Protein Structure & Function (Cellular & Molecular Biology MD105) F2024 PDF

Summary

These lecture notes cover protein structure and function in Cellular & Molecular Biology. The document explains the fundamentals of protein structure, including amino acid structure, different bonding types, and the roles of various molecules.

Full Transcript

Cellular & Molecular Biology
MD105

Dr C. Michaeloudes
Protein structure and function
Dr C. Michaeloudes
Cellular & Molecular Biology MD105
 Lecture Objectives
To understand:
The basic structure of amino acids and the formation of
polypeptide chains
The basic process of protein folding and the levels of protein
structure organization
The importance of the 3D conformation in protein activity
and the different roles of proteins in the cell
The role of enzymes in the cell and how enzyme activity is
regulated
The role of protein misfolding in causing disease
REMINDER – Chemical bonds
 Chemical bonds
Chemical bonds hold atoms together to form molecules

Chemical bond = the attractive forces between two or more
atoms leading to the formation of molecules

Chemical bonds in biological molecules:
1. Covalent bonds
2. Weak non-covalent bonds
Electrons and bonding
Atomic nucleus consists of protons (positively
charged) and neutrons (neutral)
Ø Positive charge
Electrons are continuously moving around
the nucleus in specific regions (orbits) –
shells
§ 3 shells (some atoms have 4)
§ Each shell can take a maximum number of
electrons
Atoms whose outer shells are completely
filled are very stable (e.g helium, argon)
Atoms with incomplete outer shells tend to
interact with other atoms to fill their outer
shells
Ø Transfer electrons or share electrons
Covalent bonds
Covalent bonding involves sharing
electrons between two or more atoms
§ Complete the outer shell of each atom
Shared electrons hold the nuclei
together by opposing their mutual
repulsion
Strongest bonds in the cell
§ Broken by specific chemical reactions
catalyzed by enzymes
Disulfide bonds
§ Covalent bonds between thiol (-SH)
groups of two amino acids
 Weak non-covalent interactions

Electrostatic attractions
§ Electron transferred from one atom to the other creating a
negative and a positive ion
§ Electrical attraction between the negative and positive ions
 Weak non-covalent interactions

Hydrogen bonds
§ Hydrogen and oxygen are held together by a polar covalent
bond
§ one side of the molecule is slightly more positive or negative
than the other side
§ electrical attraction between the more positively-charged H
atom and the more negatively-charged O
§ Can form between molecules other than water
Image from Essential Cell Biology, 5th Edition
Weak non-covalent interactions

Van der Waals attraction
§ Transient attractions that
form when any two atoms
approach each other
§ Non-specific
§ Form due to fluctuations
in the electron
distribution in each atom
§ Transient electrostatic
attraction
 Hydrophobic forces

Not a considered as bonds
Aqueous environment (containing water) - non-polar
molecules move away from the hydrogen bonded water
molecules
Drive hydrophobic molecules to aggregate together away
from water
Bring molecules together to promoting bonding
 Amino acid structure and
formation of polypeptide chains
 Amino acids

Amino Carboxyl
group group

Side chain

Small organic molecules, which possess a carboxyl group (-COOH)
and an amino group (-NH2) attached to a central α-carbon
The α-carbon carries a specific side chain that distinguishes one
amino acid from the other
§ 20 different amino acids
Side chains give amino acids unique chemical properties
Amino acids
 Hydrophilic side chains
Water molecule Lysine (positive charge) Asparagine (polar)

Hydrophilic = molecules that easily dissolve in water -“Water-
loving”
§ Form hydrogen bonds with water
Polar or charged (negative/positive) molecules
Polar = molecule with uneven distribution of electrons
§ one side of the molecule is more positive or negative than the other
side
 Hydrophobic side chains
Ethane Isoleucine (hydrocarbon chain) Tryptophan (ring structure)

Hydrophobic = molecules that do not dissolve in water – “Water-
fearing”
§ Do not form hydrogen bonds with water
Non-polar/uncharged side chains
Non-polar = hydrocarbon chains and ring structures
 Proteins are made of amino acids

Peptide
bond
A protein is made up of a long chain of amino acids
§ Polypeptide chains
Amino acids are held together by covalent bonds called peptide
bonds
The carbon atom of the carboxyl group of one amino acid reacts
with the nitrogen atom from the amino group of a second amino
acid leading to removal of water (condensation)
Protein synthesis
 Polypeptide chains have a specific amino acid sequence

Polypeptide backbone

Amino Carboxy
terminus terminus

Peptide
bond

Side chains
Amino acid sequence

Each polypeptide chain has an amino (-N) terminus (-NH2 group) and a
carboxy (-C) terminus (-COOH group)
Side chains project from the polypeptide backbone and are involved in
chemical bonding required for folding into active proteins
For each protein, the amino acids are present in a unique order called the
amino acid sequence
 Protein folding
Polypeptide chain

Functional protein

Polypeptide chains are folded into their 3D shapes in order to form
a functional protein
The final folded shape of a protein is called its functional
conformation
§ changes in conformation lead to changes in protein function
 Protein folding
Polypeptide chain
Polypeptide chain folded into a 3D
structure – proteins
Polypeptide backbone is flexible –
some peptide bonds can rotate
freely allowing folding of the chain
Protein This allows the formation of bonds
between atoms in the polypeptide
backbone and the amino acid side
chains
Polypeptide chain can fold into
different shapes
 Where does protein folding occur?
Protein folding in the endoplasmic reticulum

Protein folding also occurs in other compartments i.e mitochondria,
cytoplasm, nucleus
 Chaperone proteins

Newly synthesized
Protein folding in living cells is
polypeptide chain assisted by special proteins called
chaperone proteins
Bind newly-synthesized polypeptide
Chaperone chains and make the folding process
proteins
more efficient by:
§ By providing energy obtained
from ATP hydrolysis
§ By preventing polypeptide chains
from forming aggregates
Incorrectly folded Correctly folded
protein protein (becoming tangled) with other
chains
 Levels of protein structure organization
Amino
acids Amino acid sequence – the order
1. Primary structure
of amino acids in the polypeptide
chain

β-sheet
Hydrogen bonding between atoms
β-sheet α-helix
α-helix
2. Secondary structure of the polypeptide backbone causes
some sections of the chain to fold
into repeating patterns

Polypeptide chains undergo 3D
3. Tertiary structure
folding due to covalent and non-
covalent bonds between amino acid
side chains

4. Quaternary structure Two or more polypeptide chains
combine to form a complex
Levels of protein structure organization
Secondary structure
Secondary structure
Secondary structure = folding of
regions of the polypeptide chain
into specific patterns by forming
hydrogen bonds between atoms
in the backbone
Two types of secondary
structures:
1. α-helix
2. β-sheet
Most proteins have a mix of the
two patterns
The α-helix
A single polypeptide chain
twists around itself to form a
right-handed helix
The α-helix structure is stabilized
by hydrogen bonds
A hydrogen bond is formed
every 4th amino acid, linking the
carbonyl group (C=O) of one
peptide bond and an amino
group (N-H) on another
 Proteins containing α-helices

α-helices are found in proteins Two or more α-helices can wrap
located in cell membranes around each other to form
§ E.g transport proteins and structures called coiled-coils
receptors § Found in elongated proteins like
α-keratin (hair, skin, nails) and
myosin (muscle contraction)
β-sheet

Segments of polypeptide
chains lying side by side are
held together by hydrogen
bonds
§ Between carbonyl and
amino groups of peptide
bonds

Very strong structure
 β-sheets are found in immunoglobulins

Immunoglobulins are made up of 4 polypeptide chains, which are
folded into repeated domains containing 2 stacked layers of β-
sheets
Tertiary structure
Tertiary structure is determined by
bonding between side chains
Tertiary structure = folding
into the complete 3D
conformation
Electrostatic
Hydrogen
attractions
bond The tertiary structure of
Disulfide proteins is stabilised by
bond bonding between amino
acid side groups
Hydrophobic § Electrostatic attractions
interactions § Hydrogen bonds
§ Disulfide bonds
 Hydrophobic forces also determine
tertiary structure
Unfolded polypeptide In aqueous environment
(water) hydrophobic side
chains cluster together in
the interior of the
Hydrophobic Hydrophilic Polypeptide protein, away from the
side chains side chains backbone water
Hydrophilic side chains
are found near the
Hydrophilic side Hydrophobic outside of the folded
chains are on the side chains
are clustered
protein, where they form
outside
in the interior hydrogen bonds with
of the protein water molecules
Folded protein
Quaternary structure
 Quaternary structure
Some proteins contain more than one polypeptide chains
(subunits) associated together
Subunits are held together by the same types of bonds that
hold together the tertiary structure
§ Electrostatic interactions
§ Hydrogen bonds
§ Hydrophobic interactions
The tertiary structure is required for the function of the
protein
 Haemoglobin quaternary structure

β β Example: Haemoglobin
consists of 4 polypeptide
chains – tetramer
§ 2 α subunits and 2 β
subunits
Each polypeptide chain
holds a haem molecule
where oxygen is bound
α α
Protein function
Which jobs do proteins do in the cell?
Functional Proteins Structural Proteins
 Protein domains
AMP-binding Proteins are divided into functional units (40-
domain 350 aa), which are conserved and fold into a
3D conformation independently of the rest
of the chain
§ E.g α-helices and β-sheets
Each domain has a specific function
§ E.g DNA-binding, calcium-binding
Some proteins have more than one domains
linked by a region of polypeptide chain
Example: bacterial catabolite activator
protein (CAP) has 2 domains
DNA-binding
domain § Binds to the signaling molecule cAMP
§ Binds to DNA
Enzyme function
 Enzymes
Catalyze nearly all the chemical reactions in the cell
§ Accelerate the speed of chemical reactions
Bind to one or more ligands (substrates) and convert them
into chemically modified products
§ This happens again and again without the enzyme changing
Usually involves making or breaking a covalent bond in the
substrate molecule
Grouped into functional classes based on the chemical
reactions they catalyze
Each enzyme type catalyzes one specific reaction
§ E.g hexokinase adds a phosphate group to D-glucose
 Enzymes

Substrate binds to binding site (active site) forming enzyme-substrate
complex
Covalent bonds are made or broken forming an enzyme-product
complex
Product is released and enzyme binds to additional substrate
molecules
 Active site

Ligand-binding site is created by protein folding and the amino acid
side chains
Provides a complementary shape to its ligand and keeps the ligand
in place via weak non-covalent bonding
§ Hydrogen bonding, electrostatic attractions
Active site
 Enzyme Cofactors
Some enzymes need to be bound to non-protein molecules
called cofactors to function normally
Co-factors can be:
§ Inorganic ions such as Fe2+ and Mg2+ - minerals
E.g DNA polymerase requires Mg2+ as a co-factor
§ Organic molecules mostly derived from dietary vitamins
E.g Vitamin C is a coenzyme for enzymes involved in collagen
synthesis
Attach permanently (covalent bonds) or temporarily
(electrostatic attractions or hydrogen bonding) to the enzyme
Cofactors are required for the enzyme to catalyze the reaction
Enzyme activity
 Regulatory molecules
Enzymes can be regulated by other molecules that either
increase or reduce their activity.
Molecules that increase the activity of an enzyme are
called activators
Molecules that decrease the activity of an enzyme are
called inhibitors
§ Competitive and non-competitive inhibitors
Competitive inhibition
Inhibitor molecule is structurally
similar to the substrate
It binds to the active site and
prevent the substrate from
binding (competition)
The rate of reaction slows down if
the substrate concentration is low
If the substrate concentration is
high then the substrate occupies
most of the active sites so the
inhibitor cannot inhibit the rate of
reaction
Non-competitive inhibition
Inhibitor molecule binds to a site
away from the active site-
allosteric site
Changes the 3D structure of the
protein
The active site of the enzyme
changes conformation so the
substrate can bind but cannot
activate the enzyme
Regardless of how much
substrate there is the rate of
reaction is slow
Competitive and non-competitive inhibition
Protein misfolding and disease
 Misfolded proteins can cause disease
Proteins that are incorrectly folded (misfolded) are taken to the
lysosomes for degradation using the process of autophagy
In some pathological cases misfolded proteins are not degraded
§ Mutations that change the amino acid sequence
§ Defective lysosome function
§ Abnormal chaperone protein function
Misfolding of α-helix into β-sheets
§ Misfolded proteins form filaments made of continuous stacks of β-
sheets
Accumulation of these filaments leads to the formation of called
amyloid fibrils
Accumulation of these insoluble fibrils lead to the formation of
amyloid plagues that can damage cells and tissues
 Misfolding and neurodegenerative diseases

β-sheet stacks Amyloid fibrils Amyloid plagues on neurons
(filaments)
Accumulation of plagues on neurons causes them to die leading to
impaired neurotransmission
Amyloid plagues are characteristic of neurodegenerative diseases:
§ Alzheimer’s disease
§ Huntington’s disease
§ Bovine spongiform encephalopathy (mad cow disease)
§ Creutzfeldt–Jakob disease
 Sickle cell anaemia
Normal gene Single nucleotide
mutation

Pro Glu Glu Pro Val Glu

Glutamate - hydrophilic Valine - hydrophobic

Abnormal protein
Normal protein conformation –
conformation Subunits form long
rigid protein fibers

Die prematurely-
Anaemia
Rigid/sticky – blood
Normal red blood cells Sickle cells vessel obstruction