Your search keyword '"Avi I. Flamholz"' showing total 3 results

1. Quantum chemistry reveals thermodynamic principles of redox biochemistry

Author

Avi I. Flamholz, Sung-Jin Kim, Charles A. R. Cotton, Adrian Jinich, Arren Bar-Even, Alán Aspuru-Guzik, Benjamin Sanchez-Lengeling, Haniu Ren, and Elad Noor

Subjects

0301 basic medicine, Carboxylic Acids, Design elements and principles, Electron, Biochemistry, 01 natural sciences, Computational Chemistry, Electrochemistry, Biology (General), Density Functional Theory, Primary (chemistry), Ecology, Organic Compounds, Chemistry, Physics, Chemical Reactions, Enzymes, Structure and function, Biochemical Phenomena, Computational Theory and Mathematics, Modeling and Simulation, Physical Sciences, Thermodynamics, Density functional theory, Oxidoreductases, Oxidation-Reduction, Research Article, QH301-705.5, 010402 general chemistry, Quantum chemistry, Redox, 03 medical and health sciences, Cellular and Molecular Neuroscience, Oxidation, Genetics, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Quantum Mechanics, Organic Chemistry, Chemical Compounds, Biology and Life Sciences, Proteins, Quantum Chemistry, NAD, 0104 chemical sciences, 030104 developmental biology, Models, Chemical, Linear Models, Enzymology, Acids, NADP, Oxidation-Reduction Reactions

Abstract

Thermodynamics dictates the structure and function of metabolism. Redox reactions drive cellular energy and material flow. Hence, accurately quantifying the thermodynamics of redox reactions should reveal design principles that shape cellular metabolism. However, only few redox potentials have been measured, and mostly with inconsistent experimental setups. Here, we develop a quantum chemistry approach to calculate redox potentials of biochemical reactions and demonstrate our method predicts experimentally measured potentials with unparalleled accuracy. We then calculate the potentials of all redox pairs that can be generated from biochemically relevant compounds and highlight fundamental trends in redox biochemistry. We further address the question of why NAD/NADP are used as primary electron carriers, demonstrating how their physiological potential range fits the reactions of central metabolism and minimizes the concentration of reactive carbonyls. The use of quantum chemistry can revolutionize our understanding of biochemical phenomena by enabling fast and accurate calculation of thermodynamic values., PLoS Computational Biology, 14 (10), ISSN:1553-734X, ISSN:1553-7358

Published

2018

2. Hydrophobicity and charge shape cellular metabolite concentrations

Author

Ron Milo, Arren Bar-Even, Avi I. Flamholz, Joerg M. Buescher, and Elad Noor

Subjects

Chemical Phenomena, Databases, Factual, QH301-705.5, Cells, Metabolite, Saccharomyces cerevisiae, Biology, 010402 general chemistry, Microbiology, Models, Biological, 01 natural sciences, Metabolic engineering, Metabolic Networks, 03 medical and health sciences, Cellular and Molecular Neuroscience, chemistry.chemical_compound, Electrochemistry, Escherichia coli, Genetics, Humans, Solubility, Biology (General), Lipid bilayer, Theoretical Biology, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Microbial Metabolism, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Ecology, Systems Biology, Computational Biology, Biochemical evolution, 0104 chemical sciences, Metabolic pathway, Enzyme, Computational Theory and Mathematics, Biochemistry, chemistry, Modeling and Simulation, Lipophilicity, Hydrophobic and Hydrophilic Interactions, Metabolic Networks and Pathways, Research Article, Bacillus subtilis

Abstract

What governs the concentrations of metabolites within living cells? Beyond specific metabolic and enzymatic considerations, are there global trends that affect their values? We hypothesize that the physico-chemical properties of metabolites considerably affect their in-vivo concentrations. The recently achieved experimental capability to measure the concentrations of many metabolites simultaneously has made the testing of this hypothesis possible. Here, we analyze such recently available data sets of metabolite concentrations within E. coli, S. cerevisiae, B. subtilis and human. Overall, these data sets encompass more than twenty conditions, each containing dozens (28-108) of simultaneously measured metabolites. We test for correlations with various physico-chemical properties and find that the number of charged atoms, non-polar surface area, lipophilicity and solubility consistently correlate with concentration. In most data sets, a change in one of these properties elicits a ∼100 fold increase in metabolite concentrations. We find that the non-polar surface area and number of charged atoms account for almost half of the variation in concentrations in the most reliable and comprehensive data set. Analyzing specific groups of metabolites, such as amino-acids or phosphorylated nucleotides, reveals even a higher dependence of concentration on hydrophobicity. We suggest that these findings can be explained by evolutionary constraints imposed on metabolite concentrations and discuss possible selective pressures that can account for them. These include the reduction of solute leakage through the lipid membrane, avoidance of deleterious aggregates and reduction of non-specific hydrophobic binding. By highlighting the global constraints imposed on metabolic pathways, future research could shed light onto aspects of biochemical evolution and the chemical constraints that bound metabolic engineering efforts., Author Summary What governs the identity and concentrations of metabolites within living cells? The first part of this question has received much attention. Organisms were found to qualitatively prefer hydrophilic and charged metabolites, a phenomenon that was explained to be a result of constraints imposed by contemporary as well as archaic metabolism. However, among the metabolites that are used, a quantitative preference has never been analyzed systematically. Here we use the most comprehensive data sets of metabolite concentrations available to explore such trends. We find that in various organisms and growth conditions, living cells minimize the concentrations of non-polar, un-charged metabolites. More specifically, metabolites' hydrophobicity alters concentrations by two orders of magnitudes on average and explains up to half of the variation of metabolite concentrations within cells. We suggest that this can be attributed to an evolutionary pressure to avoid an unspecific hydrophobic effect: the preference of hydrophobic surfaces in an aqueous environment to adhere to other hydrophobic surfaces. Our findings shed light on the evolution of the internal makeup of living cells and can assist in establishing metabolic models that support synthetic biology and metabolic engineering efforts.

Published

2011

3. Pathway Thermodynamics Highlights Kinetic Obstacles in Central Metabolism

Author

Ed Reznik, Wolfram Liebermeister, Ron Milo, Elad Noor, Avi I. Flamholz, and Arren Bar-Even

Subjects

QH301-705.5, Citric Acid Cycle, Kinetics, Substrate channeling, Thermodynamics, Models, Biological, Biochemistry, Reversible reaction, 03 medical and health sciences, Cellular and Molecular Neuroscience, symbols.namesake, Exponential growth, Malate Dehydrogenase, Escherichia coli, Genetics, Phosphorylation, Biology (General), Biology, Molecular Biology, Ecology, Evolution, Behavior and Systematics, 030304 developmental biology, Enzyme Kinetics, 0303 health sciences, Ecology, Chemistry, Systems Biology, Osmolar Concentration, 030302 biochemistry & molecular biology, Computational Biology, Enzymes, Thermodynamic potential, Gibbs free energy, Metabolic pathway, Metabolism, Computational Theory and Mathematics, Modeling and Simulation, Fermentation, symbols, Metabolic Pathways, Chemical equilibrium, Metabolic Networks and Pathways, Research Article

Abstract

In metabolism research, thermodynamics is usually used to determine the directionality of a reaction or the feasibility of a pathway. However, the relationship between thermodynamic potentials and fluxes is not limited to questions of directionality: thermodynamics also affects the kinetics of reactions through the flux-force relationship, which states that the logarithm of the ratio between the forward and reverse fluxes is directly proportional to the change in Gibbs energy due to a reaction (ΔrG′). Accordingly, if an enzyme catalyzes a reaction with a ΔrG′ of -5.7 kJ/mol then the forward flux will be roughly ten times the reverse flux. As ΔrG′ approaches equilibrium (ΔrG′ = 0 kJ/mol), exponentially more enzyme counterproductively catalyzes the reverse reaction, reducing the net rate at which the reaction proceeds. Thus, the enzyme level required to achieve a given flux increases dramatically near equilibrium. Here, we develop a framework for quantifying the degree to which pathways suffer these thermodynamic limitations on flux. For each pathway, we calculate a single thermodynamically-derived metric (the Max-min Driving Force, MDF), which enables objective ranking of pathways by the degree to which their flux is constrained by low thermodynamic driving force. Our framework accounts for the effect of pH, ionic strength and metabolite concentration ranges and allows us to quantify how alterations to the pathway structure affect the pathway's thermodynamics. Applying this methodology to pathways of central metabolism sheds light on some of their features, including metabolic bypasses (e.g., fermentation pathways bypassing substrate-level phosphorylation), substrate channeling (e.g., of oxaloacetate from malate dehydrogenase to citrate synthase), and use of alternative cofactors (e.g., quinone as an electron acceptor instead of NAD). The methods presented here place another arrow in metabolic engineers' quiver, providing a simple means of evaluating the thermodynamic and kinetic quality of different pathway chemistries that produce the same molecules., Author Summary Given data about enzyme kinetics and reaction thermodynamics, traditional metabolic control analysis (MCA) can pinpoint the enzymes whose expression will have the largest effect on steady-state flux through the pathway. These analyses can aid experimentalists in tuning enzyme expression levels along a metabolic pathway. In this work, we offer a framework that is complementary to MCA. Rather than focusing on the relationship between enzyme levels and pathway flux, we examine a pathway's stoichiometry and thermodynamics and ask whether it is likely to support high flux in cellular conditions. Our framework calculates a single thermodynamically-derived metric (the MDF) for each pathway, which is convenient for selecting the promising pathways from a large collection. This approach has several advantages. First, enzyme kinetic properties are laborious to measure and differ between organisms and isozymes, but no kinetic data is required to calculate the MDF. Second, as our framework accounts for pH, ionic strength and allowed concentration ranges, it is simple to model the effect of these parameters on the MDF. Finally, as it can be difficult to control the exact expression level of enzymes within cells, the MDF helps identify alternative pathways that are less sensitive to the levels of their constituent enzymes.

Published

2014