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Chapter 8: An Introduction to
Metabolism
Chapter 8: An Introduction to
Metabolism
MetabolismMetabolism
The sum of all chemical reactions that take place in the organism.
It is the way in which a cell manages its material and energy resources.
The sum of all chemical reactions that take place in the organism.
It is the way in which a cell manages its material and energy resources.
Pathways Within the Cell
Pathways Within the Cell
Anabolic:These are the build up pathways that use starting materials to build biologically useful molecules.
Anabolic:These are the build up pathways that use starting materials to build biologically useful molecules.
Catabolic:These are the breakdown pathways that use energy stored in the bonds of starting materials to drive the synthesis of energetic molecules.
Catabolic:These are the breakdown pathways that use energy stored in the bonds of starting materials to drive the synthesis of energetic molecules.
Anabolic PathwaysAnabolic Pathways
Building proteins from amino acids we obtain from eating food.
Building proteins from amino acids we obtain from eating food.
Catabolic PathwaysCatabolic Pathways
Forming ATP from Glucose.Glucose comes from the food we eat.
ATP is the energy source for the cell.
Forming ATP from Glucose.Glucose comes from the food we eat.
ATP is the energy source for the cell.
2 Main Types of Energy:
2 Main Types of Energy:
Potential Energy: The stored energy or the energy of position.
Kinetic Energy: The energy of motion.
Potential Energy: The stored energy or the energy of position.
Kinetic Energy: The energy of motion.
Chemical EnergyChemical Energy
This is a form of potential energy because it is energy that is stored. It is stored in the bonds of the molecule.
This is a form of potential energy because it is energy that is stored. It is stored in the bonds of the molecule.
ThermodynamicsThermodynamics
The study of energy transformation in a collection of matter is known as thermodynamics.
The study of energy transformation in a collection of matter is known as thermodynamics.
The System Vs. The Surroundings
The System Vs. The Surroundings
The system is the matter to be studied.
The system is the matter to be studied.
The surroundings are everything outside of the system.
The surroundings are everything outside of the system.
Two Types of SystemsTwo Types of Systems
An open system is one in which energy can be transferred to its surroundings.
An open system is one in which energy can be transferred to its surroundings.
A closed system is one that is isolated from its surroundings--no energy transfer takes place between the system and its surroundings.
A closed system is one that is isolated from its surroundings--no energy transfer takes place between the system and its surroundings.
Two Laws Which Govern Energy TransformationsTwo Laws Which Govern Energy TransformationsThe first law of thermodynamics
The second law of thermodynamics
The first law of thermodynamics
The second law of thermodynamics
The First Law of Thermodynamics
The First Law of Thermodynamics
Energy cannot be created nor destroyed, it can only change form. The energy is constant within the universe.
Energy cannot be created nor destroyed, it can only change form. The energy is constant within the universe.
The Second Law of Thermodynamics
The Second Law of Thermodynamics
Entropy within the universe is increasing.
Entropy within the universe is increasing.
Gibbs Free EnergyGibbs Free Energy
In terms of the energy in a system, the only thing we are concerned with is the free energy--known as the Gibbs Free Energy.
Gibbs Free Energy is the energy that is available to do work.
In terms of the energy in a system, the only thing we are concerned with is the free energy--known as the Gibbs Free Energy.
Gibbs Free Energy is the energy that is available to do work.
Enthalpy and EntropyEnthalpy and Entropy
Enthalpy is the heat of a system
Entropy is the randomness of a system.
Enthalpy is the heat of a system
Entropy is the randomness of a system.
Gibbs Free EnergyGibbs Free Energy
G = H -TSH = Enthalpy of a systemT = Temperature in KelvinS = Entropy of a system
G = H -TSH = Enthalpy of a systemT = Temperature in KelvinS = Entropy of a system
Gibbs Free EnergyGibbs Free Energy
When G is negative, the reaction is said to be spontaneous and the free energy of the reaction can be used by the cell.
Spontaneous doesn’t necessarily mean that the reaction occurs quickly.
When G is negative, the reaction is said to be spontaneous and the free energy of the reaction can be used by the cell.
Spontaneous doesn’t necessarily mean that the reaction occurs quickly.
Chemical ReactionsChemical Reactions
Exergonic--release heat, G is negative, and they are said to be spontaneous.
The molecules give off energy as they are broken down.
Exergonic--release heat, G is negative, and they are said to be spontaneous.
The molecules give off energy as they are broken down.
Endergonic--need heat to go, G is positive, and they are non-spontaneous.
The molecules created by this reaction store energy.
Endergonic--need heat to go, G is positive, and they are non-spontaneous.
The molecules created by this reaction store energy.
How does this relate to cells?
How does this relate to cells?
Within a cell, exergonic reactions are used to drive endergonic ones.
ATP is an exergonic molecule that supplies energy for chemical reaction within a cell.
Within a cell, exergonic reactions are used to drive endergonic ones.
ATP is an exergonic molecule that supplies energy for chemical reaction within a cell.
ATPATP
When a phosphate bond is broken in the ATP molecule, 7.3kcal of energy is given off and used by the cell to power endergonic reactions.
This process is called coupling.Coupling is when an endergonic reaction is “coupled” to the breaking of a phosphate bond from ATP.
When a phosphate bond is broken in the ATP molecule, 7.3kcal of energy is given off and used by the cell to power endergonic reactions.
This process is called coupling.Coupling is when an endergonic reaction is “coupled” to the breaking of a phosphate bond from ATP.
ExampleExample
When the body synthesizes glutamine from glutamic acid and ammonia, energy is required (endergonic). To make the reaction go, it is coupled to the hydrolysis of ATP (which is exergonic).
When the ATP is hydrolyzed, an intermediate is phosphorylated. The intermediate is moe reactive and reacts easier and more quickly to give the desired result.
When the body synthesizes glutamine from glutamic acid and ammonia, energy is required (endergonic). To make the reaction go, it is coupled to the hydrolysis of ATP (which is exergonic).
When the ATP is hydrolyzed, an intermediate is phosphorylated. The intermediate is moe reactive and reacts easier and more quickly to give the desired result.
ATP GenerationATP Generation
Just as ATP is used to power cellular processes, it is regenerated from catabolic pathways.
Energy releasing processes such as cellular respiration provide energy for synthesizing ATP.
Just as ATP is used to power cellular processes, it is regenerated from catabolic pathways.
Energy releasing processes such as cellular respiration provide energy for synthesizing ATP.
EnzymesEnzymes
Enzymes are used by the cell to lower the activation energy required for a chemical reaction.
Most enzymes are proteins.
Enzymes are used by the cell to lower the activation energy required for a chemical reaction.
Most enzymes are proteins.
EnzymesEnzymes
More specifically, within a cell, enzymes are proteins that bind to a specific substrate on which the enzyme acts forming an enzyme-substrate complex.
More specifically, within a cell, enzymes are proteins that bind to a specific substrate on which the enzyme acts forming an enzyme-substrate complex.
Enzymes Enzymes
The enzyme-substrate complex forms an “induced” (tight) fit between the enzyme and the substrate at the active site.
The enzyme-substrate complex forms an “induced” (tight) fit between the enzyme and the substrate at the active site.
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Lowering of the Activation EnergyLowering of the
Activation EnergyThere are a variety of ways in which the enzyme lowers the activation energy of a reaction.
There are a variety of ways in which the enzyme lowers the activation energy of a reaction.
Lowering of the Activation EnergyLowering of the
Activation Energy1. The active site acts as a mediator that brings things close together so they can react.
2. The substrate molecules can be stretched toward their transition state which stresses bonds that need to be broken during a chemical reaction.
1. The active site acts as a mediator that brings things close together so they can react.
2. The substrate molecules can be stretched toward their transition state which stresses bonds that need to be broken during a chemical reaction.
Lowering of the Activation EnergyLowering of the
Activation Energy3. The enzyme may make the microenvironment for a reaction more favorable than normal.
4. The active site may actually participate in the chemical reaction (covalently) and the remaining steps of the reaction restore the enzyme to its beginning conformation enabling it to perform another reaction.
3. The enzyme may make the microenvironment for a reaction more favorable than normal.
4. The active site may actually participate in the chemical reaction (covalently) and the remaining steps of the reaction restore the enzyme to its beginning conformation enabling it to perform another reaction.
How Enzymes WorkHow Enzymes Work
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Things which affect enzyme function
Things which affect enzyme function
Temperature and pH denature the protein.
Cofators help an enzyme function.Often inorganic, metal ions are an example
Coenzymes which are organic substances also help. Often organic, vitamins are an example
Temperature and pH denature the protein.
Cofators help an enzyme function.Often inorganic, metal ions are an example
Coenzymes which are organic substances also help. Often organic, vitamins are an example
Things which affect enzyme function
Things which affect enzyme function
Inhibitors--slow or stop enzyme activityCompetitive inhibitors--compete with substrate molecules for the active site of an enzyme.
Non-competitive inhibitors bind to a spot other than the active site altering the active site slowing a reaction.
Inhibitors--slow or stop enzyme activityCompetitive inhibitors--compete with substrate molecules for the active site of an enzyme.
Non-competitive inhibitors bind to a spot other than the active site altering the active site slowing a reaction.
Regulation of Enzyme Activity
Regulation of Enzyme Activity
Allosteric regulation--occurs when a regulatory molecule binds reversibly to the enzyme slowing or stopping an enzyme’s function.
Allosteric regulation--occurs when a regulatory molecule binds reversibly to the enzyme slowing or stopping an enzyme’s function.
Regulation of Enzyme Activity
Regulation of Enzyme Activity
Feedback inhibition occurs when a metabolic pathway is switched off by the inhibitory binding of an end product to an enzyme early in the pathway.
This is a way for the cell to conserve energy.
Feedback inhibition occurs when a metabolic pathway is switched off by the inhibitory binding of an end product to an enzyme early in the pathway.
This is a way for the cell to conserve energy.
PlasmolysisPlasmolysis
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07_13Plasmolysis_SV.mpg
EndocytosisEndocytosis
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ExocytosisExocytosis
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PhagocytosisPhagocytosis
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PinocytosisPinocytosis
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Receptor Mediated Endocytosis
Receptor Mediated Endocytosis
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