What does protein trafficking consist of?
- membrane protein synthesis
- Protein tagging by sugars (glycosylation)
- Protein activation by trimming (proteolytic processing)
What do cells carry sugars on the outside?
Protect themselves from harsh environment and provide a tagging mechanism
- epithelial cells rich in carbohydrates
- provide protection from foreign elements
*Both lipids and proteins are often tagged by complex sugars
Different types of proteins
- Cystosolic protein= made it cytosol
- membrane and secretory proteins= made in rough EF
- Nuclear proteins= made on outer nuclear membrane
Rough ER- Smooth ER- Golgi- secretory vesicle- plama membrane
Protein synthesis starts at cytosol then goes to Rough ER
Free ribsome cycle- mRNA encoding a cytosolic protein remain free in cytosol
Membrane bound ribosome cycle- rough ER
- ER singal sequence goes to ER membrane where mRNA encoding a protein targeted to ER remains membrane bound- Polyribsosome bound to ER by multiple nascent polypeptide chains
*Common pool of ribosomal subunits in cytosol
Following synthesis pattern
Proteins move into smooth ER (where lipids are made and vesicles form)
Then to Golgi for final addition of sugars and sorting into place
Secretory vesicles then trim (protease) and activate hormones/ enzymes during maturation of vesicles
Signal recognition particle
(SRP) guides ribosome following binding to the signal peptide
SRP and its receptor allow attachment of ribosome to translocator
- Binding of SRP to signal peptide causes a pause of translation
- SRP-bound ribosome attaches to SRP receptor in ER membrane
- Translation continues and translocation begins
- SRP and SRP receptor displaced and recycled
Differential centrifugation
Separates heavy and light vesicles
- Rough microsomes have a high density and stop sedimenting and float at high sucrose conc
- Smooth microsomes have a low density and stop sedimenting and float at low sucrose conc
Low= high in tube
What shows real topography of ribosomes on ER membrane?
Electron microscopy
ER-bound signal peptidase removes signal peptides from secretory proteins
How do transmembrane proteins stay anchored in the ER membrane?
Swapping the signal peptide for a lipid anchor in the ER can take place to continue membrane association Glycosylphosphatidylinatol anchor (GPI anchor)
Protein maturation
- The signal sequence is removed by a specific signal peptide
- Followed by conformational maturation
- Disulfide bridges are formed between cysteine residues to solidify protein shape
- Protein is glycosylated by standard carbohydrate chain ( quality control)
What causes return of proteins?
ER residuent enzymes carry KDEL (lysine- asparatic acid glutami acid leucine) sequence important for their return
Golgi to ER
Addition of carbohydrates to protein is important for
Protein stability- in harsh environment
cell- cell communication
cross species separation
trimming and growth of carbohydrate chains proceed step by step in individual Golgi cisterine
Each glycosylation step requires separate Golgi compartment to keep specific glycosylation
Cis Golgi network- sorting phosphorylation of oligosscharides on lysosomal proteins
Cis cisterna- removal of man
Medial cisterna- removal of man and addition of GLCNA
Trans cisterna- addition of gal and NANA
Transgolgi network- Sulfation of lyrosine and carbohydrates
What are limitations in organ transplantation due to?
Simple sugar modifications
Human cells make beta glucose while other animals alpha galactose Humans will produce antibodies against alpha galactose and thus reject transplant
* Animal derived transplants are rejected by humans
Which animal make organ transplantation possible?
Genetically modified pigs lacking alpha galactose
- Enzyme add a sugar= normal a-gal +ve pig cells attack antibodies causing hyperactive rejection
- a-1,3 gal enzyme KO via gene targeting= a-1,3 gal neg pig cells- donor ce cells to produce cloned
Example of protein glycosylation within human population
Carbohydrates of band 3 protein in erthroyctes determine human blood compatibility
4 groups- O, A , AB, B
0-lacks terminal gal
A- acetylated gal
B- normal gal
Blood group determined by single terminal galactose residue. Terminal galactose determines blood group compatibility through immune compatibility.
Blood group rbc and plasma antigen
Type A- Antigen A and BP B (BP=blood plasma)
Type B- Antigen B and BP A
Type AB- Antigen A +B and BP neither A or B
Type 0- antigen neither A or B and BP A+B
O can give blood to any, A and B can give to AB
What can blood group be used to determine
Paternity
Protein trimming
Takes place prior to selection
Insulin example
1. preproinsulin translation, signal cleavage, proinsulin folding
2. proinsulin is transported to Golgi
3. proinsulin is cleaved to produce mature insulin and G peptide
trimming= processing/ maturation
Type 1 diabetes
- Secreted proinsulin rather than insulin
- Missfolding of proinsulin in ER due to a mutation
- Protease in secretory vesicle cannot cleave off the c peptide
- Secretion of dysfunctional pro-insulin instead of insulin into blood
- Generation of antibodies against the pancreatic cells
- Destruction of pancreatic cells
- Type 1 diabetes= blood glucose increase
Cleavage of opiomelanocortin can give rise to several hormones
ACTH and B-lipotrophin- secreted by the pituitary gland
B- endorphin- generated by neurons in responses to excerise/ stress . has approx. 80x the potency of morphine
Protein trafficking relying on vesicular transport
Rough ER (protein sugars) - Smooth ER ( lipids) - Golgi (sugars) - Secretory vesicle (final trimming) - plasma membrane (secretion)
mitochondria- energy
How is lipid synthesised at the smooth ER membrane
Form anchoring due to linking 2 fatty acids
Headgroup addition
