Biomolecules: Amino Acids PDF

Summary

This presentation provides an overview of amino acids, including their structure, types, functions, and clinical relevance. It covers various aspects of amino acids, such as their roles in protein synthesis and different types of reactions.

Full Transcript

BIOMOLECULES: NIKKI GIGI LEGASPI RMT,

AMINO ACIDS MD
 LEARNING OBJECTIVES FOR
TODAY
1. Diagram the structures and write the three and one-letter
designations of the 20 amino acids
2. Describe the importance and contribution of the R-group
3. Define Isoelectric pH and explain its relationship to the
net charge on a polyfunctional electrolyte
4. Describe the directionality, nomenclature and primary
structure of peptides
5. Describe the conformational consequences of the partial
double-bond character of a peptide bond and identify the
bonds in the peptide backbone that are free to rotate
PROTEINS
Most abundant and functionally diverse molecules in
living systems
Linear polymers of amino acids

Why are Proteins important?
Ezymes regulate metabolism
Neurotransmitters
Contractile proteins of muscles
Connective tissue framework
Transport of molecules in blood
Components of immune system
WHAT IS PROTEOME AND
PROTEOMICS?
Proteome – set of ALL PROTEINS expressed by an individual
cell at a particular time

Proteomics – study that aims to identify the entire
complement of proteins elaborated by a cell under diverse
conditions
 AMINO
ACIDS

More than 300 amino acids have been described but
only 20 are commonly found in mammalian proteins

These are the only amino acids coded by the DNA
CENTRAL DOGMA OF
MOLECULAR BIOLOGY
GENETIC
CODE
 AMINO
ACIDS
Each amino acid has the same
fundamental structure: a central
carbon atom (also known as the
alpha carbon), an amino group (NH2),
a carboxyl group (COOH) and a
hydrogen atom
In an aqueous solution, both amino and
carboxyl group are ionized

Every amino acid also has another
atom or group of atoms bonded to
the central carbon known as the R
group. This R group or side chain
TYPES OF AMINO ACIDS
1. Amino Acids with Aliphatic Side Chains
2. Amino Acids with OH groups
3. Amino Acids with SH groups
4. Amino Acids with Basic Groups
5. Amino Acids with Acidic Groups
6. Amino Acids with Aromatic Side Chains
ALIPHATIC SIDE CHAINS
(GAVIL)
1.Glycine Gly (G) 1H
2.Alanine Ala (A) 1C
3.Valine Val (V) 3C
4.Isoleucine Ile (I) 4C
5.Leucine Leu (L) 4C
 OH GROUPS (STT)
1.Serine Ser (S) 1C, 1OH
2.Threonine Thr (T) 2C, 1OH
3.Tyrosine Tyr (Y) 1C,
hexose,1OH
 SH GROUPS (CM)

1.Cysteine Cys (C) 1C,
1SH
2.Methionine Met (M) 2C,
1SH, 1C
 BASIC GROUPS (HAL)

1.Histidine His (H) 1C, 1 pentose
2.Arginine Arg (R) 3C, NCN c double
bond
3.Lysine Lys (K) 4C, 1NH3+
 ACIDIC GROUPS (AGAG)

1.Aspartic Acid Asp (D) 1C, 1COO-
2.Glutamic Acid Glu (E) 2C, 1COO-
3.Asparagine Asn (N) 2C, 1O, 1NH2+
4.Glutamine Gln (Q) 3C, 1O, 1NH2
 AROMATIC GROUPS (HPTT)
1.Histidine His (H) 1C, 1 pentose
2.Phenylalanine Phe (F) 1C, 1hexose
3.Tyrosine Tyr (Y) 1C, hexose, 1OH
4.Tryptophan Trp (W) 1C, 1hexose,
1pentose
 IMINO GROUP (P)

1.Proline Pro(P) 1pentose, 1NH2,
1COO
NONPOLAR SIDE CHAINS
NONPOLAR SIDE CHAINS
Net charge of zero at physiologic pH
Neither acid or base
Do not bind or give off protons

Promote hydrophobic (water-fearing)
interactions
Cluster in the Interior of proteins
Ex.: AVIL PTPT M
 GLYCINE
(GLY, G)

Only amino acid with an achiral carbon (it has a
hydrogen side chain)
Used in the first step of heme synthesis: Glycine +
Succinyl CoA  D-ALA
Used in purine synthesis
Major inhibitory neurotransmitter in the SPINAL CORD
Alanine (Ala, A)
Carries nitrogen from peripheral tissues to the liver

Valine, Isoleucine and Leucine (VIL)
Branched-chain amino acids whose metabolites accumulate
in MSUD (Maple Syrup Urine Disease)
Deficiency in branched chain α-ketoacid dehydrogenase

Phenylalanine (Phe, F)
Accumulate in phenylketonuria (deficiency in phenylalanine
hydroxylase)
Tryptophan
Has the largest aromatic side chain
Precursor for Niacin, Serotonin and Melatonin

Methionine
Transfer of methyl groups as SAM
Precursor of Homocysteine

Proline
Not an amino, but an imino acid
Contributes to fibrous structure of collagen and interrupts
α-helices in globular proteins
UNCHARGED, POLAR SIDE
CHAINS
UNCHARGED, POLAR SIDE
CHAINS
Uncharged: Net charge of zero at
physiologic pH
Polar: can form hydrogen bonds
Cysteine
Contains a sulfhydryl group that is an active part of many
enzymes
Two cysteines can be connected by a covalent Disulfide bond to
form Cystine
Keratin contains a lot of cystine (curly vs straight hair)
 Tyrosine
A precursor of Thyroxine and Melanin

Serine
Phosphorylation site of enzyme modification
Often linked to carbohydrate groups in glycoproteins

Serine and Threonine
Sites for O-linked glycosylation in Golgi apparatus
Asparagine
Site for N-linked glycosylation in endoplasmic reticulum
 Glutamine
Deaminated by Glutaminase resulting in
formation of ammonia
ACIDIC SIDE CHAINS
ACIDIC SIDE CHAINS
Negatively-charged at physiologic pH
because of the carboxylate group
Since they are acids, they are Proton
Donors
Participate in ionic reactions
GLUTAMATE
The precursor of GABA and Glutathione
BASIC SIDE CHAINS
BASIC SIDE CHAINS
Positively-charged at physiologic pH
because of the amine group
Since they are bases, they are Proton
Acceptors
At neutral pH:
Arginine and Lysine will have a positive
charge
 HISTIDINE
Precursor of Histamine
Used in the diagnosis of Folic Acid
Deficiency
N-formiminoglutamate Excretion Rate:
individuals deficient in folic acid excrete
increased amount of FIGlu in urine particularly
after ingestion of large doses of histidine
ARGININE
Precursor of Urea, Creatinine and Nitric
Oxide
 SELENOCYSTEINE, THE 21 ST
AMINO ACID

An L-α amino acid found
in proteins e.g.
peroxidases and
reductases,
selenoprotein P,
iodothyronine
deiodinases
OPTICAL PROPERTIES OF
AMINO ACIDS
Except for Glycine all amino acids are Chiral

L-configuration All amino acids in proteins
D-configuration Bacterial walls, antibiotics

Stereoisomers/Isomers/Enantiomers are exact mirror
images of each other
 CHARGE OF AMINO ACIDS
Amino acids can have a positive, negative or zero
charge depending on the pKa values and pH of the
environment

Zwitterion Molecule
Chemical compound that has a total net charge of Zero

Isoelectric pH or Isoelectric Point
pH where the zwitterion predominates  AA is uncharged
ESSENTIAL AMINO ACIDS

PVT TIM HALL
Phenylalanine, Valine, Tryptophan, Threonine,
Isoleucine, Methionine, Histidine, Arginine,
Leucine, Lysine

Always ARGues, never TYRes
CONDITIONALLY ESSENTIAL
AMINO ACIDS
1. Arginine – may be made in the body, but
usually not enough

2. Histidine – may be recycled, but should
eventually be consumed since it is not made
at all
PROTEIN STRUCTURES
LEVELS OF PROTEIN
STRUCTURE
1. Primary Structure
2. Secondary Structure
3. Tertiary Structure
4. Quaternary Structure
PRIMARY STRUCTURE
Linear amino acid sequence of a protein

Peptide Bonds
attach an α-amino group of one AA to the α-
carbonyl group of another
very stable; can only be disrupted by
hydrolysis or prolonged exposure to a strong
acid/base at elevated temperatures
PEPTIDE BONDS
Peptide bonds in between two amino acids
has a partial double bond character that
makes the bond rigid and planar
It is also generally in trans configuration
SECONDARY STRUCTURE
The folding of short (3-30) amino acid
residues into geometrically ordered units

Regular arrangements of AA that are located
near each other in the linear sequence

Stabilized by excessive hydrogen bonding
2 MAIN KINDS OF
SECONDARY STRUCTURES
1. Alpha-helix
2. Beta-pleated sheets
ALPHA
HELIX
Most common
R-handed spiral with polypeptide
backbone core side chains extend
outward
3.6 AA per turn of spiral
Disrupted by:
Proline
Large R groups (tryptophan)
Charged R groups (acidic/basic AA)

R groups are outside the helix and
 BETA SHEET
Surfaces appear flat
and pleated
2 or more peptide
chains parallel to each
other
Interchain and
intrachain bonds
 OTHER SECONDARY
STRUCTURES
Beta-bends
Nonrepetitive (loop and coil) structures
Motifs or Supersecondary Structures
Combinations of adjacent secondary structures
such as a βαβ unit, β barrel
COMPARISON: ALPHA HELIX
& BETA SHEET
CHARACTERIST ALPHA HELIX BETA SHEET
ICS
General Shape R-handed spiral Sheets
Direction of H Parallel to helix Perpendicular to
bonds sheets
Common Keratin (100% a Amyloid
Examples helix) (Alzheimers)
Hemoglobin Immunoglobulin
(80% a helix) s
 TERTIARY STRUCTURES
Overall three-dimensional shape
of the protein
Ex.: Globular proteins, Fibrous
proteins
Refers to the folding of Domains
and their final arrangement in
the polypeptide
Stabilized by:
Disulfide bonds
Hydrophobic interactions
Hydrogen bonds
DOMAINS
Fundamental functional and three-dimensional
structural units of a polypeptide
Formed by a combination of motifs
 QUATERNARY STRUCTURES
Structure of proteins consisting of more than
1 polypeptide chain
Held together by noncovalent bonds
 DENATURATION
Disruption of a protein’s structure
When protein becomes unfolded and disorganized, they
become dysfunctional
May be reversible
Causes of denaturation:
1. Heat
2. Organic Solvents 6. Ions of heavy metals like lead &
mercury
3. Mechanical Mixing
DENATURAT
ION
CLINICAL CORRELATIONS
1. Prion Diseases
2. Alzheimer’s Disease
REFERENCES
1. http://
www.biology.arizona.edu/biochemistry/problem_sets/aa/aa.html
2. Harpers Biochemistry, 30th Edition