Lecture 9: Intro to the ER

Question 1

Rough ER

Answer 1

• Ha ribosomes bound on the cytosolic membrane surface
• Composed of a network of cisternae
• continous with the outer membrane of the nuclear envelope

Question 1

Endoplasmic Reticulum (ER) (2)

what it is+divided into

Answer 1

• A system of membranes and vesicles that encloses the ER lumen (space inside the ER, seperate from cytosol)
• Divided into smooth ER and rough ER

Question 2

Smooth ER (3)

Answer 2

• Lacks ribosomes
• Composed of interconnected curved tubular membranes
• continous with the RER

Question 3

Smooth ER is extensive in cell types such as (3)

Answer 3

• skeletal muscles, kidney tubules and steroid-producing endocrine glands

Question 4

Functions of smooth ER (4)

Answer 4

• synthesis of steroid hormones (ex: estrogen)
• Synthesis of membrane lipids (ex: phospholipids)
• Detoxification of organic compounds in the liver
• Sequestering calcium ions (storage site for calcium within cells and released with signal) in skeletal and cardiac muscle- role in muscle contraction

Question 5

Function of rough ER (2)

Answer 5

• Protein synthesis
• Modification of protein is started here (addition of sugars)

Question 6

Rough ER is entensive in

Answer 6

• Extensive in cells with a role in protein secretion (ex: intestinal cells that secrete mucoproteins)

Question 7

Sites of protein synthesis (2)

Answer 7

• 1/3 of proteins in Rough ER
• 2/3 of proteins in free ribosomes

Question 8

Rough ER ribosomes protein synthesis (3)

Answer 8

• Co-translational translocation
• Secreted proteins (Once inside the lumen of the RER, these proteins undergo various modifications, such as folding, glycosylation, and disulfide bond formation, to attain their functional conformation. After processing in the ER, secreted proteins are transported to the Golgi apparatus for further modification, sorting, and packaging into vesicles for secretion via exocytosis.)
• Integral membrane proteins and soluble proteins that reside in compartments of the endomembrane system (The rough endoplasmic reticulum (RER) is also responsible for synthesizing integral membrane proteins and soluble proteins that reside within various compartments of the endomembrane system, including the ER itself, the Golgi apparatus, lysosomes, and vesicles.)

Question 9

Co-translational translocation

Answer 9

synthesis of secreted proteins, soluble proteins and integral membrane proteins that reside in endomembrane

Question 10

Free ribosones protein synthesis (3)

Made by+released+what kind?

Answer 10

• Synthesized by free ribosomes in the cytosol (not attached to the ER)
• Proteins are released into the cytosol
• Makes proteins that remain in the cytosol, peripheral proteins of the cytosolic surface of membranes (weakly attached to plasma) and proteins transported to the nucleus, mitochondria and chloroplast (peroxisms)

Question 11

Co-translational translocation steps for secreted and soluble proteins:

Answer 11

• Begins on a free ribosome
• Signal sequence (directs ribosome to membrane) usually at N-terminal end is 6-15 hydrophobic amino acids
• Signal secognition particle (SRP) binds to the signal sequence and the ribosome
• Polypeptide synthesis is halted temporarily
• SRP directs this complex to the ER membrane by interaction with the SRP receptor (ribosome+peptide)
• Ribosome/polypeptide then are transfered from the SRP once it docs to the receptor to the translocon (a protein pore in the ER membrane with a plug to prevent ion diffusion)
• Contact with the signal sequence displaces the plug
• SRP released from the SRP receptor
• Translocation through the pre: Polypeptie enters the ER lumen
• Upon termination, ribosome is released
• Signal sequence is removed by an enzyme: signal peptidase
• Protein chaperones (Eg: BiP) aid in protein folding

Question 12

Co-translational translocation steps for integral membrane proteins:

Answer 12

• Synthesized by co-translational translocation using the same machinery as secreted proteins (SRP, receptor etc)
• SRP recognizes the hydrophobic transmembrane domain as the signal sequence
• Transmembrane domains do not pass through the pore-instead, they directly enter the lipid bilayer
• As polypeptide pass through the translocon, a gate in the pore opens and allows the proteins to partition themselves according to their solubility properties (Either in the aqueous pore or in the hydrophobic lipid bilayer

Question 13

Co-translational translocation for integral membrane proteins the directionality of the insertion

Answer 13

Direction of insertion into the bilayer is dependent on:
1. Positively charged amino acids flank the cytosolic end of the transmembrane domain.
2. Cytoplasmic leaflet is more abundant with PS and PI phopholipids which are negatively charged

Question 14

If the positive charges are on the N-terminal side of the transmembrane domain….

Answer 14

The translocon will reorient the transmembrane domain