Chapter 7 Cellular Respiration

Chapter 7 – Cellular Respiration

Phases of aerobic cellular respiration 1. Glycolysis

2. Transition or Acetyl-CoA reaction 3. Krebs cycle

4. Electron transport system

These phases are nothing more than metabolic reactions involving the conversion of glucose & other molecules into carbon dioxide & water

The resulting energy released from this conversion will be used to produce ATP

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Mitochondria structure

Similar in arrangement to the chloroplast 1. It is a double membrane organelle

2. The intermembrane space is bounded by the outer membrane & the inner membrane

3. The inner membrane encloses a central space called the matrix. The transition reaction & Krebs cycle occur within matrix

4.The inner membrane is folded into cristae. The electron transport system is located in the inner membrane or cristae.

Chapter 7 – Cellular Respiration

Glycolysis

Aerobic cell respiration begins with glycolysis 1. Glycolysis occurs in the cytoplasm

2. Reactants = glucose, 2 NAD⁺, 2 ATP, 4 ADP, 4 P_i

3. Products = 2 pyruvates, 2 NADH, 4 ATP (Net 2 ATP), 2 H₂O

NAD⁺ = nicotinamide adenine dinucleotide – a co-enzyme necessary for the reaction to go forward, H+ donator in the electron transport chain

During glycolysis NAD⁺ is reduced to NADH.

Since it’s being reduced, are other molecules being oxidized?

What kind of a reaction is the conversion of glucose

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Does this reaction require an input of energy to get it going?

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Transition or Acetyl-CoA reaction 1. Occurs in the matrix

2. Reactants = 2 pyruvates, 2 co-enzyme A (CoA), 2 NAD⁺ 3. Products = 2 acetyl CoA, 2 NADH + H⁺, 2 CO₂

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Krebs Cycle

1. Occurs in the matrix

2. Reactants = 2 acetyl CoA, 2 ADP, 2 P_i, 6 NAD⁺, 2 FAD 3. Products = 2 ATP, 6 NADH, 2 FADH₂, 4 CO₂

4. For every acetyl-CoA that enters the Krebs cycle, the cycle turns once. For every glucose molecule that starts cell respiration, 2 pyruvates are formed, forming 2 acetyl CoAs, thus turning the Krebs cycle twice

FAD – flavin adenine dinucleotide – co-enzyme necessary for the reaction as well as an electron donor in the electron transport chain

During Krebs cycle both NAD⁺ & FAD are reduced to NADH & FADH₂ respectively If both of these molecules are being reduced, are other molecules being oxidized?

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Electron Transport System (ETS) – Arnold’s comparison with ETS in chloroplasts

Chapter 7 – Cellular Respiration

Electron transport System

1. Occurs in within the inner membrane

2. Reactants = 6 NADH, 2 FADH₂, 6 O_2, ADP + P_i

3. Products = approximately 36 – 38 ATPs, 4 H₂O, ATP

Chapter 7 – Cellular Respiration

Electrons enter ETS from NADH & FADH₂

As the electrons are passed from carrier to carrier, H⁺ are pumped from the matrix into the intermembrane space, creating a huge concentration gradient for the H⁺ to flow down

The H ⁺ flow back into the matrix through ATP synthase, thus creating ATP from ADP

& P_i

The electrons “jump off” the last carrier & combine with O₂ to form H₂O This process of producing ATP in the presence of O₂ is called oxidative

phosphorylation & the overall process of utilizing a concentration gradient to produce ATP is called chemiosmosis or chemiosmotic phosphorylation

The direct transfer of a P_i from one molecule to ADP (glycolysis & Krebs) – substrate level phosphorylation

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

Energy yield from glucose metabolism

ATP produced via substrate level phosphorylation Glycolysis – 2 ATP

Krebs Cycle – 2 ATP

ATP produced via chemiosmosis 2 NADH from glycolysis – 4 ATP 2 NADH from transition step – 6 ATP 6 NADH from Krebs Cycle – 18 ATP 2 FADH₂ from Krebs Cycle – 4 ATP TOTAL

36 ATP

Efficiency 36 ATP = 263 kcal 1 glucose = 686 kcal

39% of the energy in glucose is converted to ATP, the rest is lost as HEAT

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

How do we utilize other molecules in the cellular respiration pathway?

Chapter 7 – Cellular Respiration

Fermentation

Ability to produce ATP when oxygen is NOT available Phases

1. Glycolysis

2. Reduction of pyruvate to lactic acid or alcohol Reduction step

1. Pyruvate is reduced to lactic acid or alcohol via the oxidation of NADH back to NAD⁺

2. Once NAD ⁺ is regenerated it can go back to the glycolytic pathway & be reduced again, thus enabling glycolysis to keep on running

Details

1. Only produces 2 ATPs per glucose

2. Lactic acid buildup will eventually change the pH in the muscle, leading to ….

Efficiency = 14.6 kcal / 686 kcal = 2.1%

Chapter 7 – Cellular Respiration

Chapter 7 – Cellular Respiration

PRACTICE QUESTIONS

1. What are the 4 steps of aerobic cellular respiration & where do they specifically occur in the cell or mitochondria?

2. Describe the structure of a mitochondria

3. What goes in & comes out of glycolysis, the transition reaction, & Krebs?

4. What is NADH?

5. How many times does Krebs cycle turn with every glucose metabolized?

6. Describe how ATP is synthesized in the ETS?

7. How does this compare with ATP synthesized in glycolysis?

8. What are the 2 possible products of fermentation?

9. What do your muscles start to hurt when they are going through fermentation?