Structure-Function Relationship in Specific Proteins PDF

Summary

This document explains the structure-function relationships of various proteins, focusing on globular proteins like hemoglobin and myoglobin, and fibrous proteins such as collagen, myosin, and actin. It highlights the key characteristics, functions, and associated diseases of these proteins.

Full Transcript

STRUCTURE-FUNCTION
RELATIONSHIP IN
SPECIFIC PROTEINS
Lesson 4

Structure-function relationship in
specific proteins
• Globular proteins:

Hemoglobin and Myoglobin
• Fibrous proteins:
1. Collagen

Myosin
3. Actin fibers
2.

Globular proteins
CHARACTERISTICS:
•

Compact shape

•

Globular estructure (rounded)

•

Water soluble  Can be dissolved in blood

•

Variety of biological functions: enzymes, transport proteins, motor proteins, regulatory
proteins, immunoglobulins…

Globular proteins: Soluble proteins with
a globular (somewhat rounded) shape.

Globular proteins
•

Myoglobin and Hemoglobin

Conjugated proteins  Heme proteins
1. Apoprotein aa
2. Prosthetic group Heme group

Myoglobin

Hemoglobin

• Muscle
• Stores oxygen
• Localized oxygen reserves for times of
intense respiration
• Tertiary structure
•
•
•
•

Erythrocytes
Oxygen transport from the lung to the tissues
CO2 transport from tissues to lungs (waste)
Quaternary structure

Globular proteins

Myoglobin and Hemoglobin

Prosthetic group Heme group
Complex organic ring structure  Protoporphyrin
Iron atom in its ferrous (Fe2+) state
The iron atom of heme has 6 coordination bonds:
• 4 in the plane of, and bonded to, the flat porphyrin ring system
• 2 perpendicular to it
Proximal His

O2

Globular proteins
•

The heme is positioned within a hydrophobic pocket of the
apoprotein :
1.
2.

•

Myoglobin

To protect iron from oxidation.
To avoid CO from binding the heme group.

Important (and conservated) aa residues in myoglobin and
hemoglobin
1.
2.

Proximal His  coordinated with iron
(perpendicularly)
Distal His close to the Fe but not
bound to it and favours the entry of
Oxygen instead of other compounds
like CO

Globular proteins

Hemoglobin

• Transports gases through the blood
• Oligomeric protein  Quaternary structure

Contains 4 polypeptide chains and 4 heme prosthetic groups
2 α subunits
2 β subunits
The subunits are arranged in symmetric pairs
Noncovalent interactions between
its subunits

Globular proteins
•

4 O2 binding sites

•

2 Conformations of the subunits:

Hemoglobin
Allosteric protein: A protein (generally with multiple
subunits) with multiple ligand-binding sites, such that
ligand binding at one site affects ligand binding at another.

 T state  Tense Without oxygen
 R state  Relaxed  Oxygen binded

•

The binding of O2 to a Hb subunit in the T state
triggers a change in conformation to the R state

Oxygen binding to hemoglobin is both allosteric and cooperative

T → R transition

The binding of the first oxygen facilitates the
binding of oxygen to the other subunits.

Globular proteins

Hemoglobin

AGENTS THAT AFFECT OXYGEN BINDING
•

Protons and CO2

 End products of cellular respiration from tissues (waste)
 High protons and CO2 concentration of peripheral tissues reduced

the affinity of Hb for oxygen
ConsequentlyO2 is released to the tissues. CO2
binds to hemoglobin

•

2,3-bisphosphoglycerate (BPG)

 Physiological adaptation to high altitudes
 Decrease in the affinity of Hb for oxygen

ConsequentlyO2 is less readily bound to
hemoglobin, but easier to release in
the tissues

Fibrous proteins
• Insoluble in water  high concentration of hydrophobic amino acid

residues both in the interior of the protein and on its surface

• Adapted for structural functions  strength and/or flexibility to the

structures

• Elaborate supramolecular complexes  similar polypeptide chains are

packed together
Collagen

Myosin

Actin fibers

Fibrous proteins

• Structural functions  Strength
• Connective tissue  tendons,

cartilage, matrix of bone and
the cornea of the eye

• The most abundant protein in

mammals

Collagen

Fibrous proteins
COLLAGEN HELIX
•

Secondary structure  left-handed helix

•

Three amino acid residues per turn

•

Aa sequence

Gly–X–Y,

X often Pro
Y  often 4-HPro

1/3 Gly, 20% Pro and OH-Pro, Ala, OH-Lys.

TROPOCOLLAGEN
•

3 collagen helix are twisted about each other

•

Right-handed  Strength

COLLAGEN FIBERS
•

Tropocollagen is associated in a variety of ways to
provide different degrees of tensile strength

Collagen

Fibrous proteins

Collagen

COLLAGEN FIBERS
•

Tropocollagen is associated in a variety of ways to provide
different degrees of tensile strength

•

Covalent bonds  Cross-linked

•

Different collagen fibers have different number of crosslinks.

•

Depending on the number of cross-links collagen fibers
are more rigid or flexible.

•

Cross-links increase in number with age.

Fibrous proteins

Collagen

COLLAGEN TYPES
•

At least 27 types  depending on cross-links present  Function

TYPE

TISSUE DISTRIBUTION

CHARASTERISTICS

MAIN FUNCTION

I

Skin, bone, tendon, teeth

Thick, closely packed,
strong. Lots of cross links

Resistance to tension

II

Elastic cartilages

Very thin fibres

Resistance to
intermittent pressure

III

Smooth muscle, uterus,
arteries, liver, spleen,
lung, kidney

Loosely packed thin fibres

Structural maintenance
in expansible organs

IV

Epithelial and endothelial
basal laminae

NO fibres

Support and filtration

Fibrous proteins

Collagen

DISEASES ASSOCIATED WITH GENETIC OR METABOLIC DISORDERS OF COLLAGEN
Osteogenesis imperfecta

Scurvy

 Genetic disorder  fragile bones that

 Caused by lack of

 Commond name 

 Helix is not stable

breaks easily

brittle bone disease

Vitamin C  Required to
form hydroxyproline

 Mutation in collagen helix  shorter

 General degeneration of connective tissue

 Affects collagen type I

 Symptoms  small hemorrhages, tooth loss,

poor wound healing, bone pain and
degeneration, heart failure….

 Vit C  Fruits and vegetables

Fibrous proteins

Myosin

•

Six subunits
2 heavy chains
2 light chains

•

Carboxyl terminus  extended α hélix  Left handed
supercolid hélix

•

Amino terminus  large globular domain containing a
site where ATP is hydrolyzed

•

The light chains are associated with the globular
domains

Fibrous proteins

Myosin

THICK FILAMENTS
•

Agreggation of hundred myosin molecules

•

Muscle cells  core of the contractile unit

•

Bipolar structure

Fibrous proteins

Actin

•

G-actin (globular actin)  Monomeric actin

•

F-actin (filamentous actin)  assemblage of G-actin monomers that
polymerize two by two. Right-handed.

THIN FILAMENT
•

F-actin + troponin + tropomyosin

•

Muscle cells  Each actin monomer in the thin filament can bind tightly
and specifically to one myosin head group

Fibrous proteins

Fibrous proteins