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American Heritage Dictionary:
Krebs cycle |
[After Sir Hans Adolf KREBS.]
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Oxford Dictionary of Chemistry:
Krebs cycle |
A cyclical series of biochemical reactions that is fundamental to the metabolism of aerobic organisms, i.e. animals, plants, and many microorganisms . The enzymes of the Krebs cycle are located in the mitochondria and are in close association with the components of the electron transport chain. The two-carbon acetyl coenzyme A (acetyl CoA) reacts with the four-carbon oxaloacetate to form the six-carbon citrate. In a series of seven reactions, this is reconverted to oxaloacetate and produces two molecules of carbon dioxide. Most importantly, the cycle generates one molecule of guanosine triphosphate (GTP – equivalent to 1 ATP) and reduces three molecules of the coenzyme NAD to NADH and one molecule of the coenzyme FAD to FADH2. NADH and FADH2 are then oxidized by the electron transport chain to generate three and two molecules of ATP respectively. This gives a net yield of 12 molecules of ATP per molecule of acetyl CoA.
Acetyl CoA can be derived from carbohydrates (via glycolysis), fats, or certain amino acids. (Other amino acids may enter the cycle at different stages.) Thus the Krebs cycle is the central 'crossroads' in the complex system of metabolic pathways and is involved not only in degradation and energy production but also in the synthesis of biomolecules. It is named after its principal discoverer, Sir Hans Adolf Krebs.
Britannica Concise Encyclopedia:
tricarboxylic acid cycle |
For more information on tricarboxylic acid cycle, visit Britannica.com.
Oxford Food & Nutrition Dictionary:
Krebs' cycle |
Or citric acid cycle, a central pathway for the metabolism of fats, carbohydrates, and amino acids.
Oxford Food & Fitness Dictionary:
Krebs cycle |
A series of reactions named after the 1953 Nobel prize winner, Sir Hans Krebs, its discoverer. The Krebs cycle is an integral part of aerobic respiration in which acetyl coenzyme A, a product of carbohydrate, fat, and protein metabolism, is broken down in the presence of oxygen to release energy.
Gale Encyclopedia of Public Health:
Krebs Cycle |
The Krebs cycle is a series of biochemical changes that occur during the metabolism of nutrients, facilitating the storage of energy for further use. It is named after Hans Adolph Krebs (1900–1981), the biochemist who identified it. The alternative, and more descriptive, name is the tricarboxylic, or citric acid, cycle. The fundamental process involves oxidizing acetate molecules to carbon dioxide (CO2) and water with transfer of the metabolic energy to "high energy" bonds for later use by the body. In the process, acetate is attached biochemically to a dicarboxylic acid to produce citric acids—the tricarboxylic acid from which the cycle derives its name. The citric acid then goes through a number of biochemical steps to oxidize the two carbons from acetate, and to regenerate the dicarboxylic acid to which the acetate was originally attached.
— GEORGE A. BRAY
Oxford Dictionary of Sports Science & Medicine:
Krebs cycle |
A series of aerobic chemical reactions occurring in mitochondria, in which carbon dioxide is produced and hydrogen is removed from carbon molecules; a process known as oxidative decarboxylation. The cycle is named after Sir Hans Krebs, the 1953 Nobel prize winner in Physiology and Medicine. The reactions are exothermic, enabling one molecule of ATP to be generated during each cycle.
Columbia Encyclopedia:
Krebs cycle |
Biology Q&A:
What is the Krebs cycle? |
The Krebs cycle (also referred to as the citric acid cycle) is
central to aerobic metabolism. It is an adaptation that allows cells to gain
increased energy from glucose. The process is critical to the development of
multicellular organisms, and is essential to the harvesting of high energy
electrons during the final breakdown of the glucose molecule. By-products of
this cycle are carbon dioxide and water. It is named in recognition of the
German chemist Hans Krebs (1900-1981), who received the 1953 Nobel Prize
in Physiology or Medicine.
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Wiley Dictionary of Flavors:
Kreb's Cycle |
Oxford Dictionary of Biochemistry:
Krebs cycle |
| Krabbe's disease, Kr, KpnI | |
| Krebs mammalian Ringer, Krebs' manometer fluid, Krebs-Cohen dismutation |
Saunders Veterinary Dictionary:
tricarboxylic acid cycle |
The cyclic metabolic mechanism by which the complete oxidation of the acetyl moiety of acetyl-coenzyme A is effected; abbreviated TCA cycle. It is the chief source of mammalian energy, during which acetyl groups derived from the metabolism of sugars, fatty acids and amino acid are oxidized to yield carbon dioxide, water and reduced coenzymes. Called also Krebs cycle and citric acid cycle.
Random House Word Menu:
categories related to 'tricarboxylic acid cycle' |
Wikipedia on Answers.com:
Citric acid cycle |
The citric acid cycle — also known as the tricarboxylic acid cycle (TCA cycle), the Krebs cycle, or the Szent-Györgyi–Krebs cycle[1][2] — is a series of chemical reactions used by all aerobic organisms to generate energy through the oxidization of acetate derived from carbohydrates, fats and proteins into carbon dioxide and water. In addition, the cycle provides precursors for the biosynthesis of compounds including certain amino acids as well as the reducing agent NADH that is used in numerous biochemical reactions. Its central importance to many biochemical pathways suggests that it was one of the earliest established components of cellular metabolism and may have originated abiogenically.[3]
The name of this metabolic pathway is derived from citric acid (a type of tricarboxylic acid) that is first consumed and then regenerated by this sequence of reactions to complete the cycle. In addition, the cycle consumes acetate in the form of acetyl-CoA, reduces NAD+ to NADH, and produces carbon dioxide. The NADH generated by the TCA cycle is fed into the oxidative phosphorylation pathway. The net result of these two closely linked pathways is the oxidation of nutrients to produce energy in the form of ATP.
In eukaryotic cells, the citric acid cycle occurs in the matrix of the mitochondrion. Bacteria also use the TCA cycle to generate energy, but since they lack mitochondria, the reaction sequence is performed in the cytosol with the proton gradient for ATP production being across the plasma membrane rather than the inner membrane of the mitochondria.
The components and reactions of the citric acid cycle were established in the 1930s by seminal work from the Nobel laureates Albert Szent-Györgyi[4] and Hans Adolf Krebs.[5]
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Components of the TCA cycle were derived from anaerobic bacteria and the TCA cycle itself may have evolved more than once.[6] Theoretically there are several alternatives to the TCA cycle, however the TCA cycle appears to be the most efficient.[7] If several alternatives independently evolved, they all undoubtedly rapidly converged to the TCA cycle.
The citric acid cycle is a key component of the metabolic pathway by which all aerobic organisms generate energy. Through catabolism of sugars, fats, and proteins, a two carbon organic product acetate in the form of acetyl-CoA is produced. Acetyl-CoA along with two equivalents of water (H2O) are consumed by the citric acid cycle producing two equivalents of carbon dioxide (CO2) and one equivalent of HS-CoA. In addition, one complete turn of the cycle converts three equivalents of nicotinamide adenine dinucleotide (NAD+) into three equivalents of reduced NAD+ (NADH), one equivalent of ubiquinone (Q) into one equivalent of reduced ubiquinone (QH2), and one equivalent each of guanosine diphosphate (GDP) and inorganic phosphate (Pi) into one equivalent of guanosine triphosphate (GTP). The NADH and QH2 that is generated by the citric acid cycle is in turn used by the oxidative phosphorylation pathway to generate energy-rich adenosine triphosphate (ATP).
One of the primary sources of acetyl-CoA is sugars that are broken down by glycolysis to produce pyruvate that in turn is decarboxylated by the enzyme pyruvate dehydrogenase generating acetyl-CoA according to the following reaction scheme:
The product of this reaction, acetyl-CoA, is the starting point for the citric acid cycle. Below is a schematic outline of the cycle:
Two carbon atoms are oxidized to CO2, the energy from these reactions being transferred to other metabolic processes by GTP (or ATP), and as electrons in NADH and QH2. The NADH generated in the TCA cycle may later donate its electrons in oxidative phosphorylation to drive ATP synthesis; FADH2 is covalently attached to succinate dehydrogenase, an enzyme functioning both in the TCA cycle and the mitochondrial electron transport chain in oxidative phosphorylation. FADH2, therefore, facilitates transfer of electrons to coenzyme Q, which is the final electron acceptor of the reaction catalyzed by the Succinate:ubiquinone oxidoreductase complex, also acting as an intermediate in the electron transport chain.[9]
The citric acid cycle is continuously supplied with new carbon in the form of acetyl-CoA, entering at step 1 below.[10]
| Substrates | Products | Enzyme | Reaction type | Comment | |
|---|---|---|---|---|---|
| 1 | Oxaloacetate + Acetyl CoA + H2O |
Citrate + CoA-SH |
Citrate synthase | Aldol condensation | irreversible, extends the 4C oxaloacetate to a 6C molecule |
| 2 | Citrate | cis-Aconitate + H2O |
Aconitase | Dehydration | reversible isomerisation |
| 3 | cis-Aconitate + H2O |
Isocitrate | Hydration | ||
| 4 | Isocitrate + NAD+ |
Oxalosuccinate + NADH + H + |
Isocitrate dehydrogenase | Oxidation | generates NADH (equivalent of 2.5 ATP) |
| 5 | Oxalosuccinate | α-Ketoglutarate + CO2 |
Decarboxylation | rate-limiting, irreversible stage, generates a 5C molecule |
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| 6 | α-Ketoglutarate + NAD+ + CoA-SH |
Succinyl-CoA + NADH + H+ + CO2 |
α-Ketoglutarate dehydrogenase | Oxidative decarboxylation |
irreversible stage, generates NADH (equivalent of 2.5 ATP), regenerates the 4C chain (CoA excluded) |
| 7 | Succinyl-CoA + GDP + Pi |
Succinate + CoA-SH + GTP |
Succinyl-CoA synthetase | substrate-level phosphorylation | or ADP→ATP instead of GDP→GTP,[9] generates 1 ATP or equivalent |
| 8 | Succinate + ubiquinone (Q) |
Fumarate + ubiquinol (QH2) |
Succinate dehydrogenase | Oxidation | uses FAD as a prosthetic group (FAD→FADH2 in the first step of the reaction) in the enzyme,[9] generates the equivalent of 1.5 ATP |
| 9 | Fumarate + H2O |
L-Malate | Fumarase | Hydration | |
| 10 | L-Malate + NAD+ |
Oxaloacetate + NADH + H+ |
Malate dehydrogenase | Oxidation | reversible (in fact, equilibrium favors malate), generates NADH (equivalent of 2.5 ATP) |
Mitochondria in animals, including humans, possess two succinyl-CoA synthetases: one that produces GTP from GDP, and another that produces ATP from ADP.[11] Plants have the type that produces ATP (ADP-forming succinyl-CoA synthetase).[10] Several of the enzymes in the cycle may be loosely-associated in a multienzyme protein complex within the mitochondrial matrix.[12]
The GTP that is formed by GDP-forming succinyl-CoA synthetase may be utilized by nucleoside-diphosphate kinase to form ATP (the catalyzed reaction is GTP + ADP → GDP + ATP).[9]
Products of the first turn of the cycle are: one GTP (or ATP), three NADH, one QH2, two CO2.
Because two acetyl-CoA molecules are produced from each glucose molecule, two cycles are required per glucose molecule. Therefore, at the end of two cycles, the products are: two GTP, six NADH, two QH2, and four CO2
| Description | Reactants | Products |
| The sum of all reactions in the citric acid cycle is: | Acetyl-CoA + 3 NAD+ + Q + GDP + Pi + 2 H2O | → CoA-SH + 3 NADH + 3 H+ + QH2 + GTP + 2 CO2 |
| Combining the reactions occurring during the pyruvate oxidation with those occurring during the citric acid cycle, the following overall pyruvate oxidation reaction is obtained: | Pyruvate ion + 4 NAD+ + Q + GDP + Pi + 2 H2O | → 4 NADH + 4 H+ + QH2 + GTP + 3 CO2 |
| Combining the above reaction with the ones occurring in the course of glycolysis, the following overall glucose oxidation reaction (excluding reactions in the respiratory chain) is obtained: | Glucose + 10 NAD+ + 2 Q + 2 ADP + 2 GDP + 4 Pi + 2 H2O | → 10 NADH + 10 H+ + 2 QH2 + 2 ATP + 2 GTP + 6 CO2 |
The above reactions are balanced if Pi represents the H2PO4- ion, ADP and GDP the ADP2- and GDP2- ions, respectively, and ATP and GTP the ATP3- and GTP3- ions, respectively.
The total number of ATP obtained after complete oxidation of one glucose in glycolysis, citric acid cycle, and oxidative phosphorylation is estimated to be between 30 and 38. A recent assessment of the total ATP yield with the updated proton-to-ATP ratios provides an estimate of 29.85 ATP per glucose molecule.[13]
The regulation of the TCA cycle is largely determined by substrate availability and product inhibition. NADH, a product of all dehydrogenases in the TCA cycle with the exception of succinate dehydrogenase, inhibits pyruvate dehydrogenase, isocitrate dehydrogenase, α-ketoglutarate dehydrogenase, and also citrate synthase. Acetyl-coA inhibits pyruvate dehydrogenase, while succinyl-CoA inhibits alpha-ketoglutarate dehydrogenase and citrate synthase. When tested in vitro with TCA enzymes, ATP inhibits citrate synthase and α-ketoglutarate dehydrogenase; however, ATP levels do not change more than 10% in vivo between rest and vigorous exercise. There is no known allosteric mechanism that can account for large changes in reaction rate from an allosteric effector whose concentration changes less than 10%.[14]
Calcium is used as a regulator. It activates pyruvate dehydrogenase, isocitrate dehydrogenase and α-ketoglutarate dehydrogenase.[15] This increases the reaction rate of many of the steps in the cycle, and therefore increases flux throughout the pathway.
Citrate is used for feedback inhibition, as it inhibits phosphofructokinase, an enzyme involved in glycolysis that catalyses formation of fructose 1,6-bisphosphate,a precursor of pyruvate. This prevents a constant high rate of flux when there is an accumulation of citrate and a decrease in substrate for the enzyme.
Recent work has demonstrated an important link between intermediates of the citric acid cycle and the regulation of hypoxia-inducible factors (HIF). HIF plays a role in the regulation of oxygen homeostasis, and is a transcription factor that targets angiogenesis, vascular remodeling, glucose utilization, iron transport and apoptosis. HIF is synthesized consititutively, and hydroxylation of at least one of two critical proline residues mediates their interaction with the von Hippel Lindau E3 ubiquitin ligase complex, which targets them for rapid degradation. This reaction is catalysed by prolyl 4-hydroxylases. Fumarate and succinate have been identified as potent inhibitors of prolyl hydroxylases, thus leading to the stabilisation of HIF.[16]
Several catabolic pathways converge on the TCA cycle. Reactions that form intermediates of the TCA cycle in order to replenish them (especially during the scarcity of the intermediates) are called anaplerotic reactions.
The citric acid cycle is the third step in carbohydrate catabolism (the breakdown of sugars). Glycolysis breaks glucose (a six-carbon-molecule) down into pyruvate (a three-carbon molecule). In eukaryotes, pyruvate moves into the mitochondria. It is converted into acetyl-CoA by decarboxylation and enters the citric acid cycle.
In protein catabolism, proteins are broken down by proteases into their constituent amino acids. The carbon backbone of these amino acids can become a source of energy by being converted to acetyl-CoA and entering into the citric acid cycle.
In fat catabolism, triglycerides are hydrolyzed to break them into fatty acids and glycerol. In the liver the glycerol can be converted into glucose via dihydroxyacetone phosphate and glyceraldehyde-3-phosphate by way of gluconeogenesis. In many tissues, especially heart tissue, fatty acids are broken down through a process known as beta oxidation, which results in acetyl-CoA, which can be used in the citric acid cycle. Beta oxidation of fatty acids with an odd number of methylene groups produces propionyl CoA, which is then converted into succinyl-CoA and fed into the citric acid cycle.[17]
The total energy gained from the complete breakdown of one molecule of glucose by glycolysis, the citric acid cycle, and oxidative phosphorylation equals about 30 ATP molecules, in eukaryotes. The citric acid cycle is called an amphibolic pathway because it participates in both catabolism and anabolism.
Click on genes, proteins and metabolites below to link to respective articles. [18]
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| Citric Acid Cycle Metabolic Pathway | ||||||||||||||||||
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| Oxaloacetate | Malate | Fumarate | Succinate | Succinyl-CoA | ||||||||||||||
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| Acetyl-CoA | NADH + H+ | NAD+ | H2O | FADH2 | FAD | CoA + ATP(GTP) | Pi + ADP(GDP) | |||||||||||
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+ | H2O |  |
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NADH + H+ + CO2 | |||||||||||||
| CoA | NAD+ | |||||||||||||||||
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H2O |  |
H2O |  |
NAD(P)+ | NAD(P)H + H+ |  |
CO2 |  |
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| Citrate | cis-Aconitate | Isocitrate | Oxalosuccinate | α-Ketoglutarate | ||||||||||||||
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This entry is from Wikipedia, the leading user-contributed encyclopedia. It may not have been reviewed by professional editors (see full disclaimer)
 | citrate synthase |
| TCA |
| decarboxylation |
 | What is the Krebs Cycle? Read answer... |
| What is Krebs cycle? Read answer... |
| Does the aerobic cycle utilize the Krebs cycle? Read answer... |
 | What makes the Krebs cycle a cycle? |
| What is the 10 cycles of Krebs cycle? |
| How many cycles are in the Krebs cycle? |
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 | American Heritage Dictionary. The American Heritage® Dictionary of the English Language, Fourth Edition Copyright © 2007, 2000 by Houghton Mifflin Company. Updated in 2009. Published by Houghton Mifflin Company. All rights reserved. Read more |
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| Oxford Dictionary of Chemistry. A Dictionary of Chemistry. Sixth Edition. Copyright © Market House Books Ltd, 2008. All rights reserved. Read more |
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| Oxford Food & Fitness Dictionary. Food and Fitness: A Dictionary of Diet and Exercise. Copyright © 1997, 2003 by Oxford University Press. All rights reserved. Read more |
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| Gale Encyclopedia of Public Health. Encyclopedia of Public Health. Copyright © 2002 by The Gale Group, Inc. All rights reserved. Read more |
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| Oxford Dictionary of Sports Science & Medicine. The Oxford Dictionary of Sports Science & Medicine. Copyright © Michael Kent 1998, 2006, 2007. All rights reserved. Read more |
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