Essentials of the Living World How Cells Harvest Energy from Food

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Essentials of the Living World How Cells Harvest Energy from Food Second Edition George B. Johnson Jonathan B. Losos Chapter 8 How Cells Harvest Energy from Food Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.

8.1 Where Is the Energy in Food? The energy for living is obtained by breaking down the organic molecules originally produced in plants the ATP energy and reducing power invested in building the organic molecules are stripped away as the chemical bonds are broken and used to make ATP the oxidation of food stuffs to obtain energy is called cellular respiration

8.1 Where Is the Energy in Food? The process of aerobic respiration requires oxygen and carbohydrates C6H12O6 + 6 O2  6 CO2 + 6 H2O + energy The products are carbon dioxide, water, and energy (heat or ATP)

8.1 Where Is the Energy in Food? Cellular respiration takes place in two stages Glycolysis occurs in the cytoplasm does not require oxygen to generate ATP Krebs cycle occurs within the mitochondrion harvests energy-rich electrons through a cycle of oxidation reactions the electrons are passed to an electron transport chain in order to power the production of ATP

Figure 8.2 An overview of aerobic respiration

8.2 Using Coupled Reactions to Make ATP Glycolysis is a sequence of reactions that form a biochemical pathway in ten enzyme-catalyzed reactions, the six-carbon sugar glucose is broken into two three-carbon pyruvate molecules the breaking of the bond yields energy that is used to phosphorylate ADP to ATP this process is called substrate-level phosphorylation in addition, electrons and hydrogen are donated to NAD+ to form NADH

Figure 8.3 How glycolysis works

Figure 8.4 The reactions of glycolysis

8.2 Using Coupled Reactions to Make ATP Glycolysis yields only a small amount of ATP only two ATP are made for each molecule of glucose this is the only way organisms can derive energy from food in the absence of oxygen all organisms are capable of carrying out glycolysis this biochemical process was probably one of the earliest to evolve

8.2 Using Coupled Reactions to Make ATP Some organisms can still perform, after glycolysis, oxidation reactions to make ATP even in the absence of oxygen these organisms perform anaerobic respiration the process involves using an electron acceptor other than oxygen

8.2 Using Coupled Reactions to Make ATP Many organisms use sulfur, nitrate, or other inorganic compounds as the electron acceptor in place of oxygen during anaerobic respiration methanogens primitive archaea use CO2 as the electron acceptor in addition to hydrogens derived from organic molecules this process reduces CO2 to CH4 (methane) sulfur bacteria certain primitive bacteria can use inorganic sulfate (SO4) as an electron acceptor and form hydrogen sulfide (H2S)

8.2 Using Coupled Reactions to Make ATP In the absence of oxygen, animals and plants recycle NAD+ add the glycolysis-extracted electron in NADH to an organic compound this process is called fermentation animals, such as ourselves, add electrons to pyruvate and form lactate yeasts (single-celled fungi) first convert pyruvate into acetaldehyde and then add the extracted electron to form ethanol

Figure 8.5 Two types of fermentation

8.3 Harvesting Electrons from Chemical Bonds In the presence of oxygen, the first step of oxidative respiration in the mitochondrion is the oxidation of pyruvate pyruvate still contains considerable stored energy at the end of glycolysis the first step is to oxidize pyruvate to form acetyl-CoA

8.3 Harvesting Electrons from Chemical Bonds When pyruvate is oxidized, a single of its three carbons is cleaved off by the enzyme pyruvate dehydrogenase this carbon leaves as part of a CO2 molecule in addition, a hydrogen and electrons are removed from pyruvate and donated to NAD+ to form NADH the remaining two-carbon fragment of pyruvate is joined to a cofactor called coenzyme A (CoA) the final compound is called acetyl-CoA

Figure 8.6 Producing acetyl-CoA

8.3 Harvesting Electrons from Chemical Bonds The fate of acetyl-CoA depends on the availability of ATP in the cell if there is insufficient ATP, then the acetyl-CoA heads to the Krebs cycle If there is plentiful ATP, then the acetyl-CoA is diverted to fat synthesis for energy storage

8.3 Harvesting Electrons from Chemical Bonds The Krebs cycle is a series of nine reactions that can be broken down into three stages of oxidative respiration Acetyl-CoA enters the cycle and binds to a four-carbon molecule, forming a six-carbon molecule Two carbons are removed as CO2 and their electrons donated to NAD+. In addition, an ATP is produced. The four-carbon molecule is recycled and more electrons are extracted, forming NADH and FADH2.

Figure 8.8 How the Krebs cycle works

Figure 8.9 The Krebs cycle Note: a single glucose molecule produces two turns of the cycle, one for each of the two pyruvate molecules generated by glycolysis.

8.3 Harvesting Electrons from Chemical Bonds In the process of cellular respiration, the glucose is entirely consumed the energy from its chemical bonds has been transformed into four ATP molecules 10 NADH electron carriers 2 FADH2 electron carriers

8.4 Using the Electrons to Make ATP Mitochondria use chemiosmosis to make ATP first proton pump use energetic electrons extracted from food molecules to pump protons across the cristae as the concentration of protons builds up in the intermembrane space, the protons re-enter the matrix via ATP synthase channels their passage powers the production of ATP from ADP

8.4 Using the Electrons to Make ATP NADH and FADH2 transfer their electrons to a series of membrane-associated molecules called the electron transport chain the transport pass along the electrons to each other and act as proton pumps the last transport protein donates the electrons to hydrogen and oxygen in order to form water

Figure 8.10 The electron transport chain

8.4 Using the Electrons to Make ATP Chemiosmosis is integrated with electron transport electrons harvested from reduced carriers (NADH and FADH2) are used to drive proton pumps and concentrate protons in the intermembrane space the re-entry of the protons into the matrix across ATP synthase drives the synthesis of ATP by chemiosmosis

Figure 8.12 An overview of the electron transport chain and chemiosmosis

8.5 Glucose Is Not the Only Food Molecule Cells also get energy from foods other than sugars The other organic building blocks undergo chemical modifications that permit them to enter cellular respiration Figure 8.13 How cells obtain energy from foods

Inquiry & Analysis About how much of the total lactic acid is released after exercise stops? Is this result consistent with the hypothesis that fish maintain blood pH levels by delaying the release of lactic acid from muscles? Graph of How Lactic Acid Levels Change After Exercise