Your search keyword '"Anna Stincone"' showing total 7 results

1. The self-inhibitory nature of metabolic networks and its alleviation through compartmentalization

Author

Mohammad Tauqeer Alam, Viridiana Olin-Sandoval, Anna Stincone, Markus A. Keller, Aleksej Zelezniak, Ben F. Luisi, and Markus Ralser

Subjects

Science

Abstract

Metabolites act as enzyme inhibitors, but their global impact on metabolism has scarcely been considered. Here, the authors generate a human genome-wide metabolite-enzyme inhibition network, and find that inhibition occurs largely due to limited structural diversity of metabolites, leading to a global constraint on metabolism which subcellular compartmentalization minimizes.

Published

2017

2. A systems biology approach identifies molecular networks defining skeletal muscle abnormalities in chronic obstructive pulmonary disease.

Author

Nil Turan, Susana Kalko, Anna Stincone, Kim Clarke, Ayesha Sabah, Katherine Howlett, S John Curnow, Diego A Rodriguez, Marta Cascante, Laura O'Neill, Stuart Egginton, Josep Roca, and Francesco Falciani

Subjects

Biology (General), QH301-705.5

Abstract

Chronic Obstructive Pulmonary Disease (COPD) is an inflammatory process of the lung inducing persistent airflow limitation. Extensive systemic effects, such as skeletal muscle dysfunction, often characterize these patients and severely limit life expectancy. Despite considerable research efforts, the molecular basis of muscle degeneration in COPD is still a matter of intense debate. In this study, we have applied a network biology approach to model the relationship between muscle molecular and physiological response to training and systemic inflammatory mediators. Our model shows that failure to co-ordinately activate expression of several tissue remodelling and bioenergetics pathways is a specific landmark of COPD diseased muscles. Our findings also suggest that this phenomenon may be linked to an abnormal expression of a number of histone modifiers, which we discovered correlate with oxygen utilization. These observations raised the interesting possibility that cell hypoxia may be a key factor driving skeletal muscle degeneration in COPD patients.

Published

2011

3. The self-inhibitory nature of metabolic networks and its alleviation through compartmentalization

Author

Markus A. Keller, Aleksej Zelezniak, Ben F. Luisi, Markus Ralser, Mohammad Tauqeer Alam, Anna Stincone, and Viridiana Olin-Sandoval

Subjects

0301 basic medicine, Science, Allosteric regulation, General Physics and Astronomy, Dehydrogenase, Biology, Models, Biological, Article, General Biochemistry, Genetics and Molecular Biology, Triosephosphate isomerase, 03 medical and health sciences, Metabolomics, Allosteric Regulation, Oxidoreductase, Metabolome, Humans, Feedback, Physiological, chemistry.chemical_classification, Multidisciplinary, General Chemistry, Compartmentalization (psychology), Biological Evolution, QP, Cell Compartmentation, Enzymes, 030104 developmental biology, Enzyme, chemistry, Biochemistry, Metabolic Networks and Pathways

Abstract

Metabolites can inhibit the enzymes that generate them. To explore the general nature of metabolic self-inhibition, we surveyed enzymological data accrued from a century of experimentation and generated a genome-scale enzyme-inhibition network. Enzyme inhibition is often driven by essential metabolites, affects the majority of biochemical processes, and is executed by a structured network whose topological organization is reflecting chemical similarities that exist between metabolites. Most inhibitory interactions are competitive, emerge in the close neighbourhood of the inhibited enzymes, and result from structural similarities between substrate and inhibitors. Structural constraints also explain one-third of allosteric inhibitors, a finding rationalized by crystallographic analysis of allosterically inhibited L-lactate dehydrogenase. Our findings suggest that the primary cause of metabolic enzyme inhibition is not the evolution of regulatory metabolite–enzyme interactions, but a finite structural diversity prevalent within the metabolome. In eukaryotes, compartmentalization minimizes inevitable enzyme inhibition and alleviates constraints that self-inhibition places on metabolism., Metabolites act as enzyme inhibitors, but their global impact on metabolism has scarcely been considered. Here, the authors generate a human genome-wide metabolite-enzyme inhibition network, and find that inhibition occurs largely due to limited structural diversity of metabolites, leading to a global constraint on metabolism which subcellular compartmentalization minimizes.

Published

2017

4. The return of metabolism: biochemistry and physiology of the pentose phosphate pathway

Author

Viridiana Olin-Sandoval, Mohammad Tauqeer Alam, Nana-Maria Grüning, Anna Stincone, Kevin M. Brindle, Antje Krüger, Michael Breitenbach, Kate Campbell, Thorsten Cramer, Joshua D. Rabinowitz, Markus A. Keller, Alessandro Prigione, Mirjam M.C. Wamelink, Markus Ralser, Eric Cheung, Brindle, Kevin [0000-0003-3883-6287], Ralser, Markus [0000-0001-9535-7413], Apollo - University of Cambridge Repository, Laboratory Medicine, and NCA - Brain mechanisms in health and disease

Subjects

pentose phosphate pathway, Metabolic network, Oxidative phosphorylation, Biology, Pentose phosphate pathway, Article, General Biochemistry, Genetics and Molecular Biology, Metabolic engineering, chemistry.chemical_compound, Metabolic Diseases, stem cells, Ribose, NADPH, cancer, oxidative stress, parasitic protozoa, Humans, Glycolysis, inherited metabolic disease, metabolism of infection, Amino acid synthesis, glucose 6-phosphate dehydrogenase, chemistry.chemical_classification, QH, Metabolism, glycolysis, QP, metabolomics, 3. Good health, chemistry, Biochemistry, glucose 6‐phosphate dehydrogenase, Function and Dysfunction of the Nervous System, metabolic engineering, General Agricultural and Biological Sciences, host–pathogen interactions

Abstract

The pentose phosphate pathway (PPP) is a fundamental component of cellular metabolism. The PPP is important to maintain carbon homoeostasis, to provide precursors for nucleotide and amino acid biosynthesis, to provide reducing molecules for anabolism, and to defeat oxidative stress. The PPP shares reactions with the Entner-Doudoroff pathway and Calvin cycle and divides into an oxidative and non-oxidative branch. The oxidative branch is highly active in most eukaryotes and converts glucose 6-phosphate into carbon dioxide, ribulose 5-phosphate and NADPH. The latter function is critical to maintain redox balance under stress situations, when cells proliferate rapidly, in ageing, and for the 'Warburg effect' of cancer cells. The non-oxidative branch instead is virtually ubiquitous, and metabolizes the glycolytic intermediates fructose 6-phosphate and glyceraldehyde 3-phosphate as well as sedoheptulose sugars, yielding ribose 5-phosphate for the synthesis of nucleic acids and sugar phosphate precursors for the synthesis of amino acids. Whereas the oxidative PPP is considered unidirectional, the non-oxidative branch can supply glycolysis with intermediates derived from ribose 5-phosphate and vice versa, depending on the biochemical demand. These functions require dynamic regulation of the PPP pathway that is achieved through hierarchical interactions between transcriptome, proteome and metabolome. Consequently, the biochemistry and regulation of this pathway, while still unresolved in many cases, are archetypal for the dynamics of the metabolic network of the cell. In this comprehensive article we review seminal work that led to the discovery and description of the pathway that date back now for 80 years, and address recent results about genetic and metabolic mechanisms that regulate its activity. These biochemical principles are discussed in the context of PPP deficiencies causing metabolic disease and the role of this pathway in biotechnology, bacterial and parasite infections, neurons, stem cell potency and cancer metabolism.

Published

2014

5. Mitochondria in ageing: there is metabolism beyond the ROS

Author

Johannes Hartl, Hannelore Breitenbach-Koller, Markus Ralser, Mark Rinnerthaler, Jakob Vowinckel, Anna Stincone, and Michael Breitenbach

Subjects

Aging, Iron, ved/biology.organism_classification_rank.species, Mitochondrial Degradation, Respiratory chain, Context (language use), Saccharomyces cerevisiae, Biology, Mitochondrion, Models, Biological, Applied Microbiology and Biotechnology, Microbiology, 03 medical and health sciences, 0302 clinical medicine, Mitophagy, Model organism, 030304 developmental biology, 0303 health sciences, ved/biology, General Medicine, Carbon, Mitochondria, Cell biology, Citric acid cycle, Biochemistry, Ageing, Metabolic Networks and Pathways, Sulfur, 030217 neurology & neurosurgery

Abstract

Mitochondria are responsible for a series of metabolic functions. Superoxide leakage from the respiratory chain and the resulting cascade of reactive oxygen species-induced damage, as well as mitochondrial metabolism in programmed cell death, have been intensively studied during ageing in single-cellular and higher organisms. Changes in mitochondrial physiology and metabolism resulting in ROS are thus considered to be hallmarks of ageing. In this review, we address 'other' metabolic activities of mitochondria, carbon metabolism (the TCA cycle and related underground metabolism), the synthesis of Fe/S clusters and the metabolic consequences of mitophagy. These important mitochondrial activities are hitherto less well-studied in the context of cellular and organismic ageing. In budding yeast, they strongly influence replicative, chronological and hibernating lifespan, connecting the diverse ageing phenotypes studied in this single-cellular model organism. Moreover, there is evidence that similar processes equally contribute to ageing of higher organisms as well. In this scenario, increasing loss of metabolic integrity would be one driving force that contributes to the ageing process. Understanding mitochondrial metabolism may thus be required for achieving a unifying theory of eukaryotic ageing.

Published

2013

6. A computational framework for gene regulatory network inference that combines multiple methods and datasets

Author

Philipp Antczak, Anna Stincone, Sarah Durant, Francesco Falciani, Andreas Bikfalvi, Rita Gupta, Roy Bicknell, School of Biosciences, University of Birmingham [Birmingham], Institute of Biomedical Research, Mecanismes Moleculaires de l'Angiogenese, Université Sciences et Technologies - Bordeaux 1-Institut National de la Santé et de la Recherche Médicale (INSERM), The work described in this paper was funded by the CRUK grant C8504/A9488 and partially funded by the BBSRC grant BBC5151041. AS is a recipient of a Darwin Trust PhD fellowship and PA is a recipient of a BBSRC PhD studentship., BMC, Ed., and Université Sciences et Technologies - Bordeaux 1 (UB)-Institut National de la Santé et de la Recherche Médicale (INSERM)

Subjects

MESH: Hydrogen-Ion Concentration, Time Factors, Gene regulatory network, Inference, Multiple methods, computer.software_genre, 0302 clinical medicine, Structural Biology, Gene regulatory network inference, Neoplasms, MESH: Gene Silencing, MESH: Neoplasms, Gene Regulatory Networks, MESH: Stress, Physiological, lcsh:QH301-705.5, [INFO.INFO-BI] Computer Science [cs]/Bioinformatics [q-bio.QM], MESH: Gene Regulatory Networks, Genetics, 0303 health sciences, [SDV.BIBS] Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], MESH: Escherichia coli, Applied Mathematics, Systems Biology, Methodology Article, Hydrogen-Ion Concentration, [SDV.BIBS]Life Sciences [q-bio]/Quantitative Methods [q-bio.QM], Computer Science Applications, Modeling and Simulation, MESH: Systems Biology, [SDV.BBM.GTP] Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], Reverse engineering, MESH: Cell Line, Tumor, Systems biology, Biology, Machine learning, Models, Biological, 03 medical and health sciences, Stress, Physiological, Modelling and Simulation, [SDV.BBM.GTP]Life Sciences [q-bio]/Biochemistry, Molecular Biology/Genomics [q-bio.GN], Cell Line, Tumor, Escherichia coli, Humans, Gene Silencing, Molecular Biology, 030304 developmental biology, MESH: Humans, business.industry, MESH: Time Factors, Ode, MESH: Models, Biological, lcsh:Biology (General), Time course, Artificial intelligence, [INFO.INFO-BI]Computer Science [cs]/Bioinformatics [q-bio.QM], business, computer, 030217 neurology & neurosurgery

Abstract

Background Reverse engineering in systems biology entails inference of gene regulatory networks from observational data. This data typically include gene expression measurements of wild type and mutant cells in response to a given stimulus. It has been shown that when more than one type of experiment is used in the network inference process the accuracy is higher. Therefore the development of generally applicable and effective methodologies that embed multiple sources of information in a single computational framework is a worthwhile objective. Results This paper presents a new method for network inference, which uses multi-objective optimisation (MOO) to integrate multiple inference methods and experiments. We illustrate the potential of the methodology by combining ODE and correlation-based network inference procedures as well as time course and gene inactivation experiments. Here we show that our methodology is effective for a wide spectrum of data sets and method integration strategies. Conclusions The approach we present in this paper is flexible and can be used in any scenario that benefits from integration of multiple sources of information and modelling procedures in the inference process. Moreover, the application of this method to two case studies representative of bacteria and vertebrate systems has shown potential in identifying key regulators of important biological processes.

Published

2011

7. A systems biology approach identifies molecular networks defining skeletal muscle abnormalities in chronic obstructive pulmonary disease

Author

Anna Stincone, Nil Turan, Francesco Falciani, Susana G. Kalko, S. John Curnow, Josep Roca, Ayesha Sabah, Diego A. Rodríguez, Laura P. O'Neill, Kim Clarke, Stuart Egginton, Katherine Howlett, Marta Cascante, and Universitat de Barcelona

Subjects

Male, Pulmonology, Chronic Obstructive Pulmonary Diseases, Interleukin-1beta, Degeneration (medical), Bioinformatics, Histones, Mice, Pulmonary Disease, Chronic Obstructive, Sistemes biològics, Molecular genetics, Biology (General), Malalties pulmonars obstructives cròniques, Regulation of gene expression, COPD, Musculoskeletal system, Biological systems, Ecology, Systems Biology, Genomics, Middle Aged, Cell Hypoxia, Up-Regulation, medicine.anatomical_structure, Computational Theory and Mathematics, Modeling and Simulation, Cytokines, Medicine, Female, Aparell locomotor, Metabolic Networks and Pathways, Research Article, Muscle tissue, medicine.medical_specialty, QH301-705.5, Systems biology, Biology, Genètica molecular, Cellular and Molecular Neuroscience, Oxygen Consumption, Internal medicine, Genetics, medicine, Animals, Humans, RNA, Messenger, Chronic obstructive pulmonary diseases, Muscle, Skeletal, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Aged, Lung, Gene Expression Profiling, Skeletal muscle, medicine.disease, respiratory tract diseases, Gene expression profiling, Mice, Inbred C57BL, Endocrinology, Energy Metabolism

Abstract

Chronic Obstructive Pulmonary Disease (COPD) is an inflammatory process of the lung inducing persistent airflow limitation. Extensive systemic effects, such as skeletal muscle dysfunction, often characterize these patients and severely limit life expectancy. Despite considerable research efforts, the molecular basis of muscle degeneration in COPD is still a matter of intense debate. In this study, we have applied a network biology approach to model the relationship between muscle molecular and physiological response to training and systemic inflammatory mediators. Our model shows that failure to co-ordinately activate expression of several tissue remodelling and bioenergetics pathways is a specific landmark of COPD diseased muscles. Our findings also suggest that this phenomenon may be linked to an abnormal expression of a number of histone modifiers, which we discovered correlate with oxygen utilization. These observations raised the interesting possibility that cell hypoxia may be a key factor driving skeletal muscle degeneration in COPD patients., Author Summary Chronic Obstructive Pulmonary Disease (COPD) is a major life threatening disease of the lungs, characterized by airflow limitation and chronic inflammation. Progressive reduction of the body muscle mass is a condition linked to COPD that significantly decreases quality of life and survival. Physical exercise has been proposed as a therapeutic option but its utility is still a matter of debate. The mechanisms underlying muscle wasting are also still largely unknown. The results presented in this paper show that diseased muscles are largely unable to coordinate the expression of muscle remodelling and bioenergetics pathways and that the cause of this phenomena may be tissue hypoxia. These findings contrast with current hypotheses based on the role of chronic inflammation and show that a mechanism based on an oxygen driven, epigenetic control of these two important functions may be an important disease mechanism.