Metabolism Chapter 8 PDF

Summary

This document provides an introduction to metabolism, including details about catabolic and anabolic pathways, energy transformations, and the role of ATP. The text explains concepts like free energy and enzyme activity.

Full Transcript

Campbell and Reece
8

Chapter 8

Page
An Introduction to Metabolism

I. Metabolism, Energy and Life

Metabolism
Metabolism is all of an organism's chemical processes (an emergent property that arises from
interactions of molecules in the orderly environment of the cell)
Metabolism is very important for the management of cellular material and energy resources

Metabolic reactions
Metabolic reactions are organized into pathways of enzyme controlled chemical reactions.

Cells need a supply of molecules (food) and energy
Cells need to get rid of waste products

1. Catabolic pathways:
Catabolic pathways release energy by breaking down complex molecules into simple
molecules
Energy stored in complex molecules is made available to do work or transformed into readily
usable chemical forms (i.e., ATP)
small molecules resulting from the catabolism of complex energy rich molecules may be used
by the cell to build new molecules
Examples of catabolic reactions:
Digestive enzymes breaking down food
Cellular respiration, the breakdown of glucose in the presence of oxygen

Energy stored in compounds (potential energy) can be used to do WORK

Types of cellular work
 i. mechanical
ii. transport
iii. chemical - [i.e., endergonic reactions]

2. Anabolic pathways
Anabolic pathways use energy to synthesize complex molecules from simple molecules.
The synthesis of protein from amino acids is an example of anabolism

Bioenergetics is the study of how organisms manage their energy resources

Energy extracted from the environment is used to create order and carry out life processes
(Bioenergetics – the study of energy flows through living organisms)

II. Laws of Energy Transformations or Thermodynamics
1st Law - Energy can be transferred and transformed but cannot be created or destroyed.

2nd Law - Every energy transfer or transformation increases the entropy (i.e., randomness) of the
universe.

III. Free Energy and Metabolism

Energy = capacity to do work or cause change

Free energy (G) - portion of a system’s energy that can perform work when temperature and
pressure are uniform throughout the system
Biologists want to know which reactions occur spontaneously and which require input of energy
To do so, they need to determine energy changes that occur in chemical reactions

Change in free energy (DG)
o
DG = G final state
- Ginitial state
(spontaneous) &XCgOR
O

Re E
(non-spontaneous) endergonic
energy)
(Absorption of

Reactans-> Products

P energy - Release

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release of >
energy
-

low product
-

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enege rata
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reactant > absorb >
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IV. ATP and Energy Coupling

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High product- >
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Energy coupling - energy released by catabolic processes is used to drive anabolic processes

ATP (adenosine triphosphate)
ATP powers cellular work by coupling exergonic (i.e., energy releasing) reactions to endergonic
(i.e., energy storing) reactions
ATP mediates most but not all energy coupling in cells
ATP stores energy in unstable “high energy” bonds that can be hydrolyzed to release energy

ATP + H2O ® ADP + Pi DG= -7.3 kcal/mole in test tube
 exergonic reaction - proceeds spontaneously with a net release of free energy
energy released through the hydrolysis of ATP is coupled through production of
phosphorylated intermediates
The phosphorylated intermediate is more reactive than the original unphosphorylated molecule
endergonic reactions - stores energy

ATP is regenerated by energy coupling (ATP
cycle)
ADP + Pi ® ATP + H2O
DG= 7.3 kcal/mole in test tube

V. Chemical Reactions

Chemical reaction
Breaking and reforming of bonds resulting in the change in composition of matter
The initial energy needed to start a chemical reaction is called the free energy of activation, or
activation energy.
Steps involved in a chemical reaction

1. Absorption of Activation Energy (EA)
 Activation energy is the energy required to break bonds in reactants - usually obtained in the
form of heat from the environment
Bonds of reactants only break when molecules have absorbed enough heat from environment
to become unstable
Many exergonic reactions will not occur at a noticeable rate because of a significant EA barrier

2. Transition state
Unstable state
Enough energy has been absorbed to break chemical bonds

3. Reaction occurs
Energy is released as new bonds are formed

How can you increase the rate of a chemical reaction?

Overcoming the EA barrier
catalysts - chemical agents that increase the rate of a chemical reaction without being
permanently changed in the process.

Examples of biological catalysts
Protein enzymes

VI. Enzymes
Biological catalysts made of proteins
Enzymes
 speed up reactions by allowing the transition state to be reached at cellular temperatures,
they accelerate reactions that would occur eventually
Enzymes catalyze reactions by lowering the EA barrier but cannot change ∆G
They are very selective and therefore they determine which chemical processes will be
going on in the cell at any particular time (unlike an increase in temperature which would
increase the rate of every reaction in a cell)

Features of Enzymes
1. Enzymes are substrate specific
The reactant(s) that an enzyme acts upon is referred to as the enzyme's substrate(s)
The 3-dimensional conformation of an enzyme determines its substrate specificity

enzyme
Substrate(s) ⇄ Product(s)

2. Catalysis occurs in the enzyme's active site
The active site binds the substrate and is the enzyme's catalytic centre
The active site is usually a pocket or groove on the surface of the enzyme
Substrate entering the active site induces the enzyme to change its shape slightly so that there is
a better fit between substrate and enzyme - This is known as induced fit.
3. Catalytic cycle
Substrate + enzyme ® ES complex ® product + enzyme

a. Substrate binds to active site residues by weak interactions (e.g., H-bonds, ionic interactions)
b. Induced fit around substrate ® catalysis
Mechanisms for lowering EA
Proper positioning of two or more reactants
Distort chemical bonds
Provides appropriate microenvironment – e.g., pH
Participation of R-groups in the reaction

c. Product departs the active site.

d. Enzyme may take part in another reaction

Factors affect Enzyme Activity
Enzyme activator
i. An enzyme’s activity can be affected by
– General environmental factors, such as temperature and pH
– Chemicals that specifically influence the enzyme
ii. Each enzyme has an optimal temperature in which it can function
iii. Each enzyme has an optimal pH in which it can function
iv. Optimal conditions favor the most active shape for the enzyme molecule
2+ 2+ 2+ 2+
v. Cofactors are nonprotein enzyme helpers (metal ions – Mg , Mn , Zn , Ca )
vi. An organic cofactor is called a coenzyme ,Coenzymes include vitamins, and electron
carriers such as NADH.

Enzyme Inhibitors
a) irreversible - covalently bound to enzyme

b) reversible
competitive

noncompetitive
Note: Not all inhibitors are toxins - naturally occurring molecules regulate enzymatic reactions
by acting as inhibitors

Control of Metabolism
Selective regulation occurs in metabolic pathways (i.e., molecular traffic lights)
Example of enzyme regulation

Feedback inhibition - A metabolic pathway is switched off by its end product, which acts as an
inhibitor of an enzyme in the pathway.

In feedback inhibition, the end product of a metabolic pathway shuts down the pathway
Feedback inhibition prevents a cell from wasting chemical resources by synthesizing more
product than is needed