank, sparsity, or distribution of the non-zero entries. Furthermore, it suggests several interesting avenues for future research, in particular, concerning alternative representations of reaction networks and infinite chemical universes., (© 2022. The Author(s).)

Published

2022

8. Double-strand breaks: When DNA repair events accidentally meet.

Author

Fujii S, Sobol RW, and Fuchs RP

Subjects

DNA metabolism, DNA Damage, O(6)-Methylguanine-DNA Methyltransferase metabolism, DNA Breaks, Double-Stranded, DNA Repair

Abstract

The cellular response to alkylation damage is complex, involving multiple DNA repair pathways and checkpoint proteins, depending on the DNA lesion, the cell type, and the cellular proliferation state. The repair of and response to O-alkylation damage, primarily O 6 -methylguaine DNA adducts (O 6 -mG), is the purview of O 6 -methylguanine-DNA methyltransferase (MGMT). Alternatively, this lesion, if left un-repaired, induces replication-dependent formation of the O 6 -mG:T mis-pair and recognition of this mis-pair by the post-replication mismatch DNA repair pathway (MMR). Two models have been suggested to account for MMR and O 6 -mG DNA lesion dependent formation of DNA double-strand breaks (DSBs) and the resulting cytotoxicity - futile cycling and direct DNA damage signaling. While there have been hints at crosstalk between the MMR and base excision repair (BER) pathways, clear mechanistic evidence for such pathway coordination in the formation of DSBs has remained elusive. However, using a novel protein capture approach, Fuchs and colleagues have demonstrated that DSBs result from an encounter between MMR-induced gaps initiated at alkylation induced O 6 -mG:C sites and BER-induced nicks at nearby N-alkylation adducts in the opposite strand. The accidental encounter between these two repair events is causal in the formation of DSBs and the resulting cellular response, documenting a third model to account for O 6 -mG induced cell death in non-replicating cells. This graphical review highlights the details of this Repair Accident model, as compared to current models, and we discuss potential strategies to improve clinical use of alkylating agents such as temozolomide, that can be inferred from the Repair Accident model., (Copyright © 2022 Elsevier B.V. All rights reserved.)

Published

2022

9. ATP-consuming futile cycles as energy dissipating mechanisms to counteract obesity.

Author

Brownstein AJ, Veliova M, Acin-Perez R, Liesa M, and Shirihai OS

Subjects

Adenosine Triphosphate metabolism, Humans, Obesity metabolism, Substrate Cycling, Thermogenesis, Adipose Tissue, Brown metabolism, Energy Metabolism

Abstract

Obesity results from an imbalance in energy homeostasis, whereby excessive energy intake exceeds caloric expenditure. Energy can be dissipated out of an organism by producing heat (thermogenesis), explaining the long-standing interest in exploiting thermogenic processes to counteract obesity. Mitochondrial uncoupling is a process that expends energy by oxidizing nutrients to produce heat, instead of ATP synthesis. Energy can also be dissipated through mechanisms that do not involve mitochondrial uncoupling. Such mechanisms include futile cycles described as metabolic reactions that consume ATP to produce a product from a substrate but then converting the product back into the original substrate, releasing the energy as heat. Energy dissipation driven by cellular ATP demand can be regulated by adjusting the speed and number of futile cycles. Energy consuming futile cycles that are reviewed here are lipolysis/fatty acid re-esterification cycle, creatine/phosphocreatine cycle, and the SERCA-mediated calcium import and export cycle. Their reliance on ATP emphasizes that mitochondrial oxidative function coupled to ATP synthesis, and not just uncoupling, can play a role in thermogenic energy dissipation. Here, we review ATP consuming futile cycles, the evidence for their function in humans, and their potential employment as a strategy to dissipate energy and counteract obesity., (© 2021. The Author(s).)

Published

2022

10. Altered glucose metabolism and insulin resistance in cancer-induced cachexia: a sweet poison.

Author

Masi T and Patel BM

Subjects

Animals, Humans, Cachexia etiology, Cachexia metabolism, Glucose metabolism, Insulin Resistance, Neoplasms complications, Neoplasms metabolism

Abstract

Cancer cachexia is a wasting disorder characterised by specific skeletal muscle and adipose tissue loss. Cancer cachexia is also driven by inflammation, altered metabolic changes such as increased energy expenditure, elevated plasma glucose, insulin resistance and excess catabolism. In cachexia, host-tumor interaction causes release of the lactate and inflammatory cytokines. Lactate released by tumor cells takes part in hepatic glucose production with the help of gluconeogenic enzymes. Thus, Cori cycle between organs and cancerous cells contributes to increased glucose production and energy expenditure. A high amount of blood glucose leads to increased production of insulin. Overproduction of insulin causes inactivation of PI3K/Akt/m-TOR pathway and finally results in insulin resistance. Insulin is involved in maintaining the vitality of organs and regulate the metabolism of glucose, protein and lipids. Insulin insensitivity decreases the uptake of glucose in the organs and results in loss of skeletal muscles and adipose tissues. However, looking into the complexity of this metabolic syndrome, it is impossible to rely on a single variable to treat patients having cancer cachexia. Hence, it becomes greater a challenge to produce a clinically effective treatment for this metabolic syndrome. Thus, the present paper aims to provide an understanding of pathogenesis and mechanism underlining the altered glucose metabolism and insulin resistance and its contribution to the progression of skeletal muscle wasting and lipolysis, providing future direction of research to develop new pharmacological treatment in cancer cachexia.

Published

2021

11. Blocking mitochondrial pyruvate import in brown adipocytes induces energy wasting via lipid cycling.

Author

Veliova M, Ferreira CM, Benador IY, Jones AE, Mahdaviani K, Brownstein AJ, Desousa BR, Acín-Pérez R, Petcherski A, Assali EA, Stiles L, Divakaruni AS, Prentki M, Corkey BE, Liesa M, Oliveira MF, and Shirihai OS

Subjects

Adipose Tissue, Brown metabolism, Energy Metabolism, Lipids, Mitochondria metabolism, Thermogenesis, Uncoupling Protein 1 genetics, Uncoupling Protein 1 metabolism, Adipocytes, Brown metabolism, Pyruvic Acid metabolism

Abstract

Combined fatty acid esterification and lipolysis, termed lipid cycling, is an ATP-consuming process that contributes to energy expenditure. Therefore, interventions that stimulate energy expenditure through lipid cycling are of great interest. Here we find that pharmacological and genetic inhibition of the mitochondrial pyruvate carrier (MPC) in brown adipocytes activates lipid cycling and energy expenditure, even in the absence of adrenergic stimulation. We show that the resulting increase in ATP demand elevates mitochondrial respiration coupled to ATP synthesis and fueled by lipid oxidation. We identify that glutamine consumption and the Malate-Aspartate Shuttle are required for the increase in Energy Expenditure induced by MPC inhibition in Brown Adipocytes (MAShEEBA). We thus demonstrate that energy expenditure through enhanced lipid cycling can be activated in brown adipocytes by decreasing mitochondrial pyruvate availability. We present a new mechanism to increase energy expenditure and fat oxidation in brown adipocytes, which does not require adrenergic stimulation of mitochondrial uncoupling., (© 2020 The Authors. Published under the terms of the CC BY 4.0 license.)

Published

2020

12. Allosteric inhibition of MTHFR prevents futile SAM cycling and maintains nucleotide pools in one-carbon metabolism.

Author

Bhatia M, Thakur J, Suyal S, Oniel R, Chakraborty R, Pradhan S, Sharma M, Sengupta S, Laxman S, Masakapalli SK, and Bachhawat AK

Subjects

Adenosine Triphosphate genetics, Adenosine Triphosphate metabolism, Allosteric Regulation, Humans, Methylation, Methylenetetrahydrofolate Reductase (NADPH2) genetics, Methylenetetrahydrofolate Reductase (NADPH2) metabolism, S-Adenosylmethionine metabolism, Saccharomyces cerevisiae genetics, Saccharomyces cerevisiae Proteins genetics, Saccharomyces cerevisiae Proteins metabolism, Adenosine Triphosphate chemistry, Methylenetetrahydrofolate Reductase (NADPH2) chemistry, S-Adenosylmethionine chemistry, Saccharomyces cerevisiae enzymology, Saccharomyces cerevisiae Proteins chemistry

Abstract

Methylenetetrahydrofolate reductase (MTHFR) links the folate cycle to the methionine cycle in one-carbon metabolism. The enzyme is known to be allosterically inhibited by SAM for decades, but the importance of this regulatory control to one-carbon metabolism has never been adequately understood. To shed light on this issue, we exchanged selected amino acid residues in a highly conserved stretch within the regulatory region of yeast MTHFR to create a series of feedback-insensitive, deregulated mutants. These were exploited to investigate the impact of defective allosteric regulation on one-carbon metabolism. We observed a strong growth defect in the presence of methionine. Biochemical and metabolite analysis revealed that both the folate and methionine cycles were affected in these mutants, as was the transsulfuration pathway, leading also to a disruption in redox homeostasis. The major consequences, however, appeared to be in the depletion of nucleotides. 13 C isotope labeling and metabolic studies revealed that the deregulated MTHFR cells undergo continuous transmethylation of homocysteine by methyltetrahydrofolate (CH 3 THF) to form methionine. This reaction also drives SAM formation and further depletes ATP reserves. SAM was then cycled back to methionine, leading to futile cycles of SAM synthesis and recycling and explaining the necessity for MTHFR to be regulated by SAM. The study has yielded valuable new insights into the regulation of one-carbon metabolism, and the mutants appear as powerful new tools to further dissect out the intersection of one-carbon metabolism with various pathways both in yeasts and in humans., Competing Interests: Conflict of interest—The authors declare that they have no conflicts of interest with the contents of this article., (© 2020 Bhatia et al.)

Published

2020

13. Sustained substrate cycles between hexose phosphates and free sugars in phosphate-deficient potato (Solanum tuberosum) cell cultures.

Author

He JZ, Dorion S, Lacroix M, and Rivoal J

Subjects

Cell Culture Techniques, Hexokinase metabolism, Solanum tuberosum cytology, Hexosephosphates metabolism, Phosphates deficiency, Solanum tuberosum metabolism, Sugars metabolism

Abstract

Main Conclusion: Futile cycling between free sugars and hexose phosphates occurring under phosphate deficiency could be involved in the maintenance of a threshold level of free cellular phosphate to preserve respiratory metabolism. We studied the metabolic response of potato cell cultures growing in Pi sufficient (2.5 mM, +Pi) or deficient (125 µM, -Pi) conditions. Under Pi deficiency, cellular growth was severely affected, however -Pi cells were able to maintain a low but steady level of free Pi. We surveyed the activities of 33 primary metabolic enzymes during the course of a 12 days Pi deficiency period. Our results show that many of these enzymes had higher specific activity in -Pi cells. Among these, we found typical markers of Pi deficiency such as phosphoenolpyruvate phosphatase and phosphoenolpyruvate carboxylase as well as enzymes involved in the biosynthesis of organic acids. Intriguingly, several ATP-consuming enzymes such as hexokinase (HK) and phosphofructokinase also displayed increased activity in -Pi condition. For HK, this was associated with an increase in the steady state of a specific HK polypeptide. Quantification of glycolytic intermediates showed a pronounced decrease in phosphate esters under Pi deficiency. Adenylate levels also decreased in -Pi cells, but the Adenylate Energy Charge was not affected by the treatment. To investigate the significance of HK induction under low Pi, [U- 14 C]-glucose tracer studies were conducted. We found in vivo evidence of futile cycling between pools of hexose phosphates and free sugars under Pi deficiency. Our study suggests that the futile cycling between hexose phosphates and free sugars which is active under +Pi conditions is sustained under Pi deficiency. The possibility that this process represents a metabolic adaptation to Pi deficiency is discussed with respect to Pi homeostasis in Pi-deficient conditions.

Published

2019

14. Engineering Escherichia coli for respiro-fermentative production of pyruvate from glucose under anoxic conditions.

Author

Skorokhodova AY, Gulevich AY, and Debabov VG

Subjects

Anaerobiosis, Escherichia coli K12 genetics, Fermentation, Escherichia coli K12 metabolism, Glucose metabolism, Pyruvic Acid metabolism

Abstract

An Escherichia coli K-12 MG1655-derived strain was engineered for respiro-fermentative production of pyruvate from glucose under anoxic conditions, which is preferred for industrial-scale microbial synthesis of valuable chemicals. The pathways of anaerobic pyruvate dissimilation were blocked in the strain by the deletion of the ackA, pta, poxB, ldhA, adhE, and pflB genes. The phosphoenolpyruvate-dependent phosphotransferase system of glucose transport and phosphorylation was substituted by an alternative ATP-dependent system resulting from the overexpression of galP and glk upon deletion of ptsG. The channelling of pyruvate towards the oxidative branch of the TCA cycle under respiratory conditions was prevented in the strain due to the deletion of aceEF genes, encoding components of pyruvate dehydrogenase, while the operation of the entire reductive branch of the TCA cycle was interrupted by knocking out frdAB and sdhAB. Reoxidation of glycolytic NADH was ensured via anaerobic respiration with nitrate serving as an external electron acceptor. To enforce anaerobic ATP hydrolysis, an ATP-consuming futile cycle of pyruvate-oxaloacetate-malate-pyruvate was established in the strain by expressing the Bacillus subtilis pycA gene, encoding pyruvate carboxylase. In the presence of sufficient amounts of an external electron acceptor and CO 2 source, the engineered strain was able to efficiently utilise glucose and convert it to pyruvate anaerobically with a yield of 1.73 mol/mol, amounting to 87% of the theoretical maximum. The implemented strategy offers the potential for the development of highly efficient processes of bio-based pyruvate production., (Copyright © 2019 Elsevier B.V. All rights reserved.)

Published

2019

15. Metabolic programming a lean phenotype by deregulation of RNA polymerase III.

Author

Willis IM, Moir RD, and Hernandez N

Subjects

Animals, Gene Expression Regulation, Liver metabolism, Metabolic Networks and Pathways, Mice, Mice, Knockout, Phenotype, RNA Polymerase III genetics, RNA, Ribosomal, 5S genetics, RNA, Ribosomal, 5S metabolism, RNA, Transfer genetics, RNA, Transfer metabolism, Repressor Proteins genetics, Repressor Proteins metabolism, Body Weight, Metabolome, RNA Polymerase III metabolism

Abstract

As a master negative regulator of RNA polymerase (Pol) III, Maf1 modulates transcription in response to nutrients and stress to balance the production of highly abundant tRNAs, 5S rRNA, and other small noncoding RNAs with cell growth and maintenance. This regulation of Pol III transcription is important for energetic economy as mice lacking Maf1 are lean and resist weight gain on normal and high fat diets. The lean phenotype of Maf1 knockout (KO) mice is attributed in part to metabolic inefficiencies which increase the demand for cellular energy and elevate catabolic processes, including autophagy/lipophagy and lipolysis. A futile RNA cycle involving increased synthesis and turnover of Pol III transcripts has been proposed as an important driver of these changes. Here, using targeted metabolomics, we find changes in the liver of fed and fasted Maf1 KO mice consistent with the function of mammalian Maf1 as a chronic Pol III repressor. Differences in long-chain acylcarnitine levels suggest that energy demand is higher in the fed state of Maf1 KO mice versus the fasted state. Quantitative metabolite profiling supports increased activity in the TCA cycle, the pentose phosphate pathway, and the urea cycle and reveals changes in nucleotide levels and the creatine system. Metabolite profiling also confirms key predictions of the futile RNA cycle hypothesis by identifying changes in many metabolites involved in nucleotide synthesis and turnover. Thus, constitutively high levels of Pol III transcription in Maf1 KO mice reprogram central metabolic pathways and waste metabolic energy through a futile RNA cycle., Competing Interests: The authors declare no conflict of interest.

Published

2018

16. Maf1 phenotypes and cell physiology.

Author

Willis IM

Subjects

Animals, Caenorhabditis elegans Proteins genetics, Energy Metabolism, Gene Expression Regulation, Gene Expression Regulation, Fungal, Gluconeogenesis, MafB Transcription Factor genetics, Mammals genetics, Mammals metabolism, Mice, Mice, Knockout, Mitochondria physiology, Models, Molecular, Phenotype, Protein Conformation, RNA Polymerase III metabolism, Repressor Proteins deficiency, Repressor Proteins genetics, Repressor Proteins physiology, Saccharomyces cerevisiae Proteins genetics, Transcription Factors genetics, MafB Transcription Factor physiology, Transcription, Genetic

Abstract

As a master regulator of transcription by RNA polymerase (Pol) III, Maf1 represses the synthesis of highly abundant non-coding RNAs as anabolic signals dissipate, as the quality or quantity of nutrients decreases, and under a wide range of cellular and environmental stress conditions. Thus, Maf1 responds to changes in cell physiology to conserve metabolic energy and to help maintain appropriate levels of tRNAs and other essential non-coding RNAs. Studies in different model organisms and cell-based systems show that perturbations of Maf1 can also impact cell physiology and metabolism. These effects are mediated by changes in Pol III transcription and/or by effects of Maf1 on the expression of select Pol II-transcribed genes. Maf1 phenotypes can vary between different systems and are sometimes conflicting as in comparisons between Maf1 KO mice and cultured mammalian cells. These studies are reviewed in an effort to better appreciate the relationship between Maf1 function and cell physiology. This article is part of a Special Issue entitled: SI: Regulation of tRNA synthesis and modification in physiological conditions and disease edited by Dr. Boguta Magdalena., (Copyright © 2017 Elsevier B.V. All rights reserved.)

Published

2018

17. Metformin causes a futile intestinal-hepatic cycle which increases energy expenditure and slows down development of a type 2 diabetes-like state.

Author

Schommers P, Thurau A, Bultmann-Mellin I, Guschlbauer M, Klatt AR, Rozman J, Klingenspor M, de Angelis MH, Alber J, Gründemann D, Sterner-Kock A, and Wiesner RJ

Subjects

Animals, Diabetes Mellitus, Type 2 etiology, Diabetes Mellitus, Type 2 metabolism, Diet, High-Fat adverse effects, Glucose metabolism, Hypoglycemic Agents therapeutic use, Intestinal Mucosa metabolism, Lactic Acid blood, Liver metabolism, Male, Metformin therapeutic use, Mice, Mice, Inbred C57BL, Diabetes Mellitus, Type 2 drug therapy, Energy Metabolism, Hypoglycemic Agents pharmacology, Intestines drug effects, Liver drug effects, Metformin pharmacology

Abstract

Objective: Metformin, the first line drug for treatment of type 2 diabetes, suppresses hepatic gluconeogenesis and reduces body weight in patients, the latter by an unknown mechanism., Methods: Mice on a high fat diet were continuously fed metformin in a therapeutically relevant dose, mimicking a retarded formulation., Results: Feeding metformin in pharmacologically relevant doses to mice on a high fat diet normalized HbA1c levels and ameliorated glucose tolerance, as expected, but also considerably slowed down weight gain. This was due to increased energy expenditure, since food intake was unchanged and locomotor activity was even decreased. Metformin caused lactate accumulation in the intestinal wall and in portal venous blood but not in peripheral blood or the liver. Increased conversion of glucose-1- 13 C to glucose-1,6- 13 C under metformin strongly supports a futile cycle of lactic acid production in the intestinal wall, and usage of the produced lactate for gluconeogenesis in liver., Conclusions: The reported glucose-lactate-glucose cycle is a highly energy consuming process, explaining the beneficial effects of metformin given continuously on the development of a type 2 diabetic-like state in our mice.

Published

2017

18. Alkylrhodamines enhance the toxicity of clotrimazole and benzalkonium chloride by interfering with yeast pleiotropic ABC-transporters.

Author

Knorre DA, Besedina E, Karavaeva IE, Smirnova EA, Markova OV, and Severin FF

Subjects

Drug Synergism, Microbial Viability drug effects, ATP-Binding Cassette Transporters antagonists & inhibitors, Antifungal Agents pharmacology, Benzalkonium Compounds pharmacology, Clotrimazole pharmacology, Enzyme Inhibitors metabolism, Rhodamines metabolism, Saccharomyces cerevisiae drug effects

Abstract

ABC-transporters with broad substrate specificity are responsible for pathogenic yeast resistance to antifungal compounds. Here we asked whether highly hydrophobic chemicals with delocalized positive charge can be used to overcome the resistance. Such molecules efficiently penetrate the plasma membrane and accumulate inside the cells. We reasoned that these properties can convert an active efflux of the compounds into a futile cycle thus interfering with the extrusion of the antibiotics. To test this, we studied the effects of several alkylated rhodamines on the drug resistance of yeast Saccharomyces cerevisiae We found that octylrhodamine synergetically increases toxicity of Pdr5p substrate-clotrimazole, while the others were less effective. Next, we compared the contributions of three major pleiotropic ABC-transporters (Pdr5p, Yor1p, Snq2p) on the accumulation of the alkylated rhodamines. While all of the tested compounds were extruded by Pdr5p, Yor1p and Snq2p showed narrower substrate specificity. Interestingly, among the tested alkylated rhodamines, inactivation of Pdr5p had the strongest effect on the accumulation of octylrhodamine inside the cells, which is consistent with the fact that clotrimazole is a substrate of Pdr5p. As alkylated rhodamines were shown to be non-toxic on mice, our study makes them potential components of pharmacological antifungal compositions., (© FEMS 2016. All rights reserved. For permissions, please e-mail: journals.permissions@oup.com.)

Published

2016

19. Activation of futile cycles as an approach to increase ethanol yield during glucose fermentation in Saccharomyces cerevisiae.

Author

Semkiv MV, Dmytruk KV, Abbas CA, and Sibirny AA

Subjects

Ethanol, Glucose, Substrate Cycling, Fermentation, Saccharomyces cerevisiae genetics

Abstract

An increase in ethanol yield by yeast from the fermentation of conventional sugars such as glucose and sucrose is possible by reducing the production of a key byproduct such as cellular biomass. Previously we have reported that overexpression of PHO8 gene encoding non-specific ATP-hydrolyzing alkaline phosphatase can lead to a decrease in cellular ATP content and to an increase in ethanol yield during glucose fermentation by Saccharomyces cerevisiae. In this work we further report on 2 new successful approaches to reduce cellular levels of ATP that increase ethanol yield and productivity. The first approach is based on the overexpression of the heterologous Escherichia coli apy gene encoding apyrase or SSB1 part of the chaperon that exhibit ATPase activity in yeast. In the second approach we constructed a futile cycle by the overexpression of S. cerevisiae genes encoding pyruvate carboxylase and phosphoenolpyruvate carboxykinase in S. cerevisiae. These genetically engineered strains accumulated more ethanol compared to the wild-type strain during alcoholic fermentation.

Published

2016

20. miR-378 Activates the Pyruvate-PEP Futile Cycle and Enhances Lipolysis to Ameliorate Obesity in Mice.

Author

Zhang Y, Li C, Li H, Song Y, Zhao Y, Zhai L, Wang H, Zhong R, Tang H, and Zhu D

Subjects

Adipose Tissue metabolism, Animals, Diet, High-Fat, Glucose metabolism, Humans, Lipolysis genetics, Mice, Mice, Transgenic, MicroRNAs administration & dosage, Muscle, Skeletal metabolism, Muscle, Skeletal pathology, Obesity pathology, Obesity therapy, Oligoribonucleotides administration & dosage, Oligoribonucleotides genetics, Pyruvic Acid metabolism, Thermogenesis, Energy Metabolism genetics, MicroRNAs genetics, Obesity genetics, Substrate Cycling genetics

Abstract

Obesity has been linked to many health problems, such as diabetes. However, there is no drug that effectively treats obesity. Here, we reveal that miR-378 transgenic mice display reduced fat mass, enhanced lipolysis, and increased energy expenditure. Notably, administering AgomiR-378 prevents and ameliorates obesity in mice. We also found that the energy deficiency seen in miR-378 transgenic mice was due to impaired glucose metabolism. This impairment was caused by an activated pyruvate-PEP futile cycle via the miR-378-Akt1-FoxO1-PEPCK pathway in skeletal muscle and enhanced lipolysis in adipose tissues mediated by miR-378-SCD1. Our findings demonstrate that activating the pyruvate-PEP futile cycle in skeletal muscle is the primary cause of elevated lipolysis in adipose tissues of miR-378 transgenic mice, and it helps orchestrate the crosstalk between muscle and fat to control energy homeostasis in mice. Thus, miR-378 may serve as a promising agent for preventing and treating obesity in humans.

Published

2016

21. Futile cycling increases sensitivity toward oxidative stress in Escherichia coli.

Author

Adolfsen KJ and Brynildsen MP

Subjects

Adenosine Triphosphate genetics, Adenosine Triphosphate metabolism, DNA Repair physiology, Escherichia coli K12 genetics, Escherichia coli K12 metabolism, Oxidative Stress physiology, Reactive Oxygen Species metabolism, Substrate Cycling physiology

Abstract

Reactive oxygen species (ROS) are toxic molecules utilized by the immune system to combat invading pathogens. Recent evidence suggests that inefficiencies in ATP production or usage can lead to increased endogenous ROS production and sensitivity to oxidative stress in bacteria. With this as inspiration, and knowledge that ATP is required for a number of DNA repair mechanisms, we hypothesized that futile cycling would be an effective way to increase sensitivity to oxidative stress. We developed a mixed integer linear optimization framework to identify experimentally-tractable futile cycles, and confirmed metabolic modeling predictions that futile cycling depresses growth rate, and increases both O2 consumption and ROS production per biomass generated. Further, intracellular ATP was decreased and sensitivity to oxidative stress increased in all actively cycling strains compared to their catalytically inactive controls. This research establishes a fundamental connection between ATP metabolism, endogenous ROS production, and tolerance toward oxidative stress in bacteria., (Copyright © 2015 International Metabolic Engineering Society. Published by Elsevier Inc. All rights reserved.)

Published

2015

22. The phenotype of a flavin-containing monooyxgenase knockout mouse implicates the drug-metabolizing enzyme FMO1 as a novel regulator of energy balance.

Author

Veeravalli S, Omar BA, Houseman L, Hancock M, Gonzalez Malagon SG, Scott F, Janmohamed A, Phillips IR, and Shephard EA

Subjects

3T3-L1 Cells, Adipocytes metabolism, Adipose Tissue, Brown metabolism, Adipose Tissue, White metabolism, Adiposity genetics, Animals, Body Weight genetics, Fatty Acids metabolism, Kidney metabolism, Liver metabolism, Mice, Mice, Inbred C57BL, Mice, Knockout, Motor Activity, Muscle, Skeletal metabolism, Oxidation-Reduction, Oxygen Consumption genetics, Phenotype, Reverse Transcriptase Polymerase Chain Reaction, Energy Metabolism genetics, Gene Expression Regulation, Oxygenases genetics, Oxygenases metabolism

Abstract

Flavin-containing monooxygenases (FMOs) of mammals are thought to be involved exclusively in the metabolism of foreign chemicals. Here, we report the unexpected finding that mice lacking Fmos 1, 2 and 4 exhibit a lean phenotype and, despite similar food intake, weigh less and store less triglyceride in white adipose tissue (WAT) than wild-type mice. This is a consequence of enhanced whole-body energy expenditure, due mostly to increased resting energy expenditure (REE). This is fuelled, in part, by increased fatty acid β-oxidation in skeletal muscle, which would contribute to depletion of lipid stores in WAT. The enhanced energy expenditure is attributed, in part, to an increased capacity for exercise. There is no evidence that the enhanced REE is due to increased adaptive thermogenesis; instead, our results are consistent with the operation in WAT of a futile energy cycle. In contrast to FMO2 and FMO4, FMO1 is highly expressed in metabolic tissues, including liver, kidney, WAT and BAT. This and other evidence implicates FMO1 as underlying the phenotype. The identification of a novel, previously unsuspected, role for FMO1 as a regulator of energy homeostasis establishes, for the first time, a role for a mammalian FMO in endogenous metabolism. Thus, FMO1 can no longer be considered to function exclusively as a xenobiotic-metabolizing enzyme. Consequently, chronic administration of drugs that are substrates for FMO1 would be expected to affect energy homeostasis, via competition for endogenous substrates, and, thus, have important implications for the general health of patients and their response to drug therapy., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014