DLA 2

Question 1

What’s partition coefficient?

Answer 1

Measure of the substance’s lipophilicity

-Relates to how well a substance partitions itself between two different immiscible substances like oil (lipid) and water at equilibrium

Question 2

Give an example of partition coefficient in oil and water

Answer 2

A substance added to oil and water will dissolve in each. At equilibrium the chemical potential (free energy) will be the same in both phases. Partition coefficient is determined by measuring the concentration of the substance in the oil and water phases

The ratio is simply the concentration of a substance in oil divided by the concentration of the substances in water

Question 3

How do we calculate partition coefficient?

Answer 3

Concentration of substance in oil/ concentration of substance in water

Question 4

What would be the meaning of different partition coefficient values?

Answer 4

• A partition coefficient of 1: substance would be equally able to exist as a solute in water and in oil
• A high partition coefficient more than 1: substance is lipophilic (soluble in oil) and can pass easily through the membrane (exists mainly in oil)
• A low partition coefficient Les than 1: substance isn’t able to partition itself into the lipid phase (only soluble in water) and therefore cannot easily pass directly through the membrane (exists mainly in water )
• Use log values for aesthetics is coefficient is large/full of zeros

Question 5

What would coefficient of oxygen or carbon dioxide be?

Answer 5

High (above 1) because they pass through the membrane directly

Question 6

What would coefficient of sugars and electrolytes be?

Answer 6

Low (less than 1) because they are polar and interact poorly with the lipid phase of the membrane

Question 7

What is a permeability coefficient?

Answer 7

Degree to which a substance can pass through the membrane (directly through the bilayer or through a channel or transporter)

• a fractional coefficient on a scale of 0 to 1
• 1 means maximum permeability —substance easily crosses the membrane
• 0 means no permeability- substance cannot freely pass through the membrane

Question 8

What is a reflection coefficient?

Answer 8

This is easily a substance can cross the membrane based on its reflection
-If a substance is reflected by the barrier (does not pass through), then it’s reflection coefficient is 1

• if the substance is not reflected by the barrier(passes through) then it’s reflection coefficient is 0–> permeable substances have low (or zero) reflection coefficients

Question 9

What is absorption?

Answer 9

Movement of solutes/fluid from lumen to blood
-Na+ is absorbed across the apical membrane in the cell via the channel epithelial sodium channel (ENaC)—> pumped out of the cell into the basolateral space by the Na-K ATPase—> whole process is regulated by the selective opening and closing of specific channels in the apical membrane

Question 10

What is secretion?

Answer 10

Movement of solutes/fluid from blood into the lumen
-Apical potassium/chloride channels open and allow potassium/chloride to move from from the cell into the lumen of the structure

Question 11

What are at the sides of epithelium?

Answer 11

The cells are joined by tight junctions which delineate the apical and basolateral membranes

• some tight junctions are truly tight—> not allow substances to pass between cells
• Other epithelia are less tight abd termed ‘leaky’ epithelia—> flux of paracellular flow of substances

Question 12

Explain epithelial transport

Answer 12

Solutes must be transported across two membranes in order to reach the blood from the lumen or vice versa

• Apical membrane is in contact with the luminal space
• Basolateral membrane is in contact with the interstitium and blood
• Different transporters and pumps are present on each membrane giving rise to a difference between membranes (polarity)

The vectorial transport of substances- a combination of transporters and pumps on the basolateral and apical membranes

-Major role for epithelial cells is the secretion and/or absorption of solutes and fluid —> achieves secretion or absorption of fluid by transporting solutes and setting up an osmotic gradient that 2ater can flow down

Question 13

What are the classifications of lipids?

Answer 13

1. Simple lipids-triacylglycerol -hydrophobic
2. Complex lipids(contain non-lipid component)-amphipathic
3. Derived lipids- fatty acids, cholesterol

Question 14

What are the types of unsaturated fatty acids?

Answer 14

Monounsaturated (MUFA)

Polyunsaturated fatty acids (PUFA)

Question 15

What are saturated fatty acids?

Answer 15

No double binds

Long chain fatty acids 12-20 C atoms, e.g. palmitic acid, stearic acid

Question 16

Describe saturated fatty acids

Answer 16

• longer chain length, close packing and lower mobility in membranes
• Lipids with saturated fatty acids are solid
• Palmitic acid (16C) and stearic acid (18C)
• longer chain length rich in myelin
• Nutrition pearl: limit dietary saturated fatty acid content for cardiovascular health

Question 17

What are the monounsaturated fatty acids ?

Answer 17

• Oleic acid (18:1)
• Olive oil rich in oleic acid
• Mediterranean diet

Question 18

Describe polyunsaturated fatty acids

Answer 18

More number of double bonds

• more fluidity of membranes
• multiple kinks prevent close parking

Two families

• omega 3: a-linolenic acid: Eicosapentaenoic acid and DHA
• omega-6: linoleic acid and arachnidonic acid

Nutrition pearl:

• more omega-3 and less omega 6 fatty acids
• Lower dietary omega-6: omega 3 fatty acid ratio

Question 19

How does the essential fatty acid, linoleic acid converted to arachodonic acid?

Answer 19

1. Desaturation (addition of a double bonds)

2. Elongation (addition of 2 C atoms)

Question 20

How does alpha linoleic acid(C18:3, omega-3) become docosahexanoic acid?

Answer 20

First becomes eicosapentaenoic acid(C20:5, omega 3)

Then becomes docisahexanoic acid(C22:6, omega- 3)

Question 21

What is the purpose of eicosanoids?

Answer 21

Eicosanods from EPA are cardioprotective

-DHA important for neural/brain development and for vision

Question 22

What are the essential fatty acids?

Answer 22

-Humans cannot add double bind after C-9(starting from carboxyl end)

• Linoleic acid (omega-6) and a-linolenic acid (omega-3) dietary essential fatty acids
  
  • cannot be synthesized
  • must be provided in diet.

-Nutritional deficiency: scaly dermatitis, rough and dry skin, loos of hair

Question 23

What are trans fatty acids?

Answer 23

‘Trans’ conformation; NO kink in structure

-Limited mobility (act like saturated fatty acids)(compare unsaturated fatty acids with ‘cis’ bonds)

• Nutrition Pearl: NO ‘trans’ fatty acids
  
  • increase LDL cholesterol and risk of heart disease

Partially (artificially) hydrogenated lipids like margarine, fried foods, baked goods…

Question 24

Describe cholesterol

Answer 24

27-C atom

-Cyclopentanoperhydrophenanthrene (steroid ) ring

• Amphipathic ring
  
  • hydrophilic hydroxyl group
  • hydrophobic group

Regulation of membrane fluidity

Question 25

What are the functions of cholesterol?

Answer 25

-Cell/plasma membrane (both leaflets)

• Precursor of bile acid/bile salt synthesis in liver
  
  • efficient intestinal digestion and absorption of dietary lipids
• Precursor of steroid hormones
  
  • Cortisol and aldosterone in adrenal cortex
  • Sex steroids: estrogen and progesterone in ovaries; testosterone in Testes

Precursor for synthesis of vitamin D in skin

Question 26

How much of the diet are TAGs ?

Answer 26

About 90%-95% of dietitian lipids are TAGs

• fats(butter)
• oils

Question 27

What are the functions of TAGs?

Answer 27

Storage form of energy in adipose tissue

• hydrophobic
• 70kg adult stores 15kg as adipose TAG (fat)
• Sources if energy during fasting

Not components of membrane

Question 28

Summarize the saturated fatty acids(palmitic acid (C16) and stearic acid(C18)) functions

Answer 28

Components if TAG, phospholipids and glycolipids (decrease membrane fluidity)

Question 29

Summarize monounsaturated fatty acid functions (oleic acids C18)

Answer 29

Components if TAG, phospholipids and glycolipids

Question 30

Summarize the polyunsaturated fatty acids functions(omega-3 and omega-6 fatty acids)

Answer 30

Components of TAG, phospholipids and glycolipids (increase membrane fluidity )

Question 31

Summarize the functions of omega-3 fatty acids (alpha-linoleic acid, eicosapentansrnoic acid, docosahexaenoic acid)

Answer 31

Function: components of TAG, phospholipids and glycolipids (increase membrane fluidity

Question 32

Summarize the function of omega 6 fatty acids (linoleic acid, arachadonic acid)

Answer 32

Components of TAG, phosohlipids abd glycolipids (increase membrane fluidity)

Question 33

What are the functions of the essential fatty acids (alpha-linolenjc acid, linoleic acid)?

Answer 33

Components of TAG, phospholipids and glycolipids (increase membrane fluidity)

Question 34

Summarize the functions of cholesterol

Answer 34

Cell membrane (both leaflets), precursor of steroid hormones, Vit D and bile acids

Question 35

What are the complex lipids?

Answer 35

Based on non-lipid component(phospholipids and glycolipids)

Phospholipids- glycerophospholipids and sphingophospholipid

Glycolipid- cerebrosides, sulfatides, globosides, ganglioside

Question 36

Complex lipids are

Answer 36

Amphipathic

Question 37

Contrast saturated and unsaturated fatty acids

Answer 37

Unsaturated fatty acid susceptible to free radical damage (reactive oxygen species)

Question 38

What is phosphatidic acid ?

Answer 38

Bonding between hydroxyl of phosphate group with hydroxyl of glycerol carbon 3 results in phosphatidic acid. Phosphatidic acid is building block of phospholipids found in found in cell membrane.

Phosphatidic acid is NOT found in cell membranes

Question 39

W(at combines to make phospholipids?

Answer 39

Phosphate group, diacylglycerol —> phospholipid with phosphatidic acid

Question 40

Give examples ofglycerophospholipids

Answer 40

Phosphatidylserine

Phosphatidylcholine

Phosphatidylethanolamine

Phosphatidylinositol

Question 41

What is the function of cardiolipin?

Answer 41

• Only in inner mitochondrial membrane

- Anticardiolipin antibodies: autoimmune disorders(SLE)

Question 42

Summarize the asymmetry of phospholipid distribution

Answer 42

ECM= phosphatidylcholine = PC +sphingomyelin=

ICM= phosphatidylserine= PS, phosphatidylethanolamine = PE, phosphatidylinositol= PI

Question 43

What is phosphatidylcholine?

Answer 43

Aka lecithin:most abundant

• in both leaflets of membrane layer
• more abundant in outer leaflet

Question 44

What are the functions of phosphatidylethanolamine and phosphatidylserine(apoptosis)

Answer 44

-inner leaflet of phospholipids bilayer (cytosolic side)

Question 45

Where are phosphatidylinositol and phosphatidylinositol and biphosphate (PIP2)?

Answer 45

• inner leaflet of bilayer

- second messengers: inositol triphosphate (IP3) and diacylglycerol (DAG)

Question 46

What are the functions of Dipalmitoylphosphatidylcholine (DPPC)?

Answer 46

Lung surfactant

• decreases surface tension of alveolar fluid
  
  • prevents alveolar collapse
• Respiratory distress syndrome: collapse of alveoli
  
  • premature infants
  • chronic smokers (smoking destroys type II cells)
• Amniotic fluid Lecithin-Sphingomyelin ratio(L/S ratio)
• L/S ratio> 2: mature fetal lung and low risk of RDS
• L/S ratio <1.5: immature fetal lung
• Artificial surfactant fluids with DPPC/Maternal steroid injections

Question 47

What group of lipids does DPPC belong to?

Answer 47

Glycerophospholipid

Question 48

Describe sphingophospholipid (sphingomyelin)

Answer 48

Sphingosine (C-18)

Sphingosine with fatty acid forms ‘ceramide’

Sphingosine with fatty acid-phosphatase-choline

Myelin sheath around neurons

Question 49

Describe glycolipids

Answer 49

• Amphipathic
• Sphingosine and fatty acid: non polar
• Carbohydrate: polar head group
• outer leaflet of plasma/cell membrane
• glycocalyx with glycoproteins on outer leaflet of cell membrane
• function as receptors
• myelin sheath of nerves

Question 50

What is the composition of cerebrosides?

Answer 50

Sphingosine+ fatty acid + monosaccharide

Question 51

What is the composition of sulfatide?

Answer 51

Sphingosine+ fatty acid+ monosaccharide + saulfate

Question 52

What is the composition of globoside?

Answer 52

Sphingosine+ fatty acid + oligosaccharide

Question 53

What is the composition of a ganglioside?

Answer 53

Sphingosine + fatty acid+ oligosaccharide (with NANA) Tay-Sachs disease

Question 54

What are the functions of cerebrosides, sulfatode, globoside, and ganglioside?

Answer 54

Outer leaflet of plasma (cell) forms glycocalyx

Question 55

All mammalian cells have a …

Answer 55

Plasma membrane formed by a phospholipid bilayer containing embedded proteins

The plasma membrane has been described as a fluid mosaic of lipids and protein molecules because of their movement laterally

Question 56

Summarize the fluid mosaic model

Answer 56

The modified fluid mosaic model describes very small membrane patches or “lipid rafts” with dynamic assembles of unique protein and lipid composition which separates them from other fluid membrane areas

Question 57

Differentiate the types of lipid rafts

Answer 57

Short lived: “planar lipid rafts” rich in:
-Cholesterol

• Glycosphingolipids
• Sphingomyelin

Long-lived: Caveolae are lipid rafts forming an invagination of the plasma membrane stabilized by specific proteins (caveolins)

Lipid rafts can facilitate signal transduction and a virus infection

Question 58

What is the lipid composition of the outer leaflet of the membrane?

Answer 58

Contains mainly, phosphatidyl choline and sphingomyelin. Glycosphingolipids and less amounts of phosphatidylethanolamine

Question 59

What is the lipid composition of the inner leaflet of the cell membrane?

Answer 59

Contains mainly phosphatidylethanolamine. Phosphatidylserine, phosphatidylinositol and PIP2 and less of phosphatidylcholine

Question 60

Where are glycolipids and glycoproteins usually found? What are

Answer 60

In the outer layer and form a glycocalyx