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MB207 Molecular Cell Biology

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Title: MB207 Molecular Cell Biology


1
MB207 Molecular Cell Biology
  • Intracellular Vesicular Traffic
  • Outline
  • Principles of vesicular traffic
  • Transport from ER through Golgi Apparatus
  • Transport from trans Golgi network to lysosomes
  • Transport into cell from plasma membrane
    endocytosis
  • Transport from trans Golgi network to the cell
    exterior exocytosis

2
Endocytosis and exocytosis
3
Vesicular Transport
  • Process in which membrane-enclosed transport
    vesicles transport proteins from one
    membrane-enclosed compartment to another.
  • Shape spherical, larger irregular-shaped
    vesicles.
  • Proteins do not move across the lipid bilayer of
    any membranes. But only move between
    topologically equivalent compartments (eg. Lumen
    of ER to lumen of Golgi to exterior of the cell).

Principles of vesicular transport
  1. A protein-coated membrane-enclosed transport
    vesicle buds off from the membrane of donor
    compartment carrying a variety of specifically
    selected cargo molecules.
  2. Transport vesicle binds to the target compartment
    and fuse with the membrane of the target
    compartment.
  3. Cargo molecules transfer into lumen of the target
    compartment and inserting the vesicular membrane
    components into the target compartment membrane.
  • Overview of vesicle transport
  • Budding
  • Uncoating
  • Transport
  • Docking
  • Fusion

4
Question 1 How do transport vesicles form?
(Budding) Question 2 What deforms
the membrane to cause a vesicle form?
(A planar phospholipid lipid bilayer wants
to remain flat. But, the small transport vesicles
that are seen in cells are small and highly
curved. It is this protein coat that causes the
membrane to deform and form a transport vesicle.)
Coat proteins assemble on the membrane surface
and curve the membrane into a vesicle
5
- new synthesized ER molecules are sorted and delivered to either other organelles or the cells plasma membrane - molecules from exterior of the cell are taken up into the cell and trafficked to an appropriate intracellular compartment
  • exchange of membrane material and vesicular
    lumenal contents, each organelle maintains its
    own highly specialized characteristics.

1. Helps select the cargo by concentrating specific membrane proteins into specialized membrane patches that give rise to the vesicle membrane. 2. Assembly of the coat proteins into curved basket-like lattices deforms the membrane in a manner that helps form vesicles of uniform size
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Three types of protein-coated vesicles
(A) Clathrin-coated vesicles (B) COPI-coated vesicles (C) COPII-coated vesicles
-mediate transport from 1. The plasma membrane to early endosomes 2. Immature secretory vesicles to golgi apparatus 3. Golgi apparatus to late endosomes -mediate transport from 1. Early Golgi back to ER 2. Golgi apparatus to plasma membrane 3. Between various Golgi cisternae -mediate transport from 1. ER to the Golgi apparatus
9
  • 3 main types of coated vesicles (each type use
    for different transport steps in the cell)
  • COP II-coated (Sec complex)
  • Move material from ER to the cis-Golgi complex (5
    protein complex, including SARI GTPase)
  • COP I-coated (7 different COP subunits)
  • Retrograde movement from Golgi cisternae to ER (8
    protein complex, including ARF GTPase)
  • Clathrin-coated (Clathrin adaptin)
  • Move from the TGN (trans Golgi network) to
    endosome
  • Move from plasma membrane (endocytosis) to
    endosome
  • Golgi to lysosome

10
  • Clathrin-coated vesicles
  • Major proteins in clathrin-coated vesicle are
    clathrin and adaptin
  • Each clathrin subunit composes of heavy and light
    chain
  • Three clathrin subunits form a three-legged
    structure called triskelion.
  • Adaptin bind to both clathrin and transmembrane
    cargo receptor, which in turn bind to the target
    cargo
  • As coated bud grows, a GTP-binding protein,
    dynamin, assemble around the neck of each bud.
    Hydrolysis of GTP will regulate the speed of the
    pinching-off process for membrane fusion.
  • Shortly after vesicle formed, energy required to
    remove clathrin coat

Clathrin triskelion ( 3 legged structure)
11
The assembly and disassembly of a clathrin coat
  • Curvature was introduced into the membrane which
    leads to the formation of uniformly sized coated
    buds.
  • The adaptins bind both clathrin trikelions and
    membrane-bound cargo receptors, thereby mediating
    the selective recruitment of both membrane and
    cargo molecules into the vesicle.
  • The pinching-off of the bud to form a vesicle
    involves membrane fusion, facilitated by the
    GTP-binding protein dynamin which assembles
    around the neck of the bud.
  • The coat of clathrin-coated vesicles is rapidly
    removed shortly after the vesicle forms.

12
Small GTPases regulate budding
  • 2 conformational states
  • GDP (off)
  • GTP (on)
  • SarI proteins is a coat recruitment GTPase.
  • Inactive, soluble SarI-GDP binds to a GEF
    (called SecI2) in the ER membrane, causing SarI
    to release its GDP and bind to GTP.
  • A GTP-triggered conformational change in SarI
    exposes its fatty acid chain, which inserts into
    the ER membrane.
  • Membrane-bound, active SarI-GTP recruits COPII
    subunits to the membrane. This causes the
    membrane to form a bud which includes selected
    membrane proteins.
  • A subsequent membrane-fusion event pinches off
    and releases the coated vesicle.

13
Transport vesicle docking
  • Specificity in targeting ensures that membrane
    traffic proceeds in an orderly way.
  • Therefore, transport vesicles must be highly
    selective in recognizing the correct target
    membrane with which to fuse.
  • ? transport vesicles display surface markers that
    identify them according to their origin and type
    of cargo while target membrane display
    complementary receptors that recognize the
    appropriate markers.
  • The recognition step is thought to be controlled
    mainly by two classes of proteins
  • i) SNAREs (Soluble NSF Attachment Protein
    Receptor)
  • - central role both in providing specificity
    and in catalyzing the fusion of
  • vesicles with the target membrane.
  • ii) Rabs (GTPase)
  • - work together with other proteins to
    regulate the initial docking and
  • tethering of the vesicle to the target
    membrane.

14
SNAREs
  • compartment identifiers - required for vesicle
    docking and fusion
  • transmembrane protein that exist as
    complementary sets to ensure correct vesicle
    targeting
  • i) vesicle membrane SNAREs, v-SNAREs
  • ii) target membrane SNAREs, t-SNAREs
  • Complementary sets of v-SNAREs and t-SNAREs
    contribute to the selectivity of
    transport-vesicle docking and fusion
  • The v-SNAREs are packaged together with the coat
    proteins during the budding of transport vesicles
    from the donor membrane and bind to complementary
    t-SNAREs in the target membrane.
  • After fusion, the v- and t-SNAREs remain
    associated in a tight complex.
  • The complexes have to be dissociated before the
    t-SNAREs can accept a new vesicle or the v-SNAREs
    can be recycled to the donor compartment for
    participation in a new round of vesicular
    transport.
  • Different v-SNAREs can be packaged with
    different cargo molecules when leaving the donor
    compartment.

15
Dissociation of SNARE pairs
  • Complexes have to be disassembled before the
    SNAREs can mediate new rounds of transport.
  • NSF protein cycles between membranes and the
    cytosol and catalyzes the disassembly process.
    NSF (an ATPase) uses the energy of ATP hydrolysis
    to solubilize and facilitates refolding of
    denatured proteins.
  • After the v-SNAREs have mediated the fusion of a
    vesicle on a target membrane, the NSF binds to
    the SNARE complex via adaptor proteins and
    hydrolyzes ATP to interfere the SNAREs apart.

16
Coiled-coil SNARE complexes
  • This complex are formed hold the vesicle close to
    the target membrane. Numerous noncovalent
    interactions between SNARE protein stabilize the
    coiled-coil structure.
  • The SNAREs responsible for docking synaptic
    vesicles at the plasma membrane of nerve terminal
    consists of three proteins.
  • The v-synaptobrevin and t-SNARE syntaxin are
    both transmembrane proteins and each contributes
    one a-helix to the complex. The t-SNARE Snap25 is
    a peripheral membrane protein that contributes
    two a-helices to the four-helix bundle.
  • Trans-SNARE complexes always consists of four
    tightly intertwined a-helices, three contributed
    by t-SNARE and one by a v-SNARE.

17
Rab protein Docking of transport vesicle
  • Rab proteins are monomeric GTPases.
  • Rab proteins facilitate and regulate the rate of
    vesicle docking and the matching of v-SNAREs and
    t-SNAREs.
  • Rab proteins cycle between a membrane and the
    cytosol. In their GDP-bound state, they are
    inactive. They are active in the cytosol and in
    their GTP-bound state .
  • Rab protein hops onto the vesicle during
    budding.
  • SNARE proteins are tightly capped or turned
    off by association with other proteins.
  • Rab protein are specifically distributed through
    the secretory pathway.

18
Subcellular locations of some Rab proteins
19
Fusion of membranes mediated by SNAREs
Tight SNARE pairing forces lipid bilayers into
close apposition so that H2O are expelled from
the interface.
Lipid of 2 interaction leaflets of the barriers
then flow between the membrane to form a
connecting stalk.
Lipid of the other 2 leaflets then contact each
other forming a new bilayer, which widens the
fusion zone (hemifusion).
Split of the new bilayer completes the fusion
reaction.
20
Entry of enveloped viruses into cells HIV
21
Transport from the ER through the Golgi apparatus
  • Transport process from ER to Golgi apparatus and
    from Golgi apparatus to the cell surface and
    elsewhere.
  • ? the proteins pass through a series of
    compartments where they are successively
    modified.
  • Transport vesicles select cargo molecules and
    move them to the next compartment in the pathway,
    while others retrieve escaped proteins and return
    them to the previous compartment where they
    normally function.
  • Golgi apparatus ? major site of carbohydrate
    synthesis as well as
  • sorting and
    dispatching station for the products
  • of ER.
  • Most proteins and lipids (acquired their
    appropriate oligosaccharides in the Golgi
    apparatus) are recognized in other ways for
    targeting into the transport vesicles going to
    other destinations.

22
The recruitment of cargo molecules into ER
transport vesicles
  • By binding to the COPII coat, membrane and cargo
    proteins become concentrated in the transport
    vesicles as they leave the ER.
  • Membrane proteins are packaged into budding
    transport vesicles through the interactions of
    exit signals on their cytosolic tails with the
    COPII coat.
  • Some of the membrane proteins trapped by the
    coat in turn function as cargo receptors, binding
    soluble proteins in the lumen and helping to
    package them into vesicles.
  • Unfolded or imcompletely assembled proteins are
    bound to chaperones and are thereby retained in
    the ER compartment.

23
Protein leave ER in COPIl -coated transport
vesicles
  • Vesicular tubular clusters are the structures
    formed when ER-derived vesicles fuse with one
    another. The clusters are relatively short-lived
    because they quickly move along microtubules to
    the Golgi apparatus.
  • COPII-coated vesicles leave the ER, uncoat and
    begin to fuse with one-another to form
    vesicular-tubular clusters.
  • These clusters associate with motor proteins
    that drag them along microtubules in an
    ATP-dependent process.
  • Meanwhile, retrograde transport removes certain
    components, purifying and concentrating the
    secretory cargo further.

24
Retrieval of ER resident proteins is
receptor-mediated
  • Escaped ER resident proteins are retrieved from
    the Golgi by KDEL receptors that recognize
    specific retrieval signals in ER proteins.
  • The KDEL receptor present in the vesicular
    tubular clusters and the Golgi apparatus,
    captures the soluble ER resident proteins and
    carries them in COPI-coated transport vesicles
    back to the ER,
  • Upon binding its ligands in this low pH
    environment, the KDEL receptor may change
    conformation, so as to facilitate its recruitment
    into budding COPI-coated vesicles.

25
A model for the retrieval of ER resident proteins
  • The retrieval of ER proteins begins in vesicular
    tubular cluster and continues from all
    environment of the ER, the ER resident proteins
    dissociate from the KDEL receptor, which is
    returned to the Golgi apparatus for reuse.
  • KDEL-receptors bind to KDEL-bearing proteins in
    the low pH environment of the Golgi and release
    that Cargo in the neutral pH of the ER.
  • pH probably alters KDEL receptor conformation -
    regulating cargo binding and inclusion in COPI
    vesicles.

26
Golgi apparatus
  • The Golgi complex is typically disc-shaped with a
    stack of 4 - 6 cisternae.
  • Individual stacks may be interconnected in a
    large complex.
  • Golgi complex processes protein (glycosylation
    sulfation) and synthesizes some polysaccharides.
  • Functionally distinct compartments, arranged from
    cis face (closest to ER) to trans (exit) face
  • Cis-Golgi network sorts new proteins, separating
    those for return to the ER from those to pass to
    the next Golgi station
  • Trans-Golgi network sorts proteins into vesicles
    bound for specific destinations i.e. lysosomes,
    secretory vesicles or the cell surface.

27
Functional compartmentalization of the Golgi
apparatus
  • Post-translational modifications in the Golgi
  • Specific modifications occur in specific
    subcompartments, because modifying enzyme
    localization is tightly controlled.
  • The state of protein modification can identify
    how far a protein has proceeded in transport.

28
  • Two models for movement

29
Two Models For Cis to Trans-Golgi Progression
Traditional Model - Golgi is a static organelle.
Secretory proteins move forward in small
vesicles. Golgi resident proteins stay where
they are.
Radical Model - Golgi is a dynamic structure.
It only exists as a steady-state representation
of transport intermediates. Secreted molecules
move ahead with a cisterna. Golgi resident
proteins move backward to stay in the same
relative position.
30
Functions of Golgi apparatus
  • Sorting and processing of proteins and lipids
    coming from ER
  • Example mannose 6-phosphate is added to proteins
    that are destined for lysosomes
  • 2. Oligosaccharide synthesis
  • Many protein from ER are glycosylated during
    their transit through the Golgi
  • Pectin and hemicellulose for the cell wall of
    plants proteoglycans for the extracellular
    matrix in animal.

31
Transport from trans Golgi network to lysosomes
  • Lysosomes are organelles filled with hydrolytic
    enzymes that are used for controlled
    intracellular digestion of macromolecules
  • Turnover of cells macromolecules
  • Extracellular macromolecules from other cells
  • Bacteria (macrophages)
  • The interior of a lysosome is acidic (pH 4.6)
  • Unique enzymes of lysosomes are adapted to low pH
  • Advantages
  • Digestive reactions more rapid at low pH
  • Leaked lysosomal enzymes do not destroy the cell
    (pH 7 to 7.3)
  • Low pH is maintained by a ATPase
  • pH decreases from ER to Golgi to endosome

32
Three pathways to degradation in lysosomes
  • Lysosome can be small (25 to 50 nm) or large
    (over 1 µm).
  • Multiple paths to deliver material to lysosomes.
  • Each pathway leads to intracellular digestion of
    materials derived from different source
  • i) Through Late endosome - Developed from
    endosomes, an endocytotic vesicle derived from
    the plasma membrane.
  • ii) Through Phagosome - A vacuole formed around a
    particle absorbed by phagocytosis by the fusion
    of the cell membrane around the particle.
  • iii) Through Autophagosome - A membrane-bound
    body occurring inside a cell and containing
    decomposing cell organelles.
  • Materials delivered to lysosome may be degraded
    in the lysosome or expelled (exocytosis)

33
Transport of newly sythesized lysosomal
hydrolases to lysosomes
  • Lysosomal proteins are synthesized in the RER and
    transported to the Golgi complex, just like
    secreted proteins. However, enzymes in the Golgi
    recognize and tag lysosome-bound proteins by
    phosphorylating the mannose residues.
  • The mannose-6-phosphate groups are recognized by
    the mannose-6-phosphate receptors (MPR) at the
    trans Golgi network and hence the recognition
    signals for packaging.
  • At late endosome / lysosome, the protein will
    dissociate from the receptors and the receptors
    can then be recycled.

34
Endocytosis Transport into the cell from the
plasma membrane
  • Internalization of external material including
    proteins located on the plasma membrane
  • Purpose Cellular uptake of macromolecules
    usually en route to the lysosome. This could
    include the ingestion of metabolites, lipids like
    cholesterol through LDL and the LDL receptor or
    iron via the transferring receptor. Other reasons
    for endocytosis include the termination of cell
    surface events (i.e. signaling).
  • Types of endocytosis
  • Phagocytosis or cellular eating Ingestion of
    large particles such as microorganisms or dead
    cells (usually gt250 nm in diameter) by phagocytes
    such as macrophages neutrophils.
  • Pinocytosis or cellular drinking Fluid-phase
    endocytosis primary for the uptake of fluids and
    solutes (100 nm in diameter).

35
  • Mechanisms of Endocytosis
  • Similar to vesicle budding from the ER.
  • Coat protein clathrin is primarily responsible
    for the majority of vesicular traffic between the
    trans-golgi network and plasma membrane in both
    directions.
  • Another type of vesicles called caveolae can also
    be used for pinocytosis. Caveolae collect cargo
    by the lipid composition of the caveolar membrane
    rather than the protein coat.

Formation of clathrin coated vesicles from the
plasma membrane
36
Endocytotic pathway from the plasma membrane to
lysosomes
  • Maturation from early to late endosomes occurs
    through the formation of multivesicular bodies,
    which contain large amounts of invaginated
    membrane and internal vesicles.
  • These bodies move inward along microtubules, and
    recycling of components to the plasma membrane
    continues as the bodies move.
  • The multivesicular bodies gradually turn into
    late endosomes, either by fusing with each other
    or by fusing with pre-existing late endosomes.
  • The late endosomes no longer send vesicles to the
    plasma membrane but communicate with the trans
    Golgi network via transport vesicles, which
    deliver the proteins that will convert the late
    endosome into a lysosome.

37
Receptor-mediated endocytosis fate of the
receptors
38
An example of receptor-mediated endocytosis
cholesterol uptake
  • Low density lipoproteins (LDL) is a storage form
    of cholesterol and the primary vehicle for
    cholesterol transport in the blood.
  • Cells need cholesterol for its function and
    endocytose these LDL particles to bring them into
    the cells
  • Cell surface LDL receptor binds to LDL.
  • The cytosolic portion of the LDL receptor
    associates with a specific set of clathrin
    adapters and nucleates the binding of a few
    clathrin triskelions to form a coated pit.
  • As more receptors enter the coated pit, more
    adaptors and clathrin is recruited to form a
    coated vesicle.
  • The LDL-containing coated vesicles uncoat and
    fuse with the early endosome.
  • The receptor disengages the LDL particle due the
    pH change and is recycled to the plasma membrane.
  • The LDL particles are transported to the
    lysosomes where it is degraded and utilized.

39
Normal and mutant LDL receptors
  • LDL receptor proteins binding to a coated pit in
    the plasma membrane of a normal cell.
  • A mutant cell in which the LDL receptor proteins
    are abnormal and lack the site in the cytoplasmic
    domain that enables them to bind to adaptins in
    the clathrin-coated pits.
  • Such cells bind LDL but cannot ingest it.
    Increased risk of a heart attack caused by
    atherosclerosis.

40
Transport from the trans Golgi netowrk to the
cell exterior Exocytosis
  • 2 forms of secretory pathways for proteins,
    lipids, or modified polysaccharides
  • Constitutive secretion
  • This is a continuous pathway for the synthesis
    and export of proteins, such as those of the ECM
    (extracellular matrix) or plasma membranes.
    Operates in all cells.
  • Regulated secretion
  • In specialized secretory cells. Vesicles
    (secretory granules) are prepared and stored for
    export in response to a signal. e.g. release of
    hormones, histamine by Mast cells, digestive
    enzymes neuro-transmitters at the synapses.

41
Constitutive Secretory pathway Regulated Secretory pathway
Nonselective, default pathway- signal is not required Contents are released immediately upon contact with the plasma membrane. Secretory vesicles, released on demand (eg. Hormones, neurotransmitters, digestive enzymes).
  • Properties of regulated exocytosis
  • Proteins are typically very dense (concentrated).
  • Proteins are selected by signal patches.
  • Pre-pro-proteins and polyproteins (delayed
    activation) eg. Preproinsulin activated in
    secretory granules, trysinogen activated after
    secretion.
  • SNARE catalyzed fusion with plasma membrane is
    inhibited until appropriate signal is received
    (eg. Hormone, electrical excitation).

42
Formation of secretory vesicles
  • Secretory proteins become aggregated and highly
    concentrated in secretory vesicles by two
    mechanisms
  • They aggregate in the ionic environment of the
    trans Golgi network (often the aggregates become
    more condensed as secretory vesicles mature and
    their lumen becomes more acidic.
  • Excess membrane and lumenal content present in
    immature secretory vesicles are retrieved in
    clathrin-coated vesicles as the secretory
    vesicles mature.
  • Secretory vesicles bud from the TGN (with
    clathrin coats), uncoat, move near the plasma
    membrane, tether, dock, and fuse using PM
    specific proteins.

43
Polarized cells direct proteins from the trans
Golgi network to the appropriate domain of the
plasma membrane
  • Polarized cells cell with two compositionally
    distinct and different plasma membranes, the
    apical and basolateral plasma membrane.
  • The two different membrane domains are separated
    by a molecular fence (tight junctions) which
    prevents proteins and lipids from diffusing
    between the two domains, so that the compositions
    of the two domains are different.
  • The plasma membrane of the nerve cell body and
    dendrites resembles the basolateral plasma
    membrane domain of a polarized epithelial cell,
    whereas the plasma membrane of the axon and its
    nerve terminals resembles the apical domain of an
    epithelial cell.
  • The different membrane domains of both
    epithelial cell and the nerve cell are separated
    by a molecular fence, consisting of a meshwork of
    membrane proteins tightly associated with the
    underlying actin cytoskeleton (tight
    junction/axonal hillock).

44
The formation of synaptic vesicles
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