Presentation is loading. Please wait.

Presentation is loading. Please wait.

Living Metabolism Part 1

Published byTamsyn Hardy Modified over 5 years ago

Similar presentations

Presentation on theme: "Living Metabolism Part 1"— Presentation transcript:

1 Living Metabolism Part 1
AP Biology Living Metabolism Part 1

2 Energy and Life Life requires energy to survive. The way that different organisms acquire this energy and use it to survive allows for diversity. In this unit we will look at energy, how energy is used by living organisms, and two processes that are fundamental to life.

3 Catabolism (Hydrolysis Reaction)
Reactants Amount of energy released (G < 0) Free energy Energy Products Progress of the reaction Exergonic reaction: energy released

4 Catabolism - Exergonic
Catabolism refers to the breaking down (hydrolysis) of a molecule. This process releases potential E stored in the chemical bonds of the molecule. This is an exergonic reaction, because heat is released into the environment. Cellular respiration is an example of a natural catabolic reaction.

5 Anabolism (Dehydration Synthesis)
Products Amount of energy required (G > 0) Free energy Energy Reactants Progress of the reaction Endergonic reaction: energy required

6 Anabolism - Endergonic
Anabolism refers to the assembly (dehydration synthesis) of molecules. This requires kinetic E to position monomers in a way that chemical bonds can be formed. This is an endergonic reaction, because energy is absorbed from the environment. Photosynthesis is an example of a natural anabolic reaction.

7 Energy Coupling Two processes united by Energy
THIS IS THE BIG PICTURE IDEA OF THIS WHOLE UNIT!! The processes of cellular respiration and photosynthesis are “coupled” by energy. One process uses light energy to create organic molecules, and the other process breaks those organic molecules down to release energy. These processes need one another to continue. It is a fantastic cycle that drives all life on Earth. Life requires free energy to survive. But, what is free energy?

8 Catabolism (Hydrolysis Reaction)
Reactants Amount of energy released (G < 0) Free energy Energy Products Progress of the reaction Exergonic reaction: energy released

9 Anabolism (Dehydration Synthesis)
Products Amount of energy required (G > 0) Free energy Energy Reactants Progress of the reaction Endergonic reaction: energy required

10 Bioenergetics Video Link

11 Free Energy – “Gibb’s” Gibb’s free energy is the energy that is available in a system to do work. Energy that is available to make ATP. ATP is used for the signal transduction pathway, moving materials around within the cell, moving materials across the membrane, and anabolic/catabolic reactions. The change is the free energy, determined by using the formula on the next slide, will be positive or negative, depending on the type of reaction.

12 Gibbs “Free” Energy Δ G = ΔH – TΔ S G- Gibbs “free” energy
H – Enthalpy (Total usable energy in the system) T – Temperature in Kelvin (273 + C⁰) S- Entropy (Disorder created by something being broken down) Δ – Change in a variable over time ****Overall, the change in free energy is the final energy minus the initial energy in the system.****

13 Free Energy Not all energy is available as a result of a reaction! Much of the energy is lost as heat. However: If the Δ G is negative, then there is energy available to do work. This is the result of cellular respiration. (Catabolic, Exergonic) If the Δ G is positive, then there is energy that is not available. It is in the chemical bonds. This is the result of photosynthesis. (Anabolic, Endergonic)

14 Practice Problems Calculate the Gibbs free energy change (Δ G ) for the following chemical reaction: ATP  ADP + Pi The reaction occurs at 68 °C, the change in heat (Δ H) = 19,070 cal, and the change in entropy (Δ S) = 90 cal/K. Is the reaction anabolic or catabolic? Endergonic or exergonic?

15 Practice Problems Calculate the Gibbs free energy change (Δ G) for the following chemical reaction: glutamate + NH3  glutamine + H2O The reaction occurs at 68 °C, the change in heat (Δ H) = 4103 cal, and the change in entropy (Δ S) = 2.4 cal/K. Is the reaction anabolic or catabolic? Endergonic or exergonic?

16 Unstable (Capable of work) vs. Stable (no work)
G < 0 G = 0 A closed hydroelectric system

17 Progress of the reaction
LE 8-6a Reactants Amount of energy released (G < 0) Free energy Energy Products Progress of the reaction Exergonic reaction: energy released

18 Progress of the reaction
LE 8-6b Products Amount of energy required (G > 0) Free energy Energy Reactants Progress of the reaction Endergonic reaction: energy required

19 Potential Energy vs. Kinetic Energy

20 Types of work performed by living cells
Motor protein Protein moved Mechanical work: ATP phosphorylates motor proteins Membrane protein ADP ATP + P i P P i Solute Solute transported Transport work: ATP phosphorylates transport proteins P NH2 + NH3 Glu + P i Glu Reactants: Glutamic acid and ammonia Product (glutamine) made Chemical work: ATP phosphorylates key reactants

21 ATP

22 Phosphorylation

Download ppt "Living Metabolism Part 1"

Similar presentations

The chemistry of life is organized into metabolic pathway

The chemistry of life is organized into metabolic pathway
An Introduction to Metabolism

An Introduction to Metabolism
Unit 2 Metabolic Processes. Metabolism Living organisms must constantly capture, store and use energy to carry out the functions of life. At any given.

Unit 2 Metabolic Processes. Metabolism Living organisms must constantly capture, store and use energy to carry out the functions of life. At any given.
Free Energy, ATP and Energy Coupling

Free Energy, ATP and Energy Coupling
Chapter 8~ An Introduction to Metabolism. Metabolism Metabolism Metabolism: The totality of an organism’s chemical processes; managing the material and.

Chapter 8~ An Introduction to Metabolism. Metabolism Metabolism Metabolism: The totality of an organism’s chemical processes; managing the material and.
 Living organisms require energy to perform functions. They:  Kidney cells: › to transports materials  Digestive tract: › break macromolecules  Heart:

 Living organisms require energy to perform functions. They:  Kidney cells: › to transports materials  Digestive tract: › break macromolecules  Heart:
Cell Energetics Concept Review. Energy: Big Idea in Science Energy flows in one direction, energy never cycles back to its source.

Cell Energetics Concept Review. Energy: Big Idea in Science Energy flows in one direction, energy never cycles back to its source.
Energetics Fueling Life. Energy takes various forms MECHANICAL L.

Energetics Fueling Life. Energy takes various forms MECHANICAL L.
Energy Exchanges 1st Law of Thermodynamics 2nd Law of Thermodynamics

Energy Exchanges 1st Law of Thermodynamics 2nd Law of Thermodynamics
C HAPTER 6 W ARM -U P 1. Define metabolism. 2. List 3 forms of energy. 3. Where does the energy available for nearly all living things on earth come from?

C HAPTER 6 W ARM -U P 1. Define metabolism. 2. List 3 forms of energy. 3. Where does the energy available for nearly all living things on earth come from?
An Introduction to Metabolism. Metabolism is the totality of an organism’s chemical reactions ◦ Manage the materials and energy resources of a cell.

An Introduction to Metabolism. Metabolism is the totality of an organism’s chemical reactions ◦ Manage the materials and energy resources of a cell.
Thermodynamics / Free Energy & ATP

Thermodynamics / Free Energy & ATP
Essential Questions Why do growth, reproduction, and maintenance of the organization of living systems require free energy and matter? What mechanisms.

Essential Questions Why do growth, reproduction, and maintenance of the organization of living systems require free energy and matter? What mechanisms.
ATP and Metabolism. Metabolism Totality of an organism’s chemical reactions Pathway of defined steps beginning with a specific molecule resulting in a.

ATP and Metabolism. Metabolism Totality of an organism’s chemical reactions Pathway of defined steps beginning with a specific molecule resulting in a.
AP Biology 2007-2008 Metabolism & Enzymes AP Biology From food webs to the life of a cell energy.

AP Biology Metabolism & Enzymes AP Biology From food webs to the life of a cell energy.
Chapter 6 ATP and Energy Coupling.  G  0  G  0 Equilibrium = Death At equilibrium, forward and reverse reactions occur at the same rate; it is a state.

Chapter 6 ATP and Energy Coupling.  G  0  G  0 Equilibrium = Death At equilibrium, forward and reverse reactions occur at the same rate; it is a state.
LEQ: What is the role of ATP in cellular activities?

LEQ: What is the role of ATP in cellular activities?
 Energy is the capacity to do work  Energy is measured in kcals or joules  Examples: Kinetic, Thermal, Potential, Chemical.

 Energy is the capacity to do work  Energy is measured in kcals or joules  Examples: Kinetic, Thermal, Potential, Chemical.
Energy Transformations Ch.6 Types of Systems? CLOSED, exchanges only energy OPEN, exchanges matter and energy.

Energy Transformations Ch.6 Types of Systems? CLOSED, exchanges only energy OPEN, exchanges matter and energy.
Thermodynamics and ATP Figure 8.UN01 Enzyme 1 Enzyme 2 Enzyme 3 Reaction 1 Reaction 2Reaction 3 ProductStarting molecule A B C D.

Thermodynamics and ATP Figure 8.UN01 Enzyme 1 Enzyme 2 Enzyme 3 Reaction 1 Reaction 2Reaction 3 ProductStarting molecule A B C D.

Similar presentations

Ads by Google