Concept explainers
Videos
Cellular
(a)
To determine: Whether the glycolysis, the citric acid cycle, or the electron transport chain is directly related to O2 consumption.
Introduction: Glycolysis is a metabolic pathway in which conversion of glucose (6 carbon compounds) into pyruvate (3 carbon compound) takes place. Glycolysis results in the degradation of glucose and production of high energy molecules -ATP and NADPH. In the citric acid cycle, the oxidation of acetyl-CoA takes place through a series of chemical reactions to release high-energy molecules-ATP, NADH and, also CO2. In electron transport system, the redox reaction takes place to create an electrochemical proton gradient. This gradient will help in driving ATP synthesis.
Explanation of Solution
Glycolysis comprises of ten biochemical reactions to convert glucose into pyruvate. Glycolysis is the first step of cellular respiration, but it does not require oxygen for completion. The glycolysis also takes place in the anaerobic organism. The citric acid cycle is the second step of cellular respiration and provides energy molecules-NADH, FADH2 to electron transport chain after oxidation of acetyl CoA. The citric acid cycle does not require oxygen directly; it only depends on the product, which is formed in the presence of oxygen by the electron transport chain. Electron transport chain (ETC) is the part of the last step of cellular respiration. During ETC, the oxygen is consumed to form water.
The oxygen consumption is directly related to the electron transport system.
(b)
To determine: Whether the glycolysis, the citric acid cycle, or the electron transport chain is directly related to CO2 production.
Introduction: Glycolysis is the first step in the splitting of glucose into pyruvates and extract energy for cellular respiration. In citric acid cycle, the acetyl CoA is modified using mitochondrial enzymes and high energy intermediates are produced. These intermediates will be used in the next step of cellular respiration. In electron transport chain, a proton gradient is formed across the inner mitochondrial membrane and .ATP synthesis is derived.
Explanation of Solution
Glycolysis is the first step of cellular respiration. The pyruvate formed at the end of glycolysis can further be oxidized to carbon dioxide and two carbon acetyl group, but this oxidation of pyruvate is not a part of glycolysis. The second step of cellular respiration is citric acid cycle which provides energy molecules-NADH, FADH2 to electron transport chain after oxidation of acetyl CoA. The reduction of NAD+ to NADH during the citric acid cycle releases CO2. Electron transport chain (ETC) is the part of the last step of cellular respiration. In electron transport chain, a proton gradient is formed across the inner mitochondrial membrane and .ATP synthesis is derived. There is no production of carbon dioxide during the electron transport chain.
The carbon dioxide production is directly associated with the citric acid cycle.
Want to see more full solutions like this?
Chapter 18 Solutions
Human Physiology: An Integrated Approach (7th Edition)
- Question: Role of the triacyl glycerol cycle. Summarize the cycle referring to Figure 19.9. What role does the cycle play in metabolism? Here are some infromation: Metabolic integration within the human body depends on the redistribution of metabolites, ions, and hormones by the circulatory system. This complex network consists of ∼150,000 km of blood vessels (from major veins and arteries to microcapillaries) that recycle 6 L of blood every minute throughout the body. The circulatory system links together the major tissues and organs of the body in such a way that biochemical pathways in different cells share metabolites, ensuring that the metabolic efficiency of the whole organism is greater than the sum of its parts. This process of maintaining optimal metabolite concentrations and managing chemical energy reserves in tissues is called metabolic homeostasis. This term describes steady-state conditions that apply to a wide variety of physiologic parameters. Metabolic homeostasis is…arrow_forwardBIOC 384 Glycolytic Pathway Q9.2: What is the total number of moles of ATP generated per mole of glucose in the glycolytic pathway and which enzymatic reactions generate these ATP molecules? Why are these reactions called "substrate level phosphorylation" reactions?arrow_forwardQ.2 Answer ALL parts: The scheme shown below in Figure 3, outlines the fate of glucose during cellular respiration: Glucose (I) Рyruvate (II) (VI) Acetyl CoA Lactic acid Acetaldehyde (VII) Ethanol (III) Oxidative (IV) phosphorylation Figure 3: Schematic representation of the fate of glucose during respiration (a) Diagram the steps involved in the process labelled (I) in the figure given above.arrow_forward
- A. Using a simplified series of diagrams describe how a cell can extract 38 molecules of ATP(net)from one molecule of glucoses. B.What is the difference between aerobic and anaerobic respiration? How is fermentation different from both of them? Discuss two common fermentations that we use to make everyday useful products.arrow_forwardTopic : Connection between Electron Transport & Phosphorylation Task: 1. Define P/O ratio 2. Explain its importance State all the explanations in point formarrow_forwardQuestion:- Explain the detail summary of ATP produced for six glucose molecules in an inactive and active cells if the enzyme that convert dihydroacetone phosphate failed to convert it into the isomer glyceraldehyde-3-phosphate. Elaborate futher the difference in terms of ATP production between two types of cells.arrow_forward
- Bioenergetics: Answer the following questions regarding bioenergetics/ oxidative phosphorylation: Given the following reactions and AGs for each reaction, answer the two questions that follow; be sure to give complete answer including proper units and sign(s) wherever necessary: Reaction #1 (AG = -2.3 kcal/mol): A+ B2 C+D Reaction #2 (AG = +5.3 kcal/mol): C+ K 2R Reaction #3 (AG = -4.5 kcal/mol): R 2 Y+Z 7. Calculate AG for overall reaction: AR>Z Free Energy Change Reactions #1-3 = 8. Which direction is this overall process (#1-3) predicted to go (circle one)? forward OR backwardarrow_forwardACTIVITY 10.6.1 Label the diagram and explain the salient feature that is happening in each item. For the complexes and the mobile carriers, kindly give their alternative names Electron Transport Chain Intermembrane space Inner mitochondrial membrane Intermembrane space H* 3 7 Mitochondrial matrix 2e FADH2 NADH FAD 2H*+ 1/202 H,0 NAD* + H* ATP ADP Mitochondrial matrix Inner mitochondrial membrane P, Name of the Transporter Essential Features 1. 3. 4. 6. 7. 4. 2. 2. 5.arrow_forwardce BiochemistryQ&A Library1. Under aerobic catabolism of glucose, in which compartment of the eukaryotic cell does the following reactions occur? a. Conversion of pyruvate to acetyl CoA. b. Conversion of succinyl-CoA to succinate c. Conversion of NADH to ATP d. Conversion of phosphoglycerate to phosphoenolpyruvate 1. Under aerobic catabolism of glucose, in which compartment of the eukaryotic cell does the following reactions occur? a. Conversion of pyruvate to acetyl CoA. b. Conversion of succinyl-CoA to succinate c. Conversion of NADH to ATP d. Conversion of phosphoglycerate to phosphoenolpyruvate Question 1. Under aerobic catabolism of glucose, in which compartment of the eukaryotic cell does the following reactions occur? (i) Conversion of pyruvate to acetyl CoA. (ii) Conversion of succinyl-CoA to succinate (iii) Conversion of NADH to ATP (iv) Conversion of phosphoglycerate to phosphoenolpyruvate 2. Describe various mechanisms for regulation of…arrow_forward
- Describe redox reactions involved in the three steps of aerobic cellular respiration under the following topics: 1. Description of the two coenzymes NAD and FAD and link them to each enzyme in glycolysis; pyruvate oxidation and citric acid cycle using the backpack analogy that I described in class. (20%) 2. Describe energy harvesting of the electrons and hydrogens carried by the coenzymes in the electron transport chain and chemiosmosis using the battery analogy I described in class. (20%) 3. Describe the steps of DNA replication in bacteria as shown in our slides emphasizing the need for the Okazaki fragments (20%) 4. Describe RNA transcription emphasizing the two strands of DNA and the orientation of mRNA (20%) 5. Describe mRNA translation emphasizing the role of ribosomes and tRNA for two amino acids (20%)arrow_forwardDuring glycolysis, transition, and the citric acid cycle: How many ATP (or GTP) is made in each step? Why is CO2 made in some steps? (Hint: this is NOT from O2) Which steps make activated carrier molecules? What are they “carrying”?arrow_forwardMatching (Letters may be used twice) DD DDD DD Where is the electron transport chain located? Where does the Krebs cycle occur? What membrane do protons cross in the synthesis of ATP? Where does glycolysis occur? Where does the oxidation of pyruvate occur? Where does the most substrate level phosphorylation occur? Where is most NADH oxidized to NAD+? What membrane does glucose have to cross? 1. Cell membrane 2. nucleus 3. intermembrane space 4. mitochondrial matrix 5. chloroplast 6. cytoplasm 7. outer mitochondrial membrane 8. inner mitochondrial membranearrow_forward
Human Anatomy & Physiology (11th Edition)BiologyISBN:9780134580999Author:Elaine N. Marieb, Katja N. HoehnPublisher:PEARSON
Biology 2eBiologyISBN:9781947172517Author:Matthew Douglas, Jung Choi, Mary Ann ClarkPublisher:OpenStax
Anatomy & PhysiologyBiologyISBN:9781259398629Author:McKinley, Michael P., O'loughlin, Valerie Dean, Bidle, Theresa StouterPublisher:Mcgraw Hill Education,
Molecular Biology of the Cell (Sixth Edition)BiologyISBN:9780815344322Author:Bruce Alberts, Alexander D. Johnson, Julian Lewis, David Morgan, Martin Raff, Keith Roberts, Peter WalterPublisher:W. W. Norton & Company
Laboratory Manual For Human Anatomy & PhysiologyBiologyISBN:9781260159363Author:Martin, Terry R., Prentice-craver, CynthiaPublisher:McGraw-Hill Publishing Co.
Inquiry Into Life (16th Edition)BiologyISBN:9781260231700Author:Sylvia S. Mader, Michael WindelspechtPublisher:McGraw Hill Education