A computational model for the identification of biochemical pathways in the krebs cycle

We have applied an algorithmic methodology which provably decomposes any complex network into a complete family of principal subcircuits to study the minimal circuits that describe the Krebs cycle. Every operational behavior that the network is capable of exhibiting can be represented by some combin...

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Veröffentlicht in:	Journal of Computational Biology 2003, Vol.10 (1), p.57-82
Hauptverfasser:	Oliveira, Joseph S, Bailey, Colin G, Jones-Oliveira, Janet B, Dixon, David A, Gull, Dean W, Chandler, Mary L
Format:	Artikel
Sprache:	eng
Schlagworte:	Algorithms BASIC BIOLOGICAL SCIENCES BIOCHEMICAL REACTION KINETICS BIOMOLECULAR NETWORK, HYPERDIGRAPH, MINIMAL CYCLE, PRINCIPLE FLOW PATHS, PINCH POINTS CITRIC ACID Citric Acid Cycle - physiology Computer Simulation KREBS CYCLE MATHEMATICAL MODELS Metabolism - physiology Models, Biological Models, Chemical Multienzyme Complexes - physiology Signal Transduction - physiology
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container_title	Journal of Computational Biology
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creator	Oliveira, Joseph S Bailey, Colin G Jones-Oliveira, Janet B Dixon, David A Gull, Dean W Chandler, Mary L
description	We have applied an algorithmic methodology which provably decomposes any complex network into a complete family of principal subcircuits to study the minimal circuits that describe the Krebs cycle. Every operational behavior that the network is capable of exhibiting can be represented by some combination of these principal subcircuits and this computational decomposition is linearly efficient. We have developed a computational model that can be applied to biochemical reaction systems which accurately renders pathways of such reactions via directed hypergraphs (Petri nets). We have applied the model to the citric acid cycle (Krebs cycle). The Krebs cycle, which oxidizes the acetyl group of acetyl CoA to CO(2) and reduces NAD and FAD to NADH and FADH(2), is a complex interacting set of nine subreaction networks. The Krebs cycle was selected because of its familiarity to the biological community and because it exhibits enough complexity to be interesting in order to introduce this novel analytic approach. This study validates the algorithmic methodology for the identification of significant biochemical signaling subcircuits, based solely upon the mathematical model and not upon prior biological knowledge. The utility of the algebraic-combinatorial model for identifying the complete set of biochemical subcircuits as a data set is demonstrated for this important metabolic process.
doi_str_mv	10.1089/106652703763255679
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This study validates the algorithmic methodology for the identification of significant biochemical signaling subcircuits, based solely upon the mathematical model and not upon prior biological knowledge. 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Every operational behavior that the network is capable of exhibiting can be represented by some combination of these principal subcircuits and this computational decomposition is linearly efficient. We have developed a computational model that can be applied to biochemical reaction systems which accurately renders pathways of such reactions via directed hypergraphs (Petri nets). We have applied the model to the citric acid cycle (Krebs cycle). The Krebs cycle, which oxidizes the acetyl group of acetyl CoA to CO(2) and reduces NAD and FAD to NADH and FADH(2), is a complex interacting set of nine subreaction networks. The Krebs cycle was selected because of its familiarity to the biological community and because it exhibits enough complexity to be interesting in order to introduce this novel analytic approach. This study validates the algorithmic methodology for the identification of significant biochemical signaling subcircuits, based solely upon the mathematical model and not upon prior biological knowledge. The utility of the algebraic-combinatorial model for identifying the complete set of biochemical subcircuits as a data set is demonstrated for this important metabolic process.</description><subject>Algorithms</subject><subject>BASIC BIOLOGICAL SCIENCES</subject><subject>BIOCHEMICAL REACTION KINETICS</subject><subject>BIOMOLECULAR NETWORK, HYPERDIGRAPH, MINIMAL CYCLE, PRINCIPLE FLOW PATHS, PINCH POINTS</subject><subject>CITRIC ACID</subject><subject>Citric Acid Cycle - physiology</subject><subject>Computer Simulation</subject><subject>KREBS CYCLE</subject><subject>MATHEMATICAL MODELS</subject><subject>Metabolism - physiology</subject><subject>Models, Biological</subject><subject>Models, Chemical</subject><subject>Multienzyme Complexes - physiology</subject><subject>Signal Transduction - physiology</subject><issn>1066-5277</issn><issn>1557-8666</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2003</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><recordid>eNqF0U1LxDAQBuAgit9_wIMEBG-rmaaZpEcRv0DwongsyTRlo22zNllk_73VXfDgwdOEyTPDwMvYCYgLEKa6BIGoCi2kRlkohbraYvuglJ4ZRNye3hOYTULvsYOU3oQAiULvsj0oUKNQsM9erzjFfrHMNoc42I73sfEdb-PI89zz0PghhzbQzzePLXch0tz3U6fjC5vnn3aVeBh-9PvoXeK0os4fsZ3Wdskfb-ohe7m9eb6-nz0-3T1cXz3OSCqTp0NBgHNYGJSqITKqkNiUtqoa0bQgS-U8mUZY61qLBM5aVRkjhXHYeirkITtb740phzpRyJ7mFIfBU65BCWEAykmdr9VijB9Ln3Ldh0S-6-zg4zLVWgIilP9DMFqVZakmWKwhjTGl0bf1Ygy9HVc1iPo7nfpvOtPQ6Wb70vW--R3ZxCG_AEo9idY</recordid><startdate>2003</startdate><enddate>2003</enddate><creator>Oliveira, Joseph S</creator><creator>Bailey, Colin G</creator><creator>Jones-Oliveira, Janet B</creator><creator>Dixon, David A</creator><creator>Gull, Dean W</creator><creator>Chandler, Mary L</creator><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QO</scope><scope>8FD</scope><scope>FR3</scope><scope>P64</scope><scope>7X8</scope><scope>OTOTI</scope></search><sort><creationdate>2003</creationdate><title>A computational model for the identification of biochemical pathways in the krebs cycle</title><author>Oliveira, Joseph S ; 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Every operational behavior that the network is capable of exhibiting can be represented by some combination of these principal subcircuits and this computational decomposition is linearly efficient. We have developed a computational model that can be applied to biochemical reaction systems which accurately renders pathways of such reactions via directed hypergraphs (Petri nets). We have applied the model to the citric acid cycle (Krebs cycle). The Krebs cycle, which oxidizes the acetyl group of acetyl CoA to CO(2) and reduces NAD and FAD to NADH and FADH(2), is a complex interacting set of nine subreaction networks. The Krebs cycle was selected because of its familiarity to the biological community and because it exhibits enough complexity to be interesting in order to introduce this novel analytic approach. This study validates the algorithmic methodology for the identification of significant biochemical signaling subcircuits, based solely upon the mathematical model and not upon prior biological knowledge. The utility of the algebraic-combinatorial model for identifying the complete set of biochemical subcircuits as a data set is demonstrated for this important metabolic process.</abstract><cop>United States</cop><pmid>12676051</pmid><doi>10.1089/106652703763255679</doi><tpages>26</tpages></addata></record>
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subjects	Algorithms BASIC BIOLOGICAL SCIENCES BIOCHEMICAL REACTION KINETICS BIOMOLECULAR NETWORK, HYPERDIGRAPH, MINIMAL CYCLE, PRINCIPLE FLOW PATHS, PINCH POINTS CITRIC ACID Citric Acid Cycle - physiology Computer Simulation KREBS CYCLE MATHEMATICAL MODELS Metabolism - physiology Models, Biological Models, Chemical Multienzyme Complexes - physiology Signal Transduction - physiology
title	A computational model for the identification of biochemical pathways in the krebs cycle
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