2. Membrane proteins
• Membrane proteins are common proteins that are part of
membrane or interact with Biological membrane
Three Types of Membrane Proteins Differ in Their Association with the
Membrane
• Integral membrane proteins
• Peripheral membrane proteins
• Amphitropic proteins
3. Integral membrane proteins
• Transmembrane proteins
• Integral membrane proteins are very firmly associated with the lipid
bilayer
• Are removable only by agents that interfere with hydrophobic
interactions, such as
• Detergents, Organic solvents, or Denaturants
4. Peripheral membrane proteins
Associated with membrane
• Electrostatic interactions
• Hydrogen bonding
• With the hydrophilic domains of integral proteins
• With the polar head groups of membrane lipids.
Can be released by relatively mild treatments that interfere with
• Electrostatic interactions
• Break hydrogen bonds
• Commonly used agent is carbonate at high pH
5. Amphitropic proteins
• Amphitropic proteins are found both in the cytosol and in association with
membranes.
• Protein’s noncovalent interaction with a membrane
protein or lipid,
• Presence of one or more lipids covalently attached to
the amphitropic protein.
Reversible association of amphitropic proteins with the
membrane is regulated
e.g. Phosphorylation or ligand binding can force a
conformational change in the protein, exposing a
membrane-binding site that was previously inaccessible
6. Many Membrane Proteins Span the Lipid Bilayer
• the Erythrocyte glycoprotein glycophorin.
• Its amino-terminal domain (bearing the carbohydrate
chains) is on the outer surface and is cleaved by trypsin.
• The carboxyl terminus protrudes on the inside of the
cell, where it cannot react with impermeant reagents.
• Both the amino-terminal and carboxyl-terminal domains
contain many polar or charged amino acid residues and
are therefore hydrophilic.
• However, a segment in the center of the protein
(residues 75 to 93) contains mainly hydrophobic amino
acid residues, suggesting that glycophorin has a
transmembrane segments arranged as shown in figure
7. Hydrophobic Interactions of Integral Proteins
with Lipids
• The firm attachment of integral proteins to
membranes is the result of hydrophobic
interactions between membrane lipids and
hydrophobic domains of the protein
• Some proteins have a single hydrophobic
sequence in the middle (as in glycophorin) or
at the amino or carboxyl terminus.
• Others have multiple hydrophobic sequences,
each of which, when in the alpha-helical
conformation, is long enough to span the lipid
bilayer
8. Transmembrane proteins (Bacteriorhodopsin)
• Bacteriorhodopsin, has seven very hydrophobic internal
sequences and crosses the lipid bilayer seven times
• Bacteriorhodopsin is a light-driven proton pump
densely packed in regular arrays in the purple
membrane of the bacterium Halobacterium salinarum
• Seven segments of about 20 hydrophobic residues can
be identified, each forming an helix that spans the
bilayer
• Hydrophobic interactions between the nonpolar amino
acids and the fatty acyl groups of the membrane lipids
firmly anchor the protein in the membrane
9. Annular lipids
• phospholipid molecules lie on the protein surface
• head groups interacting with polar amino acid
residues at the inner and outer membrane–
• Water interfaces and their side chains associated
with nonpolar residues.
• These annular lipids form a bilayer shell (annulus)
around the protein, oriented roughly as expected
for phospholipids in a bilayer
10. Embedded phospholipids (Grease Seal)
• Other phospholipids are found at the
interfaces between monomers of multi-
subunit membrane proteins, where they form
a “grease seal.”
• Yet others are embedded deep within a
membrane protein, often with their head
groups well below the plane of the bilayer.
• For example, succinate dehydrogenase
(Complex II, found in mitochondria has
several deeply embedded phospholipid
molecules)