Transcript CHAPTER 19 AMINO ACIDS AND PROTEINS The Importance of Proteins…    Many functions in the body! (supportive, enzymes, hormones, antibodies…) Can be small or very.

CHAPTER 19
AMINO ACIDS AND PROTEINS
The Importance of Proteins…
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Many functions in the body! (supportive, enzymes,
hormones, antibodies…)
Can be small or very large (hemoglobin: molar mass
64,000)
Composed of individual amino acids
A. Proteins and Amino Acids
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Amino acid: the building block of a protein
◦ Contain two functional groups: amino (-NH2) and carboxylic
acid (-COOH)
◦ At physiological pH, the carboxyl group and the amino group are
usually ionized
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There are 20 naturally occurring amino acids. The R
group gives each its unique characteristics.
Based on R group, amino acids can be classified as
nonpolar, polar, acidic, or basic.
20 Amino Acids…
Now, let’s think.
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The pI of cysteine is 5.1. Draw the predominant form
of this amino acid at pH 1, and at pH 12. (you will have
two different drawings!)
Proteins and Amino Acids
Except for glycine, all amino acids are chiral.
 We can also write Fischer projections for amino acids -just place the carboxyl group (the most highly oxidized
carbon) at the top.
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◦ L isomer: amino group on the left
◦ D isomer: amino group on the right
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In biological systems, only L amino acids are
incorporated into proteins.
B. Amino Acids as Acids and Bases
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The form of the amino acid at physiological pH (with
amino and carboxyl groups ionized) is called a
zwitterion
For a given amino acid, there is a pH where the positive
and negative charges are equal. This is called the pI -isoelectric point. Here, the amino acid has a net charge
= 0.
◦ When the solution pH < pI, the -COO- group accepts a proton.
◦ When the solution pH > pI, the -NH3+ group donates a proton.
Zwitterions and pI
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For polar and nonpolar amino acids, the pI is typically in
the pH 5.0-6.0 range.
For acidic amino acids, the pI is around pH 3 due to the
presence of a carboxyl group in the side chain
For basic amino acids, the pI is in the pH 7.6-10.8 range
due to amino groups in the side chain
Electrophoresis
A method to separate a mixture of amino acids (also
used to separate mixtures of proteins and nucleic acids)
 Place a mixture of amino acids in the center of a
chamber between a positive and negative electrode.
Start an electric current.
 Amino acids with zero net charge will not move; those
with a positive charge will migrate toward the negative
electrode; those with a negative charge will migrate
toward the positive electrode.
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An Electrophoresis Setup
C. Formation of Peptides
Peptide: two or more amino acids linked together
 Peptide bond: amide bond between the -COO- of one
amino acid and the -NH3+ of another amino acid
 In a long peptide chain, one end is called the N terminal,
and the other end is called the C terminal
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Peptide Bond Between Gly and Ala
Naming Peptides
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Starting with the N terminus… name each amino acid
in sequence with a -yl ending.
Until you get to the amino acid at the C terminus, and
you use the full name of that amino acid.
Example: alanylglycylserine
However… we typically use 3 letter abbreviations out of
convenience (Ala-Gly-Ser)
D. Protein Structure: Primary and
Secondary Levels
Larger peptides are called proteins (usually >50 amino
acids)
 Primary structure refers to the sequence of amino
acids in a protein.
 The secondary structure refers to the first level of
folding. The primary structure curls back in upon itself,
initially in a few very regular patterns. The most
common types of secondary structure = alpha helix,
beta-pleated sheet, and triple helix.
 Secondary: hydrogen bonds between backbone
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Alpha helix
Beta pleated sheet
E. Protein Structure: Tertiary and
Quaternary Levels
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Tertiary structure: additional folding above and beyond
that of secondary structure. May involve:
◦ Hydrophobic interactions between nonpolar R groups
◦ Hydrophilic interactions between polar/ionized R groups and
aqueous environment
◦ Salt bridges between ionized basic/acidic R groups
How might a change in pH affect this?
◦ Hydrogen bonds between polar amino acid R groups
◦ Disulfide bonds between R groups that contain sulfur (cysteine)
Tertiary Structure in a Protein
Protein Structure
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Quaternary structure: protein consisting of two or
more peptide subunits
◦ Example: hemoglobin -- two alpha chains, two beta chains. Four
chains all together.
◦ Quaternary structure is held together by the same forces that
hold tertiary forces together.
An Example of Quaternary Structure
Overview: Levels of Protein Structure
Thought question…
What kind of interaction would you expect between a
glutamic acid and a lysine, in the tertiary structure of a
peptide?
F. Protein Hydrolysis and Denaturation
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A protein or peptide can be hydrolyzed into individual
amino acids. (This is what happens in the stomach…)
Denaturation occurs when secondary, tertiary, or
quaternary structure is disrupted. Primary structure is
not affected. The protein unfolds “like a loose piece of
spaghetti”.
Denaturation
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How do various denaturing agents work?
◦ Heat breaks hydrogen bonds
◦ Acids/bases protonate/deprotonate key areas, affecting hydrogen
bonding and disrupting any ionic bonding
◦ Organic compounds destroy hydrophobic interactions by
forming their own hydrophobic interactions with the protein
◦ Heavy metals disrupt ionic bonding and disrupt disulfide bonds
◦ Agitation stretches polypeptide chains
Denaturation
One more time… let’s think
What structural level of a protein is affected by
denaturation? How is this different from the structural
level of a protein affected by hydrolysis?