Biochemistry 1: Amino Acid PDF

Summary

This document is a lecture presentation about amino acids, covering their classification, properties, and functions. It explains different types of amino acids and their diverse roles in the human body.

Full Transcript

Faculty of Physical therapy
Biochemistry 1
Amino acid
Dr. Esraa M. Elnshar
 protein
Proteins are Large molecules made up of 20
amino acids linked together in long chains
called polypeptides
Amino acids are the building blocks for
proteins found in all living cells.
 Amino acid
Amino Acids are the building
units of proteins.
There are about 300 amino acids
occur in nature.
Only 20 of them enter in
proteins synthesis.
Amino acid found in cells and in Composition
proteins is in the L consists of carboxyl group and basic
configuration. amino group bonded to α-carbon (C-
atom next to COOH)
Side chain (R) bound to a-carbon.
R identifies amino acid
 Amino acids in protein must be
1. α-amino acid
The amino group attached to the next carbon of the carboxyl group is
called “α-amino acid”. All naturally occurring amino acids in protein ar
“α-amino acids”
2. L-amino acid
It can occur in one of the forms: the L-form (left-handed form)
3. amino acids are chiral, α- carbon has 4 different groups attached to it
except glycine.
Classification of Amino Acids:

I. Classification based on Chemical structure [R group]
II. polarity
III. Nutritional Classification
IV. Metabolic Classification
Classification according to R-Group
Amino acids can be classified into 3 groups : Aliphatic [ R= Carbon Chain, not ring]
Aromatic [ Benzene Ring]
Heterocyclic amino acids [ Ring with hetero atoms
(S,N,O), not contain benzene ring]
Aliphatic amino acids
1. Aliphatic neutral amino acids:
a) simple: These have no functional group in their side chain [ non
branched, (Example: glycine, alanine)] or [branched (ex: valine, leucine, isoleucine)]
b) Hydroxy amino acids: These have a hydroxyl group in their side
chain. Ex: serine, threonine

c) Sulfur containing amino acids:
have sulfur in their side chain.
Ex: cysteine, methionine
2. Aliphatic acidic amino acids:
have carboxyl group in their side
chain. Ex: Aspartic and Glutamic
acid [COOH > NH2]

3. Aliphatic basic amino acids:
contain amino group in their side
chain. Ex: Lysine, Arginine
[NH2 > COOH]

Guanido group
Acid amide amino acid

Glutamine
 Aromatic amino acids
have benzene ring in their side chain. Ex: phenylalanine, tyrosine.
 Heterocyclic amino acids
have a side chain ring which possess at least on atom other than carbon
Ex: Tryptophan, histidine, proline.

Tryptophan
Classification according to polarity of side chain (R)

Polar amino acids: in which R contains polar hydrophilic group so can forms
hydrogen bond with H2O.
R may contain:
OH group : as in serine, threonine and tyrosine
SH group : as in cysteine
amide group: as in glutamine and aspargine
NH2 group or nitrogen act as a base (basic amino acids ): as lysine, arginine
and histidine
COOH group (acidic amino acids): as aspartic and glutamic.
Non polar amino acids: R is alkyl hydrophobic group
[aliphatic and aromatic group] which can’t enter in hydrogen
bond formation.
They are embedded in other hydrophobic structures, such as
interior of cell membranes.
amino acids are non-polar (glycine, alanine, valine, leucine,
isoleucine, phenyl alanine, tryptophan, proline and
methionine).
Classification according to nutritional requirements

Essential amino acids:  Non essential amino acids:  Semi-essential amino
cannot be synthesized by An amino acid that can be acids:
the body. As a result, they made by humans and so is formed in the body but
must come from food. Their essential to the human diet. not in sufficient amount
deficiency affects growth, The nonessential amino for body requirements
health and protein synthesis. acids: Alanine, asparagine, especially in children.
The essential amino acids are: aspartic acid, cysteine, Arginine and histidine
Arginine, histidine, valine, glutamic acid, glutamine, are semi-essential.
isoleucine, leucine, lysine, glycine, proline, serine, and
methionine, threonine, tyrosine
tryptophan and phenylalanine.
Classification according to Metabolic

Amino acids can be classified according to their metabolic in
the body.
They are degraded inside our body by removal of the amino
group in the form of ammonia (NH3) and leave the carbon
skeleton.
Purely ketogenic: These amino acids enter the metabolic pathway
of ketone bodies. i.e They can give ketone bodies e.g. Leucine and
lysine

α-keto acid

Purely glucogenic: They can give glucose e.g. glycine, alanine,
valine, serine, threonine, cysteine, methionone, aspartic acid,
asparagines, glutamic acid, glutamine, arginine, histidine and proline

Ketogenic and glucogenic: During metabolism, they can give
ketone bodies and glucose e.g. isoleucine, phenylalanine, tyrosine
and tryptophan.
Physical properties

 Colourless
 Crystalline in nature
 Melting point above 200ᵒC
 Soluble in polar solvent and Insoluble in non
polar solvent Amino acid can be present in
2 configuration ( L- and D-
 All amino acids possess optical isomers except
isomers)
glycine due to the presence of asymmetric α-
L- isomer only present in
carbon atoms. protein.
 Some are structurally stable and sterically
hindered [Glycine]
 Amino acids [proteins]posses enzymatic activities
 Amino acids exhibit colloidal nature and
denaturing property
Acid–Base Properties of Amino Acids
Although we commonly write amino acids with whole carboxyl group and
amino group, their actual structure is ionic and depends on the pH. The
carboxyl group loses a proton, giving a carboxylate ion, and the amino group
is protonated to an ammonium ion. This structure is called a dipolar ion or a
zwitterion (has both +ve and –ve charges (net charge=zero)).
Isoelectric Point (PI):
The pH at which the amino acid molecule carries no net charge.

Because amino acids contain both basic –NH3+ and acidic COO- groups, they are
amphoteric (having both acidic and basic properties).

In an acidic solution, the -COO- group is protonated to a free –COOH group so
the molecule has positive charge.
In alkaline solution, -NH3 + loses its proton, the molecule has an overall negative
charge.
Chemical properties
1) Detection for amino acids (Ninhydrin test)

When ninhydrin reacts with an amino acid, one of the products (reduced ninhydrin) is
a deep violet. The side chain of the amino acid is lost as an aldehyde.
3) Decarboxylation:
The amino acids will undergo decarboxylation to form the corresponding
“amines”. Thus amines are produced
Histidine → Histamine + CO2
Tyrosine →Tyramine + CO2
Lysine →Cadaverine + CO2

4) Reaction with Alkalis (Salt formation):
The carboxyl group of amino acids can release a H+ ion with the formation of
Carboxylate (COO–) ions.

5) Reaction with Alcohols (Esterification):
the amino acids is reacted with alcohol to form, “Ester”. The esters are volatile in
contrast to the form
6) Formation of peptide bonds:
Amines and acids can condense, with the loss of water, to form amides.
Amino acid has both an amino group and a carboxyl group to form an amide
linkage (covalent bond). The amide linkage between the amino acids is called a
peptide bond.

 Proteins are made of polymerization of amino acid through peptide bonds.
7) Disulfide Linkages
Amino acid with SH side chain can form covalent bond. Cysteine can form disulfide
bridges (also called disulfide linkages) which can join two chains.
Functions of Amino Acids:

L-α-amino acids and their derivatives participate in some
cellular functions e.g.:
 Nerve transmission e.g. glutamate, serotonin &
dopamine
 Biosynthesis of porphyrins, purines, pyrimidine and urea
 Thyroid hormones and adrenaline are synthesized from
tyrosine
 Some hormones, hormone-releasing factors,
neuromodulators, or neurotransmitters are peptides