Membranes Flashcards
(35 cards)
Glycerophospholipids
Consists of a polar head groups and fatty acids that are attached to a glycerol backbone Example include. They are the most abundant lipid component of membranes. They are glycerol-based compounds with two hydrophobic fatty acid chains that can differ in length (normally between 14 to 24 carbon atoms). One hydrophobic tail usually has one or more cis-bonds (double bond, i.e. it is unsaturated) while the other tail does not (i.e. it is saturated). Each double bond creates a small kink in the structure of the tail. The two tails are linked to glycerol via ester linkages. The hydrophilic head of a glycerolphospholipid molecule in the case of Phosphatidylcholine consists of a phosphate group attached to the glycerol backbone again via an ester linkage as well as choline further attached to the phosphate group also through an ester linkage.
Sphingolipids
They consist of polar head groups and fatty acids attached to a sphingosine backbone Examples include; Sphingomyelin, Glycosphingolipids (a.k.a glycolipids)
Cholesterol
amphipathic. Consists of a small polar head, steroid ring structure and short fatty acid tail
How are glycerophospholipids named?
The different glycerolphospholipid molecules are named after the side groups attached to the phosphate group. For example, phosphatidylcholine has a choline group; phosphatidylethanolamine has an ethanolamine group; phosphatidylserine has a serine group etc.
Ceramide
Sphingosine + fatty acid
sphingomyelin
Sphingosine + fatty acid = ceramide
ceramide + phosphate + choline = sphingomyelin
ceramide + sugars = ?
glycolipids –> galactocerebrosides or gangliosides
Cerebrosides
(e.g. galactocerebrosides) are important in nerve tissues and prevalent in the membranes of brain cells.
Gangliosides
(acidic glycosphingolipids) are the most complex sphingolipids, and are found primarily in the ganglion cells of the central nervous system. Gangliosides are of medical interest because several lipid storage disorders involve the accumulation of NANA (N-Acetyl Neuraminic Acid)-containing cells.
glycolipids
sphingolipids that contain carbohydrates attached to them. They are found in greatest amounts in nerve tissues and are located in the outer leaflet of the plasma membrane, where they interact with the extracellular environment. glycolipds found ONLY in the outer leaflet, with carbohydrate portions exposed on the cell surface.
outer leaflet lipid distribution
The ‘outer leaflet’ (which faces the outside of the cell) consists mainly of phosphatidylcholine and sphingomyelin + glycolipids exclusively on this side. +even distribution of cholesterol on both leaflets
lipid distribution in the membrane
outer leaflet: mainly phosphatidylcholine and sphingomyelin + glycolipids are exclusively found here. inner leaflet: consists mostly of
phosphatidylethanolamine,
phosphatidylserine and
phosphatidylinositol.
Cholesterol is evenly distributed among the bilayer.
Depending on the type of cell/organelle, the plasma membrane composition can vary significantly.
inner leaflet lipid distribution
consists mostly of phosphatidylethanolamine, phosphatidylserine and phosphatidylinositol. \+even distribution of cholesterol on both leaflets
Lipid Rafts
more rigid and dense than other portions of the membraneSphingomyelin and glycolipids tend to cluster in small semi-solid patches termed lipid rafts, which are enriched with cholesterol and GPI-anchored proteins. Certain membrane proteins with long enough membrane-spanning segments preferentially partition into the lipid rafts. Several proteins that are typically found in the membrane bilayer (such as G proteins and several protein kinases) can move in and out of rafts during the cell signaling process. The transient presence of these proteins in rafts allows for the clustering that is necessary for processes such as endocytosis and receptor-mediated signaling. Some rafts are stabilized by interactions with the cytoskeleton through peripheral membrane proteins.
Membrane fluidity
Lipids with saturated fatty acids pack more densely in the membrane and provide less fluidity.
Membrane fluidity is also affected by the length of fatty acid chains. Short fatty acid chains increased membrane fluidity when compared to long chains.Higher temperatures - in general - favor increased fluidity. As a lipid bilayer cools, it eventually undergoes a phase change in which it becomes a gel-like solid (and loses fluidity). However, the effects of temperature are dependent on fatty acid chain length and saturation status. Short fatty acid chains and high unsaturation lowers the phase transition temperature.
Cholesterol’s effects on membrane fluidity
depends on temperature. At high temperatures, the bulky steroid rings of cholesterol interfere with the movement of the fatty acid chains and reduce fluidity. At lower temperatures an opposite effect has been observed. By interfering with interactions between fatty acid chains, cholesterol prevents membranes from freezing and maintains membrane fluidity.
Lipid-anchored membrane proteins of the cytosol
In the cytosol, proteins can be anchored to the bilayer by a covalently-attached, hydrophobic fatty acid tail. A number of growth signaling proteins whose function depends on their association with the plasma membrane (such as the signaling protein Ras) are modified in this way.
Lipid-anchored membrane proteins
these are covalently linked to a membrane-embedded lipid via a fatty acid chain or an oligosaccharide chain
Integral Membrane Proteins
anchor themselves within the bilayer via stretches of hydrophobic amino acids located in specific regions of the protein
peripheral proteins
Peripheral proteins are loosely associated (via electrostatic force or H-bonds) with Integral Membrane Proteins through protein-protein interactions and can be dissociated from membranes by relatively mild processes (e.g. high salt solution washing, metal chelating agents, or pH changes).
Myristic Acid
Fatty acid which is covalently attached to specific amino acids within in protein to make a lipid anchored protein. Protein attachment site = N-terminus (glycine). Fatty acid length = 14-Carbon
palmitic acid
Fatty acid which is covalently attached to specific amino acids within in protein to make a lipid anchored protein. Protein attachment site = internal cysteine residue. Fatty acid length = 16-Carbon
Prenyl group
Fatty acid which is covalently attached to specific amino acids within in protein to make a lipid anchored protein. Protein attachment site = c-terminus (cysteine). Fatty acid length = 15-Carbon (farnesyl group) 20-Carbon geranyl geranyl group
Lipid anchored membrane proteins outside of the cell
Proteins on the outer surface of the cell can be tethered to the plasma membrane via a glycophosphatidylinositol (GPI) anchor. Enzymes residing in the membrane of the cell can cleave the phoshatidylinositol moiety to release the GPI-linked protein from its association with the membrane.
