Endoplasmic Reticulum (ER) and Golgi Apparatus PDF

Summary

This document provides information about the endoplasmic reticulum (ER) and Golgi apparatus, including their functions, structure, and roles in cells. It also details the basic transport mechanisms between them and learning objectives related to both structures.

Full Transcript

Endoplasmic Reticulum
(ER)
and
Golgi Apparatus

Dr Wendy Francis
[email protected]
Learning objectives

Describe the endomembrane system
Describe the structure and function of the smooth and
rough endoplasmic reticulum
Explain the basic transport mechanisms between the
endoplasmic reticulum and Golgi apparatus
Describe the structure and function of the Golgi
apparatus
Reading List

Pgs 174-178 Chapter 12 Endoplasmic reticulum
Endomembrane system

Multitude of membrane-enclosed
organelles
Nuclear envelope
Endoplasmic reticulum (ER)
Golgi apparatus
Lysomes, vesicles
Plasma membrane
Compartmentalises organelles

Complex distribution systems

Membranes are not identical and
are dynamic in nature
 Endoplasmic Reticulum (ER)
Membrane constitutes more than half of the total membrane of an
average animal cell

Labyrinth of branching
tubules and sacs which
interconnect, continuous
with outer nuclear
membrane
Single internal space
called ER lumen
Endoplasmic Reticulum (ER)

Rough ER
Flattened sheets
with ribosomes
bound to cytosolic
surface

Smooth ER
Tubular structure
with no ribosomes
 ER Function

Smooth ER (diverse metabolic functions)
Lipid biosynthesis (e.g. oils, steroids,
phospholipids)
Carbohydrate metabolism
Calcium storage
Detoxification of drugs and poisons

Rough ER
Protein biosynthesis
 Water soluble secretory proteins
 Transmembrane proteins
Protein folding and modification
Removal of incorrect proteins
 Smooth ER: Synthesis of lipids & steroid
hormones
Each step in lipid synthesis is catalysed by
enzymes within the SER

What are membranes largely made up
of?
Phospholipids
Glycolipids
ER
(5%)
membran
Cholesterol
e
Cholesterol: role in membrane
structure and acts to reduce
permeability of cell membrane

Involved in bile synthesis and steroid
synthesis
 Smooth ER

Calcium storage
Ca2+ pump transports Ca2+ from cytosol into ER lumen
where it’s stored at Ca2+ binding proteins
Specialised sites e.g. sarcoplasmic reticulum in muscle to
allow for contraction (release of Ca2+) and relaxation of
muscle (Ca2+ uptake)
Drug detoxification
Site of specialist enzymes that catalyse a series of reactions
to detoxify lipid-soluble drugs and harmful metabolites
produced during metabolism
Example: cytochrome p450 enzymes in liver hepatocytes
Addition of hydroxyl groups to drug molecules, making them
more water soluble and easier to excrete from the body
 Rough ER: protein biosynthesis

Ribosomal sub-units complex together with mRNA in the
cytoplasm to initiate protein synthesis

N
terminus
Amino Acid Signal
Sequence
N-terminal or internal
Localisation signal for the
protein
 Rough ER: protein biosynthesis
Translation always begins in the cytosol (except for a few
proteins made in mitochondria or chloroplasts)

Khan Academy
 Protein Distribution
NO Amino Amino Acid
Acid Signal
Signal Sequence
Sequence

Protein
remains within
the cytosol
Protein distribution to the ER

Step 1
Signal recognition
particle (SRP) recognises
and binds to the signal
sequence.

Step 2
SRP-ribosome complex binds
to SRP receptor and the
translocation complex on
ER membrane
 Protein distribution to the ER
Step 3
The signal sequence enters the
translocon in ER membrane

Step 4
Polypeptide
chain is
synthesised and
translocated
across the
Step 5 membrane
For secretory proteins, the protein is completely translocated
across the membrane. The signal sequence is cleaved by a signal
peptidase and protein released
 Transmembrane Proteins

Type I: single pass
N terminus signal sequence targeted N terminus signal sequence
to ER lumen

2nd hydrophobic region in the protein
called a ‘Stop Transfer Signal’,
which closes the translocon

The transmembrane protein moves
along the membrane laterally

The amino acid signal sequence is
cleaved
 Transmembrane Proteins
Types II/III: single pass
Internal amino acid signal sequence Internal signal sequence

Internal signal sequences can be
orientated through the translocon either
way. Either the carboxy or amino
terminus can be located in the cytosol

The transmembrane protein moves
along the membrane laterally using the
signal sequence

Examples: tyrosine kinase receptors,
integrins or cytokine receptors
 Transmembrane Proteins

Internal signal
Multipass transmembrane sequence
Alternating internal Signal
Sequences and Stop Transfer Signals

Internal signal sequences can be
orientated through the translocon
either way. Either the carboxy or
amino terminus can be located in the
cytosol

Each time a hydrophobic section
enters the translocon the protein
moves laterally along membrane https://www.nature.com/scitable/topicpage/gpcr-
14047471/
https://www.youtube.com/watch?v=u0g82N
ul1Qc
 Protein folding

ER is a major protein folding site
Molecular chaperones and folding enzymes in ER lumen
assist in folding and control subsequent release from the
ER
 Protein folding by ER chaperones

BiP (Binding immunoglobulin protein)
chaperone protein
Binds to polypeptide chain
ATP-driven (binding and release): drives
unidirectional translocation
Mediates protein folding
Prevents protein aggregation
Detects incorrectly folded proteins by
binding to exposed amino acids that
shouldn’t be exposed
Prevents incorrectly folded proteins
leaving ER
 Protein folding: disulfide bond formation

Resident proteins in ER lumen contain ER retention signal (at C
terminus)
Protein disulfide isomerase: catalyses oxidation of sulfhydryl
groups on cysteines to form disulfide (-S-S-) bonds
 N-linked glycosylation

About half of the proteins
processed in ER are
glycoproteins.
90% glycoproteins undergo N-
linked glycosylation in ER lumen
Addition of a pre-formed
precursor oligosaccharide (14
sugars) onto side chain NH2 group
of asparagine.
 N-linked glycosylation: Why

Stabilises proteins by masking hydrophobic stretches,
proteolytic cleavage sites or immune recognition:
prevents early degradation
Increase protein solubility and prevents aggregation
Facilitates protein folding
Acts as a critical check point in glycoprotein folding
An unfolded protein will undergo continuous cycles
of glucose trimming and glucose addition until it
has achieved its fully folded state
Chaperone proteins recognise and bind to glucose
molecules
Once 3 glucose and 1 mannose trimmed, the
protein can be transported to the Golgi
 Endoplasmic reticulum quality control
(ERQC)
Very inefficient process with more than 80% of proteins never
achieving their fully folded state
The accumulation of unfolded, misfolded or damaged proteins
leads to ER stress, which is dealt with through protein
degradation
Ubiquitin-proteosome system: translocated into the
cytosol, tagged with ubiquitin, and degraded by
proteosomes
Autophagic-lysosomal system: aberrant protein
fragments degraded by lysosomes
When the misfolded proteins exceed ER degradation capacity,
the unfolded protein response is activated to eliminate
misfolded proteins and reduce the synthesis
Jiang etof
al new proteins
(2021) in Reticulum
Endoplasmic
the ER Quality Control in Immune Cells. Front
 ER Summary
ER part of the endomembrane system continuous with nuclear
envelope
Factory producing almost all the cell’s proteins and lipids
Rough ER primarily responsible for protein biosynthesis: secretory or
transmembrane
Smooth ER has diverse metabolic functions including lipid
biosynthesis, carbohydrate metabolism, calcium storage and drug
detoxification
Signal sequence and signal-recognition particle directs
ribosome and polypeptide chain to ER membrane
Chaperone proteins and enzymes in ER lumen, mediate protein
folding
N-linked glycosylation – signalling molecule in the folding process
 Transport mechanisms

Endocytosis: Internalisation of
nutrients or removal of plasma
membrane components

Exocytosis: Secretory pathway
outwards from the cell

Transport vesicles: Membrane
enclosed transport containers to
move cargo between
compartments
 Transport vesicles

3 main types of coated vesicles:
1) Clathrin-coated: mediate
transport from PM and
between endosomal and trans
Golgi network
2) COPI-coated: transport at
Golgi network (retrieval
pathway)
3) COPII-coated: transport from
ER to Golgi
 Transport vesicles

COPII COPI clathrin
coat coat coat
ER Exit sites Forward and Endosomal
concentrate reverse movement movement of
 Vesicular tubular clusters

Fusion of ER derived COPII vesicles into Vesicular
Tubular clusters
Move along microtubules towards Golgi Apparatus
COPI coated transport vesicles then bud off the vesicular
tubular clusters (ER retrieval signals to return ER
resident proteins to ER)
Golgi Apparatus

https://www.youtube.com/watch?v=rvfvRgk0MfA
 Golgi Apparatus

Multiple discrete compartments (cisternae)
Cis Golgi network (collection of fused vesicular tubular
clusters arriving from ER): modification of proteins, lipids
and polysaccharides begins
Golgi stack: further modification
Trans Golgi network: Sorting and distribution centre
Oligosaccharide processing in Golgi

Series of
enzymes within
each cisternae
perform different
functions in
removal or
addition of
sugars
Golgi Apparatus

Function
Complete the processing of
proteins and lipids received
from the ER
Packaging and transport to
eventual destinations (POST
OFFICE!)
 Summary

Correctly folded proteins in ER congregate at exit sites and
are packaged into COPII coated transport vesicles
Vesicles shed their coat and fuse with each other to form
vesicular tubular clusters
Clusters move on microtubule tracks to Golgi apparatus to
form cis Golgi network
Movement of cargo from cis Golgi network to the trans
Golgi network
Lipids and proteins are modified within each cisternae of
the Golgi apparatus
Protein sorting and distribution in trans Golgi network