Chapter 9

Question 1

• What is a lipid bilayer and its permeability?

Answer 1

Form bilayers- essential components
of cellular membranes
■ Hydrocarbon chains (in some lipids)-
energy stores
■ Intra- and intercellular signaling
events

Question 2

• What does it means for a lipid bilayer to be asymmetric?

Answer 2

Lipid bilayer asymmetry refers to the difference between the lipid composition and/or physical properties of the two lipid monolayers that make up a lipid bilayer
-That means that the two sides of membrane are structurally and functionally different
happens over time

Question 3

•What is membrane fluidity?

Answer 3

Lipids move in the
bilayer
■ Depends on membrane
composition and
temperature
-Transverse diffusion (flip-flop) is very slow
-Lateral diffusion is rapid

Question 4

• What factors effect fluidity of membrane?

Answer 4

• Temperature-Real membranes have liquid-ordered domains (Lo) or “rafts” due, in part, to cholesterol, a membrane “plasticizer” and sphingolipids
  
  • above transition temperature
    
    • Ld: liquid-disordered stat
  • Below transition temperature
    
    • So: solid-ordered state
• Fatty acid chain length alters fluidity- shorter chain, closer to temp on graph

Question 5

Experimentally how you can test membrane fluidity?

Answer 5

■ FRAP – Fluorescence Recovery After Photobleaching

• watch video
• Be able to read and draw FRAP data.

Question 6

• What is the fluid mosaic model?

Answer 6

Biologists use the fluid mosaic model to describe a membrane’s structure—diverse protein molecules suspended in a fluid phospholipid bilayer (phospholipids, cholesterols, and proteins)

Question 7

• Integral membrane proteins
  
  • How can they be isolated from the membrane?

Answer 7

The isolation of integral membrane proteins requires more drastic conditions, and generally, detergents (also called surfactants) or organic solvents have to be used to extract the protein from the bilayer.

Contain transmembrane domains

Question 8

(Integral membrane proteins) What amino acids would you expect to find spanning the membrane?

Answer 8

Nonpolar amino acids like Leucine

Question 9

How do you read and interpret a hydrophobicity plot.

Answer 9

Watch video-

Question 10

• Peripheral membrane proteins
  
  • Describe how are they associated with the membrane and how can they be isolated from the membrane?

Answer 10

■ Bind to membrane surface – Electrostatic interactions – Hydrogen bonding

Adhere only temporarily

peripheral proteins are removed by shifting the ionic strength or pH of the aqueous solution, thereby dissociating the ionic interactions of the peripheral protein with either phospholipid polar head groups or other membrane proteins

Question 11

• Lipid-linked proteins
  
  • What is Prenylation?

Answer 11

■ CXXY motif

– X = aliphatic amino acid

– Y = Ala, Met, Ser à farnesylated

– Y = Leu à geranylgeranylated

Prenylated proteins have covalently attached lipids that are built from isoprene units

Question 12

• Lipid-linked proteins
  
  • What is the recognition sequences for addition of farnesyl and geranylgeranyl residue?

Answer 12

I cant find how it actually recongizes???

In general, the consensus prenylation sequence contains the CAAX motif (referred to as the CAAX box; C is cysteine, A is usually an aliphatic amino acid, and X can be a variety of amino acids). The X residue of this motif largely determines the choice of the isoprenoid

Question 13

• Lipid-linked proteins
  
  • Acylation

Be able to identify and know how they are linked

Answer 13

■ Myristolation – Myristic acid attached to Nt amino group of Gly

■ Palmitoylation – Thioester linkage to Cys

Question 14

• GPI anchored proteins
  
  • Be able to identify/describe the GPI anchor
  • Where is the lipid modification added to a protein?

Answer 14

GPI anchor – Glycosylphosphatidylinositol- linked protein – amide linked to Ct

Question 15

• Secretory system
  
  • What are free and bound ribosomes and where proteins that are translated on each are distributed in the cell?

Answer 15

Free ribosomes – Soluble and mitochondrial-bound proteins

■ Membrane bound ribosomes – Secreted, transmembrane, lysosomal, and ER proteins

Question 16

• Secretory system
  
  • What is the process by which Type I transmembrane proteins are manufactured in eukaryotic cells?

Answer 16

Translation begins on a free ribosome

■ Signal peptide leads to halting of translation and localization to the rough endoplasmic reticulum

■ Ribosome binds translocon and translation continues

■ N-terminal signal peptide not part of final protein

■ Signal-anchor sequence transfers into rough ER membrane during translation

■ Post-translational modifications occur in the ER and secretory pathway

■ No signal-anchor: soluble protein

Question 17

• Secretory system
  
  • What is the functions of the translocon?

Answer 17

■ Allows passages of peptide sequences into the ER

■ Facilitates insertion of proteins into the membrane – Signal-anchor sequences

Question 18

• Secretory system
  
  • Describe the movement of COPI, COPII, and clatherin coated vesicles.
    
    • What is the purpose of the protein coat?

Answer 18

• Clathrin-coated vesicles transport TM, GPI-linked, and secreted proteins to the plasma membrane
• COPI-coated vesicles bud from the Golgi compartments
• COPII-coated vesicles bud from the ER

■ Vesicle coating

– Occurs after cargo binding

– Causes the membrane to evaginate

Vesicles cannot fuse to a membrane with coat bound

■ Vesicles also contain: – Targeting proteins – Fusion proteins

Question 19

• Secretory system
  
  • Describe v-SNAREs and t-SNAREs and how they facilitate membrane fusion.

Also, be able to describe their disassembly

Answer 19

R-SNARE (v-SNARE) and QSNARE (t- SNARE) zip together and cause membrane fusion

■ Vesicle and target membrane become continuous

Interior of the vesicle and outside of the cell are topologically equivalent

■ Fusion with membrane preserves the orientation of integral proteins

■ Upon fusing, cargo inside vesicles is released to the extracellular matrix