Cellular Respiration 1. g. Students know the role of the mitochondria in making stored chemical-bond energy available to cells by completing the breakdown of glucose to carbon dioxide. Mitochondria consist of a matrix where three-carbon fragments originating from carbohydrates are broken down (to CO2 and water) and of the cristae where ATP is produced. Cell respiration occurs in a series of reactions in which fats, proteins, and carbohydrates, mostly glucose, are broken down to produce carbon dioxide, water, and energy. Most of the energy from cell respiration is converted into ATP, a substance that powers most cell activities. 1. i.* Students know how chemiosmotic gradients in the mitochondria and chloroplast store energy for ATP production. Enzymes called ATP synthase, located within the thylakoid membranes in chloroplasts and cristae membranes in mitochondria, synthesize most ATP within cells. The thylakoid and cristae membranes are impermeable to protons except at pores that are coupled with the ATP synthase. The potential energy of the proton concentration gradient drives ATP synthesis as the protons move through the ATP synthase pores. The proton gradient is established by energy furnished by a flow of electrons passing through the electron transport system located within these membranes.

Mitochondria The matrix where 3-carbon pieces that came from carbohydrates are broken down to (CO2 and water) The cristae is where ATP is made

What Is ATP? Energy used by all Cells Adenosine Triphosphate Organic molecule containing high-energy Phosphate bonds

Chemical Structure of ATP Adenine Base 3 Phosphates Ribose Sugar

What Does ATP Do for You? It supplies YOU with ENERGY!

How Do We Get Energy From ATP? By breaking the high- energy bonds between the last two phosphates in ATP

When is ATP Made in the Body? During a Process called Cellular Respiration that takes place in both Plants & Animals

Cellular Respiration Is a series of reactions where fats, proteins, and carbohydrates, mostly glucose, are broken down to make CO2, water, and energy.

ATP Most of the energy from cell respiration is converted into ATP ATP is a substance that powers most cell activities.

Cellular Respiration Cellular Energy The Stages of Cellular Respiration Cellular respiration has two stages. Glycolysis The first stage of cellular respiration is called glycolysis. Aerobic and Anaerobic Respiration The second stage of cellular respiration is either aerobic respiration (in the presence of oxygen) or anaerobic respiration (in the absence of oxygen). A large amount of ATP is made during aerobic respiration. NAD+ is recycled during the anaerobic process of fermentation. 12

Cellular Respiration Stage One: Breakdown of Glucose Glycolysis Glucose is broken down to pyruvate during glycolysis, making some ATP. 13

Cellular Respiration Stage Two: Production of ATP Krebs Cycle The Krebs cycle is a series of reactions that produce energy-storing molecules during aerobic respiration. Electron Transport Chain During aerobic respiration, large amounts of ATP are made in an electron transport chain. 14

Cellular Respiration Fermentation in the Absence of Oxygen Fermentation When oxygen is not present, fermentation follows glycolysis, regenerating NAD+ needed for glycolysis to continue. Lactic Acid Fermentation In lactic acid fermentation, pyruvate is converted to lactate. 15

Cellular Respiration Cellular Respiration is a metabolic process like burning fuel Releases much of the energy in food to make ATP This ATP provides cells with the energy they need to carry out the activities of life. C6H12O6+6O2 6CO2 + 6H2O + ATP 1. g. Students know the role of the mitochondria in making stored chemical-bond energy available to cells by completing the breakdown of glucose to carbon dioxide. Mitochondria consist of a matrix where three-carbon fragments originating from carbohydrates are broken down (to CO2 and water) and of the cristae where ATP is produced. Cell respiration occurs in a series of reactions in which fats, proteins, and carbohydrates, mostly glucose, are broken down to produce carbon dioxide, water, and energy. Most of the energy from cell respiration is converted into ATP, a substance that powers most cell activities. 1. i.* Students know how chemiosmotic gradients in the mitochondria and chloroplast store energy for ATP production. Enzymes called ATP synthase, located within the thylakoid membranes in chloroplasts and cristae membranes in mitochondria, synthesize most ATP within cells. The thylakoid and cristae membranes are impermeable to protons except at pores that are coupled with the ATP synthase. The potential energy of the proton concentration gradient drives ATP synthesis as the protons move through the ATP synthase pores. The proton gradient is established by energy furnished by a flow of electrons passing through the electron transport system located within these membranes.