Lipids Flashcards
(25 cards)
properties of lipids
insoluble in water and highly soluble in organic solvent
are lipids macromolecules?
no. they are unable to form covalent bonds with one another to form larger molecules
how to classify lipids?
simple lipids - fatty acids and alcohol (usually glycerol)
compound lipids - fatty acids, alcohol and other groups
lipid derivatives
simple lipid definition
alcohol (usually glycerol) linked to one or more fatty acids via ester linkage
structure of glycerol
C3H8O3
3 carbon alcohol, each carbon atom bearing an hydroxyl group
soluble in water due to hydroxyl group
structure of fatty acids
fatty acids are carboxylic acids, wth carboxyl functional group (COOH) at one end and attached hydrocarbon chain
long carbon skeletons
non-polar C-H bonds
why are lipids insol in water
abundance of non-polar C-H bonds makes lipids hydrophobic
how can fatty acids defer + explain saturated vs unsaturated fatty acids
- length of hydrocarbon chain
- number and locations of double bonds along their carbon skeletons
- saturated fatty acid -> no double bonds (every carbon maximally bonded to hydrogen atoms)
- unsaturated fatty acid -> one or more double C=C bonds, kink in its tail
explain formation of a glyceride
forms when glycerol linked to one or more fatty acids, resuling in formation of an ester linkage
condensation reaction - formation of ester linkage between a hydroxyl group of glycerol and the carboxyl group of fatty acid, one molecule of water lost
types of glyceride
one fatty acid + glycerol - monoglyceride
2 fatty acid + glycerol - diglyceride
3 fatty acid + glycerol - triglyceride (commonly known as fats)
properties of a triglyceride + explain
- melting point of fats increases with hydrocarbon chain length
- longer the hydrocarbon chains -> more extensive the hydrophobic interactions between the chains -> more thermal energy required to break bonds -> higher melting points - melting point of fats decreases as degree of unsaturation of fatty acids tails increases
- kinks where the double bonds are located prevent the molecules from packing closely -> hydrophobic interactions
are less extensive -> less thermal energy required to break enough of these interactions to liquefy triglycerides
what are hydrophobic interactions
weak bond that exists between hydrophobic molecules,
force of attraction between non-polar molecules.
eg of saturated and unsaturated fat
saturated fat -> animal fats, butter, solid at room temp
unsaturated fat -> fat of plant and fish, cooking oil, liquid at room temp
structures and functions of triglyceride in animals (5)
- Structure: lower molecular weight than water per unit volume
function: less dense than water, fats aid buoyancy of aquatic animals - structure: Hydrocarbon tails are non-polar, thus Weak hydrophobic interaction occur between
triglyceride molecules.
Function: triglyceride can slide under pressure, adipose tissue around vital organs cushion and protect them against physical impacts - structure: C-H bonds are non-polar, triglycerides are
hydrophobic. No associated water molecules stored along with triglycerides, and thus triglycerides have no extra weight due to the water of hydration.
function: triglyceride do not affect water potential of cells. absence of water of hydration in triglycerides
fulfils the requirement for an animal’s body mass
to be kept to a minimum to facilitate locomotion.
Triglycerides are a good thermal insulator and
hence a layer of fat beneath the skin (subcutaneous fat) insulates body. (thick in marine animals living in cold
climates, blubber)
- Structure:Triglycerides are highly
reduced molecules.
(two-fold more hydrogen atoms per unit mass than carbohydrates.)
Function: Triglycerides release more water when they are oxidised during cellular respiration compared to carbohydrates.
(This water, known as metabolic water, is
extremely important to desert animals like camels) - Structure: triglyceride have higher proportion of C and H atoms compared to O atoms, greater number of carbon atoms per unit mass than carbohydrates
Function: upon oxidation, triglycerides release larger amount of energy, more efficient energy stores
compound lipid
ester of fatty acid and an alcohol phus other chemical groups (eg phosphate and sugar)
e.g. phospholipid, glycolipid
phospholipid structure
one glycerol, 2 fatty acids, third OH group of glycerol is joined to negatively charged phosphate group, additional small molecules, usually charged or polar can
be linked to the phosphate group
(REF TO NOTES IMAGE)
formation of phospholipid
The two fatty acids are linked to the glycerol by an ester linkage while the phosphate group is linked to the third OH group of the glycerol by a phosphoester linkage
properties of phospholipids
- amphipathic
- The two fatty acids that comprise the hydrocarbon tails are non-polar and hence hydrophobic
- phosphate group and its attachments form a polar / charged hydrophilic head that has an affinity for water - Three types of lipid aggregates can form when amphipathic phospholipids are situated in
aqueous environments, aggregates shield the hydrophobic tails from water/ aqueous environment.
- micelle -> phospholipid monolayer
- bilayer -> two-dimensional sheet, hydrophilic heads are exposed to the polar exterior and hydrophobic tails are in contact
with those of neighbouring molecules, excluded from water in the non-polar interior of the
bilayer
- liposome / vesicle -> formed when lipid bilayer folds back on itself to form a
hollow sphere. bilayer sheets avoid exposing their hydrophobic edge
regions, achieving maximal stability in their
aqueous environment. These bilayer vesicles
enclose aqueous solutions, creating a separate aqueous compartment
Structure and function of phospholipid
- structure: Phospholipids are
amphipathic molecules, each with 2 non-polar, hydrophobic fatty acids ‘tails’ and a charged,
hydrophilic phosphate ‘head’.
Function:
- form a selectively permeable cell membrane, hydrophilic heads are exposed to aqueous medium, hydrophobic tails are in contact
with those of neighbouring molecules but excluded from
aqueous medium in the non-polar interior of the bilayer.
This forms an effective barrier / boundary between cell and
its external environment
- Phospholipids form liposome / vesicle when a lipid bilayer
folds back on itself to form a hollow sphere.
Liposomes are used as vesicles for storage and transport
of cellular products and
digestion of waste (lysosomes).
Liposomes also serve as vesicles for drug delivery in humans.
- Phospholipids form micelles to transport fats between the gut and body tissues. The hydrophilic heads of phospholipids are in contact with the aqueous
environment, and the hydrocarbon tails are restricted to the water-free interior of the micelle
- Structure: Hydrophobic interactions exist between fatty acids tails.
Function: The integrity of the membrane bilayer / liposomes /
vesicles / micelles is maintained due to large number of
interactions.
Individual hydrophobic interactions are weak, permitting lateral movement of phospholipids ->
membrane fluidity
3 Structure: Most phospholipids contain choline.
Function: The most abundant phospholipids in the cell membrane contain choline and represent a large proportion of the body’s store of choline. Choline is important for the
synthesis of acetylcholine, a neurotransmitter.
glycolipids structure
composed of 2 hydrophobic hydrocarbon tails, and.a polar, short carbohydrate chain with no phosphate, glycerol
learn to draw
formation of glycolipid
short carbohydrate chain joined to glycerol’s OH group by glycosidic bond, which is a covalent bond
structure and function of glycolipid
- structure: carbohydrate chain attached to glycerol
Function: Found at the cell surface membrane facing the
exterior environment. It serves as a marker that distinguishes one cell from another in cell-cell recognition as Cells recognise other cells by binding to these carbohydrate chains.
It is also involved in cell-cell adhesion as a result of this binding in tissue formation - structure and property: hydrophobic interactions exist between fatty acid tails
function: hydrophobic interactions anchor entire glycolipids at cell surface membrant
structure of cholesterol
cholesterol possesses a carbon skeleton made up of three fused six-membered and one five-membered ring
function of cholesterol
regulates membrane fluidity, precursor for synthesis of bile acids, steroid hormones such as estrogen and testosterone and vitamin D
