L.bio amino_acids (1).pdf

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Department of Biochemist
Faculty of Pharmacy, Suez Ca
University

Amino Acids
 Protein Function
Proteins are the most abundant molecules in
living systems
Some functions of proteins:
1. Enzymes: biological catalysts, increase reaction
rates
2. Polypeptide hormones: direct and regulate
metabolism
3. Contractile proteins: in muscles, allow
movement
4. Structural proteins: in bone, collagen forms
framework for calcium deposition
 Protein Function

5. Transport and storage: hemoglobin and
myoglobin transport oxygen in the blood,
plasma albumin transports fatty acids
6. Immunoglobulins: fight infection

Proteins are made from amino acids
 Structure of Amino Acids
Amino acids consist of a
primary amino group, a
carboxyl group, a
hydrogen atom and a
distinctive side chain (R
group)bonded to a
carbon atom
The carbon is called the
α-carbon, because it is
adjacent to the carboxyl
group
 Properties of Amino Acids
At physiological pH (~ pH 7.4):
– The carboxyl group is dissociated forming
the negatively charged carboxylate ion COO-
– The amino group is protonated NH3+
Under normal cellular conditions (pH 7.4),
amino acids are zwitter ions (dipolar ions):
– Carboxyl group = COO-
– Amino group = NH3+
 Properties of Amino Acids
In proteins, carboxyl
group of one amino acid
is bound to the amino
group of the adjacent
amino acid in the
peptide linkage amide bond

Carboxyl and amino
groups of amino acids
are usually not involved
in chemical reactions
except hydrogen bond
formation
 Properties of Amino Acids
Chemical properties and role of an amino acid
is dependent on the side chain, R-group
Amino acids are classified according to the
properties of the side chain:
1. Amino acids with non-polar side chains
2. Amino acids with uncharged polar side chains
3. Amino acids with acidic side chains
4. Amino acids with basic side chains
1. Amino Acids with Non-Polar Side Chains (9)

Side chain does not bind protons
Side chain does not release protons
Side chain does not participate in hydrogen or
ionic bonds
1. Amino Acids with Non-Polar Side Chains (9)

Aliphatic
side
groups
1. Amino Acids with Non-Polar Side Chains (9)

Aromatic side groups Cyclic
NOT aromatic
 1. Amino Acids with Non-Polar Side Chains
Side chains of non-polar
amino acids cluster
together in the interior
of the protein due to
hydrophobicity of the
side group
Membrane proteins:
non-polar groups are on
outside surface of
protein, interact with
non-polar lipid
membrane
 1. Amino Acids with Non-Polar Side Chains

(imino acid)

Proline
Side chain and α-amino nitrogen form a rigid 5-
membered ring
Proline has a secondary amino group
Proline plays a large role in structure of collagen
2. Amino Acids with Uncharged Polar Side Chains (6)
Zero net charge at neutral pH

hydroxyl group participates in hydrogen bond formation
hydroxyl of serine, threonine serves as site of attachment for
phosphate groups in proteins
hydroxyl of serine, threonine serves as site of attachment for
oligosaccharides in glycoproteins
2. Amino Acids with Uncharged Polar Side Chains (6)
Zero net charge at neutral pH

carbonyl and amide groups participate in hydrogen
bonds
sulfhydryl (-SH) group loses proton at alkaline pH
amide group of asparagine serves as site of attachment
of oligosaccharides in glycoproteins
2. Amino Acids with Uncharged Polar Side Chains (6)

Disulfide bond:
– Sulfhydryl (-SH) group of cysteine plays role in
active site of enzymes
– -SH groups of two cysteines can become oxidized
to the dimer cystine
– Cystine contains disulfide bond (- S – S -)
 3. Amino Acids with Acidic Side Chains (2)

proton donors: side chains are fully ionized and
negatively charged at physiological pH
4. Amino Acids with Basic Side Chains (3)

proton acceptors: side chains are fully protonated
and positively charged at physiological pH
4. Amino Acids with Basic Side Chains (3)
weak base
amino acid is mostly
uncharged at physiological
pH
side chain can either be
positively charged or neutral
depending on the ionic
environment
Amino Acid Abbreviations
Amino Acid Abbreviations
Amino Acid Abbreviations
Amino Acid Abbreviations
 Optical Properties of Amino Acids

α-carbon of amino acids is chiral or optically active
Glycine is the exception
amino acids have D-forms and L-forms (stereoisomers,
optical isomers, enantiomers)
Amino acids in mammals are in L-form
 Acid Base Properties of Amino Acids
Amino acids contain weakly acidic α-carboxyl
groups and weakly basic α-amino groups
Acidic and basic amino acids contain ionizable
groups in the side chain
Amino acids can act as buffers
Buffers are weak acids or bases (with ionizable
groups) which resist small changes in pH
 Acid Base Properties of Amino Acids:
Henderson-Hasselbalch Equation
+ -
HA  H +A
weak proton conjugate
acid base

The dissociation constant, Ka of the acid is:
+ -
[H ] [A ]
Ka =
[HA]
the larger the Ka, the stronger the acid, since all the acid
would have dissociated into protons and conjugate base
 Acid Base Properties of Amino Acids:
Henderson-Hasselbalch Equation
+ -
[H ] [A ]
Ka =
[HA]
By solving for H+:
+ K a [HA]
[H ] =
-
[A ]
 Acid Base Properties of Amino Acids:
Henderson-Hasselbalch Equation
By taking the logarithm of each side:

+  K a [HA] 
log[ H ] = log  
 [A- ] 
 
Rearranging:
+ −
log[H ] = logK a + log[HA] − log[A ]
 Acid Base Properties of Amino Acids:
Henderson-Hasselbalch Equation
By multiplying each side by -1:

− log[H+ ] = −logK a − log[HA] + log[A− ]

Rearranging:
−
+ [A ]
− log[H ] = −logK a + log
[HA]
 Acid Base Properties of Amino Acids:
Henderson-Hasselbalch Equation

Since pH = -log [H+] and pKa = -log Ka,
we obtain the Hendersen-Hasselbalch
equation

−
[A ]
pH = pK a + log
[HA]
 Acid Base Properties of Amino Acids
Buffers
Resist small changes in pH on addition of acid
or base
Formed by mixing a weak acid (HA) with its
conjugate base (A-):
– If acid is added, A- neutralizes it forming HA
– If base is added, HA neutralizes it, forming A-
Maximum buffering capacity occurs at pH
equal to Ka ± 1 unit
Acid Base Properties of Amino Acids
Buffers
Acetic acid (HA) + acetate
(A-) has pKa 4.8
Buffer region only between
pH 3.8 – 5.8
pH < pKa: HA is
predominant
pH > pKa: A- is predominant
 Acid Base Properties of Amino Acids
Titration of Amino Acids

Amino acids have a pK value for every dissociable group
Alanine: α- carboxyl group and α-amino group
Acid pH: both groups are protonated
Neutral pH: carboxyl group dissociates, loses proton
Basic pH: amino group dissociates, loses proton
 Acid Base Properties of Amino Acids
Titration of Alanine

Alanine has two titratable groups (α-carboxyl and α-amino)
Dissociation constant for carboxyl group is called K1
−
[A ] [II]
pH = pK + log
a
pH =pK1 +log
[HA] [I]
 Acid Base Properties of Amino Acids
Titration of Alanine

Dissociation constant for amino group is called K2

−
[A ] [III]
pH = pK + log p H = pK 2 + log
a [HA] [II]
 Acid Base Properties of Amino Acids
Titration of Alanine: pK’s

Alanine has two pK’s
pK is equal to the pH where half of the protons is removed from the
group
pK1 = 2.3: at pH 2.3, half of the carboxyl groups in solution are
dissociated
pK for the most acidic group is the smallest, pK increases with
increasing basisity
Titration Curve of Alanine
1. Buffer pairs: -COOH/COO- is a
buffer pair in the acid pH range,
-NH3+/-NH2 pair buffers in the
basic pH range
2. pH = pK: if pH = pK1, then equal
amounts of forms I and II are
present
3. Isoelectric point (pI):
pI is pH at which form II is
predominant, with equal
amounts of forms I and III
pI is average of pK1 and pK2
alanine exists in dipolar
form II at neutral pH. Net
charge is zero
 Acid Base Properties of Amino Acids
Most amino acids have a net charge of zero at
physiological pH
– Negatively charged α - carboxyl (–COO-)
– Positively charged α – amino (-NH3+)
Isoelectric point (pI): pH at which the molecule
has a net charge of zero
Amino acids are called zwitter ions (carry both a
positive and negative charge)
Amino acids are amphoteric: can act as acids or
bases
Glu, Asp, His, Arg and Lys have additional charged
side groups, thus are not zwitter ions
 Other Applications
of the Henderson-Hasselbalch Equation

−
[A ]
pH = pK a + log
[HA]

Can be used to estimate change in pH in response
to changes in concentration of a weak acid or its
conjugate base e.g. bicarbonate buffer system
 The Bicarbonate Buffer System
+ −
CO2 + H 2O  H2CO3  H + HCO 3
−
[HCO3 ]
pH = pK + log
[H2CO3 ]

Pulmonary embolism causes an increase in carbon
dioxide in the blood → increase in H2CO3 → decrease in
pH (Respiratory acidosis) decrease

An increase in bicarbonate conc. causes an increase in
pH
 Effect of pH on Drug Absorption
Drugs pass through membranes readily in
their uncharged form
Drugs are either weak acids or weak bases:
– Weak acid: HA ↔ H+ + A-
– Weak base: BH+ ↔ B + H+
Aspirin is a weak acid, permeates membrane
in the HA, undissociated, form
Morphine is a weak base, permeates
membrane in its B, dissociated form
 Effect of pH on Drug Absorption
Effective concentration of a drug at the
absorption site depends on the concentration
of the dissociated and undissociated forms
Concentration of dissociated and
undissociated forms depends on:
– pH at absorption site
– pKa of the ionizable group (i.e. how strong the
acid or base)
 Effect of pH on Drug Absorption
Aspirin, the weak acid
is protonated in the
acidic environment of
the stomach, is
absorbed in the
stomach
 Effect of pH on Drug Absorption
The Hendersen-Hasselbalch equation is used to
estimate how much of a drug is present on either
side of a membrane that separates between
environments with different pH

Stomach Blood
pH 1.5 pH 7.4
A-
HA
HA HA HA H+ + A-
HA
HA A -
HA A-
A- A-
HA A-