Exocytosis and Endocytosis PDF

Summary

This document describes the processes of exocytosis and endocytosis, focusing on the movement of molecules within and out of cells. It explains the steps involved in these processes and the key proteins and structures involved. The article covers various aspects of the cellular transport process.

Full Transcript

MODULE 16

Exocytosis versus Endocytosis
endocytosis: brings molecules and other substances into the cell; associated with the
formation and budding of vesicles from the plasma membrane

exocytosis: the exit of molecules from the cell; associated with the fusion of vesicles
originating from intracellular organelles with the plasma membrane

Introduction to Exocytosis
transport of molecules out of the cells through the fusion of vesicles with the plasma
membrane

three classes of proteins from TGN to (1) lysosomes, (2) secretory vesicles, or (3)
immediate delivery to the cell surface

constitutive and regulated (as in specialized secreting cells)

in unpolarized cells, soluble proteins from the Golgi are carried by constitutive pathway to
the cell surface, unless these are retained as ER or Golgi residents, or sorted for the
lysosomes or regulated secretion

Steps of Exocytosis
four steps for constitutive exocytosis, five for regulated exocytosis:

trafficking: vesicle transport to the cell membrane on microtubules

tethering: vesicle’s contact with the cell membrane

docking: the vesicle and cell membranes attach; the two phospholipid bilayers merge

priming: only in regulated exocytosis

fusion: the vesicle membrane fully fuses with the cell membrane, and the result is the
release of vesicle contents into the extracellular space

Coated Vesicles
vesicle budding is mediated by protein coats, structures that cycle on and off membranes

coats have adaptor proteins that recognize cargo molecules and cage/coat proteins
assembling a lattice on the membranes to collect adaptor-cargo complexes

the coat deforms membranes into buds and selects the cargo
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coat proteins are recruited from the cytosol by Arf1/Sar1 small GTPases

three types of coats: clathrin-coated vesicles mediate transport between the Golgi and
plasma membrane; COPI- (retrograde) and COPII-coated vesicles mediate transport
between the ER and Golgi

Formation of Secretory Vesicles
some hormones, neuropeptides, and hydrolytic enzymes are synthesized as inactive
precursors; the proteolysis to active forms begins in the TGN and continues in the vesicles
and extracellular fluid after secretion

for proteins synthesized as pre-pro-proteins, the pre-peptide is the ER signal peptide
cleaved in rER

some signaling molecules are polyproteins that contain multiple copies of the same amino
acid sequence; some peptides are synthesized as parts of a single polyprotein, a precursor
for multiple products

Sorting Signals
polarized epithelial cells: proteins are sorted in the TGN to vesicles for different plasma
membrane domains

proteins for the basolateral membrane contain specific signals recognized by coat proteins

the apical plasma membrane is enriched in glycosphingolipids and GPI-anchored proteins
(that associate with glycosphingolipids in lipid rafts in the TGN)

Coat Assembly GTPases
ADP-ribosylation factor (ARF) GTPases: small GTPases, activated by guanine nucleotide
exchange factors (GEFs); inactivated by GTPase-activating proteins (GAPs)

ARFs recruit coat proteins, lipid-modifying enzymes, scaffold proteins

Sar1 regulates anterograde transport of proteins (ER → Golgi) through COPII vesicles

ARF1 regulates retrograde transport (Golgi → ER) through COPI vesicles; it also regulates
recruitment of clathrin

Pinching-off and Uncoating
dynamin binds to a forming bud on the membrane and assembles into a ring around the
neck of the bud
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the ring recruits other proteins that together with dynamin destabilize the membrane

once the vesicle is released from the membrane, the clathrin coat is lost

an uncoating ATPase peels off the coat

Transport, Tethering, Docking
vesicles traffic: along microtubules with kinesin/dynein motors; or myosin motors along
the actin network

transport vesicles have surface markers identifying their origin/cargo

target membranes have receptors for vesicle markers; the recognition step is controlled
by SNAREs and Rab GTPases

Rab effectors accomplish the tethering/docking of appropriate vesicles to the target
membranes

Fusion
at docking: proteins on the two lipid bilayers interact

for fusion, water is displaced from the surface of the two membranes

SNAREs are transmembrane proteins; there are vesicle membrane SNAREs (v-SNAREs)
and target membrane SNAREs (t-SNAREs)

when a v-SNARE interacts with a t-SNARE, the helical domains of one wrap around the
helical domains of the other to form trans-SNARE complexes; this provides energy to pull
the membranes together and squeeze water from the interface

Release of Secretory Vesicle Cargo
for regulated exocytosis, after docking, the secretory vesicles need to be primed to fuse
and release their contents

the fusion and release of cargo is triggered by a signal; the signal could be a chemical
messenger (e.g., a hormone leading to intracellular signals such as cytosolic Ca²⁺)

at nerve terminals, the signal is an action potential causing a Ca²⁺ influx; Ca²⁺ binding to
sensors triggers vesicles fusion with the plasma membrane and release of cargo to the
extracellular space
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Putting It Together
proteins are secreted by exocytosis in a constitutive or regulated fashion; secretory
vesicles bud from the TGN; secretory proteins condense during the formation and
maturation of secretory vesicles

there are four steps in constitutive exocytosis and five in regulated exocytosis; in
regulated exocytosis, in addition to trafficking, tethering, docking, and fusion, there is
priming (i.e., molecules are stored in vesicles until a signal is received)

in polarized cells, the transport from the TGN to the plasma membrane selectively delivers
different sets of molecules to the different domains of the plasma membrane

transport vesicles bud from coated regions of the donor membrane; the coat helps to
collect specific cargo and drives the formation of the vesicle; the process is regulated by
small GTPases (e.g., Sar1, ARF)

the docking/tethering requires the small GTPases Rab that bind to specific effectors, and
the fusion requires v-SNAREs and t-SNAREs to form trans-SNARE complexes

How to Kill Cancer Cells

degranulation: release of antimicrobial cytotoxic or other molecules from secretory
vesicles

utilized by granulocytes and mast cells

also used by lymphocytes such as natural killer (NK) cells and cytotoxic T cells to
destroy invading microorganisms

cytotoxic T cells and NK cells release molecules like perforin and granzymes by a
process of directed exocytosis to kill infected target cells (or cancer cells)