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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?

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Presentation on theme: "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?"— Presentation transcript:

1 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?

2 C H. 6 W ARM -U P 1. What are the 1 st and 2 nd laws of thermodynamics? 2. Give the definition and an example of: A. Catabolic reaction B. Anabolic reaction 3. Is the breakdown of glucose in cellular respiration exergonic or endergonic?

3 C H. 6 W ARM -U P 1. Draw and label the following: enzyme, active site, substrate. 2. Describe what is meant by the term induced fit. 3. What types of factors can affect an enzyme’s function?

4 C HAPTER 6 An Introduction to Metabolism

5 W HAT Y OU N EED T O K NOW : Examples of endergonic and exergonic reactions. The key role of ATP in energy coupling. That enzymes work by lowering the energy of activation. The catalytic cycle of an enzyme that results in the production of a final product. The factors that influence enzyme activity.

6 Metabolism is the totality of an organism’s chemical reactions Manage the materials and energy resources of a cell

7 Catabolic pathways release energy by breaking down complex molecules into simpler compounds Eg. digestive enzymes break down food  release energy Anabolic pathways consume energy to build complex molecules from simpler ones Eg. amino acids link to form muscle protein

8 E NERGY = CAPACITY TO DO WORK Kinetic energy (KE) : energy associated with motion Heat (thermal energy) is KE associated with random movement of atoms or molecules Potential energy (PE) : stored energy as a result of its position or structure Chemical energy is PE available for release in a chemical reaction converted Energy can be converted from one form to another Eg. chemical  mechanical  electrical

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10 closed A closed system, such as liquid in a thermos, is isolated from its surroundings open In an open system, energy and matter can be transferred between the system and its surroundings Organisms are open systems T HERMODYNAMICS IS THE STUDY OF ENERGY TRANSFORMATIONS THAT OCCUR IN NATURE

11 T HE F IRST L AW OF T HERMODYNAMICS  The energy of the universe is constant Energy can be transferred and transformed Energy cannot be created or destroyed Also called the principle of Conservation of Energy

12 T HE S ECOND L AW OF T HERMODYNAMICS  Every energy transfer or transformation increases the entropy (disorder) of the universe During every energy transfer or transformation, some energy is unusable, often lost as heat

13 Free energy Free energy : part of a system’s energy available to perform work  G = change in free energy Exergonic reaction Exergonic reaction : energy is released Spontaneous reaction  G < 0 Endergonic reaction Endergonic reaction : energy is required Absorb free energy  G > 0

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16 A cell does three main kinds of work: Mechanical Transport Chemical energy coupling: Cells manage energy resources to do work by energy coupling: using an exergonic process to drive an endergonic one

17 ATP ( adenosine triphosphate ) is the cell’s main energy source in energy coupling ATP = adenine + ribose + 3 phosphates

18 hydrolysis When the bonds between the phosphate groups are broken by hydrolysis  energy is released chemical change to a state of lower free energy This release of energy comes from the chemical change to a state of lower free energy, not in the phosphate bonds themselves

19 H OW ATP P ERFORMS W ORK Exergonic release of P i is used to do the endergonic work of cell When ATP is hydrolyzed, it becomes ADP (adenosine diphosphate)

20 NH 2 Glu P i P i P i P i NH 3 P P P ATP ADP Motor protein Mechanical work: ATP phosphorylates motor proteins Protein moved Membrane protein Solute Transport work: ATP phosphorylates transport proteins Solute transported Chemical work: ATP phosphorylates key reactants Reactants: Glutamic acid and ammonia Product (glutamine) made + + +

21 Catalyst Catalyst: substance that can change the rate of a reaction without being altered in the process Enzyme Enzyme = biological catalyst activation energy Speeds up metabolic reactions by lowering the activation energy (energy needed to start reaction)

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23 S UBSTRATE S PECIFICITY OF E NZYMES substrate The reactant that an enzyme acts on is called the enzyme’s substrate enzyme-substrate complex The enzyme binds to its substrate, forming an enzyme-substrate complex active site The active site is the region on the enzyme where the substrate binds

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27 INDUCED FIT : ENZYME FITS SNUGLY AROUND SUBSTRATE -- “CLASPING HANDSHAKE”

28 An enzyme’s activity can be affected by: temperature pH chemicals

29 C OFACTORS Cofactors Cofactors are nonprotein enzyme helpers such as minerals (eg. Zn, Fe, Cu) Coenzymes Coenzymes are organic cofactors (eg. vitamins) Enzyme Inhibitors Competitive inhibitor: active site Competitive inhibitor: binds to the active site of an enzyme, competes with substrate Noncompetitive inhibitor: another part nonfunctional Noncompetitive inhibitor: binds to another part of an enzyme  enzyme changes shape  active site is nonfunctional

30 I NHIBITION OF E NZYME A CTIVITY

31 R EGULATION OF E NZYME A CTIVITY To regulate metabolic pathways, the cell switches on/off the genes that encode specific enzymes Allosteric regulation : protein’s function at one site is affected by binding of a regulatory molecule to a separate site (allosteric site) Activator Activator – stabilizes active site Inhibitor Inhibitor – stabilizes inactive form Cooperativity Cooperativity – one substrate triggers shape change in other active sites  increase catalytic activity

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34 F EEDBACK I NHIBITION End product of a metabolic pathway shuts down pathway by binding to the allosteric site of an enzyme Prevent wasting chemical resources, increase efficiency of cell

35 F EEDBACK I NHIBITION


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