1. Chapter 4 Cellular Metabolism
Hole’s Human Anatomy and Physiology Twelfth Edition Shier w Butler w Lewis
Chapter 4
Cellular Metabolism
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2. 4.2: Metabolic Processes
Metabolic processes – all chemical reactions that occur in the body
There are two (2) types of metabolic reactions:
Anabolism
Larger molecules are made from smaller ones
Requires energy
Catabolism
Larger molecules are broken down into smaller ones
Releases energy

3. Anabolism
Anabolism provides the materials needed for cellular growth and repair
Dehydration synthesis
Type of anabolic process
Used to make polysaccharides, triglycerides, and proteins
Produces water
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CH2OH
CH2OH
CH2OH
CH2OH O O O O H H H H H H H H H H H H
H2O O HO OH H OH HO OH H OH HO OH H OH H OH H OH H OH H OH H OH
Monosaccharide +
Monosaccharide
Disaccharide +
Water

4. Anabolism + + H O H O H C OH HO C (CH2)14 CH3 H C O C (CH2)14 CH3 O O
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. H O H O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3 O O
H2O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3
H2O
H2O O O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3 H H
Glycerol +
3 fatty acid molecules
Fat molecule (triglyceride) +
3 water
molecules
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Peptide
bond H H H H H O O R R H O H O H H H O O N C C N C C N N C C C C N N C C C C OH OH
H2O H O H H O H H H R R R R H H H H
Amino acid +
Amino acid
Dipeptide molecule +
Water

5. Catabolism Catabolism breaks down larger molecules into smaller ones
Hydrolysis
A catabolic process
Used to decompose carbohydrates, lipids, and proteins
Water is used to split the substances
Reverse of dehydration synthesis
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CH2OH
CH2OH
CH2OH
CH2OH O O O O H H H H H H H H H H H H
H2O O HO OH H OH HO OH H OH HO OH H OH H OH H OH H OH H OH H OH
Monosaccharide +
Monosaccharide
Disaccharide +
Water

6. Catabolism + + H O H O H C OH HO C (CH2)14 CH3 H C O C (CH2)14 CH3 O O
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. H O H O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3 O O
H2O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3
H2O
H2O O O H C OH HO C
(CH2)14 CH3 H C O C
(CH2)14 CH3 H H
Glycerol +
3 fatty acid molecules
Fat molecule (triglyceride) +
3 water
molecules
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Peptide
bond H H H H H O O R R H O H O H H H O O N C C N C C N N C C C C N N C C C C OH OH
H2O H O H H O H H H R R R R H H H H
Amino acid +
Amino acid
Dipeptide molecule +
Water

7. 4.3: Control of Metabolic Reactions
Enzymes
Control rates of metabolic reactions
Lower activation energy needed to start reactions
Most are globular proteins with specific shapes
Not consumed in chemical reactions
Substrate specific
Shape of active site determines substrate
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Substrate molecules
Product molecule
Active site
Enzyme
molecule
Enzyme-substrate
complex
Unaltered
enzyme
molecule
(a)
(b)
(c)

8. Enzyme Action Metabolic pathways Enzyme names commonly:
Series of enzyme-controlled reactions leading to formation of a product
Each new substrate is the product of the previous reaction
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Substrate 1
Enzyme A
Substrate 2
Enzyme B
Substrate 3
Enzyme C
Substrate 4
Enzyme D
Product
Enzyme names commonly:
Reflect the substrate
Have the suffix – ase
Examples: sucrase, lactase, protease, lipase

9. Cofactors and Coenzymes
Make some enzymes active
Non-protein component
Ions (magnesium, zinc, etc.) or coenzymes
Coenzymes
Organic molecules that act as cofactors
Vitamins

10. Factors That Alter Enzymes
Heat
Radiation
Electricity
Chemicals
Changes in pH

11. Animation: How Enzymes Work
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12. Regulation of Metabolic Pathways
Limited number of regulatory enzymes
Negative feedback
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Inhibition
Rate-limiting
Enzyme A
Substrate 1
Substrate 2
Enzyme B
Substrate 3
Enzyme C
Substrate 4
Enzyme D
Product

13. 4.4: Energy for Metabolic Reactions
Energy is the capacity to change something; it is the ability to do work .
Common forms of energy:
Heat
Light
Sound
Electrical energy
Mechanical energy
Chemical energy

14. ATP Molecules Each ATP molecule has three parts:
An adenine molecule
A ribose molecule
Three phosphate molecules in a chain
Third phosphate attached by high-energy bond
When the bond is broken, energy is transferred
When the bond is broken, ATP becomes ADP
ADP becomes ATP through phosphorylation
Phosphorylation requires energy released from cellular respiration
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. P P P
Energy transferred
from cellular
respiration used
to reattach
phosphate
Energy transferred
and utilized by
metabolic
reactions when
phosphate bond
is broken P P P P

15. 4.5: Cellular Respiration
Occurs in a series of reactions:
Glycolysis
Citric acid cycle (or Kreb’s Cycle)
Electron transport system
Chemical bonds are broken to release energy
We burn glucose in a process called oxidation

16. Cellular Respiration Produces: Carbon dioxide Water
ATP (chemical energy)
Heat
Includes:
Anaerobic reactions (without O2) - produce little ATP
Aerobic reactions (requires O2) - produce most ATP

17. Glycolysis Series of ten reactions
Breaks down glucose into 2 pyruvic acid molecules
Occurs in cytosol
Anaerobic phase of cellular respiration
Yields two ATP molecules per glucose molecule
Summarized by three main phases or events:
Phosphorylation
Splitting
Production of NADH and ATP

18. Glycolysis Event 1 - Phosphorylation Two phosphates added to glucose
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Event 1 - Phosphorylation
Two phosphates added to glucose
Requires ATP
Phase 1
priming
Glucose
Carbon atom P
Phosphate 2
ATP
2 ADP
Fructose-1,6-diphosphate P P
Phase 2
cleavage
Event 2 – Splitting (cleavage)
6-carbon glucose split into two 3-carbon molecules
Dihydroxyacetone
phosphate
Glyceraldehyde
phosphate P P
Phase 3
oxidation and
formation of
ATP and release
of high energy
electrons P
2 NAD+
4 ADP
2 NADH + H+ 4
ATP
2 Pyruvic acid O2 O2
2 NADH + H+
2 NAD+
To citric acid cycle
and electron transport
chain (aerobic pathway)
2 Lactic acid

19. Glycolysis Event 3 – Production of NADH and ATP
Hydrogen atoms are released
Hydrogen atoms bind to NAD+ to produce NADH
NADH delivers hydrogen atoms to electron transport system if oxygen is available
ADP is phosphorylated to become ATP
Two molecules of pyruvic acid are produced
Two molecules of ATP are generated
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Phase 1
priming
Glucose
Carbon atom P
Phosphate 2
ATP
2 ADP
Fructose-1,6-diphosphate P P
Phase 2
cleavage
Dihydroxyacetone
phosphate
Glyceraldehyde
phosphate P P
Phase 3
oxidation and
formation of
ATP and release
of high energy
electrons P
2 NAD+
4 ADP
2 NADH + H+ 4
ATP
2 Pyruvic acid O2 O2
2 NADH + H+
2 NAD+
To citric acid cycle
and electron transport
chain (aerobic pathway)
2 Lactic acid

20. Anaerobic Reactions If oxygen is not available:
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If oxygen is not available:
Electron transport system cannot accept new electrons from NADH
Pyruvic acid is converted to lactic acid
Glycolysis is inhibited
ATP production is less than in aerobic reactions
Phase 1
priming
Glucose
Carbon atom P
Phosphate 2
ATP
2 ADP
Fructose-1,6-diphosphate P P
Phase 2
cleavage
Dihydroxyacetone
phosphate
Glyceraldehyde
phosphate P P
Phase 3
oxidation and
formation of
ATP and release
of high energy
electrons P
2 NAD+
4 ADP
2 NADH + H+ 4
ATP
2 Pyruvic acid O2 O2
2 NADH + H+
2 NAD+
To citric acid cycle
and electron transport
chain (aerobic pathway)
2 Lactic acid

21. Aerobic Reactions If oxygen is available:
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If oxygen is available:
Pyruvic acid is used to produce acetyl CoA
Citric acid cycle begins
Electron transport system functions
Carbon dioxide and water are formed
34 molecules of ATP are produced per each glucose molecule
Glucose
High energy
electrons (e–) and
hydrogen ions (H+) 2
ATP
Pyruvic acid
Pyruvic acid
Cytosol
Mitochondrion
High energy
electrons (e–) and
hydrogen ions (h+)
CO2
Acetyl CoA
Oxaloacetic
acid
Citric acid
High energy electrons (e–) and hydrogen ions (H+)
2 CO 2 2
ATP
Electron transport chain
32-34
ATP O 2 2e –
+ 2H + H 2 O

22. Citric Acid Cycle
Begins when acetyl CoA combines with oxaloacetic acid to produce citric acid
Citric acid is changed into oxaloacetic acid through a series of reactions
Cycle repeats as long as pyruvic acid and oxygen are available
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Pyruvic acid from glycolysis
Cytosol
Carbon atom + P
Phosphate
NAD CO 2
Mitochondrion
CoA
Coenzyme A
NADH + H +
Acetic acid
CoA
Acetyl CoA
(replenish molecule)
Oxaloacetic acid
Citric acid
(finish molecule)
(start molecule)
NADH + H +
CoA
NAD +
Malic acid
Isocitric acid
NAD +
For each citric acid molecule:
One ATP is produced
Eight hydrogen atoms are transferred to NAD+ and FAD
Two CO2 produced
Citric acid cycle CO 2
NADH + H +
Fumaric acid
-Ketoglutaric acid CO 2
CoA
FADH 2
NAD +
FAD
NADH + H +
Succinic acid
Succinyl-CoA
CoA
ADP + P
ATP

23. Electron Transport System
NADH and FADH2 carry electrons to the ETS
ETS is a series of electron carriers located in cristae of mitochondria
Energy from electrons transferred to ATP synthase
ATP synthase catalyzes the phosphorylation of ADP to ATP
Water is formed
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ATP synthase
ADP + P
ATP
Energy
NADH + H+
Energy
2H+
+ 2e–
FADH2
Energy
NAD+
2H+
+ 2e–
FAD
Electron transport chain
2e–
2H+ O 2
H2O

24. Summary of Cellular Respiration
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Glucose
Glycolysis
The 6-carbon sugar glucose is broken down in the cytosol into two 3-carbon pyruvic acid molecules with a net gain of 2 ATP and release of high-energy electrons.
High-energy electrons (e–) 1
Glycolysis 2 A T P
Cytosol
Pyruvic acid
Pyruvic acid
Citric Acid Cycle
The 3-carbon pyruvic acids generated by glycolysis enter the mitochondria. Each loses a carbon (generating CO2 and is combined with a coenzyme to form a 2-carbon acetyl coenzyme A (acetyl CoA). More high-energy electrons are released. 2
High-energy electrons (e–) CO 2
Acetyl Co A 3
Each acetyl CoA combines with a 4-carbon oxaloacetic
acid to form the 6-carbon citric acid, for which the cycle
is named. For each citric acid, a series of reactions
removes 2 carbons (generating 2 CO2’s), synthesizes
1 ATP, and releases more high-energy electrons.
The figure shows 2 ATP, resulting directly from 2
turns of the cycle per glucose molecule that enters
glycolysis.
Oxaloacetic acid
Citric acid
Citric acid
cycle
Mitochondrion
High-energy electrons (e–)
2 CO 2 2 A T P
Electron Transport Chain
The high-energy electrons still contain most of the
chemical energy of the original glucose molecule.
Special carrier molecules bring the high-energy electrons to a series of enzymes that convert much of the remaining energy to more ATP molecules. The other products are heat and water. The function of oxygen as the final electron acceptor in this last step is why the overall process is called aerobic respiration.
Electron
transport
chain 4
32–34 A T P 2e –
and 2H + O 2 H 2 O

25. Carbohydrate Storage Carbohydrate molecules from foods can enter:
Catabolic pathways for energy production
Anabolic pathways for storage

26. Carbohydrate Storage Excess glucose stored as:
Glycogen (primarily by liver and muscle cells)
Fat
Converted to amino acids
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Carbohydrates
from foods
Hydrolysis
Monosaccharides
Catabolic
pathways
Anabolic
pathways
Energy + CO2 + H2O
Glycogen or Fat
Amino acids

27. Summary of Catabolism of Proteins, Carbohydrates, and Fats
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
Food
Food
Proteins
(egg white)
Proteins
(egg white)
Carbohydrates
(toast, hashbrowns)
Carbohydrates
(toast, hashbrowns)
Fats
(butter)
Fats
(butter) 1 1
Breakdown of large
macromolecules
to simple molecules
Breakdown of large
macromolecules
to simple molecules
Amino acids
Amino acids
Simple sugars
(glucose)
Simple sugars
(glucose)
Glycerol
Glycerol
Fatty acids
Fatty acids
Glycolysis
Glycolysis
ATP
ATP
Pyruvic acid
Pyruvic acid 2 2
Breakdown of simple
molecules to acetyl
coenzyme A
accompanied by
production of limited
ATP and high energy
electrons
Breakdown of simple
molecules to acetyl
coenzyme A
accompanied by
production of limited
ATP and high energy
electrons
Acetyl coenzyme A
Acetyl coenzyme A
Citric
acid
cycle
Citric
acid
cycle
CO2
CO2 3 3
Complete oxidation
of acetyl coenzyme A
to H2O and CO2 produces
high energy electrons
(carried by NADH and
FADH2), which yield much
ATP via the electron
transport chain
ATP
ATP
High energy
electrons carried
by NADH and FADH2
High energy
electrons carried
by NADH and FADH2
Electron
transport
chain
Electron
transport
chain
ATP
ATP
2e– and 2H+
2e– and 2H+
–NH2
–NH2
CO2
CO2
½ O2
½ O2
H2O
H2O
Waste products
Waste products
© Royalty Free/CORBIS.
© Royalty Free/CORBIS.

28. 4.6: Nucleic Acids and Protein Synthesis
Instruction of cells to synthesize proteins comes from a nucleic acid, DNA
Genetic information – instructs cells how to construct proteins; stored in DNA
Gene – segment of DNA that codes for one protein
Genome – complete set of genes
Genetic Code – method used to translate a sequence of nucleotides of DNA into a sequence of amino acids. Each amino acid is represented by a triplet code

29. Structure of DNA Two polynucleotide chains
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Two polynucleotide chains
Hydrogen bonds hold nitrogenous bases together
Bases pair specifically (A-T and C-G)
Forms a helix
DNA wrapped about histones forms chromosomes
(a) Hydrogen
bonds P G C P
Thymine (T)
Adenine (A) P T P
Cytosine (C)
Guanine (G) P C G P P G C P P A P G C
Nucleotide strand A G C T C G
Segment
of DNA
molecule A
(b)
Globular
histone
proteins
Chromatin
Metaphase
chromosome
(c)

30. Animation: DNA Structure
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31. DNA Replication Hydrogen bonds break between bases
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. A T
Hydrogen bonds break between bases
Double strands unwind and pull apart
New nucleotides pair with exposed bases
Controlled by DNA polymerase C G G C C G
Original DNA
molecule T A C G C G T A A T C G A T
Region of
replication G C C G G T A T A T A T T A A
Newly formed
DNA molecules G C G C T A T A C G C G C G C G T A A

32. Animation: DNA Replication
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33. RNA Molecules Messenger RNA (mRNA):
Making of mRNA (copying of DNA) is transcription
Transfer RNA (tRNA):
Carries amino acids to mRNA
Carries anticodon to mRNA
Translates a codon of mRNA into an amino acid
Ribosomal RNA (rRNA):
Provides structure and enzyme activity for ribosomes

34. RNA Molecules Messenger RNA (mRNA):
Delivers genetic information from nucleus to the cytoplasm
Single polynucleotide chain
Formed beside a strand of DNA
RNA nucleotides are complementary to DNA nucleotides (exception – no thymine in RNA; replaced with uracil)
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DNA
RNA S P A U P S S P T A P S S P
Direction of “reading” code G C P S S P C G P S S P G C P S

35. Animation: Stages of Transcription
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36. Animation: How Translation Works
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37. Protein Synthesis Cytoplasm 3 Translation begins as tRNA anticodons
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Cytoplasm 3
Translation begins as tRNA anticodons
recognize complementary mRNA codons,
thus bringing the correct amino acids into
position on the growing polypeptide chain
DNA
double
helix
Amino acids
attached to tRNA
Nucleus T A T A 6
tRNA molecules
can pick up another
molecule of the
same amino acid
and be reused G C G C 2
mRNA leaves
the nucleus
and attaches
to a ribosome A T A T
Polypeptide
chain
Messenger
RNA G C
DNA
strands
pulled
apart A T A T T U A C G G G C T A G G C G G C C C G 5
At the end of the mRNA,
the ribosome releases
the new protein C G T U A T A C C G G C C C G A T G C G C C G A A T G C A A T
Nuclear
pore 4
As the ribosome
moves along the
mRNA, more amino
acids are added
Amino acids
represented A T C C G C G G G C T A G G C 1
DNA
information
is copied, or
transcribed,
into mRNA
following
complementary
base pairing A C C G U
Codon 1
Methionine A A T G C G G G C T A G G C G G C C C G G
Codon 2
Glycine A T T U A C C C G C C G U G C A A T C
Codon 3
Serine A T T U A C C G G G C G T A A A T
Messenger
RNA
DNA
strand C
Codon 4
Alanine C C G G C A C G G C A T A C G C
Codon 5
Threonine G C A T G
Transcription
(in nucleus) G C
Translation
(in cytoplasm) G G C C
Codon 6
Alanine C G A U A G C G G
Codon 7
Glycine C

38. Protein Synthesis 1 2 1 The transfer RNA molecule
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display. 1 2 1
The transfer RNA molecule
for the last amino acid added
holds the growing polypeptide
chain and is attached to its
complementary codon on mRNA.
Growing
polypeptide
chain 3 4
Next amino acid 5 6
Transfer
RNA
Anticodon U G C C G U A U G G G C U C C G C A A C G G C A G G C A A G C G U 1 2 3 4 5 6 7
Codons 1
Peptide bond 2 2
A second tRNA binds
complementarily to the
next codon, and in doing
so brings the next amino
acid into position on the ribosome.
A peptide bond forms, linking
the new amino acid to the
growing polypeptide chain.
Growing
polypeptide
chain 3 4
Next amino acid 5 6
Transfer
RNA
Anticodon U G C C G U A U G G G C U C C G C A A C G G C A G G C A A G C G U
Messenger
RNA 1 2 3 4 5 6 7
Codons 1 2
Next
amino acid 3
The tRNA molecule that
brought the last amino acid
to the ribosome is released
to the cytoplasm, and will be
used again. The ribosome
moves to a new position at
the next codon on mRNA. A 3 4 5 7 6
Transfer
RNA U G C C C G C G U A U G G G C U C C G C A A C G G C A G G C A A G C G U
Messenger
RNA 1 2 3 4 5 6 7
Ribosome 1 2 4
A new tRNA complementary to
the next codon on mRNA brings
the next amino acid to be added
to the growing polypeptide chain. 3 4 5
Next
amino acid 6 7
Transfer
RNA C G U C C G A U G G G C U C C G C A A C G G C A G G C A A G C G U
Messenger
RNA 1 2 3 4 5 6 7

39. Animation: Protein Synthesis
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40. 4.7: Changes in Genetic Information
Only about 1/10th of one percent of the human genome differs from person to person
Mutations – change in genetic information
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Code for
glutamic
acid
Mutation
Code for
valine
Result when:
Extra bases are added or deleted
Bases are changed P P T T S S
Direction of “reading” code P P T A S S P P C C S S
May or may not change the protein
(a)
(b)
Repair enzymes correct the mutations

41. Code for Glutamic acid Mutation Code for valine P P T T S S P P T A S
Fig. 4.25
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Code for
Glutamic
acid
Mutation
Code for
valine P P T T S S
Direction of “reading” code P P T A S S P P C C S S
(a)
(b)

42. Inborn Errors of Metabolism
Occurs from inheriting a mutation that then alters an enzyme
This creates a block in an otherwise normal biochemical pathway

43. ALA dehydratase deficiency
Copyright © The McGraw-Hill Companies, Inc. Permission required for reproduction or display.
STARTING MATERIALS
Enzyme #1
INTERMEDIATE #1
Enzyme #2
ALA dehydratase deficiency
INTERMEDIATE #2
Enzyme #3
acute intermittent porphyria
INTERMEDIATE #3
Enzyme #4
congenital erythropoietic
porphyria
INTERMEDIATE #4
Enzyme #5
porphyria cutanea tarda
INTERMEDIATE #5
Enzyme #6
coproporphyria
INTERMEDIATE #6
Enzyme #7
porphyria variegata
INTERMEDIATE #7
Enzyme #8
erythropoietic protoporphyria
HEME

44. Important Points in Chapter 4: Outcomes to be Assessed
4.1: Introduction
Define metabolism.
Explain why protein synthesis is important.
4.2: Metabolic Processes
Compare and contrast anabolism and catabolism.
Define dehydration synthesis and hydrolysis.
4.3: Control of Metabolic Reactions
Describe how enzymes control metabolic reactions.
List the basic steps of an enzyme-catalyzed reaction.
Define active site.

45. Important Points in Chapter 4: Outcomes to be Assessed
Define a rate-limiting enzyme and indicate why it is important in a metabolic pathway.
4.4: Energy for Metabolic Reactions
Explain how ATP stores chemical energy and makes it available to a cell.
State the importance of the oxidation of glucose.
4.5: Cellular Respiration
Describe how the reactions and pathways of glycolysis, the citric acid cycle, and the electron transport chain capture the energy in nutrient molecules.
Discuss how glucose is stored, rather than broken down.

46. Important Points in Chapter 4: Outcomes to be Assessed
4.6: Nucleic Acids and Protein Synthesis
Define gene and genome.
Describe the structure of DNA, including the role of complementary base pairing.
Describe how DNA molecules replicate.
Define genetic code.
Compare DNA and RNA.
Explain how nucleic acid molecules (DNA and RNA) carry genetic information.
Define transcription and translation.
Describe the steps of protein synthesis.

47. Important Points in Chapter 4: Outcomes to be Assessed
4.7: Changes in Genetic Information
Compare and contrast mutations and SNPs.
Explain how a mutation can cause a disease.
Explain two ways that mutations originate.
List three types of genetic changes.
Discuss two ways that DNA is protected against mutation.