Protein Structure & Function 2022-2023 PDF

Summary

This document is a lecture on protein structure and function, covering topics like protein structure levels, bonds, types, functions, and protein folding. It also includes examples of different protein types and diseases related to protein misfolding.

Full Transcript

Protein Structure &
Function
Foundation - I Module

Johar Iqbal

Faculty of Medicine 2022-2023
 Objectives
Levels of protein structure: Primary, secondary, tertiary and quaternary
Various types of bonds and forces that stabilizes these structures
Protein denaturation
Prion and Prion related diseases
Conjugated proteins
Globular and fibrous proteins
Functions of proteins
 Levels of Protein Structure

Types of bonds in protein structure
Covalent bonds Non-covalent bond (Interactions)
Peptide Hydrophobic Interactions
Disulphide Ionic Interactions
Hydrogen bonds
All bonds shown together
 Primary structure of proteins
Primary Structure: What are the amino acids that
make up the protein and how are they arranged in
the chain? (The amino acid sequence)

ala arg asn asp cys gln glu

gly his ile leu lys met phe

pro ser thr trp tyr val
 Peptide Bond
In a protein, Amino Acids are joined covalently by peptide bonds

Characteristics of peptide bond
– It is a partial double-bond.
– It is shorter than a single bond
– Rigid & planar, no rotation
– Trans in configurations
– Uncharged but polar
 Physiologically important peptides
Glutathione 3 Angiotensin II 8
Enkephalin 5
Oxytocin 9
GnRH 10
Vasopressin 9

Cys-Tyr-Ile-Gln-Asn-Cys-Pro-Leu-Gly Oxytocin
Cys-Tyr-Phe-Gln-Asn-Cys-Pro-Arg-Gly Vasopressin
 Glutathione

Tripeptide
Pseudopeptide
Function of Glutathione (GSH)
Detoxification
Antioxidant
Glucose-6-phosphate dehydrogenase deficiency
 Secondary Structure of Proteins
α-Helix
– Most common

β-sheets

β-Bends & Loops
 Secondary structure: the a helix
It is the most common conformation.
It is a spiral structure.
Tightly packed coiled polypeptide
backbone, with extending side chains.
The formation of the α-helix is
spontaneous.
It is stabilized by H-bonding
e.g.
– Keratin - entirely α-helical
– Myoglobin - 80% helical.
*Proline and glycine break helices
 An amino acid that disrupts an α helix -
– Glycine and proline,
– bulky amino acids (tryptophan, valine),
– charged amino acids (glutamate, histidine)
The disruption of the helix is important as it introduces
additional folding of the polypeptide backbone to allow the
formation of globular proteins.
 Secondary structure: the b sheets
β-sheets are either parallel or
antiparallel.
Makes up the core of many proteins
– Parallel chain: two peptide strands
running in the same direction held
together by hydrogen bonds
– Anti-parallel chain: two peptide
strands running in opposite
directions held together by hydrogen
bonds
 β-Sheets

β-sheets is stabilized by Hydrogen-bonding.
Unlike the compact backbone of the α helix, the peptide backbone
of the β sheet is highly extended.
 β-Bends & Loops
Roughly half of the residues in a “typical” globular protein
reside in α helices and β sheets while the rest in loops, turns,
bends, and other extended conformational features.
β-Bends are generally composed of four amino acids, one of
which may be proline. Glycine, the smallest amino acid is also
frequently found in β-bends.
β-Bends are stabilized by the formation of hydrogen and
ionic bonds.
 Components of Tertiary Structure
Fold – used differently in different contexts – most broadly
a reproducible and recognizable 3-dimensional arrangement
Domain – a compact and self folding component of the
protein that usually represents a discreet structural and
functional unit
Motif (super-secondary structure) a recognizable
subcomponent of the fold – several motifs usually comprise
a domain
 Tertiary Structure of Globular proteins
Tertiary structure refers to the complete three-dimensional
structure of the polypeptide units of a given protein.
It is stabilized by following interactions
– Hydrogen bonds
– Disulfide bonds
– Hydrophobic interaction
– Ionic interactions
 Protein Folding
Protein folding takes place in Endoplasmic Reticulum

Some proteins fold spontaneously

Some proteins require help to fold correctly
– Molecular chaperones
Proteins that interact with partially folded or improperly folded proteins and
provide a microenvironment in which folding can occur
Details of the mechanism of action remain unknown
 Chaperones
Two classes of molecular chaperones
– Chaperonins
– Heat shock proteins (example: Hsp70)
Heat shock proteins are expressed in large quantities after cells experience high
temperatures
Recognize denatured proteins by binding to hydrophobic patches
 Protein Denaturation
The normal three-dimensional conformation (i.e., normally folded)
of proteins which is primarily maintained due to intracellular
physiological conditions can be disturbed when exposed to extreme
conditions not typically found inside a cell, e.g., heat, pH or organic
solvents, etc., which may result into partial or complete loss of
tertiary structure is called denaturation.
Factors causing denaturation
– Temperature
– Organic solvents e.g., Urea
– pH
– Shear force
 Prion
Prions are misfolded proteins.
Prions cause diseases, but they
aren't viruses or bacteria or fungi
or parasites. They are proteins.
When they encounter normally
folded proteins of our body, they
can change their conformation
and make them misfolded
(abnormal).
 Prion related diseases
Bovine spongiform encephalopathy (BSE or mad cow
disease) is seen in cattle and livestock and Creutzfeldt-Jakob
disease (CJD) is seen in humans. ‘Mad cow’ epidemic that hit
England in 1986
Scrapie in sheep and goats has the same basis.
Kuru, a transmissible spongiform encephalopathy, is found in
the people of a tribe in New Guinea due to their practice of
cannibalism.
 Quaternary structure
Quaternary structure only exist in proteins containing two or more
than two polypeptide. e.g., Myoglobin – One Polypeptide – No
Quaternary Structure, whereas hemoglobin carrying four polypeptides
and does have the quaternary structure.
It is stabilized by hydrogen, ionic bonds and hydrophobic
interactions.
o Hemoglobin – Four Polypeptide
o Lactate Dehydrogenase – Four Polypeptide
o Creatine Kinase – Two Polypeptide
Hemoglobin and Myoglobin
structure
MYOGLOBIN
 Protein Classification
Monomeric proteins - One polypeptide chain
Multimeric proteins - More than one polypeptide chains
– Homomultimer – all one kind of chain e.g., Lactate Dehydrogenase (H4)
– Heteromultimer - two or more different chains
For example, hemoglobin is made up of 2𝛼 and 2𝛽 chains, therefore, it is a
heterotetramer.
 Protein Classification
Fibrous Protein –
– Polypeptides arranged in long strands or sheets
– Water insoluble – made up of lots of hydrophobic amino acids
– Strong but flexible
– They perform mainly Structural functions e.g., keratin, collagen

Globular Protein (Soluble Protein)–
– Polypeptide chains folded into a spherical or globular form
– Water soluble
– Contain several types of secondary structure
– They perform a variety of functions inside a cell e.g., enzymes,
immunoglobulins, regulatory proteins, etc.
 Conjugated PROTEIN

Simple – composed only of amino acid residues

Conjugated – contain prosthetic groups
(metal ions, co-factors, lipids, carbohydrates)
Example: Hemoglobin – Heme

Phosphoprotein Nucleoprotein

Glycoprotein Lipoprotein

e.g.

Mucin Casein (Milk Protein) LDL Telomerase
 Protein Function
– Enzymes (Amylase, Hexokinase, Urokinase)
– Structural (Collagen, Laminin)
– Transport (Albumin)
– Motor (Actin)
– Storage (Ferritin)
– Signaling (Integrins and Cadherin)
– Receptors (GPCRs - G-protein coupled receptors)
– Gene regulation (transcription factors e.g., HIF-1)
Q1-Which of the following bonds stabilizes
the secondary structures of proteins?

A. Ionic interactions
B. Hydrophobic interactions
C. Disulfide linkage
D. Peptide bonds
Q2-Which of the following proteins is more
likely to have a quaternary structure?

A. Lactate dehydrogenase
B. Oxytocin
C. Glucagon
D. Vasopressin
 Q3-Which of the following diseases is
caused by prion proteins?

A. Scrub typhus
B. Scabies
C. Scrapie
D. Scleroderma
 Q4-Ferritin is an example of which of the
following categories of proteins?

A. Structural
B. Transport
C. Storage
D. Signaling
 Thank you

Faculty of Medicine 2022-2023