Structures of membrane proteins.

Question 1

What is the speed of ATP powered pumps?

Answer 1

10^0 to 10^3 ions per second.

Question 2

What is the speed of ion channels?

Answer 2

10^7 to 10^8 ions per second.

Question 3

What is the main feature of a uniporter?

Answer 3

Moves substance with concentration gradient.

Question 4

What is the main feature of a symporter?

Answer 4

Moves 1 substance against the concentration gradient and 1 with it. Move in the same direction

Question 5

What is the main feature of a antiporter?

Answer 5

Moves 1 substance against the concentration gradient and 1 with it. Move in opposite directions.

Question 6

What proved that aquaporins moved water into the cell?

Answer 6

When a frog lays a oocyte in freshwater the cell does not burst. When mRNA for aquaporins are placed into the cell the cell bursts.

Question 7

What is in each subunit of an aquaporin?

Answer 7

6 transmembrane helices and 2 short helices per subunit.

Question 8

What is the order of short and long subunits in the aquaporin?

Answer 8

Long, long, short, long.

Question 9

How many subunits make up a aquaporin?

Answer 9

8.

Question 10

How many pores are found in an aquaporin?

Answer 10

4. Each subunit has a pore.

Question 11

How is it possible for the short helices in the aquaporin to span the membrane?

Answer 11

Each one of the short helices goes into one of the membranes and together they can span the membrane.

Question 12

What parts of the aquaporin are hydrophilic?

Answer 12

The top and the bottom.

Question 13

How large is the aquaporin pore?

Answer 13

2.8A.

Question 14

What is the aquaporin too small for?

Answer 14

H3O+.

Question 15

What two highly conserved residues form the gate of the aquaporin?

Answer 15

Arg195 and His180. Both are these are positive so repel H3O+ residues.

Question 16

What makes the transport of water through the aquaporin very fast?

Answer 16

The pore is lined with hydrophobic residues.

Question 17

Explain why no protons are co translated in the aquaporin.

Answer 17

The proton wire is distributed by two Asn residues acting as proton donors.

Question 18

When a proton wire is in place in the aquaporin what are all water molecules acting as?

Answer 18

Proton donors and acceptors.

Question 19

What two processes allowed the determination of the Asn residues in the aquaporin?

Answer 19

X ray crystallography and electron microscopy.

Question 20

What is the electrochemical potential gradient made up of?

Answer 20

Concentration and electron gradient.

Question 21

What sets up the electron gradient?

Answer 21

K+ channel.

Question 22

What sets up the chemical gradient?

Answer 22

K+/Na+ pump.

Question 23

What does the Na+/lysine symporter do?

Answer 23

Pumps lysine up hill using the Na+ gradient.

Question 24

What three things make up the single subunits in the potassium ion channels?

Answer 24

5s helix outside, 56 helix inside, P loop.

Question 25

What two things make up the P loop in the single subunits in the potassium ion channel?

Answer 25

P segment and the selectivity filter.

Question 26

What part of the of the potassium ion channel subunit is partially embedded in the membrane?

Answer 26

The P loop.

Question 27

How many subunits make up the potassium ion channel?

Answer 27

4.

Question 28

There are four subunits in the potassium ion channel. How many pores does this result in?

Answer 28

1.

Question 29

What part of the K channel is homologous in all K channels?

Answer 29

P segment.

Question 30

What is the role of the p segment in the K channel?

Answer 30

Imparts selectivity.

Question 31

What does a mutation in the P loop of the K+ channel result in?

Answer 31

Loss of selectivity.

Question 32

If the P segment in the bacterial P loop is mutated can not be replaced by a mammalian P segment. True or false?

Answer 32

False.

Question 33

What is the transport rate of the K+ channel?

Answer 33

10^8 ions per second.

Question 34

What is the empty space in the middle of the K+ channel called?

Answer 34

Vestibule.

Question 35

What is the diameter of the vestibule in the K+ channel?

Answer 35

10A.

Question 36

What is the diameter of the P loop/selectivity channel in the K+ channel?

Answer 36

3A.

Question 37

What part of the K+ channel is hydrophobic?

Answer 37

Selectivity channel.

Question 38

What part of the K+ channel is hydrophilic?

Answer 38

Vestibule.

Question 39

Na+ is smaller than K+ but the K+ channel can still distinguish between the two. How?

Answer 39

Both ions are found in the solvated forms. Ka+ coordinates to 8 water molecules and Na+ coordinates to 6. Both of these need to be stripped. This normally costs energy but due to the arrangement of the carbonyl main chains in the selectivity factor this energy can be regained by the formation of 8 bonds, meaning it is only energetically favourable for Ka+ to enter the channel.

Question 40

Is the desolvation of Na+ or K+ greater?

Answer 40

Na+.

Question 41

What is the desolvation energy of Na+?

Answer 41

-301.

Question 42

What is the desolvation energy of K+?

Answer 42

-230.

Question 43

How many binding sites are there for K+ in the K+ channel?

Answer 43

4.

Question 44

Energy increases in the binding sites in the K+ channel as you go down the channel. True or false?

Answer 44

False, they is only a small energy difference between the sites.

Question 45

When travelling through the K+ channel/ selectivity filter K+ions fill the binding sites in turn. True or false?

Answer 45

False. They alternate between 1 and 3 and 2 and 4.

Question 46

What drives K+ through the K+ channel/ selectivity filter?

Answer 46

Electrostatic repulsion of ions.

Question 47

Movement through the K+ channel/ selectivity filter can been two states (1 and 2) What are these?

Answer 47

State 1: 1 ,3

State 2: 2, 4

Question 48

What face are the N and C terminals on in the K+ ion channel?

Answer 48

Cytosol.

Question 49

What joins the two transmembrane helices in the K+ channel?

Answer 49

The P loop.

Question 50

What minimises the distance that the K+ has to move through the hydrophobic membrane?

Answer 50

The large vestibule.

Question 51

The inside of compartmentalised organelles is classed as the outside. True or false?

Answer 51

True.

Question 52

What are the key features of a type 1 membrane protein?

Answer 52

COO- in and NH3+ out. NH3+ contains a signal sequence.

Question 53

What are the key features of a type 2 membrane protein?

Answer 53

NH3+ in and COO- out.

Question 54

What are the key features of a type 3 membrane protein?

Answer 54

COO- in and NH3+ out. NO signal sequence.

Question 55

What are the key features of a type 4 membrane protein?

Answer 55

Multipath

Question 56

What are the key features of a GPI membrane protein?

Answer 56

NH3+ out, no cytosol domain.

Question 57

What can the stop anchor sequence be describe as?

Answer 57

Hydrophobic.

Question 58

What terminus of a protein is made first?

Answer 58

N terminus.

Question 59

What happens when the stop anchor sequence is reached?

Answer 59

The translocation channel opens and allows it to enter the membrane.

Question 60

What is an example of a type 1 membrane protein?

Answer 60

LDL receptors.

Question 61

What is an example of a type 2 membrane protein?

Answer 61

Transferrin receptors.

Question 62

What is an example of a type 3 membrane protein?

Answer 62

Cytochrome P450.

Question 63

What is an example of a type 4 membrane protein?

Answer 63

G-protein coupled receptors.

Question 64

What is an example of a type 5 membrane protein?

Answer 64

Plasminogen activation receptors.

Question 65

What two amino acid residues are found in a type two signal pass outside the membrane?

Answer 65

Positive/ basic lysine and arginine residues.

Question 66

What three things can you do during analysis the sequence of the membrane protein?

Answer 66

1. Try to predict the membrane spanning helices from the hydropathy plot.
2. Look for positive residues either side of the membrane ‘ positive inside rule’.
3. Predict N terminal signal sequence.

Question 67

What residues is the signal sequence made from?

Answer 67

Run of hydrophobic residues flanked by positive residue.s

Question 68

The signal sequence is not long enough for it to be a transmembrane helix. How long is it?

Answer 68

10-18 residues.

Question 69

What is the difference between a STA and a SA?

Answer 69

A STA is a internal stop-transfer anchor sequence and aa SA is a internal signal anchor sequence.

Question 70

What key points did sequence analysis show about type one proteins? (3)

Answer 70

1. Signal sequence.
2. One STA.
3. NH3+ lumen.

Question 71

What key points did sequence analysis show about type two proteins? (3)

Answer 71

1. Positive charge in cytosol next to the SA.
2. One SA.
3. NH3+ cytosol.

Question 72

What key points did sequence analysis show about type three proteins? (3)

Answer 72

1. Postive charge in cytosol next to the SA.
2. One SA.
3. NH3+ lumen.

Question 73

What key points did sequence analysis show about type four A proteins? (3)

Answer 73

1. SA/ STA/ SA/ STA
2. Postive charge in cytosol next to SA.
3. NH3+ cytosol.

Question 74

What key points did sequence analysis show about type four B proteins?

Answer 74

1. SA/ SA/ STA/ SA/ STA/ SA/ STA
2. Postive charge in cytosol next to SA.
3. NH3+ lumen.

Question 75

What experimental tags can be used to determine the positioning of the membrane protein?

Answer 75

1. Enzyme tags- reporter proteins.
2. Chemical modification.
3. Antibodies against protein epitopes.
4. Microscopy (EM).
5. N or C terminal tags with GFP.
6. Protease accessibility.

Question 76

You can use C terminal deletions to study membrane proteins but not N. Why?

Answer 76

The signal sequence is found at the N terminus.

Question 77

How many subunits is reporter protein LacZ made from?

Answer 77

4.

Question 78

How can LacZ be used as a reporter protein with membrane proteins?

Answer 78

LacZ is active in the cytoplasm as it is folder correctly. Can add it to the C terminus and follow the activity using Xgal sugar (blue when active.)

Question 79

What type of protein is the reporter protein is PhoA alkaline phosphatase?

Answer 79

Periplasmic.

Question 80

Where is reporter protein PhoA alkaline phosphatase expressed?

Answer 80

In prokaryotes, however it can be used as a reporter in prokaryotes and eukaryotes.

Question 81

How many subunits make up the reporter protein PhoA alkaline phosphatase dimer?

Answer 81

2.

Question 82

Why can the reporter protein PhoA alkaline phosphatase carry out its function?

Answer 82

It contains disulphides which are formed in the oxidative conditions of the periplasm but are not formed in the cytoplasm- making the reporter teportein inactive. tThis results in no phosphate bring produced and X-P not being activated (blue when active). The reporter protein is fussed to the C terminus.

Question 83

What type of protein is the reporter protein B-lactamase?

Answer 83

Periplasmic.

Question 84

What is the structure of the reporter protein B-lactamase?

Answer 84

Monomeric.

Question 85

What is the role of B-lacatamase?

Answer 85

It prevents cells against the action of B lactic antibodies such as ampicillin.

Question 86

How can B-lactamase be used as a reporter protein?

Answer 86

It can be fused to the C terminal of the protein and activity can be followed with the growth of cells on amp plates.

Question 87

Eukaryote proteins are N-glycoslated in the ER. What does this?

Answer 87

Ogliosaccharide transferases (OST).

Question 88

What does N glycosaltion involve?

Answer 88

Sugar groups added to ASN in NxT/S sequence in the luminal loop of the membrane protein.

Question 89

How can potential glycosalation sites be detected?

Answer 89

SDM assay for glycosalation site by SDS/phage electrophoresis or mass spec to detect site sites (glycosaltion sites 2-5kd bigger.)

Question 90

What can N-glycosaltion scanning also be used for in addition to adding sugars to ASN in the NxT/S sequence?

Answer 90

C terminal deletion of fusion proteins. Can link the glycosaltion domain to protein being studied.

Question 91

Where must the glcyoslation site be for OST to work?

Answer 91

12 residues upstream or 14 residues downstream of the membrane.

Question 92

What does cysteine mutagenesis scanning involve?

Answer 92

The addition of a reactive thiol group to cys mutants of the membrane proteins. Membrane then probed with membrane impermeable and membrane impermeable blocks. The mutated cys must first be changed into a serine.

Question 93

Is the mutant protein in cysteine mutagenesis scanning usually active?

Answer 93

Yes.

Question 94

What reagents can be used in cystitis mutagenesis scanning?

Answer 94

Biotin, fluorescent molecules or radiolabels.

Question 95

What are three examples of a membrane permeable probe used in cysteine mutagenesis scanning?

Answer 95

1. Biofinmalemide.
2. N-[C14]ethlymaleimide.
3. Fluroesceinmalemide.

Question 96

What is an example of a membrane impermeable probe used in cysteine mutagenesis scanning?

Answer 96

Acetomalemide disuphonate.

Question 97

What are thee advantages of cysteine mutagenesis scanning?

Answer 97

1. Protein still active.
2. In vivo studies possible.
3. Small changes made to the protein.

Question 98

What 4 methods can be used to determine membrane topology other than the scanning methods?

Answer 98

1. Antibodies raised to natural or engineered epitopes.
2. Immune affinity chromatography.
3. GFP/ fluorescence microscopy.
4. EM to directly visualise protein.

Question 99

How can EM be used to determine membrane topology?

Answer 99

Protein labelled with gold antibody and particles coasted with protein A- this non specifically binds to the FC region.