16.1: Translocation of Secretory Proteins Across the ER Membrane

The rough ER is formed through:
- Secreted proteins synthesizing
- Enzymes
- Golgi complex
- Lysosome
- Integral plasma membrane
They attach to the membrane of the ER and form the rough ER
ER signal sequences on nascent secretory proteins contain hydrophobic amino acids located at the N-terminus
The ER binds to the signal recognition particle (SRP) which helps it turn into a nascent secretory protein, which targets the ribosome/nascent chain complex
SRP and the SRP receptor conduct the insertion of secretory protein in the translocon, and no additional energy is needed for this
Competed secretory proteins target the ER membrane through interaction with the translocon in post-translational translocation

16.2: Insertion of Proteins into the ER Membrane

There are four different classes of topology that the synthesized proteins of the integral membrane can fall into on the ER:
- Topogenic sequences
- N-terminal signal sequences
- Internal stop-transfer sequences
- Internal signal-anchor sequences
They all direct proteins in the ER membrane
Membrane proteins that are single-pass contain up to two sequences, while multiple pass ones contain multiple
Cell-surface proteins can be initially synthesized into type I proteins and cleaved with a luminal domain transfer

N-linked oligosaccharides contain two N-acetylglucosamine and three mannose
O-linked oligosaccharides are short and contain one to four sugar residues
Glycoproteins may be assisted in their folding by oligosaccharide side proteins, along with helping protect mature proteins from proteolysis, work as antigens and help with cell-cell adhesion
Protein disulfide isomerase (PDI) works as a catalyst for the formation and rearrangement of disfutile bonds in the ER lumen
The only proteins that are transported into the Golgi complex from the rough ER are properly folded proteins

Completed proteins can be translocated through gram-negative bacteria, and the translocation takes the proteins through a translocon related to eukaryotic cells in the ER
The SecA protein works as the driver for post-translational translocation through the inner membrane
Hydrolysis and cytosolic ATP help with bacterial secretion throughout all of the cellular systems
The pathogenic bacteria use type III secretion apparatus to inject proteins into cells

Nuclear genes take up most of the encoding go of mitochondrial and chloroplast proteins and they also use synthesized ribosomes which are imported into the organelles
The N terminal uptake targeting sequence contains the information needed to target precursor proteins
Organelles only take unfolded proteins, which are maintained through cytosolic chaperones
Proteins transfer to the general import pore once they bind to the receptors on the outer membrane of the mitochondria if they are meant to be in the mitochondrial matrix
Proteins can have secondary targeting sequences if they are meant to be a part of the thylakoid
The inner and outer membrane translocation channels help with the import of proteins through the chloroplast stomata channels

The synthesization of peroximal proteins occurs on cytosolic ribosomes and they are post-translationally incorporated into the organelle
They contain a C-terminal PTS1 targeting sequence and sometimes an N-terminal PTS2 targeting sequence, which aren’t cleaved after importing
If a protein is destined to the peroxisomal matrix, then they bind to a cytosolic receptor and they are directed to common import receptors along with translocation machinery along the peroxisomal membrane
Peroxisomal membrane proteins contain a targeting sequence that is different from the peroxisomal matrix proteins, also, they move along a different pathway

The rough ER is formed through:
- Secreted proteins synthesizing
- Enzymes
- Golgi complex
- Lysosome
- Integral plasma membrane
They attach to the membrane of the ER and form the rough ER
ER signal sequences on nascent secretory proteins contain hydrophobic amino acids located at the N-terminus
The ER binds to the signal recognition particle (SRP) which helps it turn into a nascent secretory protein, which targets the ribosome/nascent chain complex
SRP and the SRP receptor conduct the insertion of secretory protein in the translocon, and no additional energy is needed for this
Competed secretory proteins target the ER membrane through interaction with the translocon in post-translational translocation

There are four different classes of topology that the synthesized proteins of the integral membrane can fall into on the ER:
- Topogenic sequences
- N-terminal signal sequences
- Internal stop-transfer sequences
- Internal signal-anchor sequences
They all direct proteins in the ER membrane
Membrane proteins that are single-pass contain up to two sequences, while multiple pass ones contain multiple
Cell-surface proteins can be initially synthesized into type I proteins and cleaved with a luminal domain transfer

N-linked oligosaccharides contain two N-acetylglucosamine and three mannose
O-linked oligosaccharides are short and contain one to four sugar residues
Glycoproteins may be assisted in their folding by oligosaccharide side proteins, along with helping protect mature proteins from proteolysis, work as antigens and help with cell-cell adhesion
Protein disulfide isomerase (PDI) works as a catalyst for the formation and rearrangement of disfutile bonds in the ER lumen
The only proteins that are transported into the Golgi complex from the rough ER are properly folded proteins

Completed proteins can be translocated through gram-negative bacteria, and the translocation takes the proteins through a translocon related to eukaryotic cells in the ER
The SecA protein works as the driver for post-translational translocation through the inner membrane
Hydrolysis and cytosolic ATP help with bacterial secretion throughout all of the cellular systems
The pathogenic bacteria use type III secretion apparatus to inject proteins into cells

Nuclear genes take up most of the encoding go of mitochondrial and chloroplast proteins and they also use synthesized ribosomes which are imported into the organelles
The N terminal uptake targeting sequence contains the information needed to target precursor proteins
Organelles only take unfolded proteins, which are maintained through cytosolic chaperones
Proteins transfer to the general import pore once they bind to the receptors on the outer membrane of the mitochondria if they are meant to be in the mitochondrial matrix
Proteins can have secondary targeting sequences if they are meant to be a part of the thylakoid
The inner and outer membrane translocation channels help with the import of proteins through the chloroplast stomata channels

The synthesization of peroximal proteins occurs on cytosolic ribosomes and they are post-translationally incorporated into the organelle
They contain a C-terminal PTS1 targeting sequence and sometimes an N-terminal PTS2 targeting sequence, which aren’t cleaved after importing
If a protein is destined to the peroxisomal matrix, then they bind to a cytosolic receptor and they are directed to common import receptors along with translocation machinery along the peroxisomal membrane
Peroxisomal membrane proteins contain a targeting sequence that is different from the peroxisomal matrix proteins, also, they move along a different pathway