Cholera and Endocytosis/Protein Degradation

Question 1

What are the two types of diarrhea?

Answer 1

Non-inflammatory (cholera) and inflammatory

Question 2

How is non-inflammatory diarrhea characterized?

Answer 2

Watery. Small bowel

Question 3

How is inflammatory diarrhea characterized?

Answer 3

^ Temp; fecal WBC; RBC. Colon

Question 4

What is the name and type of bacteria that causes cholera?

Answer 4

Vibrio cholerae. Gram-negative motile rod (from brackish water). Infects only humans

Question 5

What are clinical symptoms and signs?

Answer 5

Severe acute rapidly fatal watery diarrhea; vomiting; abd. pain; dehydration; renal failure low K+; Ca++; - ileus; muscle pain/spasm low HCO3- - metabolic/lactic acidosis; hypoglycemia; coma. OR you could be asymptomatic

Question 6

What are 3 virulence factors of V. cholerae?

Answer 6

1: >200 serogroups (O-specific polysaccharide of LPS. EG 01 and 0139) 2: Pili (TCP: Toxin coregulated pilus) = colonization 3: Toxin (CT;AB5) = secretory diarrhea

Question 7

What do 2 subunits of cholera toxin do?

Answer 7

A subunit is the active subunit that actually causes the secretion. B subunit is the binding subunit. 5 B subunits for each A subunit

Question 8

What is the receptor for cholera toxin?

Answer 8

Ganglioside GM1 (on epithelial cells)

Question 9

How does cholera toxin work?

Answer 9

Stimulates cAMP. Very similar to ETEC

Question 10

What actually produces the CT?

Answer 10

A bacteriophage causes this change. Not the bacteria itself

Question 11

How does increase of cAMP lead to diarrhea?

Answer 11

cAMP leads to more chloride secretion through CFTR (cysitc fibrosis transmembrane receptors?). Once you have chloride secretion sodium and water follow

Question 12

How will histology of the bowel of a person with cholera look?

Answer 12

It will be completely normal

Question 13

What are 5 factors that influence the pathogenesis of V. cholerae diarrhea?

Answer 13

Inoculum; pH (cholera is resistant); flagella; TCP (to cause adhesion/colonies); CT (cause diarrhea)

Question 14

What are susceptibility factors to V.cholerae 01-related diarrhea?

Answer 14

Bug (colonizing strains); Host (children; hypochlorhydria; blood group O; Prior immunity; cystic fibrosis gene); Social (upheaval/war/migration)

Question 15

How does cystic fibrosis transmembrane conductance regulate (CFTR) on chr. 7 affect cholera?

Answer 15

If you have cystic fibrosis your CFTR channel does not fold properly so you will be less susceptible to cholera. (This protective effect is seen in heterzygotes too)

Question 16

Combined with IV fluids; what else really helps treat cholera?

Answer 16

Oral rehydration solution/treatment (ORT)

Question 17

What is the mechanism of protection in cholera vaccine?

Answer 17

Antibodies to OPS of LPS are the primary mechanism of protection

Question 18

What is present in the dukoral vaccine to cholera?

Answer 18

Killed V. cholerae 01 x2 + CtxB (WC-rBS). Killed bacteria plus B subunit of the toxin

Question 19

What is present in the shanchol vaccine to cholera?

Answer 19

Killed V. cholerae 01 and 0139. Killed species of 2 different strains

Question 20

Now onto endocytosis and protein degradation lecture

Answer 20

OK

Question 21

What are the two mechanisms for vesicle formation?

Answer 21

Clathrin coat proteins (better understood) or caveolae

Question 22

What does AP2 do with respect to LDL receptor-mediated endocytosis?

Answer 22

Lines the membrane pits and binds to clathrin and also to the LDL receptor

Question 23

What is the order of vesicles after dynamin pinches it off from the plasma membrane?

Answer 23

Coated vesicle. Early endosome. Late endosome.

Question 24

Where does the LDL particle become unbound from the LDL receptor? How does this happen? What is the fate of the LDLR and the LDL particle?

Answer 24

In the late endosome the pH is low (about 5.0). The LDLR gets recycled back to the plasma membrane and the LDL particle gets broken down into amino acids; fatty acids; and cholesterol in the lysosome.

Question 25

What are caveolae?

Answer 25

Small endocytic vesicles that form without coat proteins.

Question 26

What are caveolae especially important for?

Answer 26

Membrane domains known as lipid rafts (regions high in cholesterol and signaling molecules)

Question 27

What are some examples of bad things that enter specifically through caveolae?

Answer 27

Simian virus 40. Cholera toxin

Question 28

What structural protein is required for caveolae formation? What else is it important for?

Answer 28

Caveolin. Also important as a scaffolding protein for coordinating protein complexes

Question 29

How many caveolins are in each vesicle?

Answer 29

144

Question 30

Mutations in caveolin-3 gene leads to which diseases?

Answer 30

Limb Girdle disease and Rippling Muscle disease

Question 31

Which virus enters specifically through clathrin-mediated entry?

Answer 31

vesicular stomatitis virus (a problem for horses and cows)

Question 32

How does HIV enter the cells?

Answer 32

Fusion-entry

Question 33

How does vaccinia virus enter the cells?

Answer 33

Macropinocytosis-mediated entry

Question 34

How does herpes simplex virus enter the cells?

Answer 34

Phagocytosis-like-mediated entry

Question 35

How do bacteria enter the cells?

Answer 35

Phagocytosis-mediated entry

Question 36

What are three major protein degradation pathways in eukaryotic cells?

Answer 36

Ubiquitin-proteasome system (UPS - responsible for the rapid degradation of proteins when fast adaptation is needed). The lysosome (part of the endocytosis pathway). Autophagy (mainly involved in the degradation of long-lived proteins and entire organelles)

Question 37

What are the 2 best examples of chaperone (folding) proteins?

Answer 37

hsp70 and hsp60 (hsp=heat shock protein)

Question 38

How does hsp70 work?

Answer 38

helps fold a protein by binding to exposed hydrophobic patches in incompletely folded proteins and prevents aggregation

Question 39

How does hsp60 work?

Answer 39

Forms an elaborate barrel-shaped structure that acts as an isolation chamber. Misfolded proteins are fed into the chamber to prevent aggregation and to help it to refold

Question 40

How does the ER establish an environment conducive for protein folding?

Answer 40

Contains folding enzymes like ERp57 (allows formation of disulfide bonds). Contains molecular chaperones like BiP (similar to Hsp70 - uses ATP to help proteins fold). There are folding sensors that monitor unfolded proteins and hold them in the ER until they fold properly or are shuttled to a degradation pathway

Question 41

What two enzymes and two ER-resident proteins are involved in the protein refolding/degradation pathway?

Answer 41

Glucosyltransferase; glucosidase and calnexin; calreticulin

Question 42

What do calnexin and calreticulin do?

Answer 42

Bind the oligosaccharide chain if there is a glucose (they are lectins) and hold it until glucosidase removes the glucose. (Note: Calnexin is transmembrane and calreticulin is a soluble protein in the ER lumen)

Question 43

What does glucosyltransferase do?

Answer 43

Recognizes misfolded proteins and prevents them from leaving the ER. Puts a glucose back on the sugar chain so the protein will again be bound to calnexin/calreticulin. This process will continue until either the protein folds properly and exits the ER OR it “times out” and is retrotranslocated out of ER and destined for degradation

Question 44

What is the ubiquitin-proteasome degradation system?

Answer 44

Proteins destined for degradation are deglycosylated and have multiple ubiquitin molecules attached in order to target them to the proteosome. In the proteosome the misfolded protein is unwound and cut into short (7-9 AA) peptides.

Question 45

Where does proteolytic cleavage take place?

Answer 45

The central cylinder of the proteasome

Question 46

Which part of the proteasome recognizes polyubiquitin and uses ATP to unfold the protein?

Answer 46

The caps on each end of the cylinder

Question 47

What is required to attach ubiquitin to a protein?

Answer 47

3 ligase enzymes: E1; E2 and E3

Question 48

What is ubiquitin?

Answer 48

76 AA protein. Very conserved in all cells

Question 49

What does E1 do? How many genes code for it?

Answer 49

binds and activates ubiquitin and then pases it to E2. 1 gene codes for E1

Question 50

What does E3 do?

Answer 50

Has substrate specificity (roughly 500 E3 enzymes in mammals). Transfers ubiquitin from E2 to the protein by attaching the ubiquitin to a lysine in the protein. E3 then attaches a string of additional ubiquitins to the first one.

Question 51

How many ubiquitins are required by the proteasome as a tag for degradation?

Answer 51

A chain of at least four ubiquitins (polyubiquitins)

Question 52

How else are ubiquitins used?

Answer 52

mono or multiubiquitination can be use as regulatory signals (EX to regulate transcription)

Question 53

What is the primary role of lysososomes?

Answer 53

Degrade extracellular materials taken up by endocytosis (also degrade some intracellular components)

Question 54

How are plasma membrane proteins targeted for endocytosis/degradation?

Answer 54

They are monoubiquitinated. Then transferred via the late endosome/multivesicular body to the lysosome for degradation

Question 55

What is the multivesicular body?

Answer 55

A prelysosomal compartment; vesicles containing proteins slated for destruction bud into the lumen. When the multivesicular body fuses with the lysosome these vesicles are delivered into the lysosome for degradation

Question 56

Where do lysosomal membrane proteins like proton pumps and transporters come from?

Answer 56

They reach the lysosome by vesicles that bud from the Golgi and fuse with the lysosome. They are protected from degradation

Question 57

When is autophagy used?

Answer 57

A stress response to starvation or used to degrade organelles that are damaged or undergo normal turnover.

Question 58

Describe the general process of autophagy?

Answer 58

A double membrane forms around the organelle. The outer membrane fuses with the lysosome and the membrane enclosed organelle is delivered (like the vesicles in the multivesicular body) to the lysosome for degradation.