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Go to Section: Interest Grabber Rolling and Folding Some of the steps in cellular respiration take place in the membrane inside the cell structure called the mitochondrion, which has a folded inner membrane. What purpose do these folds serve? To find out the answer to this question, perform this activity. Section 9-2
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Go to Section: Interest Grabber continued 1.Obtain two sheets of paper and a metric ruler. What is the surface area of the paper? 2.Roll one sheet of paper into a tube lengthwise. What is the surface area of the rolled paper? 3.Fold the second sheet of paper into a fan. Then, roll the first sheet of paper around the folded paper so it is inside the rolled paper. What has happened to the surface area of the inside of the rolled paper? 4.What would be the value of increasing the surface area of the membrane inside a mitochondrion? Section 9-2
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Go to Section: Interest Grabber continued 1.Obtain two sheets of paper and a metric ruler. What is the surface area of the paper? The area will vary depending on the size of paper used. A sheet of notebook paper has an area of approximately 600 cm 3. Section 9-2
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Go to Section: Interest Grabber continued 2.Roll one sheet of paper into a tube lengthwise. What is the surface area of the rolled paper? The surface area is the same as the original sheet of paper. Section 9-2
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Go to Section: Interest Grabber continued 3.Fold the second sheet of paper into a fan. Then, roll the first sheet of paper around the folded paper so it is inside the rolled paper. What has happened to the surface area of the inside of the rolled paper? The surface area has increased (surface area of rolled paper + surface area of folded paper). Section 9-2
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Go to Section: Interest Grabber continued 4. What would be the value of increasing the surface area of the membrane inside a mitochondrion? Increasing the surface area increases the amount of space where chemical reactions can take place. Section 9-2
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Go to Section: Section Outline 9–2The Krebs Cycle and Electron Transport A.The Krebs Cycle B.Electron Transport C.The Totals D.Energy and Exercise 1.Quick Energy 2.Long-Term Energy E.Comparing Photosynthesis and Cellular Respiration Section 9-2
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Go to Section: Glucose Glycolysis Krebs cycle Electron transport Fermentation (without oxygen) Alcohol or lactic acid Chemical Pathways Section 9-1 The “fork in the road” happens following glycolysis. It just depends if oxygen is absent or present in deciding the path it takes next.
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Go to Section: Citric Acid Production Figure 9–6 The Krebs Cycle Section 9-2 Mitochondrion We will focus on the citric acid production first.
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Video 1 Chapter 09A.mpg video Video 1 Aerobic Respiration
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Go to Section: Flowchart Section 9-2 Glucose (C 6 H 12 0 6 ) + Oxygen (0 2 ) Glycolysis Krebs Cycle Electron Transport Chain Carbon Dioxide (CO 2 ) + Water (H 2 O) Cellular Respiration We will next focus on the Krebs Cycle. This is the path that is taken when oxygen is present.
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Go to Section: Citric Acid Production Figure 9–6 The Krebs Cycle Section 9-2 Mitochondrion
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Video 3 Chapter 09C.mpg video Video 3 Krebs Cycle, Part 1
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The end product of glycolysis was pyruvic acid (also known as pyruvate). The pyruvic acid enters the mitochondrion. The pyruvic acid & coenzyme A combine to form acetyl-CoA. 1 carbon atom from pyruvic acid becomes part of carbon dioxide and is released into the air. 1 CO 2 and 1 NADH are produced. Krebs Cycle AnimationKrebs Cycle Animation-(select #1) Acetyl-CoA Formation:
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Krebs Cycle AnimationKrebs Cycle Animation-(select #2) Citric Acid Formation: Pyruvic acid combines with oxaloacetic acid (oxaloacetate) to form citric acid, a 6- carbon molecule.
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Krebs Cycle AnimationKrebs Cycle Animation-(select #3) Electron Carriers are Reduced: In each turn of the Krebs cycle, the cell quickly converts a molecule GTP (guanosine triphosphate) into ADP producing ATP. A pair of high-energy electrons is accepted by electron carriers, changing NAD + to NADH and FAD into FADH 2.
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Video 4 Chapter 09D.mpg video Video 4 Krebs Cycle, Part 2
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Krebs Cycle (continued) 1 pyruvic acid generates 3 CO 2 4 NADH 1 FADH 2 1 ATP
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Go to Section: Flowchart Section 9-2 Glucose (C 6 H 12 0 6 ) + Oxygen (0 2 ) Glycolysis Krebs Cycle Electron Transport Chain Carbon Dioxide (CO 2 ) + Water (H 2 O) Cellular Respiration We will next focus on the Electron Transport Chain.
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Video 5 Chapter 09E.mpg Video 5 Electron Transport Chain, Part 1
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Video 6 Chapter 09F.mpg video Video 6 Electron Transport Chain, Part 2
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Electron Transport Chain AnimationElectron Transport Chain Animation- (select start, continue, and #1) Electron Transport Chain: High-energy electrons from NADH are passed along the electron transport chain. Every time 2 high-energy electrons transport down the electron transport chain, their energy is used to transport hydrogen ions (H + ) across the membrane.
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Electron Transport Chain AnimationElectron Transport Chain Animation- (select start, continue, and #2) Electron Transport Chain: High-energy electrons from FADH 2 are passed along the electron transport chain. Every time 2 high-energy electrons transport down the electron transport chain, their energy is used to transport hydrogen ions (H + ) across the membrane.
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Electron Transport Chain AnimationElectron Transport Chain Animation- (select start, continue, and #3) Electron Transport Chain: The high concentration of hydrogen ions in the intermembrane space represents potential energy that is harnessed to make ATP. As H + escape through protein channels, ATP synthase spin. Each time is rotates, ATP synthase grabs a low-energy ADP and attaches a phosphate forming ATP.
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Electron Transport Chain: At the end of the electron transport chain, is an enzyme that combines the electrons with the hydrogen ions and oxygen to form water. Oxygen serves as the final electron acceptor of the electron transport chain.
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Go to Section: Figure 9–7 Electron Transport Chain Section 9-2 Electron Transport Hydrogen Ion Movement ATP Production ATP synthase Channel Inner Membrane Matrix Intermembrane Space Mitochondrion
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Go to Section: Glucose Glycolysis Cytoplasm Pyruvic acid Electrons carried in NADH Krebs Cycle Electrons carried in NADH and FADH 2 Electron Transport Chain Mitochondrion Figure 9–2 Cellular Respiration: An Overview Mitochondrion Section 9-1
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KREBS CYCLE (also called the ___________ CYCLE) Happens in ___________ NADPH donates _______________ ATP donates _________________ CO 2 donates _________________________ to make __________ mitochondria Citric acid ENERGY STROMA Hydrogen Carbon & oxygen GLUCOSE
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SOUTH DAKOTA CORE SCIENCE STANDARDS 9-12.L.1.1. Students are able to relate cellular functions and processes to specialized structures within cells. Photosynthesis and respiration ATP-ADP energy cycle Role of enzymes Mitochondria Chloroplasts LIFE SCIENCE: Indicator 1: Understand the fundamental structures, functions, classifications, and mechanisms found in living things
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Core High School Life Science Performance Descriptors High school students performing at the ADVANCED level: analyze chemical reaction and chemical processes involved in the Calvin Cycle and Krebs Cycle; predict the function of a given structure; High school students performing at the PROFICIENT level: describe and give examples of chemical reactions required to sustain life (…role of enzymes) describe and give examples of chemical reactions required to sustain life (hydrolysis, dehydration synthesis, photosynthesis, cellular respiration, ADP/ATP, role of enzymes); describe the relationship between structure and function High school students performing at the BASIC level name chemical reactions required to sustain life (… role of enzymes) name chemical reactions required to sustain life (hydrolysis, dehydration synthesis, photosynthesis, cellular respiration, ADP/ATP, role of enzymes); recognize that different structures perform different functions;
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SOUTH DAKOTA ADVANCED SCIENCE STANDARDS 9-12.L.1.1A. Students are able to explain the physical and chemical processes of photosynthesis and cell respiration and their importance to plant and animal life. (SYNTHESIS) Examples: Krebs Cycle LIFE SCIENCE: Indicator 1: Understand the fundamental structures, functions, classifications, and mechanisms found in living things.
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Interne t Links from the authors on Creatine Share kimchi lab data Interactive test For links on cellular respiration, go to www.SciLinks.org and enter the Web Code as follows: cbn-3091. www.SciLinks.org For links on the Krebs cycle, go to www.SciLinks.org and enter the Web Code as follows: cbn-3092. www.SciLinks.org Go Online
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