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Introduction to Lipids. Functions Classifications Simple lipids Complex lipids Precursor and derived lipids Complex lipids incorporate Phospholipids Glycerophospholipids Sphingophospholipids Glycolipids Other complex lipids. More Introduction. Saturated lipids Unsaturated lipids
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Introduction to Lipids • Functions • Classifications • Simple lipids • Complex lipids • Precursor and derived lipids • Complex lipids incorporate • Phospholipids • Glycerophospholipids • Sphingophospholipids • Glycolipids • Other complex lipids
More Introduction • Saturated lipids • Unsaturated lipids • Nomenclature • Essential and non-essential fatty acids • Specialized fatty acids: PG’s and related compounds
Lipids • Insoluble or poorly soluble in water • Soluble in non-polar solvents • Water-hating nature is due to the predominance of hydrocarbon chains • Functions • As a storage form of metabolic fuel • As a transport form of metabolic fuel • They provide structural composition of membranes • They have protective functions in bacteria, plants, and insects serving as a part of the outer coating between the body of the organism and the environment
Classification • Simple: Esters of fatty acids with alcohols • Complex: • Phospholipids = Fatty acid + Alcohols +Phosporic • Glycolipids = Fatty acid + Sphingosine + Cholesterol • Others = Sulfolipids, Amino lipids • Precursor and derived lipids: • Fatty acids, vitamins, hormones • Fatty acids are water insoluble long-chain hydrocarbons
Saturated and Unsaturated Lipids • Saturated fatty acids have no double bond. • General formula: CH3(CH2)n-COOH • The systematic name gives the number of carbons with the suffix anoic. For example, palmitic acid has sixteen carbons and the systematic name is hexadecanoic. • Unsaturated fatty acids have one or more double bonds. • Enoic is the suffix used. • Octadecenoic • Oleic acid unsaturated • Double bond are nearly always found in thecis configuration.
Nomenclature • 20:4 (5,8,11,14) = Arachidonic acid • This is a tetraenoic acid (four double bonds). • The carbon atoms are numbered with the –COOH carbon counted as C #1.
Space filling models of Sphingomyelin (A) and phosphatidyl choline (B) A. B.
There are 3 types of membrane lipids • 1. Phospholipids • 2. Glycolipids • 3. Cholesterol
Phospholipids • Phospholipids are the major class of membrane lipids. • Phospholipids are the most abundant lipids in membranes. • They are derived from glycerol (3 C alcohol) or sphingosine (complex alcohol). • Phospholipids derived from glycerol are called phosphoglycerides. • Components of a phosphoglyceride: Glycerol backbone (two fatty acids attached to) and phosphorylated alcohol. Fatty acid --- GLYCEROL --- P --- Alcohol
More Phospholipids • The length and the degree of unsaturation of fatty acid chains in membrane lipids have a profound effect of membrane fluidity. • In general, increasing the chain length will increase the melting temperature, Tm, of a fatty acid. • Addition of double bonds will decrease the Tm. • Therefore, the presence in membrane lipids of fatty acid’s that contain double bonds helps maintain the fluid nature of those lipids. • At physiological PH, the COOH (PKg = 4.8) ionizes, becoming COO-. It has an affinity for H2O. It gives fatty acid’s amphipathic nature. • The longer the fatty acid chain the more hydrophobic the chain is. • Since most of them are long-chain fatty acids, and highly insoluble in water, they are transported in the circulation with ALBUMIN.
Still More Phospholipids • Because they are ionized at physiological PH, two common fatty acids • Palmitic Palmitate (C16) • Oleic Oleate (C18, one double bond) • 1CH2OH - 2CH2OH - Glycerol 3CH2OH - The OH on 1 and 2 are esterified to the COOH groups of two fatty acids and 3 has PO32-. • Phosphatidate: simplest phosphoglyceride and key intermediate in the biosynthesis of the other phosphoglycerides.
Common Alcohol Moieties of Phophoglycerides
Membrane lipids • Sphingomyelin is a phospholipid found in membranes that is not derived from glycerol. Instead the backbone in sphingomyelin is sphingosine, an amino alcohol that contains a long, unsaturated hydrocarbon chain. In sphingomyelin, the amino group of the sphingosine backbone is linked to a fatty acid by an amide bond. • Glycolipids, as their name implies, are sugar-containing lipids. Like sphingomyelin, the glycolipids in animal cells are derived from sphingosine. The amino group of the sphingosine backbone as acylated by a fatty acid, as in sphingomyelin.
Sphingolipids, etc. • Sphingomyelin is the only phospholipid in membranes that is not derived from glycerol. Instead, the backbone is sphingosine, an amino alcohol that contains a long, unsaturated hydrocarbon chain. • Are found in large quantities in brain and nerve tissue… • On hydrolysis… • No glycerol is present… • Many membranes also contain glycolipids and cholesterol. • Are sugar containing lipids • Cell surface carbohydrates • Derived from sphingosine • Contain ceramide and one or more sugars • Look like sphingomyelin… instead of phosphoryl choline, they have a sugar unit…
Steroids • Steroids play many physiologically important roles. • Cholesterol is the best known. • This sterol is present in eukaryotes but not in most prokaryotes because cholesterol evolved after the Earth’s atmosphere became aerobic. • Important steroids include: • Bile acids • Adrenocortical homrone • Sex hormones • D vit • Cardiac glycosides, etc. • Cholesterol
More Steroids Cholesterol • Plasma membranes are rich in cholesterol. • It occurs in animal fats but not in plant fats. • Most highly decorated small molecule. Ergosterol • A precursor of Vitamin D. • Lipid peroxidation • Serparation of Lipids. • Oil : water interfaces
Membrane Structure and Dynamics • Common features of biological membranes • Major membrane lipids: phospholipids, glycolipids, and cholesterol. • Dynamic properties of the membrane • Membrane proteins • Lipid vesicles (liposomes) • Antibiotics as carriers or channels • Permeability of lipid bilayers • Membrane fluidity • Carbohydrates in the membrane, glycophorin • Transmembrane helices, spectrin*
Common Features of Biological Membranes • Sheet-like structures 6-10 nm thick form closed boundaries between different compartments. • Consist mainly of lipids and proteins and chs are attached to them. • Lipids have hydrophobic and hydrophilic moiety. They form closed biomolecular sheets in aqueous environment. • Globular proteins are embedded in the membrane. They serve as pumps, channels, receptors, energy transducers, and enzymes. • Membranes are non-covalent assemblies. • Most membranes are electrically polarized. • Membranes are asymmetric. • The individual lipid and protein subunits in a membrane form the fluid mosaic.
Lipid Vesicles and Planar Membranes • Permeability of lipid bilayers can be measured by two model systems: • Lipid vesicles (liposomes) • Planar bilayer membranes • We can make liposomes experimentally. These liposomes can be used to deliver drugs into certain cells. • Lipid bilayers are highly impermeable to ions and most polar molecules. • Transport antibiotics are carriers or channels. • Proteins in membranes: membrane proteins span the lipid bilayer.
Red-blood-cell plasma membrane: An EM micrograph of a preparation of plasma membranes from RBCs
Diagram of a section of a micelle: ionized fatty acids readily form such structures.
Preparation of glycine-containing Liposomes: Liposomes containing Gly are formed by sonication of phospholipids in the presence of Gly. Free Gly is removed by gel filtration.
Permeability coefficients (P) of ions and molecules in a lipid bilayer. The ability of molecules to cross a lipid bilayer spans a wide range of values.
SDS-PAGE pattern of : A. Red blood cells B. Retinal cells C. Sarcoplasmic reticulum membrane Membranes differ in their protein content!
