Multiple-Choice Questions PDF

Summary

This document contains multiple choice questions about vesicle transport. It includes questions on topics such as coat assembly, vesicle budding, and the role of different proteins in the process. The questions cover a range of concepts related to this complex biological process.

Full Transcript

Multiple-Choice Questions

1. What is the first step in the coat assembly process?

A) Scission
B) Uncoating
C) Initiation of coat assembly
D) Tethering

2. Which component is responsible for recruiting coat components to the donor compartment?

A) SNAREs
B) Phosphoinositides
C) GTPase
D) Rab proteins

3. During which step does the membrane curvature increase?

A) Tethering
B) Budding
C) Uncoating
D) Docking

4. What occurs during the scission step?

A) The coat proteins are recycled
B) The vesicle loses its coat
C) The neck between the vesicle and donor compartment is severed
D) The cargo is concentrated

5. What leads to the uncoating of the vesicle?

A) Addition of new coat components
B) Inactivation of the small GTPase
C) Polymerization of SNAREs
D) Binding of Rab proteins

6. What guides the naked vesicle to the acceptor compartment?

A) SNARE proteins
B) Cytoskeleton
C) GTPase
D) Phosphoinositides

7. What is the role of Rab proteins in vesicle transport?

A) They sever the neck of the vesicle
B) They assist in docking vesicles to target membranes
C) They polymerize into a mesh-like structure
D) They degrade misfolded proteins

8. What happens to SNAREs after the cargo is transferred to the acceptor compartment?

A) They are degraded
B) They are recycled
C) They are phosphorylated
D) They are transported back to the donor compartment
9. What can cause a single amino acid substitution in a protein?

A) Phosphoinositide hydrolysis
B) Point mutation
C) GTPase activation
D) SNARE complex formation

10. What is a potential consequence of protein misfolding in the ER?

A) Increased protein synthesis
B) Accumulation of misfolded proteins
C) Enhanced vesicle budding
D) Improved receptor binding

11. How can immunofluorescence techniques be used in studying mutant proteins?

A) To enhance protein synthesis
B) To detect mutant proteins using antibodies
C) To increase vesicle docking
D) To promote protein folding

12. What happens to transferrin in the absence of iron ions?

A) It binds to its receptor
B) It is endocytosed
C) It circulates freely in the blood
D) It releases iron in endosomes

13. What occurs when transferrin binds to iron?

A) It is degraded by lysosomes
B) It is recycled back to the cell surface
C) It is released into the cytoplasm
D) It prevents receptor binding

14. What is the role of dynamin in synaptic transmission?

A) It promotes vesicle budding
B) It facilitates endocytosis
C) It assists in cargo transfer
D) It stabilizes SNARE complexes

15. What happens if dynamin is defective?

A) Vesicle retrieval from the membrane is enhanced
B) Endocytosis is blocked
C) SNARE proteins are overproduced
D) Cargo is transferred more efficiently

16. What is the function of t-SNAREs in vesicle docking?

A) They sever the vesicle neck
B) They bind to Rab proteins
C) They form a complex with v-SNAREs
D) They promote uncoating

17. What is a potential effect of a mutation that interferes with the ER signal sequence?
 A) Enhanced protein folding
B) Prevention of protein entry into the ER
C) Increased vesicle budding
D) Stabilization of the protein structure

18. What is the role of lysosomal targeting signals?

A) To promote protein synthesis
B) To direct mutated proteins to lysosomes for degradation
C) To enhance vesicle docking
D) To stabilize SNARE complexes

19. What is the significance of phosphoinositide hydrolysis in vesicle uncoating?

A) It promotes cargo transfer
B) It activates Rab proteins
C) It contributes to coat disassembly
D) It enhances SNARE complex formation

20. What is the primary function of the trans-SNARE complex?

A) To initiate coat assembly
B) To promote fusion of vesicle and acceptor lipid bilayers
C) To recycle coat proteins
D) To sever the vesicle neck

21. What happens to the receptor after transferrin releases iron in endosomes?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It binds to new transferrin molecules

22. What is the role of accessory proteins during the scission step?

A) They assist in coat assembly
B) They sever the neck of the vesicle
C) They promote cargo concentration
D) They facilitate uncoating

23. What is the consequence of a continuous ER/Golgi retrieval signal?

A) The protein is secreted
B) The protein is trapped within the cell
C) The protein is degraded
D) The protein is synthesized more efficiently

24. How does the cytoskeleton assist in vesicle transport?

A) By degrading misfolded proteins
B) By guiding the vesicle to the acceptor compartment
C) By promoting coat assembly
D) By enhancing SNARE complex formation

25. What is the primary role of transmembrane cargo proteins during coat assembly?

A) To sever the vesicle neck
 B) To bind to GTPases
C) To gather at the assembling coat
D) To promote uncoating

26. What is the effect of a point mutation on protein synthesis?

A) It always enhances synthesis
B) It may lead to defective protein synthesis
C) It has no effect on synthesis
D) It guarantees proper folding

27. What is the role of the acceptor compartment in vesicle transport?

A) To initiate coat assembly
B) To serve as the destination for cargo transfer
C) To degrade misfolded proteins
D) To recycle SNARE proteins

28. What happens to coat proteins after uncoating?

A) They are degraded
B) They are recycled for additional rounds of vesicle budding
C) They are permanently inactivated
D) They are transported to lysosomes

29. What is the significance of the lower pH in endosomes for transferrin?

A) It enhances receptor binding
B) It promotes iron release
C) It prevents endocytosis
D) It stabilizes the transferrin structure

30. What is the function of the v-SNAREs in the docking process?

A) They sever the vesicle neck
B) They bind to Rab proteins
C) They form a complex with t-SNAREs
D) They promote uncoating

31. What is the role of GTPase in the initiation of coat assembly?

A) It promotes vesicle fusion
B) It recruits coat components to the donor compartment
C) It degrades misfolded proteins
D) It assists in cargo transfer

32. What is a potential outcome of protein misfolding in the ER?

A) Increased protein secretion
B) Accumulation of misfolded proteins
C) Enhanced vesicle docking
D) Improved receptor binding

33. How does the binding of Rab proteins to effectors assist in vesicle transport?

A) By promoting uncoating
B) By facilitating docking to target membranes
 C) By severing the vesicle neck
D) By enhancing cargo concentration

34. What is the primary function of the coat components during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

35. What happens to the receptor after transferrin binds to iron?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It is released into the cytoplasm

36. What is the role of the cytoskeleton in vesicle transport?

A) To degrade misfolded proteins
B) To guide the vesicle to the acceptor compartment
C) To promote coat assembly
D) To enhance SNARE complex formation

37. What is the consequence of a mutation that destabilizes a protein?

A) Enhanced protein function
B) Increased protein synthesis
C) Defective protein synthesis
D) Improved protein folding

38. What is the role of the trans-SNARE complex in vesicle fusion?

A) To sever the vesicle neck
B) To promote the fusion of vesicle and acceptor lipid bilayers
C) To recycle coat proteins
D) To enhance cargo concentration

39. What is the effect of phosphoinositide hydrolysis on vesicle uncoating?

A) It promotes cargo transfer
B) It activates Rab proteins
C) It contributes to coat disassembly
D) It enhances SNARE complex formation

40. What is the primary function of the coat proteins during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

41. What happens to the receptor after transferrin releases iron in endosomes?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
 D) It binds to new transferrin molecules

42. What is the role of dynamin in synaptic transmission?

A) It promotes vesicle budding
B) It facilitates endocytosis
C) It assists in cargo transfer
D) It stabilizes SNARE complexes

43. What happens if dynamin is defective?

A) Vesicle retrieval from the membrane is enhanced
B) Endocytosis is blocked
C) SNARE proteins are overproduced
D) Cargo is transferred more efficiently

44. What is the consequence of a continuous ER/Golgi retrieval signal?

A) The protein is secreted
B) The protein is trapped within the cell
C) The protein is degraded
D) The protein is synthesized more efficiently

45. How does the cytoskeleton assist in vesicle transport?

A) By degrading misfolded proteins
B) By guiding the vesicle to the acceptor compartment
C) By promoting coat assembly
D) By enhancing SNARE complex formation

46. What is the primary role of transmembrane cargo proteins during coat assembly?

A) To sever the vesicle neck
B) To bind to GTPases
C) To gather at the assembling coat
D) To promote uncoating

47. What is the effect of a point mutation on protein synthesis?

A) It always enhances synthesis
B) It may lead to defective protein synthesis
C) It has no effect on synthesis
D) It guarantees proper folding

48. What is the role of the acceptor compartment in vesicle transport?

A) To initiate coat assembly
B) To serve as the destination for cargo transfer
C) To degrade misfolded proteins
D) To recycle SNARE proteins

49. What happens to coat proteins after uncoating?

A) They are degraded
B) They are recycled for additional rounds of vesicle budding
C) They are permanently inactivated
D) They are transported to lysosomes
50. What is the significance of the lower pH in endosomes for transferrin?

A) It enhances receptor binding
B) It promotes iron release
C) It prevents endocytosis
D) It stabilizes the transferrin structure

51. What is the function of the v-SNAREs in the docking process?

A) They sever the vesicle neck
B) They bind to Rab proteins
C) They form a complex with t-SNAREs
D) They promote uncoating

52. What is the role of GTPase in the initiation of coat assembly?

A) It promotes vesicle fusion
B) It recruits coat components to the donor compartment
C) It degrades misfolded proteins
D) It assists in cargo transfer

53. What is a potential outcome of protein misfolding in the ER?

A) Increased protein secretion
B) Accumulation of misfolded proteins
C) Enhanced vesicle docking
D) Improved receptor binding

54. How does the binding of Rab proteins to effectors assist in vesicle transport?

A) By promoting uncoating
B) By facilitating docking to target membranes
C) By severing the vesicle neck
D) By enhancing cargo concentration

55. What is the primary function of the coat components during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

56. What happens to the receptor after transferrin binds to iron?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It is released into the cytoplasm

57. What is the role of the cytoskeleton in vesicle transport?

A) To degrade misfolded proteins
B) To guide the vesicle to the acceptor compartment
C) To promote coat assembly
D) To enhance SNARE complex formation

58. What is the consequence of a mutation that destabilizes a protein?
 A) Enhanced protein function
B) Increased protein synthesis
C) Defective protein synthesis
D) Improved protein folding

59. What is the role of the trans-SNARE complex in vesicle fusion?

A) To sever the vesicle neck
B) To promote the fusion of vesicle and acceptor lipid bilayers
C) To recycle coat proteins
D) To enhance cargo concentration

60. What is the effect of phosphoinositide hydrolysis on vesicle uncoating?

A) It promotes cargo transfer
B) It activates Rab proteins
C) It contributes to coat disassembly
D) It enhances SNARE complex formation

61. What is the primary function of the coat proteins during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

62. What happens to the receptor after transferrin releases iron in endosomes?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It binds to new transferrin molecules

63. What is the role of dynamin in synaptic transmission?

A) It promotes vesicle budding
B) It facilitates endocytosis
C) It assists in cargo transfer
D) It stabilizes SNARE complexes

64. What happens if dynamin is defective?

A) Vesicle retrieval from the membrane is enhanced
B) Endocytosis is blocked
C) SNARE proteins are overproduced
D) Cargo is transferred more efficiently

65. What is the consequence of a continuous ER/Golgi retrieval signal?

A) The protein is secreted
B) The protein is trapped within the cell
C) The protein is degraded
D) The protein is synthesized more efficiently

66. How does the cytoskeleton assist in vesicle transport?

A) By degrading misfolded proteins
 B) By guiding the vesicle to the acceptor compartment
C) By promoting coat assembly
D) By enhancing SNARE complex formation

67. What is the primary role of transmembrane cargo proteins during coat assembly?

A) To sever the vesicle neck
B) To bind to GTPases
C) To gather at the assembling coat
D) To promote uncoating

68. What is the effect of a point mutation on protein synthesis?

A) It always enhances synthesis
B) It may lead to defective protein synthesis
C) It has no effect on synthesis
D) It guarantees proper folding

69. What is the role of the acceptor compartment in vesicle transport?

A) To initiate coat assembly
B) To serve as the destination for cargo transfer
C) To degrade misfolded proteins
D) To recycle SNARE proteins

70. What happens to coat proteins after uncoating?

A) They are degraded
B) They are recycled for additional rounds of vesicle budding
C) They are permanently inactivated
D) They are transported to lysosomes

71. What is the significance of the lower pH in endosomes for transferrin?

A) It enhances receptor binding
B) It promotes iron release
C) It prevents endocytosis
D) It stabilizes the transferrin structure

72. What is the function of the v-SNAREs in the docking process?

A) They sever the vesicle neck
B) They bind to Rab proteins
C) They form a complex with t-SNAREs
D) They promote uncoating

73. What is the role of GTPase in the initiation of coat assembly?

A) It promotes vesicle fusion
B) It recruits coat components to the donor compartment
C) It degrades misfolded proteins
D) It assists in cargo transfer

74. What is a potential outcome of protein misfolding in the ER?

A) Increased protein secretion
B) Accumulation of misfolded proteins
 C) Enhanced vesicle docking
D) Improved receptor binding

75. How does the binding of Rab proteins to effectors assist in vesicle transport?

A) By promoting uncoating
B) By facilitating docking to target membranes
C) By severing the vesicle neck
D) By enhancing cargo concentration

76. What is the primary function of the coat components during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

77. What happens to the receptor after transferrin binds to iron?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It is released into the cytoplasm

78. What is the role of the cytoskeleton in vesicle transport?

A) To degrade misfolded proteins
B) To guide the vesicle to the acceptor compartment
C) To promote coat assembly
D) To enhance SNARE complex formation

79. What is the consequence of a mutation that destabilizes a protein?

A) Enhanced protein function
B) Increased protein synthesis
C) Defective protein synthesis
D) Improved protein folding

80. What is the role of the trans-SNARE complex in vesicle fusion?

A) To sever the vesicle neck
B) To promote the fusion of vesicle and acceptor lipid bilayers
C) To recycle coat proteins
D) To enhance cargo concentration

81. What is the effect of phosphoinositide hydrolysis on vesicle uncoating?

A) It promotes cargo transfer
B) It activates Rab proteins
C) It contributes to coat disassembly
D) It enhances SNARE complex formation

82. What is the primary function of the coat proteins during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
 D) To recycle SNARE proteins

83. What happens to the receptor after transferrin releases iron in endosomes?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It binds to new transferrin molecules

84. What is the role of dynamin in synaptic transmission?

A) It promotes vesicle budding
B) It facilitates endocytosis
C) It assists in cargo transfer
D) It stabilizes SNARE complexes

85. What happens if dynamin is defective?

A) Vesicle retrieval from the membrane is enhanced
B) Endocytosis is blocked
C) SNARE proteins are overproduced
D) Cargo is transferred more efficiently

86. What is the consequence of a continuous ER/Golgi retrieval signal?

A) The protein is secreted
B) The protein is trapped within the cell
C) The protein is degraded
D) The protein is synthesized more efficiently

87. How does the cytoskeleton assist in vesicle transport?

A) By degrading misfolded proteins
B) By guiding the vesicle to the acceptor compartment
C) By promoting coat assembly
D) By enhancing SNARE complex formation

88. What is the primary role of transmembrane cargo proteins during coat assembly?

A) To sever the vesicle neck
B) To bind to GTPases
C) To gather at the assembling coat
D) To promote uncoating

89. What is the effect of a point mutation on protein synthesis?

A) It always enhances synthesis
B) It may lead to defective protein synthesis
C) It has no effect on synthesis
D) It guarantees proper folding

90. What is the role of the acceptor compartment in vesicle transport?

A) To initiate coat assembly
B) To serve as the destination for cargo transfer
C) To degrade misfolded proteins
D) To recycle SNARE proteins
91. What happens to coat proteins after uncoating?

A) They are degraded
B) They are recycled for additional rounds of vesicle budding
C) They are permanently inactivated
D) They are transported to lysosomes

92. What is the significance of the lower pH in endosomes for transferrin?

A) It enhances receptor binding
B) It promotes iron release
C) It prevents endocytosis
D) It stabilizes the transferrin structure

93. What is the function of the v-SNAREs in the docking process?

A) They sever the vesicle neck
B) They bind to Rab proteins
C) They form a complex with t-SNAREs
D) They promote uncoating

94. What is the role of GTPase in the initiation of coat assembly?

A) It promotes vesicle fusion
B) It recruits coat components to the donor compartment
C) It degrades misfolded proteins
D) It assists in cargo transfer

95. What is a potential outcome of protein misfolding in the ER?

A) Increased protein secretion
B) Accumulation of misfolded proteins
C) Enhanced vesicle docking
D) Improved receptor binding

96. How does the binding of Rab proteins to effectors assist in vesicle transport?

A) By promoting uncoating
B) By facilitating docking to target membranes
C) By severing the vesicle neck
D) By enhancing cargo concentration

97. What is the primary function of the coat components during vesicle budding?

A) To degrade misfolded proteins
B) To polymerize into a mesh-like structure
C) To assist in cargo transfer
D) To recycle SNARE proteins

98. What happens to the receptor after transferrin binds to iron?

A) It is degraded
B) It is recycled back to the cell surface
C) It is transported to lysosomes
D) It is released into the cytoplasm

99. What is the role of the cytoskeleton in vesicle transport?
 A) To degrade misfolded proteins
B) To guide the vesicle to the acceptor compartment
C) To promote coat assembly
D) To enhance SNARE complex formation

100. What is the consequence of a mutation that destabilizes a protein?

A) Enhanced protein function
B) Increased protein synthesis
C) Defective protein synthesis
D) Improved protein folding