Lipid membrane

Question 1

Example and location of integral proteins

Answer 1

Integral proteins are within the bilayer e.g. GPCRs
Polyprotic- both sides
Monoprotic- one side
Integral membrane proteins are very firmly associated with the lipid bilayer and are removable only by agents that interfere with hydrophobic interactions, such as detergents, organic solvents, or denaturants

Question 2

How and why can integral proteins be removed from the membrane?

Answer 2

Integral membrane proteins are very firmly associated with the lipid bilayer and are removable only by agents that interfere with hydrophobic interactions (cause a change in pH), such as detergents, chelating agents organic solvents, or denaturants
Hydrophobic domain become coated with the detergent

Question 3

Where are amphiprotic proteins found? How are they attached?

Answer 3

Amphitropic proteins are found both in the cytosol and in association with membranes.
Their affinity for membranes results in some cases from the protein’s noncovalent interaction with a membrane protein or lipid, and in other cases from the presence of one or more lipids covalently attached to the amphitropic protein

Question 4

How are amphiprotic proteins detached from the membrane?

Answer 4

Need enzymes (phospholipase C) or post-translational covalent modifications (phosphorylation) to be cleaved off and taken away from the membrane

Question 5

Which type of membrane protein (amphitropic or integral protein) would be involved in cell signalling?

Answer 5

amphitropic as it can go into cytoplasm

Question 6

Inner and outer layer are different/ the same

Answer 6

Different

Question 7

Components that are involved in cell signaling such as PIP2, have a higher concentration on the inside/outside of the lipid bilayer

Answer 7

Inside

Question 8

Phosphatidylserine is always maintained __ at __ concentration

Answer 8

Phosphatidylserine is always maintained inside at high concentration

Question 9

What happens when Phosphatidylserine moves from inside to outside?

Answer 9

When is it moved to outer bilayer, the cells are targeted for apoptosis - marks the cell for phagocytosis by white blood cells
Also is involved in blood clotting

Question 10

Which groups affect bilayer flexibility?

Answer 10

Acil

Question 11

Ordered membrane state is more __ compared to disordered

Answer 11

Ordered membrane state is more solid compared to disordered

Question 12

What are the factors affecting membrane flexibility?

Answer 12

Temperature (20-40C)
Saturation of FA chain
Uniformity of FA chains
Sterol content

Question 13

How does saturation of FA chain affect order

Answer 13

Saturation of FA chain increases order

Question 14

How does uniformity of FA chain affect order

Answer 14

Uniformity increases order

Question 15

How does Sterol content affect order

Answer 15

Sterol content affects fluidity both ways- Think of them as of ball that can induce gaps (disordered-> more mobile and liquid) or fill them up (ordered-> more solid)

Question 16

Cell mobility and division requires __ membrane mobility

Answer 16

Cell mobility and division requires higher membrane mobility

Question 17

Structural cells such as muscle cells require __ membrane mobility

Answer 17

Structural cells such as muscle cells require lower membrane mobility

Question 18

Describe Floppase

Answer 18

ABC transporter- moves phospholipids from inside out

Question 19

Describe flippase

Answer 19

P-type ATPase

Moves PE and PS from outer to cytosolic (inner) leaflet

Question 20

Membrane proteins are usually freeley mobile. Describe the cases when they aren’t

Answer 20

Proteins can be held in place when they are attached to other proteins
Integral proteins attached to cytoskeletal proteins are non-mobile

Question 21

Lipid rafts contain clusters of __ and specific __. They are more __

Answer 21

Lipid rafts contain clusters of glycosphingolipids and specific doubly or triply acylated proteins They are more ordered

Question 22

What kind of a domain is a lipid raft?

Answer 22

Microdomain

Question 23

Which effect do lipid rafts have on surrounding area?

Answer 23

Whatever is within that region is less mobile, the structure as a whole though is fully mobile

Question 24

Lipid rafts contain si__ that are attached to __ within that area

Answer 24

Lipid rafts contain signaling proteins that are attached to membrane within that area

Question 25

What are lipid rafts enriched in?

Answer 25

In sphingolipids and cholesterol

Question 26

What does fusion of 2 membrane require? (6)

Answer 26

Triggering signal
Recognition of each other
Close apposition 
Local disruption of bilayer before fusion
Hemi- fusion
Fusion proteins

Question 27

What’s hemi fusion

Answer 27

The outer membrane of one component to inner membrane of other component if the two components are within each other
If the two components ae separate from each other ,the outer components fuse first

Question 28

What are the situations when membrane fusion is required?

Answer 28

Budding of vesicles from Golgi complex
Exocytosis 
Endocytosis
Fusion of endosome and lysosome
Viral infection
Fusion of sperm and egg
FUsion of small vacuoles
Separation of two plasma membranes at cell division

Question 29

What do fusion proteins do

Answer 29

the process is triggered at the appropriate time or in response to a specific signal. Integral proteins called fusion proteins mediate these events, bringing about specific recognition and a temporary local distortion of the bilayer structure that favors membrane fusion.

Question 30

What are the 3 types of proteins involved in membrane fusion at synapse?

Answer 30

3 types of snare proteins: T-SNARE, V-SNARE, Q-SNARE

Question 31

What does T-SNARE do? Where does it assemble

Answer 31

T-SNARE (target-snare) helps in recognition of the target membrane
Assembles on the target membrane

Question 32

What does V-SNARE do? Where does it assemble

Answer 32

V-SNARE marks the vesicle that needs to be emptied out

Assembles on the vesicle membrane

Question 33

In which process are SNARE proteins involved?

Answer 33

All neurons store their neurotransmitters in vesicles
Vesicle bilayer has to be integrated into neuronal cytoplasmic bilayer so that it opens up and empties vesicle’s contents
SNARE proteins are involved

Question 34

Describe Q-SNARE. What does it do

Answer 34

Q-SNARE (e.g., SNAP-25) are
regulatory proteins that are
Ca2+ induced.
Help V and T SNARE to come together

Question 35

What’s NSF?

Answer 35

NSF (N-ethylmaleimide sensitive

fusion factor) proteins disassemble the SNARE complex

Question 36

Describe the process of vesicle emptying with SNARE proteins - neurotransmitter vesicle and neuron membrane

Answer 36

1. Neurotransmitter-filled vesicle approaches plasma membrane.
2. When a local increase in [Ca2+] signals release of neurotransmitter, the v-SNARE (on a vesicle), SNAP25 (on plasma membrane) , and t-SNARE (on plasma membrane )interact, forming a coiled bundle of four helices, pulling the two membranes together and disrupting the bilayer locally.
   v-SNARE and t-SNARE bind to each other, zipping up from the amino termini and drawing the two membranes together.
   Zipping causes curvature and lateral tension on bilayers, favoring hemi-fusion between outer leaflets.
3. Hemi-fusion: outer leaflets of both membranes come into contact.
4. Complete fusion creates a fusion pore.
   Pore widens; vesicle contents are released outside cell.

Question 37

What happens to SNARE proteins after the vesicle was emptied out

Answer 37

Snare proteins are degraded and recycled

Question 38

Which compounds can be transported by simple diffusion?

Answer 38

Nonpolar compounds only

Question 39

Describe secondary active transport

Answer 39

Against electrochemical gradient, driven by ion moving down its gradient
No ATP involved

Question 40

Describe ionophores

Answer 40

Ionophores are lipid-soluble molecules that bind specific ions and carry them passively across membranes, dissipating the energy of electrochemical ion gradients.
Down electrochemical gradient

Question 41

Are GLUT transporters active or passive?

Answer 41

passive

Question 42

What is GLUT4 is sensitive to ?

Answer 42

GLUT4 is sensitive to insulin signaling

Question 43

What is the purpose of passive transporters?

Answer 43

Transporter enhances the rate of the transport

Question 44

GLUT1
Tissue where expressed
Role

Answer 44

Expressed in Erythrocytes and most tissues at a low level

Role: Basal glucose uptake

Question 45

GLUT2
Tissue where expressed
Role

Answer 45

Expressed: Liver, pancreatic islets, intestine, kidney
Role: In liver and kidney,

Question 46

GLUT4
Tissue where expressed
Role

Answer 46

Expressed: Muscle, fat, heart
Role: Activity increased by insulin

Question 47

Steps of insulin control of GLUT4

Answer 47

1. Glucose transporters “stored” within cell in membrane vesicles.
2. When insulin interacts with RTK, vesicles move to surface and fuse with the plasma membrane, increasing the number of glucose transporters in the plasma membrane.
3. When insulin level drops, glucose transporters are removed from the plasma membrane by endocytosis, forming small vesicles.
4. The smaller vesicles fuse with larger endosome.
5. Patches of the endosome enriched with glucose transporters bud of to become small vesicles, ready to return to the surface when insulin levels rise again.

Question 48

What is the the consequence of lack of signal transduction by insulin signaling

Answer 48

Diabetes mellitus

Question 49

Describe CO2 transport by RBC

Answer 49

CO2 concentration is high outside RBC
CO2 easily enters erythrocyte, where it is converted to bicarbonate (HCO3- ) by the enzyme carbonic anhydrase.
Now there’s a high concentration of HCO3- in RBC which is excreted into blood plasma and then travels to the lungs. There, HCO3- concentration is high and it reenters the erythrocyte. When Bicarbonate concentration in the RBC is high, an enzyme converts it to CO2 which can be excreted into the lung space and exhaled.

Question 50

What does carbonic anhydrase do

Answer 50

Converts CO2 to bicarbonate (HCO3- ) in RBC

Question 51

How is the movement of HCO2- across the erythrocyte

membrane is made more effective?

Answer 51

The chloride-bicarbonate exchanger, also called the anion exchange (AE) protein, increases the rate of HCO3- transport across the erythrocyte membrane.
It’s an antiporter- moves HCO3- and Cl- with no net transfer of charge; the exchange is electroneutral.

Question 52

What is a chloride-bicarbonate exchanger

Answer 52

The chloride-bicarbonate exchanger, also
called the anion exchange (AE) protein is an integral protein and aintipoter that mediates the simultaneous movement of HCO3- and Cl-

Question 53

What happens when Cl- is absent?

Answer 53

In the absence of chloride, bicarbonate transport stops.

Question 54

What’s primary active transport?

Answer 54

solute is transported to the transporter and is moved against the gradient by using ATP
solute accumulation is coupled directly to an exergonic chemical reaction, such as conversion of ATP to ADP

Question 55

What’s secondary active transport?

Answer 55

a gradient of ion X (S1) (often Na) has been established by primary active transport. Movement of X (S1) down its electrochemical gradient now provides the energy to drive cotransport of a second solute (S2) against its electrochemical gradient
active transport occurs when endergonic (uphill) transport of one solute is coupled to the exergonic (downhill) flow of a different solute that was originally pumped uphill by primary active transport

Question 56

Describe a symport system that is important in digestion

Secondary or primary?

Answer 56

Na+:Glucose and Na+:amino acid in intestinal epithelium- occurs when food is eaten
Secondary

Question 57

Describe an antiport system that is important in water balance
Secondary or primary?

Answer 57

Na+:K+-ATPase; Na+:H+ pumps in kidney

Secondary

Question 58

Describe transport through F-type ATPase

Answer 58

Found in mitochondria

Can do both ATP synthesis and hydrolysis

Question 59

What can serves as solutes for ABC transporters?

Answer 59

amino acids, peptides, proteins, metal ions, lipids, bile salts and drugs

Question 60

Cassette is another name for __

Answer 60

Cassette is another name for domain

Question 61

Explain ABC transporters

Answer 61

When ATP is bound to the cassette, the transporter is opened outward, when ADP- inward, when the molecule comes there is a change in conformation, because of ATP\ADP

Question 62

Difference between RBC and stem cells

Answer 62

Stems cells proliferate-
RBCs don’t

Stems cells have nuclei, mitochondria; RBCs don’t

Mitochondria are needed for ATP production
RBCs use glycolysis to make ATP-> can’t survive without glucose

Question 63

Energy sources of cardiac myocytes, RBC and neurones

Answer 63

Neurons and RBC depend more on glucose

Cardiac myocytes depend more on fatty acids

Question 64

What do you need for any regulatory mechanism to take place? WHat does it generally lead to?

Answer 64

You need a signal which will result in a response

This signal generally lead to a change in gene expression

Question 65

How are TF generally regulated?

Answer 65

by phosphorylation or dephosphorylation; by TF interactions

Question 66

What are the methods of regulation enzymatic levels (6)

Answer 66

1. Extracellular signal
2. Transcriptional regulation –
   a. TF phosphorylation/ dephosphorylation
   b. TF interactions
3. mRNA stability
4. mRNA translation
5. Protein stability (half-life)
   e. g. Cyclins
6. Enzyme localization e.g. Mitorchondrial enzymes

Question 67

How mRNA stability can affect enzymatic levels?

Answer 67

the length of time mRNA is maintained inside the cells (the longer mRNA is maintained inside the cell ,the more protein is produced)

Question 68

Cyclins as an example of cell degradation

Answer 68

Cyclins - enzymes involved in cell division- degraded immediately after completion of division - targeted through ubiquitination

Question 69

Pathways in opposite directions are favored/ not favored simultaneously

Answer 69

not favored

Question 70

Common regulatory mechanisms at organism level (5)

Answer 70

ü Pathways in opposite directions are not favored simultaneously
ü Maximizes product utilization (e.g Glycolysis and Gluconeogenesis)
ü Ability to partition metabolites between alternate pathway- e.g. Glycolysis or pentose-phosphate pathway
ü Draw on fuel best suited for the need
ü Slow down synthetic pathways when products accumulate

Question 71

What is GPI?

Answer 71

Glycosylphosphatidyllinositol

Question 72

An example of GPI linked protein

Answer 72

Phosphatases