Chemistry of Amino Acids and Proteins - I AAU 2024 PDF

Summary

This document is a past paper from AAU for the year 2024, related to the chemistry of amino acids and proteins. The paper contains details about the structure, function, classification, and other relevant topics of amino acids.

Full Transcript

Chemistry of Amino
Acids and Proteins - I

1
 Outline of the topic
 General structure of Amino Acids
 Classification of Amino acids
 Function of Amino Acids
 Acid-Base property of amino acids
 Peptide bond structure and functional peptides
 Protein structure
 Biological functions of proteins
 Protein classification
2
 Objectives of the topic
At the end of this session, you will be able to
Describe general structure of amino acids
List the biochemical functions of amino acids
Categorize amino acids by different basis of classification
Explain acid-base property of amino acids
Explain peptide bond and its character
Mention functional peptides
Give details of protein structure
Elucidate biological functions of proteins
Classify proteins 3
What are Proteins?
Unbranched Polymers of amino acids linked head to tail

Major constituent of most cells

Usually form multi-molecular complexes

They are folded into specific conformations

Their conformation and functional-group chemistry controls
function

Responsible for most of our phenotype (define what an
organism is, what it looks like, how it behaves, etc.)

Made from almost 20 different types of standard amino-
acids
Special condition: Selenocysteine incorporated during co-
translation in human 4
 Amino acids
 Structure:
 central carbon H O
 amino group
H | ||
 Carboxyl group
—N—
—C— C—OH
H |
Side chain (R group)
 variable group
R
 confers unique
chemical functionality

 Chiral/ Optically active
 Acid–base properties
 Capacity to polymerize
5
 Classification of Amino Acids

Amino acids can be classified based on

 Side chain character

 Nutritional value

 Metabolic fate

 Presence/ absence in proteins
6
Amino Acid Classification by Side Chain Character

 Hydrophobic side chain: stabilize protein structure by hydrophobic
interactions.

 Tyrosine can form hydrogen bonding. 7
Classification...

 Reversible formation of a
disulfide bond by the
oxidation of two molecules
of cysteine
8
 Classification…

Acidic side chain:
H+ (proton) donor

9
 Classification …

Basic side chains:
H+ acceptors

 Histidine side chain
pKa= 6.0

 10% protonated at pH= 7

 Serving as a proton
donor/ acceptor in many
enzymatic reactions

 Identification of carbon atoms
in amino acids
10
 Names and Codes of Amino Acids
Name One Three R-Group Properties
letter Letter
Glycine G Gly Hydrophobic
Alanine A Ala Hydrophobic
Valine V Val Hydrophobic
Leucine L Leu Hydrophobic
Isoleucine I Ile Hydrophobic, two chiral carbons
Proline P Pro Cyclic, not terribly hydrophobic
Phenylalanine F Phe Hydrophobic, bulky
Tyrosine Y Tyr Less hydrophobic (than Phe), bulky
Tryptophan W Trp Hydrophobic, bulky (indole ring)
Cysteine C Cys Hydrophobic, highly reactive (S-S link)
Methionine M Met Hydrophobic (start a.a.)
Serine S Ser Hydrophilic, reactive
Threonine T Thr Hydrophilic, reactive, two chiral carbons
Lysine K Lys Highly hydrophilic, positively charged
Arginine R Arg Highly hydrophilic, positively charged
Histidine H His Highly hydrophilic, positive or neutral
Aspartate D Asp Highly hydrophilic, negatively charged
Glutamate E Glu Highly hydrophilic, negatively charged
Asparagine N Asn Polar, Uncharged
Glutamine Q Gln Polar, Uncharged 11
Amino Acid Classification Based on Nutritional Value
 Basedupon whether the AAs can be synthesized in
human body or not
 Indispensable or essential amino acids: 9 amino
acids
 Not synthesizable in the body in adequate amounts

 Val, Ile, Thr, Trp, Leu, Lys, Met, Phe and His.

 Dispensable or non-essential AAs
o Can be synthesizable in the body from the essential
ones
 Conditionally essential amino acids: During illness or stress

 Tyrosine, cysteine, arginine, glutamine, glycine, proline, and serine.

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 CLASSIFICATION BASED ON METABOLIC FATE
 Based upon the catabolic fate of
Carbon skeleton of amino acids Ketogenic
Mixed
Glucogenic
Type
 Ketogenic

Catabolically give intermediates Leu IIe
convertible into Acetyl-CoA or
Acetoacetyl-CoA
Lys Tyr Ala, Arg Asp,
 Glucogenic
Asn Glu, Gln
14 of them give rise to intermediates of Ser, Met Pro,
Trp
glycolysis or Kreb’s cycle Gly His, Thr
Val, Cys
 Mixed type
Carbon-skeleton of which is catabolized to Phe
produce glycolytic intermediates or acetyl
CoA derivatives
13
Some Common Biological Functions of Amino Acids
 Formation of peptides and proteins

 Stabilize 3D structure of proteins by forming multiple bonds

 Specific AAs at the active site are vital for enzyme catalysis

 Some AAs as source of glucose

 Cys and Met are sources of S in the body (e.g. for Fe-S center
formation)

 Carbon skeleton and Nitrogen of AAs used for nucleic acid
synthesis

 Gly and Met help in the detoxification mechanisms

 Met can act as a methyl group donor in methylation reactions 14
Amino Acids as Precursors of Biologically Important Derivatives

 Gycine is a precursor for
 Heme

 Creatine

 Tyrosine is the precursor for number of hormones:
 Thyroxine & Triiodothyronine

 Epinephrine & nor-epinephrine

 Skin pigment melanin

 Tryptophan can give rise to
Niacin
Serotonin
 Histidine can be converted to Histamine
15
Uncommon Amino Acids – Found in proteins
Hydroxylysine and hydroxyproline
- Mainly in collagen
- Found in connective tissues

Tyroxine and Triiodotyronine
- Produced from degradation of thyroglobulin

- Act as hormones for growth &
development

N-methylarginine and N-acetyllysine
- found in histone proteins

16
Uncommon Amino Acids – Found in proteins

Methylhistidine, -N-methyllysine, &
N,N, N-trimethyllysine
- Methylated amino acids in myosin

-Carboxyglutamic acid
- In blood clotting proteins & Ca2+
containing proteins
e.g. Prothrombin

17
Uncommon Amino Acids – Found in proteins

Desmosine
- Derivative of four Lys residues
- Found in fibrous protein elastin

Selenocysteine
- Derived from serine
- Introduced during protein synthesis
- Role in antioxidant activity
e.g. Gluthione peroxidase active site
18
 Amino Acids not found in proteins

GABA (decarboxylation of
glutamic acid)
- a potent neurotransmitter.

Histamine (decarboxylation of
histidine) & Serotonin (from
tryptophan)
- function in smooth muscle
contraction, as nurotransmitter, vascular
permeability, etc

-Alanine
- for synthesis of carnosine (for muscle
endurance)
19
 Amino Acids not found in proteins
Epinephrine

Ornithine & Citrulline
- in urea cycle, Arg synthesis.

Dopa (3,4-dihydroxyphenylalanine): Precursor of melanin

S-adenosyl methionine (SAM): a methyl donor in transmethylation rxn
20
Acid-Base Properties of Amino Acids

 Ammonium form acts as an acid, the carboxylate as a base.
21
 pI of Neutral Amino Acids

 The PI can be
calculated as the
average of pKa1
and pKa2

22
pI of Amino Acids - Alanine

23
Amino Acids with Ionizable Side Chains

Lysine

24
pI of Amino Acids – With Acidic, Neutral and Basic Side Chains

25
pKa and PI Values of Common Amino Acids

26
 Peptide Bond
&
Functional Peptides

27
 Peptide Bonds (Amide bond)
Condensation rxn
Formation of dipeptide, tripeptides, etc....
 Forms N-terminal and C-terminal
Acid-base behavior of a peptide can be
predicted from its free -amino and -carboxyl
groups as well as the nature and number R
groups.

 Have characteristic characteristic pI

 pKa value for an ionizable R group can
Serylglycyltyrosylalanylleucine
change somewhat when an amino acid or
becomes a residue in a peptide. Ser–Gly–Tyr–Ala–Leu
28
 Planar peptide groups in a polypeptide chain
Amide nitrogen are non-basic because their unshared electron pair is
delocalized by interaction with the carbonyl group.
Rotation around C-N bond is restricted due to the double bond nature
Peptide groups are therefore planar

Planar Structure of peptide
29
 Biologically Active Peptides
 Glutathione
– Formed from -glutamic acid, Cysteine & Glycine

– It protects the cell membrane from damage,

 e.g., prevents hemolysis of erythrocytes

Slightly larger peptides/ Oligopeptides
 Insulin

– contains two polypeptide chains

one having 30 and the other has 21amino acid residues

 Corticotropin

– is a 39-residue hormone of the anterior pituitary gland

– stimulates the adrenal cortex
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 Commercial peptide: Example

O O O

H2N CH C NH C CH C OCH3
 Aspartame/ L-Aspartyl-
CH2 CH2
L-phenylalanine methyl Methyl ester
ester/ Neurasweet C OH
 Artificial sweetener O

Aspartic Acid
Phenylalanine

31
 Structure
and
Classification of Proteins

32
 Protein structure
 The 3-D structure mainly depends on types,
number and sequence of amino acids
 twisted, folded, coiled into unique shape
Pepsin
 Structure determines the function of a protein

 Native, folded structure of the protein depends on
several factors Collagen
(1) interactions with solvent molecules
(2) the pH and ionic composition of the solvent
(3) the sequence of amino acid in a protein.
Hemoglobin 33
Primary structure of proteins
 Describes sequence and number of amino acids
in chain
◦ Determined by gene (DNA sequence)
◦ Contain all information necessary for folding into its
“native” structure

 Amino acid sequence of Lysozyme
34
 Primary structure...
Does Amino Acid Sequence determine protein function?

Oxytocin Ile Gln
Tyr Asn
- Initiates contractions of the uterus during childbirth
Cys Cys
Pro-Leu-GlyNH 2
- Plays a role in the release of milk during lactation S S

Vasopressin (ADH) Phe Gln
Tyr Asn
- Regulate the amount of water
Cys Cys
present in the body Pro-Arg-GlyNH2
S S

35
 Primary structure...
Change in amino acid sequence may cause problem!
Hemoglobin – 574 amino acids

36
Secondary structure of proteins: Local folding

 Formed by H-bonding
 Describes about folding
pattern along short
sections of polypeptide

 The Development of
regular patterns of
hydrogen bonding result
in distinct folding patterns

37
Secondary structure:
Examples
 -helix
 Peptide carbonyl H-bonded to peptide N-
H group four residues farther
 One turn of the helix represents 3.6
amino acid residues (13 atoms from
the O to the H of the H-bond - 3.613
helix)
 All of the H-bonds lie parallel to the
helix axis
 All of the carbonyl groups are
pointing in one direction along the
helix axis

38
Secondary (2°) structure: Examples

e.g. Myoglobin – 153 AAs
- Eight stretches of  -helix forming a
box to contain the heme prosthetic grp.

Other forms of Helix

310 helix
- 3.0 residues per turn (with 10 atoms in the ring
formed by making the hydrogen bond three residues up the
chain)
27 ribbon

39
Secondary (2°) structure: Examples
 -Pleated Sheet
 Each strip of paper as a
single peptide strand
 Peptide backbone makes a
zigzag pattern along the
strip
 –carbons lying at the
folds of the pleats.
 Formation of interstrand H-
bonds
 Side chains oriented
perpendicular to the plane
of the sheet,
 Side chains extending out
from the plane on
alternating sides
40
 Secondary (2°) structure: Examples

Two types
Parallel pleated sheet

- Typically large structures

Usually > five strands

Antiparallel pleated sheet

- Usually having hydrophobic side chain
on one side, so it requires alternating
hydrophobic & hydrophilic residues
arrangement in primary structure

41
 Secondary (2°) structure: Examples
-Turn/ tight turn/ -bend

- A tight loop formed by the carbonyl O
of the 1st is H-bonded with amide N of
the 4th residue down the chain

- Proline & glycine, occur
frequently in -turn sequences

- Abundant in globular structures

42
 Secondary (2°) structure: Examples

-Bulge

 A small piece of non-repetitive structure
that can occur by itself
 Most often occurs as an irregularity in
antiparallel -structures
 Occurs between two normal –
structure H-bonds and comprises 2
residues on one strand and one residue on
the opposite strand
 Bulges thus cause changes in the
direction of the polypeptide chain, but to a
lesser degree than -turns.

43
Super Secondary
Common motifs:
Examples

44
Super-secondary structures
commonly found in some DNA-
binding proteins

45
Tertiary (3°) structure: All things hold together
 Shows the whole molecule folding pattern
◦ Describes about overall 3-D structure of a polypeptide
◦ Determined by interactions between R groups
◦ Bonds that determine 3D-structure are:
 Hydrogen bond
 Hydrophobic
interactions
 Disulfide bridges
 Ionic bonds
 Van der Waals Force
46
Bonds determining 3°
structure of proteins

47
Examples of some domains

-Barrel Bundle Saddle

48
 Quaternary (4°) structure
 Formed from more than one polypeptide chain
 Organized by the same types of bonds as tertiary
structure
 Most intracellular enzymes are oligomers

C) Immunoglobulin49
 Advantages of Quaternary Association

Stability
- Favorable reduction of the protein’s surface-to-volume ratio

- Interactions stabilizes the protein energetically

- Shield hydrophobic residues from solvent water

Genetic Economy and Efficiency

- Less DNA is required to code for a monomer

50
 Advantages of …
Bringing Catalytic Sites Together
 Monomer may not constitute a complete enzyme active site

 May also carry out different but related reactions on different subunits

e.g. Tryptophan synthase (22)
-subunit:
- subunit :

Cooperativity
- Regulate catalytic activity by subunit interactions

- Some proteins are inactive when oligomers
e.g. Insulin hexamer formation in solution

- Ligand binding at one site changes affinity of Hb the other site for O2
51
Examples of Proteins with Quaternary Structure

52
 Summary of Levels of Protein Structure

aa sequence
peptide bonds
determined by DNA

H bonds of carbonyl O
and Amide H of peptide R groups
Hydrophobic, Ionic,
Disulfide bridges, H-bond

Multiple polypeptides
All bond types like tertiary53
Classification of Proteins – Based on Function
 a. Enzymes:
 e.g. Glucokinase
 b. Regulatory Proteins
 Regulating other proteins
 Eg. Insulin

 Regulation of gene expression
e.g. Transcription activators

c. Transport Proteins
e.g. Hb:
Serum albumin: Fatty acid transport
Membrane transporters (channels): e.g. AA & Glucose
transporters 54
 Functional classes …
d. Storage Proteins:
e.g. Casein: Major source of
Calcium phosphate in mammalian
infants
E.g. Ferritin: for Hb synthesis
e. Contractile and Motile Proteins፡ For
cell motility, muscle contraction , cell
division
e.g. Actin & Myosin: muscle
contraction

Dynein and Kinesin (Motor
proteins): drive the movement of
vesicles, granules, and organelles
along microtubules 55
 Functional classes …
f. Structural Proteins

- Provide strength & protection to cells & tissues

e.g. -keratin: hair, horns, and fingernails

Collagen: bone, connective tissue, tendons, cartilage,

Elastin: an important component of ligaments

Collagen and proteoglycans: in ECF that cushion and lubricate

g. Scaffold Proteins (Adapter Proteins)

eg. Can act as a scaffold onto which a set of different proteins assembled

Anchoring (or targeting) proteins: bind other proteins, causing them to
associate with other structures in the cell
56
 Functional classes …
h. Protective proteins
- active role in cell defense & protection

- Eg. Immunoglobulins or antibodies by lymphocytes

- thrombin and fibrinogen:

57
 Protein Classification Based on Nutritional Value

◦ Complete or high quality proteins:
 Contain all the necessary essential amino acids; eggs, meat, etc.

◦ Incomplete or low-quality proteins:
 Deficient in one or more essential amino acids

 Eg. corn deficient with Lys, Met, Try

 Protein Classification Based on composition: Simple Vs
Conjugated
◦ Simple proteins: only amino acids

◦ Conjugated proteins: amino acids + something else.
58
 Types of Conjugated Proteins
i. Glycoproteins

- Mostly Proteins destined for an extracellular location

e.g. Fibronectin (adhesive glycoproteins) and proteoglycans for ECM

IgG: circulate in plasma

- Many glycosylated membrane proteins on extracellular segment

ii. Lipoproteins: Primarily in the transport of lipids

iii. Nucleoproteins: for storage & transmission of genetic information

e.g. Ribosomes, Chromosomes
59
 Types of Conjugated Proteins
iv. Phosphoproteins: Esterified with phosphates by ser, thr or tyr

e.g. Casein: bring phosphorous to growing infant

v. Metalloproteins: - metal storage proteins (e.g. ferritin)

- metal containing enzymes e.g SOD

vi. Hemoproteins

- Subclass of metalloproteins

- Having heme prosthetic grp

vii. Flavoproteins - Containing flavin (vitamin B2 derivative)

E.g. oxidoreductases
60
Protein Classification Based on Shape (Architecture)
- Fibrous proteins, “long & thin”
- Simple, regular linear structure
- Polypeptides organized nearly parallel along a single axis
- Insoluble proteins in water or in dilute salt solution
e.g -Keratins in Collagen
- Serve structural role in cells (e.g. Hair, wool, skin, nail)
- Often assembled into large cables or threads

- Globular Proteins, “Spherical Shape”
- Roughly spherical
- Compactly folded with hydrophobic interior
- Usually very soluble in aqueous solution
- Most soluble cellular proteins
e.g. Insulin, Hb, Enzymes, Abs, Carrier proteins 61
- Membrane Proteins
- Hydrophobic side chains oriented outward for interaction with
membrane
- Hence, insoluble in aqueous but solubilized by detergents
- Have fewer hydrophilic amino acids than cytosolic proteins

62
Common Fibrous and Globular Proteins: Occurrence & Use

63
 Example of Fibrous proteins: -Keratin
 Major components of hair & nails
 A fibrous structural protein coiled
into a right-handed helix
 -helix strands are wound into a
“superhelix”.
 One complete superhelix turn for
each 35 turns of the -helix.
 -helix stabilized by H-bonds
between amide N–H groups and C=O
groups four residues away a-helical
segments in their chains

64
Your hair

65
 Examples of Fibrous Proteins: Collagen
 Constituent of connective tissues

 Tendons, cartilage, bones, teeth, skin, & blood vessels

A Triple Helix

 Rigid, inextensible fibrous

 High tensile strength

 Helps for running and jumping that put severe stresses on joints and
skeleton

 Collagen is just like rope -- enables your skin to be strong and flexible.

 Most common collagen types

 Type I - bones, tendons, and skin – two 1 (I) & one 2 (I)

 Type II – Cartilage

 Type III - Blood vessels
66
 Examples of Fibrous Proteins: Collagen
Tropocollagen: Basic structural unit of collagen
Three intertwined polypeptide chains each >1000 AAs
Mainly composed of Glycine (one in three) & proline
Sequence are repeats of a Gly-x-y motif, where
x is frequently Pro
y is frequently Pro or Hyp
In the triple helix, every third residue faces or contacts the
crowded center of the structure. So only glycine fit
Contain 4-hydroxyproline (Hyp), 3-hydroxyproline, & 5-
hydroxylysine (Hyl)
Important for intermolecular and intramolecular cross linkage
Hydroxylation require ascorbic acid
67
Examples of Fibrous Proteins: Collagen
- Collagen triple helices are 300 nm long,

- 40-nm gaps occur between adjacent collagen
molecules in a row

- Pattern repeats every five rows (5 X 68 nm =
340 nm)

Hole regions: 40-nm gaps are important for

 Attachment of sugars to 5-hydroxylysine
 plays a role in organizing fibril assembly

 Plays a role in bone formation.

 Microcrystals of hydroxyapatite (Ca5(PO4)3OH)
embedded in a matrix of collagen fibrils.

68