Chapter 21: Amino Acids, Proteins, and Enzymes PDF

Summary

This document presents information on amino acids, proteins, and enzymes, including their structures, functions, and properties.

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Chapter 21
Amino acids, Proteins, and Enzymes
 Proteins
Proteins serve many functions, including the following:
1. Structure: Collagen and keratin are the chief
constituents of skin, bone, hair, and nails.

2. Catalysts: Virtually all reactions in living systems are
catalyzed by proteins called enzymes.
 Proteins
Proteins serve many functions, including the following:
3. Movement: Muscles are made up of proteins called myosin and
actin.
4. Transport: Hemoglobin transports oxygen from the lungs to
cells; other proteins transport molecules across cell membranes.

5. Hormones: Many hormones are proteins, among them insulin,
oxytocin, and human growth hormone.
 Proteins
6. Protection: Blood clotting
involves the protein fibrinogen; the
body uses proteins called antibodies
to fight disease.

7. Storage: Casein in milk and
ovalbumin in eggs store nutrients
for newborn infants and birds.
Ferritin, a protein in the liver, stores
iron.

8. Regulation: Certain proteins not
only control the expression of
genes, but also control when gene
expression takes place.
Proteins
 Amino Acids
Amino acid: A compound that contains both an amino
group and a carboxyl group.
 Amino Acids
Although α-amino acids are commonly written in the un-
ionized form, they are more properly written in the
zwitterion (internal salt) form, the form they are
predominantly present at physiological pH.
 Chirality of α-Amino Acids
With the exception of glycine, all protein-derived amino
acids have at least one stereocenter (the α-carbon) and
are chiral.

Glycine

The vast majority of α-amino acids have the L-
configuration at the α-carbon.
 Chirality of α-Amino Acids
A comparison of the configuration of L-alanine and D-
glyceraldehyde (as Fischer projections):
 Amino Acids

The simplest amino acid is glycine, where R = H.
The 20 Common Naturally Occurring Amino Acids
 Protein-Derived α-Amino Acids
Nonpolar side chains. Each ionizable group is shown in the
form present in highest concentration at pH 7.0.
Protein-Derived α-Amino Acids
Polar side chains (at pH 7.0)
 Protein-Derived α-Amino Acids
Acidic and basic side chains (at pH 7.0)

What is the overall
charge for each
amino acid?
 Protein-Derived α-Amino Acids
1. For 19 of the 20, the α-amino group is primary; for
proline, it is secondary.

2. With the exception of glycine, the α-carbon of each is a
stereocenter.

3. Isoleucine (left) and threonine (right) contain a second
stereocenter.
 Ionization vs. pH
An amino acid exists as a neutrally charged zwitterion
at a certain pH, the isoelectric pH.

The amino acid can exist in different forms, depending
on the pH of the aqueous environment.
 Ionization vs. pH

When the pH < isoelectric pH, the carboxylate anion ____
a proton, and the amino acid has a net _____ charge.
 Ionization vs. pH
When the pH > isoelectric pH, the ammonium cation
____ a proton, and the amino acid has a net ____ charge.
 Cysteine
Amino acids have the same functional groups but differ
primarily on their side chains. The properties of amino acids
and their polymers, i.e. proteins, are thus determined by these
side chains.
The -SH (sulfhydryl) group of cysteine is easily oxidized to an
-S-S- (disulfide).
 Phe, Trp, and Tyr
The amino acids phenylalanine, tryptophan, and tyrosine
have aromatic rings on their side chains.
Tryptophan is the precursor to the neurotransmitter serotonin.
Bipolar disorder can be managed by controlling the levels of
serotonin.
 Peptides
What is the product of the reaction between a
carboxylic acid and amine?
 Peptides
In 1902, Emil Fischer proposed that proteins are long chains of amino acids
joined by amide bonds.
Peptide bond (peptide linkage): The special name given to the amide bond
between the α-carboxyl group of one amino acid and the α-amino group
of another.

Peptide: A short polymer of amino acids joined by peptide bonds; they
are classified by the number of amino acids in the chain.
Dipeptide: A molecule containing two amino acids joined by a peptide
bond.
 Peptides
Polypeptide: A macromolecule containing many amino acids joined
by peptide bonds.

Linear Polymer
 Peptides
Protein: A biological macromolecule containing at least
30 to 50 amino acids joined by peptide bonds.
The individual amino acid units are often referred to as
“residues”.
 Peptides
The amino acids Ala and Ser can combine with the
carboxylate group of Ala reacting with the quaternary
amine of Ser:
 Peptides
Alternatively, the carboxylate group of Ser can react with
the quaternary amine of Ala:
Peptides
 Peptides
HOW TO Draw a Dipeptide from Two Amino Acids

Example Draw the structure of the dipeptide Val–
Gly, and label the N-terminal and C-
terminal amino acids.

Step Draw the structures of the individual amino
acids from left to right.

Draw valine (Val) on the left.
Draw glycine (Gly) on the right.
 Peptides
HOW TO Draw a Dipeptide from Two Amino Acids

Step
 Peptides
HOW TO Draw a Dipeptide from Two Amino Acids

Step
 Peptides
HOW TO Draw a Dipeptide from Two Amino Acids

Step Final Answer:
 Writing Peptides
By convention, peptides are written from the left to right, beginning
with the free -NH3+ group and ending with the free -COO- group.

N-Terminus C-Terminus

C-terminal amino acid: The amino acid at the end of the chain
having the free -COO- group.
N-terminal amino acid: The amino acid at the end of the chain
having the free -NH3+ group.
 Peptides
Example shown : A small peptide showing the direction of
the peptide chain.
 Peptide Bond
A peptide bond is typically written as a carbonyl group bonded
to an N-H group. Linus Pauling, however, discovered that
there is about 40% double bond character to the C-N bond
and that a peptide bond between two amino acids is planar,
which Pauling explained using the concept of resonance.

C–N = 1.49Å
C=N = 1.27Å
Peptide Bond = 1.32Å
(Partial Double Bond Character)
Planar
No Free Rotation
Peptide Bond
Levels of Structure
 Levels of Structure
Primary structure: The sequence of amino acids in a
polypeptide chain. Read from the N-terminal amino acid to
the C-terminal amino acid.
 Primary Structure
How important is the exact amino acid sequence?

Vasopressin and oxytocin are both nonapeptides but have
quite different biological functions.
Vasopressin is an antidiuretic (limiting production of urine)
hormone.
Oxytocin affects contractions of the uterus in childbirth and
the muscles of the breast that aid in the secretion of milk.
The structures of vasopressin an oxytocin (next slide).
Differences are shown in color.
 Primary Structure
Vasopressin and oxytocin are both nonapeptides but have
quite different biological functions.
Vasopressin is an antidiuretic (limiting production of urine)
hormone.

Oxytocin affects contractions of the uterus in childbirth and
the muscles of the breast that aid in the secretion of milk.
 Secondary Structure
Secondary structure: 3D arrangement of localized regions
of a protein.
These regions arise due to hydrogen bonding between the N-
H group of one amide with the C=O group of another.
2˚ Protein Structure:
Folding of the polypeptide backbone
 Secondary Structure
The most common types of secondary structure are
α-helix and β-pleated sheet.
α-Helix: A type of secondary structure in which a section of
polypeptide chain coils into a spiral, most commonly a right-
handed spiral.
β-Pleated sheet: A type of secondary structure in which two
polypeptide chains or sections of the same polypeptide chain
align parallel to each other; the chains may be parallel or
antiparallel.
 Secondary Structure: The α-Helix
The α-Helix
A single chain of protein
twists into a right-handed
coiled spring – a helix.
The shape is maintained
by intramolecular hydrogen
bonds between backbone
C=O and the N-H groups.
 β-Pleated Sheet
The β-pleated
sheet structure.

The backbone of
two protein
chains is held
together by
intermolecular or
intramolecular
hydrogen bonds.
 β Sheet
β-Sheet
β-pleated sheets can occur between polypeptide
chains (intermolecular H bonds) or in one polypeptide
chain when it makes a U turn forming a hairpin
structure.

C N

N C

C N
 β Sheet
β-Sheet

The six atoms of each peptide bond of a β-pleated sheet lie in the same plane.
The C=O and N-H groups of the peptide bonds from adjacent chains point
toward each other and are in the same plane so that hydrogen bonding is
possible between them.
All R- groups on any one chain alternate, first above, then below the plane of
the sheet, etc.

Anti - Parallel Parallel
C N
C N

C N
N C
N
C N C

Purple color:
side chains
 Random Coil
Few proteins are
predominanatly α-
helix or β-sheets
structures. Most
proteins though
have only certain
portions of their
molecules in these
conformations and
the rest consists of
random coil.
 Secondary Structure
Many globular proteins contain all three kinds of secondary structure
in different parts of their molecules: α-helix, β-pleated sheet, and
random coil.
Schematic structure of the enzyme carboxypeptidase. The β-pleated
sheet sections are shown in blue, the α-helix portions in green, and
the random coils as orange strings.
 Tertiary Structure
Tertiary structure: the overall conformation (3-D
arrangement of every atom) of a protein molecule.
Complex? Includes all types of interactions.

Tertiary structure is stabilized in five ways:
Covalent bonds
Hydrogen bonding
Salt bridges/electrostatic interaction
Hydrophobic interactions (London
Dispersion)
Metal ion coordination
 Tertiary Structure
Forces that stabilize tertiary structures of proteins.
London dispersion Electrostatic interaction

Hydrogen bonds

Metal ion Covalent bonds
coordination
 Quaternary Structure
Quaternary structure: Some proteins have more than one
polypeptide chain.
The quaternary structure of the protein is shape adopted
when two or more folded poly-peptide chains come
together into one complex.
 Quaternary Structure
Hemoglobin
Adult hemoglobin: Made up
of two identical alpha
chains of 141 amino acids
each, and two beta chains
of 146 amino acids each.

Fetal hemoglobin: Made up
of two alpha chains and
two gamma chains. Fetal
hemoglobin has a greater
affinity for oxygen than does
(the alpha/beta/gamma
adult hemoglobin.
designations in hemoglobin
have nothing to do with the α-
helix and β-pleated sheets).
 Proteins
Proteins are divided into two types:
Fibrous proteins (rod or wire-like shapes)
Globular proteins (spherical or "globe-like” proteins—
somewhat soluble in water as colloids)
 Common fibrous proteins
Collagen
α keratins

Vitamin C helps stabilize the chains of
collagen, and, when missing, poorly
formed collagen fibers result.
 Common globular proteins
Myoglobin has 153 Hemoglobin has 4
amino acids in 1 polypeptide chains,
polypeptide chain: each carrying a heme
unit.
Protein Hydrolysis
Hydrolysis: breaking
the peptide bonds by
treatment with aqueous
acid, base, or certain
enzymes.

Pepsin in gastric juice
cleaves some of the
peptide bonds of large
proteins.

In the intestines, trypsin
and chymotrypsin
hydrolyze the
remainder.
 Denaturation
Denaturation: The process of destroying the native conformation
(the 3D structure) of a protein by chemical or physical means.

A common method used in enzyme purification.

Denaturation does not break the amide bonds that form the primary
structure. That’s why it may in some cases be reversible, if the
impact is small.
 Denaturation
Denaturing agents include:
Heat: heat can disrupt hydrogen bonding; in globular
proteins, it can cause unfolding of polypeptide chains with
the result that coagulation and precipitation may take place.

6 M aqueous urea: Disrupts hydrogen bonding.

Surface-active agents: Detergents such as sodium
dodecylbenzenesulfate (SDS) disrupt hydrogen bonding.

Alcohols: 70% ethanol penetrates bacteria and kills them by
coagulating their proteins. It is used to sterilize skin before
injections.
 Denaturation
Reducing agents: 2-Mercaptoethanol (HOCH2CH2SH)
cleaves disulfide bonds by reducing -S-S- groups to
-SH groups.
 Enzymes
Enzymes are proteins that catalyze biological reactions.
Ribbon diagram of cytochrome c oxidase, the enzyme that
directly uses oxygen during respiration.
 Enzyme Catalysis
Enzyme: A biological catalyst.

Highly efficient catalysts: Enzymes can increase the rate of a
reaction by a factor of 109 to 1020 over an uncatalyzed reaction.
Specificity: Highly selective catalysts: Some enzymes catalyze the
reaction of only one compound.

Others are stereoselective; for example, enzymes that catalyze the
reactions of only L-amino acids.
Others catalyze reactions of specific types of compounds or
bonds; for example, trypsin catalyzes hydrolysis of peptide bonds
formed by the carboxyl groups of Lys and Arg.
 Enzyme Catalysis
Trypsin catalyzes the hydrolysis of peptide bonds formed
by the carboxyl group of lysine and arginine.
 Catalytic Power of Enzymes
Enzymes provide an alternative pathway for reaction. (a) The
activation energy profile for a typical reaction. (b) A
comparison of the activation energy profiles for a hypothetical
catalyzed and uncatalyzed reactions.
 Classification of Enzymes
Enzymes are commonly named after the reaction or
reactions they catalyze. The names of most enzymes end
with the suffix “-ase”.
Example: aldehyde dehydrogenase
 Cofactor

A cofactor is a metal ion or an organic molecule needed for
an enzyme-catalyzed reaction to occur.

NAD+ is the cofactor (coenzyme) that oxidizes lactate
lactate to pyruvate with the aid of the enzyme lactate
dehydrogenase:
Classification of Enzymes

Oxidoreductases
Transferases
Hydrolases
Lyases
Ligases
Isomerases
 Oxidoreductase
1. Oxidoreductase: catalyze oxidation-reduction reactions.

When a substrate is oxidized or reduced, a coenzyme is required, which
serves are the oxidizing or reducing agent.
 Transferase
Transferase: catalyze transfer of a group of atoms from one
molecule to another.
 Hydrolase
Hydrolase: catalyze hydrolysis (cleavage of bonds with
water) reactions.
Forward: Single bond cleavage via addition of H2O (hydrolysis)
Reverse: Bond formation via the removal of H2O
 Lyases
Lyase: catalyze the addition of two groups to a double bond, or
removal of two groups from adjacent atoms to create a double
bond

Not a
O O
O
-
O
- hydrolysis!
C H2 O C

HC OPO32- C OPO32-

CH2OH H2 O CH2

2-phosphoglycerate Phosphoenolpyruvate
 Ligase
Ligase: bond formation coupled to ATP cleavage;
joining of two molecules.

This process is energetically unfavorable, so the
energy released in a hydrolysis reaction is used to
drive the reaction.
 Isomerase
Isomerase: catalyze isomerization reactions. INTRAmolecular
rearrangement
What class does the
enzyme that
catalyzes this
reaction belong to?

A. Oxidoreductase
B. Transferase
C. Ligase
D. Lyase
E. Hydrolase
F. Isomerase
What class does the enzyme that catalyzes
this reaction belong to?
A. Oxidoreductase
B. Transferase
C. Ligase
D. Lyase
E. Hydrolase
F. Isomerase
What class does the enzyme that catalyzes
this reaction belong to?
A. Oxidoreductase
B. Transferase
C. Ligase
D. Lyase
E. Hydrolase
F. Isomerase
 Enzyme Terminology
Substrate: The compound or compounds whose
reaction an enzyme catalyzes.
Active site: The specific portion of the enzyme to
which a substrate binds during reaction.
 Enzyme Terminology
Once the reaction has occurred, the catalyst released the
product(s).

Two models have been proposed to explain the
specificity of a substrate for an enzyme’s active site.
Enzyme Specificity-the lock and key model

The lock-and-key model states that the active site is a
rigid cavity; to react, the substrate must exactly match
the shape of the active site.
Enzyme Specificity-the induced-fit model

The induced-fit model states that the active site has a
flexible shape, which can adjust to fit a variety of
substrate shapes.
 Enzyme Specificity-the induced-fit model

a. Shape of the active site before binding b. Shape of the active site after binding

The open cavity of the active site of the
enzyme closes around the substrate for
a tighter fit.
 Enzyme Activity
Enzyme activity: A measure of how much a reaction rate
is increased over the non-catalyzed reaction.

The activity of an enzyme is affected by both temperature
and pH.
 Allosteric Control
Allosteric control is the binding of a regulator to a site
on an enzyme that affects the enzyme’s ability to bind
a substrate at its active site.
 Terms in Enzyme Chemistry
Activators: Substances that initiates or increases the
activity of an enzyme.
Inhibitors: Substances that makes an active enzyme less
active or inactive.
Inhibitor

Reversible Irreversible

A reversible inhibitor binds to an enzyme but then
enzyme activity is restored when the inhibitor is released.

An irreversible inhibitor covalently binds to an enzyme,
permanently destroying its activity.
 Enzyme Inhibitors

Penicillin is an antibiotic that kills bacteria because it
irreversibly binds to the enzyme required for the
synthesis of a bacterial cell wall
 Enzyme Inhibitors

Inhibitor

Reversible Irreversible

Noncompetitive Competitive
 Terms in Enzyme Chemistry

Noncompetitive inhibitor: Any substance that binds to a
portion of the enzyme other than the active site and
thereby inhibits the activity of the enzyme.

Competitive inhibitor: A substance that binds directly to
the active site of an enzyme thereby preventing binding
of substrate. Inhibits the action of the enzyme.
 Mechanism of Inhibition
The mechanism of competitive inhibition:
A competitive inhibitor enters the active site, thus,
preventing the substrate to enter to complex with the
enzyme.
 Mechanism of Inhibition
Mechanism of noncompetitive inhibition:
The inhibitor in this case binds itself to a site other than the
active site (aka allosteric site). This changes the conformation
of the active site. The substrate still binds but no catalysis
takes place.
 Mechanism of Action
Both the lock-and-key model and the induced-
fit model emphasize the shape of the active site
(next slide).
Just five amino acids participate in the active
site in more than 65% of the enzymes studied
to date. They are in order of dominance:
His > Cys > Asp > Arg > Glu
Four of these amino acids have either acidic or
basic side chains; the fifth has a sulfhydryl
group (-SH).
Carboxypeptidase A Enzyme
 Enzyme Regulation
Feedback control (Non-covalent)

Proenzymes (zymogens) (Covalent)

Allosterism (Non-covalent)

Protein modification (Covalent)

Isoenzyme (isozymes)
Proenzymes (zymogens; covalent)

Zymogens (proenzymes) are an inactive form of an
enzyme that can be converted to the active form when
needed.
 Protein Modification: Covalent
The best known examples of protein modification involve
phosphorylation/dephosphorylation.