Endomembrane II

Question 1

The early endosome is involved in

Answer 1

cargo sorting

Question 2

The recycling endosome is involved in

Answer 2

recycling vesicles

Question 3

Transport between the Golgi and the late endosome is

Answer 3

• secretory
• results in endosomal convergence.

Question 4

The Golgi is involved in

Answer 4

• carbohydrate synthesis
• cargo sorting

Question 5

The endoplasmic reticulum is involved in

Answer 5

• protein translocation
• lipid synthesis

Question 6

How is macromolecular transport achieved in the cell?

Answer 6

The discrete secretory pathway and endocytic pathways interact

Question 7

What are the resident molecules?

Answer 7

characteristic set of functional proteins and lipids of the secretory and endocytic pathways

Question 8

What is the cargo?

Answer 8

proteins and lipid

Question 9

What else in necessary for the secretory and endocytic pathways, excluding resident molecules and cargo?

Answer 9

compartments to receive the cargo

Question 10

What are the consequences of having disparate secretory and endocytic pathways?

Answer 10

cell requires an efficient sorting system of signals to distinguish resident from cargo molecules and maintain compartmental identity.

Question 11

What do resident/cargo discrimination systems usually reply upon?

Answer 11

signals to fuse vesicles to the appropriate protein

Question 12

Compartmental specialisation relies upon 4 precedents:

Answer 12

I) resident and cargo molecules are efficiently sorted
ii) carrier vesicles are accurately targeted
iii) proteins are sorted and retained in the correct transport vesicles and compartments by protein signalling
iv) transport vesicles are targeted to the correct compartments using signalling

Question 13

Transport vesicles are designed to

Answer 13

transport cargo.

Question 14

Describe transport vesicle formation

Answer 14

• self-assembly of protein coats from coat subunits on the cytoplasmic side of the endomembrane system
• budding of this membrane from the organelle lumen
• disassembly of this coat, as the vesicle fuses to the ER.

Question 15

Describe the effect of the protein coat

Answer 15

• aids the deformation of the membrane bilayer
• necessary for vesicles with large membrane curvature.

Question 16

COP-II vesicles basics

Answer 16

• transfer secretory proteins and lipids with signal membranes from the ER lumen or membrane to the cis Golgi
• leave ER resident proteins behind.

Question 17

Describe COP-II vesicle protein coats

Answer 17

• composed of two layers which coat the membrane I) the adaptor layer and ii) the cage layer
• vary for 50 to >90nm in diameter.
  Under biological logic, a dynamic entity must have a minimum of two fates

Question 18

Describe the COP-II adaptor layer

Answer 18

made of adaptor proteins that interact with the membrane

Question 19

Describe the COP-II cage layer

Answer 19

• made of rod-like cage proteins that assemble into a lattice
• bending allows curvature that will stabilise the structure
• can visualised under cross-section using TEM or cyro-electron microscopy

Question 20

Describe COP-II vesicle transport

Answer 20

when sorting, the residents are retained in the ER and become enriched, whereas the cargo are exported for secretion at the plasmamembrane, or transport to other organelles.

Question 21

Describe an experiment that tested COP-II vesicle transport

Answer 21

• introducing bacterial proteins and artificial peptides into the ER: fusing a bacterial gene onto a eukaryotic signal peptide gene sequence targeting the ER, and adding eukaryotic transcription signals such as promotor and polyA signal, then introducing into a eukaryotic cell
• ER secretion occurred for bacterial proteins
• ER resident proteins have short amino acid sequences signalling residency which are necessary and sufficient

Question 22

Why is often useful to introduce bacterial proteins in endomembrane experiments?

Answer 22

unlikely to carry genes coding for organelle export functions, as they do not contain organelles

Question 23

How were the short amino acid sequences signalling residency of resident proteins proven to be necessary?

Answer 23

genetic deletion of the signal resulted in secretion

Question 24

How were the short amino acid sequences signalling residency of resident proteins proven to be sufficient?

Answer 24

transprotein transplanting of the signal onto a cargo protein results in retention

Question 25

Export is the

Answer 25

default state, not requiring a signal; occurs by ‘bulk flow’

Question 26

ER residency is

Answer 26

the signalled state

Question 27

ER residency is in fact

Answer 27

continuous retrieval from the cis-Golgi in a form of recycling

Question 28

Describe continuous retrieval of resident proteins from the cis-Golgi

Answer 28

achieved by COP-I coated vesicles, whose coat proteins recognise and bind to ER retrieval signals, returning them to the ER

Question 29

ER retrieval signals

Answer 29

• short lysine/arginine enriched proteins xRR and KKxx
• on the cytoplasmic tails of escaped ER-membrane proteins

Question 30

COP-I is

Answer 30

a selective vesicle for secreted cargo membrane proteins – this is cargo selection.

Question 31

Describe the mechanism of COP-I interaction

Answer 31

• allows interaction of its cytoplasmic head and the cis-Golgi membrane on the cytoplasmic side through the cis-Golgi’s KDEL receptor
• binds to the KDEL ER-retrieval signal on the soluble proteins of the ER lumen on the lumenal side

Question 32

Describe COP-I

Answer 32

• pre-assembled coatomer recruited to the membrane, forming a curved triad subunit
• triads are connected by flexibly attached domains that allow self-assembly, and propagation of membrane bending
• visualised under cryo-electron tomography

Question 33

Coatomer

Answer 33

heteroheptameric complex

Question 34

Describe COP-I membrane

Answer 34

KKxx cargo-motif binding sites

Question 35

Cargo binding and release is regulated by

Answer 35

• lumenal pH
• KDEL-receptor binds to the cargo for recycling at pH 6-6.5 but releases at 7. – COP-I vesicles can recycle KDEL-receptors to the cis-Golgi from the ER.

Question 36

pH of the cis-Golgi

Answer 36

6-6.5

Question 37

pH of the ER

Answer 37

7

Question 38

Resident membrane proteins of the Golgi are

Answer 38

• made in the ER
• transported as cargo to the Golgi, but not to the plasmamembrane
  – signalled fate

Question 39

Describe Golgi residence

Answer 39

resident Golgi enzymes contain a very distinctive large catalytic lumen domain for their enzymatic function of polysachharide synthesis and modification

Question 40

Describe Golgi resident localisation signals

Answer 40

single TMDs in the membrane, and the short N-terminal cytosolic tail domain

Question 41

TMD subcellular localisation is promoted via

Answer 41

• promoted via protein–lipid interactions
• dependent upon the different lengths of the ER , Golgi and plasmamembrane TMDs.

Question 42

ER TMD length

Answer 42

approximately 15-17aas

Question 43

Golgi TMD length

Answer 43

approximately 17-20aa

Question 44

Plasmamembrane TMD length

Answer 44

> 20aas

Question 45

TMD has been found to be both … and … for Golgi localisation.

Answer 45

necessary … sufficient

Question 46

What happens if TMDs are longer?

Answer 46

localised to the plasmembrane

Question 47

What happens if TMDs are shorter?

Answer 47

localised to the ER

Question 48

If ER TMDs are made longer, or plasmamembrane TMDs are made shorter…

Answer 48

they are localised to the Golgi

Question 49

Describe cholesterol transport

Answer 49

• small lipid droplets with phospholipids and protein in hydrophilic environments
• endocytosed as LDL particles
• bound by LDL receptor proteins with LDL binding sites on the plasmamembrane
• LDL receptor is collected at the plasmembrane into pits coated in clathrin and other coat-associated proteins on the cytosolic side
• the coated pit can be actively pinched off into a CCV, where its clathrin coat dissociates with the aid of a large protein suite

Question 50

Where is cholesterol transported?

Answer 50

Blood vessels

Question 51

LDL

Answer 51

• low density lipoprotein
• cholesteryl ester molecules surrounded by cholesterol and phospholipid molecules
• surface protrusion and specific head composition
• 22nm

Question 52

Describe Familial hypercholesterolaemia

Answer 52

• lack the gene to synthesise this LDL receptor proteins, or exhibit mutations that alter the cytoplasmic domain of the LDR receptor
• prevents interaction with adaptin
• cholesterol cannot be internalised from the bloodstream
• cholesterol build up
• early heart attack

Question 53

CCV

Answer 53

Clathrin Coated Vesicle

Question 54

Describe CCVs

Answer 54

two proteinous layers: the inner, AP2 complex, and outer clathrin complex

Question 55

AP2

Answer 55

• adaptin2
• selective
• binds to the cytoplasmic tail domains of cargo receptor complices
• recruits outer clathrin complex

Question 56

Outer Clathrin complex

Answer 56

• bends the membrane
• provides structure

Question 57

Describe adaptin binding

Answer 57

• by clathrin triskelions
• creates a high radius of curvature that is extremely stable, and requires a lot of proteins to break

Question 58

Describe clathrin triskelions

Answer 58

• molecular assembly of six differently-weighted protein subunits
• spontaneously self-assembling into small, closed clathrin lattices
• can be viewed under cryo- and deep-etch electron microscopy
• always present in the cell

Question 59

Describe what happens to CCVs post-endocytosis and coat removal

Answer 59

• targeted to and merge with the early endosome for sorting
• receptor-cargo complex dissociates
• LDL receptor is repackaged and recycled, via the recycling endosome, back to the plasmamembrane
• cargo travels to the late endosome and lysosome for degradation by the lysosomal hydrolases
• endocytic cargo and the hydrolases are trafficked to the late endosome
• remaining cargo is trafficked to the lysosome

Question 60

What causes receptor-cargo dissociation?

Answer 60

acidic pH relative to the plasmamembrane and extracellular space

Question 61

Give a lysosome hydrolase

Answer 61

Cathepsin-D

Question 62

Describe the structure of Cathepsin-D

Answer 62

• inactive precursor proenzyme form is synthesised in the ER with a distinguishing signal patch of a specific mannose residue on the N-glycan in the tertiary structure

Question 63

Describe the action of Cathepsin-D

Answer 63

• recognised and phosphorylated by cis-Golgi kinases for binding to a mannose-6-P receptor in the trans-Golgi for sorting to the Late Endosome
• packaging into different uncoated CCVs with the same clathrin but AP1 adaptin molecule, which can also recognise the Man-6P receptor at the trans-Golgi, and converge with the endocytic cargo at the early endosome

Question 64

What happens at the Late Endosome?

Answer 64

• lower PH causes dissociation of the Man-6P receptor
• produces molecules of ADP and Pi from ATP
• dephosphorylated cargo to produce a mature lysosomal hydrolase
• allows Man-6P receptor recycling back to the trans-Golgi

Question 65

What happens at the lysosome?

Answer 65

proteases activate the hydrolases by proteolytic cleavage of the peptide bond, removing the protein tail that has been blocking its catalytic site, exposing it and releasing them.

Question 66

Describe the basics of the SNARE hypothesis of 1993

Answer 66

• efficient and accurate targeted and compartmentalisation of vesicles
• introduced the concepts of the proteinous v-SNAREs and t-SNAREs

Question 67

Describe SNAREs

Answer 67

• incorporated in the membranes and exposed on the cytoplasmic side of each vesicle (v) and target (t) membranes
• involved in determination of vesicle identity and targeting, as well as their corresponding NSF complex

Question 68

Describe the specifics of the SNARE hypothesis of 1993

Answer 68

• different combinations of SNAREs exist for each vesicle targeting event, specific to their origins and destinations
• specificity of v/t-SNARE pairing provided the specificity required for vesicle targeting and fusion

Question 69

Describe trans-SNARE formation

Answer 69

• tight trans-SNARE complex would be created upon docking, pulling the vesicle closer to the membrane for fusion and cargo release
• an NSF complex separates SNARE complices post-vesicle fusion in an ATP-dependent manner
• variant forms with unique identities of each of these proteins would be employed at each vesicle targeting step

Question 70

Describe the SNARE hypothesis for compartments with mixed identities such as lipids and proteins

Answer 70

• vSNARE would have to be removed, docking onto the system and breaking it up
• separated SNAREs would be recycled, ready to transport and receive more cargo

Question 71

Describe the infallibility programme of the SNARE hypothesis

Answer 71

wrongly targeted vesicles would approach a target membrane, but incompatibility would result in too much diffusion, temporally blocking it from fusion