Lecture 12

Question 1

are lipids water soluble?

Answer 1

no because of the increase in hydrocarbons

they do not form covalent polymers –> there are noncovalent interactions

Question 2

structure of lipids

Answer 2

polar, hydrophilic head
&
larger, nonpolor hydrophobic tail

tail driven by entropy effect
2nd stabilizing force: van der waals @ HC

Question 3

amphiapatic

Answer 3

causes formation of micelles and membrane bilayers.

Question 4

fatty acids

Answer 4

carboxylic acid with a long HC chain– usually 12-24 carbons

• weak acid with pka of ~4.5

Question 5

saturated

Answer 5

all carbons saturated with hydrogens (no double bonds)

Question 6

unsaturated

Answer 6

1+ double bonds, naturally occurring, (cis)

as bonds insert and bend into HC, still have freedom of rotation–> many conformations

there are even # of C’s b/c of 2C precursor

Question 7

monolayers in air

Answer 7

water interface with carboxylate group immersed in water and HC tail out of water

Question 8

micelles

Answer 8

if shaken with water, HC tail cluster together

Question 9

Triacylglycerols: Fats

Answer 9

long HC= ^ energy storage b/c carbon is in reduced form so it yields a large amount of energy on oxidation.

this is why it’s used for storage of metabolic energy.

Question 10

Triacylglycerols structure

Answer 10

triester of fatty acids and glycerols; major long term energy storage molecules in many organisms.

Question 11

simple fats

Answer 11

same fatty acid esterified, mixed= more common

fats rich in unsat EA = liquid at room temp

Question 12

fat storage functions

Answer 12

E production: most fat in animals is oxidized for the generation og ATP, to drive metabolic processes

heat prod: some specialized cells oxidized triglycs for heat prod rather than to make ATP

insulation: layers of fat cells under the skin serve as thermal insulation

Question 13

membrane lipids

Answer 13

amphipathic- form surface monolayers, bilayers or vesicles when in contact with h2o

Question 14

Boundary – defines cells and organelles

Answer 14

But - must be selectively permeable & allow for transmission of molecules and information

Question 15

Membranes can be used to store and utilize energy

Answer 15

Must maintain concentration gradients
(eg. H+, Na+, K+, Ca+2, small molecules)
(used for transport and signaling)

Question 16

membrane must be

Answer 16

flexible- adopt various shapes and be self sealing

• Must accommodate proteins of various types and shapes
• Must allow for diffusion (both Lipids and Proteins)
• Must allow for vesicle formation and membrane fusion

• Must be adaptable to varying cellular conditions and functions

Question 17

Glycerophospholipids :

Answer 17

Important building blocks of biological membranes

Question 18

ion gradient

Answer 18

way to store energy

• transport molecules
• signaling

Question 19

Fatty Acids:

Answer 19

Important building blocks of glycerophospholipids and many other lipids like sphingolipids, and fats

Question 20

Fatty Acids- four key biological roles

Answer 20

1. Essential components of biological
   membranes

2.Post-translational modifications –
localization of proteins to membranes

3.Intra- and Inter-cellular signaling molecules

4.Energy storage: Main component of
Fats

Question 21

Fatty Acids - starting point for understanding Cellular Membranes and Lipid Metabolism

Answer 21

Carboxylic Acids with long hydrocarbon chains

Most commonly have 12-24 carbons

Typically linear

Can have one or more double bonds

(cis-double bonds: 30° kink in the hydrocarbon chain)

Question 22

n-Octadecanoate

Answer 22

18:0

Question 23

Oleate cis-9-Octadecanoate

Answer 23

18:1(Δ9)

Question 24

9,12,15- Octadecanoate

Linolenate

Answer 24

18:3(Δ9,12,15)
18:3 n-3
ω3 fatty acid

Double bonds in Fatty Acids are not conjugated

Question 25

Laurate

Answer 25

12:0 44.2

Question 26

Myristate

Answer 26

14:0 53.9

Question 27

Palimitate

Answer 27

16:0 63.1

Question 28

Stearate

Answer 28

18:0 69.6

Question 29

Arachidate

Answer 29

20:0 76.5

Question 30

Palmitoleate

Answer 30

16:1Δ9 -0.5

Question 31

Oleate

Answer 31

18:1Δ9 16.0

Question 32

Linoleneate

Answer 32

18:3Δ9,12,15 -11.0

Question 33

Arachidonate

Answer 33

20:4Δ5,8,11,14 -50.0

Question 34

diff between 18 carbon fatty acids

stearate
oleate
elaidate

Answer 34

stearate 18:0 69.6°C
oleate 18:1Δ9 12.0 °C
elaidate 18:1Δ9 45.0 °C

(oleate= cis, elaidate= trans)

Note: Elaidate is the major trans fat found in hydrogenated vegetable oils. Some is found naturally in cow milk.

Question 35

Lipid

Answer 35

A Lipid is: “any of various substances that are soluble in nonpolar organic solvents (such as chloroform and ether), that are usually insoluble in water, that with proteins and carbohydrates constitute the principal structural components of living cells”

Question 36

Triacylglycerols (Fats or Triglycerides)

Answer 36

Stored in Lipid Droplets in Adipocytes (below) and other cell types

Fats are very hydrophobic

Fats pack closely together excluding water

Efficient form of stored energy.

Question 37

Membrane Lipids – Cardiolipins

Answer 37

• Cardiolipin - “double” phospholipid that has four fatty acid tails
• Important component of the inner mitochondrial membrane. Constitutes about 20% of the total lipid.
• Serves as an insulator and stabilizes the activity of protein complexes important to the electron transport chain

Question 38

Ceramides

Answer 38

the parent compounds of more abundant sphingolipids

Question 39

Sphingomyelins

Answer 39

Conformationally similar to phosphoglycerides.

Found in Myelin sheath that surrounds neuronal cells

Question 40

Cerebrosides

Answer 40

Head group is a single

sugar (non-ionic)

Question 41

Gangliosides

Answer 41

Complex oligosaccharide head group with at least one sialic acid

Question 42

Complex carbohydrate head group:

Answer 42

• Can specifically bind proteins
• Certain pituitary hormones
• Attachment site for Cholera Toxin
• Cell-cell recognition
• Growth and Differentiation

• Altered metabolism can lead to severe neurological disorders
• Tay-Sachs disease
• Defect in a lysosomal
enzyme needed to degrade Gangliosides

Question 43

Membrane Lipids - Cholesterol

Answer 43

Steroids have four fused, non-planar rings
(Sterols are a subgroup of steroid alcohols)

Parent compound to other steroids

Question 44

Lipids self-associate into larger complexes in aqueous solutions

Answer 44

Lipid self-association is driven by the Hydrophobic Effect

• Minimize contact of hydrocarbon chains with water
– maximize entropy (ΔS) (ΔG=ΔH-TΔS)
• Favorable van der Waals Interactions

Amphipathic Lipids like Glycerophospholipids & Sphingolipids

• Hydrophilic head group is highly hydrated
• Spontaneously form a bilayer
• No exposed edges – self-sealing
• Self-assembly is a highly cooperative process

Question 45

Amphipathic properties of phospholipids

promote self-assembly of lipid bilayers

Answer 45

Shape matters – Phosphoglycerides spontaneously form bilayers.
Single Fatty-Acyl chains, like detergents, tend to form micelles.

What would you expect from the self-assembly of fats in aqueous solutions?

Question 46

Amphipathic properties of phospholipids promote self-assembly of lipid bilayers

Answer 46

Shape matters – Phosphoglycerides spontaneously form bilayers.

Single Fatty-Acyl chains, like detergents, tend to form micelles.

Question 47

Biological Membranes

The Fluid Mosaic Model of membrane organization

Answer 47

• The Lipid Bilayer – a thin two-dimensional fluid
• Membrane is assembled by non-covalent interactions
• Membrane is Asymmetric
• Lipids, Peripheral and Integral Proteins, Glycosylation

Question 48

Summary

Answer 48

• Structures, nomenclature, and properties of fatty acids
• Fatty acids are an important component of many biological lipids
• Properties of many lipids are determined by their component fatty acids

• Types of Membrane Lipids
• Triacylglycerols (fats) - energy storage
• Glycerophospholipids, sphigolipids, sterols –
Membrane lipids (amphipathic molecules)

• Self-Assembly into larger structures
• Globules, micelles, bilayers