Your search keyword '"Avi I. Flamholz"' showing total 4 results

1. Trajectories for the evolution of bacterial CO

Author

Avi I, Flamholz, Eli, Dugan, Justin, Panich, John J, Desmarais, Luke M, Oltrogge, Woodward W, Fischer, Steven W, Singer, and David F, Savage

Subjects

Bacteria, Escherichia coli, Biological Transport, Carbon Dioxide, Carbonic Anhydrases

Abstract

Cyanobacteria rely on CO

Published

2022

2. Phosphoglycolate salvage in a chemolithoautotroph using the Calvin cycle

Author

Axel Fischer, Giovanni Scarinci, Avi I. Flamholz, Oliver Lenz, Arren Bar-Even, Nico J. Claassens, William Newell, and Stefan Frielingsdorf

Subjects

Cyanobacteria, Chemoautotrophic Growth, Cupriavidus necator, Glyoxylate cycle, Malates, Microbiology, glycolate secretion, Carbon Cycle, Bacterial Proteins, Acetyl Coenzyme A, Malate synthase, Life Science, Photosynthesis, CO2 fixation, Multidisciplinary, biology, Chemistry, Carbon fixation, RuBisCO, Malate Synthase, Metabolism, Biological Sciences, glycolate oxidation, biology.organism_classification, Glycolates, hydrogen-oxidizing bacteria, Biochemistry, biology.protein, Photorespiration, Oxidation-Reduction

Abstract

Significance The Calvin cycle is the most important carbon fixation pathway in the biosphere. However, its carboxylating enzyme Rubisco also accepts oxygen, thus producing 2-phosphoglycolate. Phosphoglycolate salvage pathways were extensively studied in photoautotrophs but remain uncharacterized in chemolithoautotrophs using the Calvin cycle. Here, we study phosphoglycolate salvage in the chemolithoautotrophic model bacterium Cupriavidus necator H16. We demonstrate that this bacterium mainly reassimilates 2-phosphoglycolate via the glycerate pathway. Upon disruption of this pathway, a secondary route, which we term the malate cycle, supports photorespiration by completely oxidizing 2-phosphoglycolate to CO2. While the malate cycle was not previously known to metabolize 2-phosphoglycolate in nature, a bioinformatic analysis suggests that it may support phosphoglycolate salvage in diverse chemoautotrophic bacteria., Carbon fixation via the Calvin cycle is constrained by the side activity of Rubisco with dioxygen, generating 2-phosphoglycolate. The metabolic recycling of phosphoglycolate was extensively studied in photoautotrophic organisms, including plants, algae, and cyanobacteria, where it is referred to as photorespiration. While receiving little attention so far, aerobic chemolithoautotrophic bacteria that operate the Calvin cycle independent of light must also recycle phosphoglycolate. As the term photorespiration is inappropriate for describing phosphoglycolate recycling in these nonphotosynthetic autotrophs, we suggest the more general term “phosphoglycolate salvage.” Here, we study phosphoglycolate salvage in the model chemolithoautotroph Cupriavidus necator H16 (Ralstonia eutropha H16) by characterizing the proxy process of glycolate metabolism, performing comparative transcriptomics of autotrophic growth under low and high CO2 concentrations, and testing autotrophic growth phenotypes of gene deletion strains at ambient CO2. We find that the canonical plant-like C2 cycle does not operate in this bacterium, and instead, the bacterial-like glycerate pathway is the main route for phosphoglycolate salvage. Upon disruption of the glycerate pathway, we find that an oxidative pathway, which we term the malate cycle, supports phosphoglycolate salvage. In this cycle, glyoxylate is condensed with acetyl coenzyme A (acetyl-CoA) to give malate, which undergoes two oxidative decarboxylation steps to regenerate acetyl-CoA. When both pathways are disrupted, autotrophic growth is abolished at ambient CO2. We present bioinformatic data suggesting that the malate cycle may support phosphoglycolate salvage in diverse chemolithoautotrophic bacteria. This study thus demonstrates a so far unknown phosphoglycolate salvage pathway, highlighting important diversity in microbial carbon fixation metabolism.

Published

2020

3. Visual account of protein investment in cellular functions

Author

Wolfram Liebermeister, Avi I. Flamholz, Ron Milo, Dan Davidi, Jörg Bernhardt, and Elad Noor

Subjects

Proteomics, Internet, Multidisciplinary, Proteome, Quantitative proteomics, Cellular functions, Proteins, Computational biology, Saccharomyces cerevisiae, Biology, Biological Sciences, Models, Biological, Cell biology, Mycoplasma pneumoniae, Species Specificity, Escherichia coli, Humans, Protein abundance, Databases, Protein, Signal Transduction

Abstract

Proteomics techniques generate an avalanche of data and promise to satisfy biologists' long-held desire to measure absolute protein abundances on a genome-wide scale. However, can this knowledge be translated into a clearer picture of how cells invest their protein resources? This article aims to give a broad perspective on the composition of proteomes as gleaned from recent quantitative proteomics studies. We describe proteomaps, an approach for visualizing the composition of proteomes with a focus on protein abundances and functions. In proteomaps, each protein is shown as a polygon-shaped tile, with an area representing protein abundance. Functionally related proteins appear in adjacent regions. General trends in proteomes, such as the dominance of metabolism and protein production, become easily visible. We make interactive visualizations of published proteome datasets accessible at www.proteomaps.net. We suggest that evaluating the way protein resources are allocated by various organisms and cell types in different conditions will sharpen our understanding of how and why cells regulate the composition of their proteomes.

Published

2014

4. Glycolytic strategy as a tradeoff between energy yield and protein cost

Author

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

Subjects

Microbial metabolism, Carbohydrate metabolism, Biology, Models, Biological, 03 medical and health sciences, chemistry.chemical_compound, Adenosine Triphosphate, Bacterial Proteins, Species Specificity, Commentaries, Escherichia coli, Glycolysis, Anaerobiosis, Entner–Doudoroff pathway, Phylogeny, 030304 developmental biology, chemistry.chemical_classification, 0303 health sciences, Multidisciplinary, Bacteria, 030306 microbiology, Aerobiosis, Metabolic pathway, Kinetics, Enzyme, Glucose, chemistry, Biochemistry, Prokaryotic Cells, Thermodynamics, Energy Metabolism, Adenosine triphosphate, Flux (metabolism), Algorithms, Metabolic Networks and Pathways

Abstract

Contrary to the textbook portrayal of glycolysis as a single pathway conserved across all domains of life, not all sugar-consuming organisms use the canonical Embden–Meyerhoff–Parnass (EMP) glycolytic pathway. Prokaryotic glucose metabolism is particularly diverse, including several alternative glycolytic pathways, the most common of which is the Entner–Doudoroff (ED) pathway. The prevalence of the ED pathway is puzzling as it produces only one ATP per glucose—half as much as the EMP pathway. We argue that the diversity of prokaryotic glucose metabolism may reflect a tradeoff between a pathway’s energy (ATP) yield and the amount of enzymatic protein required to catalyze pathway flux. We introduce methods for analyzing pathways in terms of thermodynamics and kinetics and show that the ED pathway is expected to require several-fold less enzymatic protein to achieve the same glucose conversion rate as the EMP pathway. Through genomic analysis, we further show that prokaryotes use different glycolytic pathways depending on their energy supply. Specifically, energy-deprived anaerobes overwhelmingly rely upon the higher ATP yield of the EMP pathway, whereas the ED pathway is common among facultative anaerobes and even more common among aerobes. In addition to demonstrating how protein costs can explain the use of alternative metabolic strategies, this study illustrates a direct connection between an organism’s environment and the thermodynamic and biochemical properties of the metabolic pathways it employs.

Published

2013