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If you're behind a web filter, please make sure that the domains *.kastatic.org and *.kasandbox.org are unblocked. No worries! We‘ve got your back. Try BYJU‘S free classes today! Pyruvic acid is converted to CO2 Right on! Give the BNAT exam to get a 100% scholarship for BYJUS courses Glucose is converted in CO2 No worries! We‘ve got your back. Try BYJU‘S free classes today! Pyruvic acid is converted to ATP No worries! We‘ve got your back. Try BYJU‘S free classes today! Solution The correct option is CPyruvic acid is converted to CO2The Krebs cycle is the second phase in cellular respiration. It occurs in the mitochondria in the cell. The number of ATP molecules produced in the Krebs cycle is 2.Textbooks Question Papers Home Solution TCA cycle:The Tricarboxylic acid (TCA) cycle, commonly known as the Krebs or citric acid cycle, is the primary source of energy for cells and is an essential component of aerobic respiration. The TCA cycle and glycolysis are both parts of the cellular respiration process. In living organisms, cellular respiration occurs when food materials are broken down and the energy released is stored in the form of ATP, which is used to perform a variety of essential functions. The primary respiratory substrate is carbohydrate. Glycolysis occurs in the cytoplasm of all living creatures and is the first step in cellular respiration. Because it does not require oxygen, it can also be found in anaerobic organisms. It's a multi-step enzymatic reaction in which glucose is partially oxidized and two molecules of pyruvate are formed. In glycolysis, there is a net gain of 2 ATPs. 2 ATPs are produced in the TCA cycle per glucose molecule (2 acetyl CoA).Following glycolysis, the mechanism of cellular respiration involves another multi-step process—the Krebs cycle, which is also called the citric acid cycle or the tricarboxylic acid cycle. The Krebs cycle uses the two molecules of pyruvic acid formed in glycolysis and yields high-energy molecules of NADH and flavin adenine dinucleotide (FADH2), as well as some ATP. The Krebs cycle occurs in the mitochondrion of a cell (see Figure 6-1). This sausage-shaped organelle possesses inner and outer membranes and, therefore, inner and outer compartments. The inner membrane is folded over itself many times; the folds are called cristae. They are somewhat similar to the thylakoid membranes in chloroplasts (see Chapter 5). Located along the cristae are the important enzymes necessary for the proton pump and for ATP production. Prior to entering the Krebs cycle, the pyruvic acid molecules are altered. Each three-carbon pyruvic acid molecule undergoes conversion to a substance called acetyl-coenzyme A, or acetyl-CoA. During the process, the pyruvic acid molecule is broken down by an enzyme, one carbon atom is released in the form of carbon dioxide, and the remaining two carbon atoms are combined with a coenzyme called coenzyme A. This combination forms acetyl-CoA. In the process, electrons and a hydrogen ion are transferred to NAD to form high-energy NADH. Acetyl-CoA enters the Krebs cycle by combining with a four-carbon acid called oxaloacetic acid. The combination forms the six-carbon acid called citric acid. Citric acid undergoes a series of enzyme-catalyzed conversions. The conversions, which involve up to ten chemical reactions, are all brought about by enzymes. In many of the steps, high-energy electrons are released to NAD. The NAD molecule also acquires a hydrogen ion and becomes NADH. In one of the steps, FAD serves as the electron acceptor, and it acquires two hydrogen ions to become FADH2. Also, in one of the reactions, enough energy is released to synthesize a molecule of ATP. Because for each glucose molecule there are two pyruvic acid molecules entering the system, two ATP molecules are formed. Also during the Krebs cycle, the two carbon atoms of acetyl-CoA are released, and each forms a carbon dioxide molecule. Thus, for each acetyl-CoA entering the cycle, two carbon dioxide molecules are formed. Two acetyl-CoA molecules enter the cycle, and each has two carbon atoms, so four carbon dioxide molecules will form. Add these four molecules to the two carbon dioxide molecules formed in the conversion of pyruvic acid to acetyl-CoA, and it adds up to six carbon dioxide molecules. These six CO2 molecules are given off as waste gas in the Krebs cycle. They represent the six carbons of glucose that originally entered the process of glycolysis. At the end of the Krebs cycle, the final product is oxaloacetic acid. This is identical to the oxaloacetic acid that begins the cycle. Now the molecule is ready to accept another acetyl-CoA molecule to begin another turn of the cycle. All told, the Krebs cycle forms (per two molecules of pyruvic acid) two ATP molecules, ten NADH molecules, and two FADH2 molecules. The NADH and the FADH2 will be used in the electron transport system. Is 38 ATP produced in Krebs cycle?Enzymes of Krebs cycle are located in the fluid-filled matrix of mitochondria. Therefore, pyruvate diffuses into mitochondria and the gets converted into acetyl CoA to enter citric acid cycle. During citric acid cycle, 36 ATP molecules are produced.
Does Krebs cycle produce 36 ATP?Electron transfer from glycolysis' NADH and FADH2 molecules, pyruvate transformation, and the Krebs cycle generates up to 32 additional ATP molecules. As a result, in the process of cellular respiration, a single molecule of glucose can yield up to 36 molecules of ATP.
How many ATP are produced after glycolysis and the Krebs cycle?Glycolysis produces 2 ATP molecules, and the Krebs cycle produces 2 more. Electron transport from the molecules of NADH and FADH2 made from glycolysis, the transformation of pyruvate, and the Krebs cycle creates as many as 32 more ATP molecules.
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How many ATP are produced in Krebs cycle
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