Moving Proteins into Membranes & Organelles PDF

Summary

This document details the various methods of protein targeting and translocation within cellular organelles. It explores concepts like signal sequences and the involvement of the endoplasmic reticulum and other organelles during the process. The document also goes into the details of how these mechanisms are used in different aspects of cellular functions.

Full Transcript

Moving Proteins into
Membranes & Organelles
 Protein Sorting
how proteins are targeted to & translocated across
the membranes of different cellular organelles
a typical mammalian cell contains thousands of
proteins
– may be localized to:
the cytosol
within organelles
embedded in organellar membranes
– may also be meant for export from the cell or for positioning
in the plasma membrane
 Protein targeting or sorting
Two processes are involved
1. signal-based targeting
2. vesicle- based trafficking

- For membrane proteins, targeting leads to
insertion of the protein in the lipid bilayer

-For water soluble protein, targeting leads to
translocation of the entire protein across the
membrane into the aqueous interior of the organelle
 How are Proteins Sorted?
Two general, but different, processes are involved:

1. Nonsecretory Pathway: Targeting to organellar membranes
& transport across organellar membranes
– refers to the sorting of proteins synthesized on free
ribosomes
– localized to the cytosol, peroxisomes, mitochondria,
chloroplasts & nucleus

2. Secretory Pathway: Targeting to the plasma membrane &
export from the cell
– refers to the sorting of proteins synthesized on bound
ribosomes
– these proteins may be excreted, localized to the ER,
plasma membrane, Golgi apparatus or to lysosomes
Eukaryotic Protein-sorting Pathways

Non secretory pathway
 How are Proteins Targeted?
information needed to target proteins to particular
organelles is encoded within the protein in a sequence of
about 20-50 amino acids
– called targeting sequences; these are also called signal
sequences or signal peptides
each organelle carries receptors
that bind to only one type of signal
sequence

bound receptor then transfers the
polypeptide to a translocation
channel

protein is then passed through the lipid
bilayer, by coupling the translocation to an
energetically favorable process
example: ATP hydrolysis
Four Considerations in Protein-Targeting
Mechanisms

1. What is the nature of the signal sequence and what
makes it different from other signal sequences?

2. What is the receptor for the signal sequence?

3. What is the structure of the translocation channel, and
do folded or unfolded proteins pass?

4. What is the source of energy that drives unidirectional
transfer across the membrane?
 Secretory Pathway

Soluble, secreted
proteins whose final
destination is localization
to the plasma membrane,
lysosomes, or secretion
from the cell use the
secretory pathway
 Signal Sequence Targets Nascent
Secretory Proteins to the ER
After synthesis begins on free
ribosomes in cytosol, 16-30 aa ER
signal sequence directs ribosome to
ER membrane (making it RER)
ER Signal sequence:
– found at N-terminus

– typically cleaved before mature
protein formed, often prior to
separation of polypeptide from
ribosome

– contain >1 + charged aa next to a
core of 6 -12 hydrophobic aa

– hydrophobic core critical for
binding to receptor and
translocation
 Co-translational Translocation

translocation of the nascent polypeptide occurs before
the protein is fully synthesized
fully formed protein cannot enter the ER
typically a ~70 aa long sequence (including signal
sequence) is formed before translocation begins
mechanism of cotranslational translocation requires 2
components:
Signal-Recognition Particle (SRP)

SRP Receptor on the ER membrane
 Signal-Recognition Particle (SRP)
SRP consists of:
300 nt RNA molecule bound to 6
different polypeptides (P54, P19,
P68, P72,P9 & P14)
role of RNA is not fully
understood
– may serve as scaffold to support
the proteins
– May also have an active role in
the process

P54 recognizes and binds to the
nascent protein via the signal
sequence

P9 & P14 bind to the ribosome

P68 and P72 are required for
translocation

P19 is required for attachment of
P54 to the rest of the particle
 SRP Receptor
Integral membrane protein
Consists of 2 subunits: large α subunit & smaller β subunit
– α subunit interacts w/ the SRP & binds GTP
– β subunit is embedded in the membrane
 Translocon: translocation channel
analogous to chemical-gated channels (transmembrane protein)
consists of the Sec61 complex of proteins
closed when it is not bound to SRP/SRP receptor/ribosome complex
open once it binds to the complex
permits signal sequence (& polypeptide) to enter
signal sequence comes in contact w/ aa of the Sec61 complex
Co-translational Translocation Across the
ER membrane
 Post-translational Translocation
Most eukaryotes: co-translational translocation used for
secretory proteins to enter ER
In yeast (and other eukaryotes) some proteins enter ER
lumen after translation has completed
Unidirectional
translocation involves:
– Sec61 translocon
– Sec63 complex
– BiP (chaperone)
– do not use the
SRP or SRP
receptor
 Export of Bacterial Proteins

Yersinia pestis is a Gram
negative bacteria that causes
bubonic plague

injects disabling proteins into
macrophages by type III
secretion apparatus (T3SS)

incapacitated macrophages
cannot destroy the bacteria, thus
permitting them to increase in
numbers
 Membrane Proteins:
Insertion of Proteins into the ER Membrane
Each membrane protein has a unique orientation with
respect to the phospholipid bilayer
– ER, golgi, lysosomes, plasma membrane
Integral proteins that are synthesized in RER remain
embedded in membrane as they move to final destination
– Orientation along the way is preserved
– ie: some segments face cytosol, other face opposite direction all
the way through
Therefore, orientation of membrane proteins are
determined in the ER membrane

Topology of an integral membrane protein refers to:
– the orientation of its membrane-spanning segments
– the number of such segments
 ER Membrane Proteins
Integral proteins are categorized in topological classes
– Types I, II and III are single-pass proteins
– Type IV are multi-pass proteins
– GPI linked proteins are tethered to membrane w/ phospholipid
 Type I Proteins
N-terminal signal sequence, that is cleaved
N terminus in exoplasmic face & C terminus in cytosol
stop-transfer anchor sequence:
– 22aa hydrophobic sequence that stops translocation
– lateral movement across translocon wall inserts protein in membrane
 Type II Proteins

lack a cleavable N-terminus
contain a signal-anchor
sequence
– acts as both ER signal
sequence & membrane-
anchor sequence
N terminus faces the cytosol
 Type III Proteins

lack a cleavable N-terminus
contain a signal-anchor sequence that acts as both an ER signal
sequence and a membrane-anchor sequence
N terminus faces the exoplasmic face
 Type IV Proteins

Type IV A Proteins
N-terminus in the cytosol
Examples:
– the GLUT transporters
– most ion channels, including ABC superfamily transporters

Type IV B Proteins
N-terminus extends into the exoplasmic face
Examples:
– the G-protein coupled receptors
Arrangement of Topogenic Sequences in
ER Membrane
 Lipid-anchored Proteins
final class of membrane
protein

do not have hydrophobic
membrane-spanning
domains

instead are anchored by
amphipathic phospholipids

anchoring molecule is GPI
glycosylphosphatidylinositol
– called GPI linked
proteins
 Protein Modifications
Proteins may be modified in the ER, Golgi &
secretory vesicles

Four principal modifications before they reach their
final destination:

Glycosylation in the ER & Golgi

Formation of disulfide bonds in the ER

Proper polypeptide folding & assembly of multi subunit proteins in the ER

Proteolytic cleavages in the ER, Golgi & secretory vesicles
 Glycosylation
Principal chemical modification to most proteins

Carbohydrates may be added to:
– the OH group of serine and threonine
named O-linked oligosaccharides
– the NH2 group of asparagine
most common
Named N-linked oligosaccharides

Why glycosylation?
– Promotes proper folding
– Promotes stability

13-16: N-linked oligosaccharides
Addition & Initial Processing of N-linked
Glycosylation in ER
 Disulfide Bonds

these covalent bonds help stabilize tertiary & quaternary
structures
Protein Disulfide Isomerase (PDI)
– Enzyme that catalyzes addition of disulfide bonds
– found in the lumen of the ER of all eukaryotic cells

Only proteins that enter the lumen of the ER contain
disulfide bridges:
– disulfide bonds only found in secretory proteins & exoplasmic
domains of membrane proteins
– proteins synthesized on free ribosomes are stabilized by other
means
Formation & Rearrangement of Disulfide
Bonds by PDI
 Folding
Folding is facilitated by chaperones and other ER
proteins.

– Lectins are carbohydrate-binding proteins
Bind selectively to N-linked glycosylated proteins
eg) calnexin, calreticulin

– Peptidyl-propyl isomerases
Enzymes that accelerate rotation about peptidyl-
prolyl bonds in unfolded segments
What about Improperly Folded Proteins?
Misfolded proteins cannot exit the lumen of the RER
Activation of the unfolded protein response:
– Accumulation of unfolded
proteins within the lumen
of the RER will cause the
synthesis of proteins that
assists folding
– Ire1: ER membrane
protein that exists that is a
key participant in the
unfolded protein response
– Hac1: TS factor that turns
on TS of genes encoding
several protein-folding
catalysts
 Hereditary (Familial) Emphysema
Illustrates detrimental effects that can result from
misfolding of proteins in the ER
Hereditary point mutation of a blood component called
alpha-1-antitrypsin (AAT)
– normally secreted by hepatocytes & macrophages
– absence results in the loss of a lung structural protein, elastin.

– The mutant AAT does not fold properly and is not exported from
the cell
– Mutant AAT can not inhibit elastase, resulting in destruction of
elastin

Wild type AAT binds to and inhibits both trypsin &
elastase
– Elastase breaks down elastin
 Degradation of Misfolded Proteins
misfolded proteins may also be degraded
they are exported through the translocon to the cytosol
typically broken down by ubiquitin/ proteasome
associated pathways

Figure 3-29:
Ubiquitin & proteasome
mediated proteolysis
 Sorting of Proteins to Mitochondria
Mitochondrial proteins may be synthesized on ribosomes
found in the mitochondrial matrix, but the majority of the
proteins used in mitochondria are synthesized on free
ribosomes in the cytosol and imported
Mitochondrial destined proteins from cytosol have targeting
sequence named MTS:
– Found at N-terminus
– 20-50 aa long
– Amphipathic: R & K aa on one end; hydrophobic aa on the other
– MTS is cleaved in the matrix

Import into the Mitochondrion:
– only an actively respiring mitochondrion can import proteins
proton-motive force is required for translocation
– only unfolded proteins can cross mitochondrial membranes
 Mitochondrial Import
protein maintained in unfolded
state by bound Hsc70 chaperone
targeting sequence binds to
Tom20/22
– OMM import receptor
protein transferred to Tom40
– OMM general import pore
protein binds to Tim23/17
– IMM pore
translocated to matrix at contact
sites b/w IMM & OMM
protein w/ matrix chaperone
Hsc70 localized to pore w/ Tim44
once protein is in matrix, signal
sequence cleaved by MPP
final protein folding requires help
of matrix chaperonins
Targeting to Sub-Mitochondrial Compartments

Proteins have
different signal
sequences &
pathways that
target them to
different
mitochondrial
areas
 Peroxisomal Proteins
Peroxisomes: single-membrane bound organelles that
contain oxidases and catalase

all peroxisomal proteins are synthesized on cytosolic
free ribosomes

Peroxisomal proteins are imported in a folded state
Most require a C-terminal target sequence called PTS1
(peroxisomal targeting sequence)
– PTS1 contains a SKL (serine-lysine-leucine) motif

A few require N-terminal PTS2

requires ATP
Mechanism of Translocation into Peroxisome

Protein with PTS1
sequence binds to a free
cytosolic receptor, Pex5.
Bound Pex5 interacts with
the membrane-bound
receptor Pex14.
Bound Pex5 is then
transferred to a complex of
transmembrane proteins
that induce translocation.
Unbound Pex5 is returned
to the cytosol.

PTS2 uses Pex7 instead
 Zellweger Syndrome
rare, congenital disorder
Autosomal recessive mutation involving defective peroxisomes
Transport of peroxisomal proteins is impaired, peroxisomes are
fewer in number and do not work
Lead to severe impairment of many organs
– liver, kidneys & brain

Common features include:
– enlarged liver, prenatal growth failure
– high blood levels of iron & copper
– vision disturbances
– at birth: lack of muscle tone, an inability to move (suck, swallow),
unusual facial characteristics, mental retardation, seizures, jaundice
& GI bleeding
No cure or treatment for Zellweger syndrome
– Most infants do not survive past first 6 months
– usually succumb to respiratory distress, GI bleeding or liver failure
 Transport Across the Nuclear Membrane
Nucleus surrounded by two membranes: each membrane consists of
phospholipid bilayer and proteins.
Molecules of all sizes enter and leave the nucleus via Nuclear Pore
Complexes (NPC)

NPCs are large
allowing for
bidirectional transport:
– passive diffusion of
small molecules,
ions
– selective energy-
dependent transport
of nuclear proteins,
RNAs, and RNPs
(>9nm)
 NPC Structure

NPC composed of different nucleoporin proteins attached to nuclear
basket on nuclear side, cytoplasmic filaments on cytoplasmic side,
and central transporter through the middle
 FG Nucleoporins and Transporters
FG nucleoporins contain many Nuclear transporters
short hydrophobic FG repeats and have hydrophobic
long hydrophilic regions regions on their surface
(dark blue dots) that bind
reversibly to FG-domains
in FG-nucleoporin.
Form molecular
sieve that allows
H2O-soluble
molecules
through, but not
macromolecules

FG = phenylalanine and
Glycine
 Import into the Nucleus

Proteins synthesized in the cytosol and meant for use in the
nucleus enter via the NPC
Such proteins contain a
nuclear-localization signal
(NLS) that directs their
translocation into nucleus
– NLS is a short amino acid
sequence often near the
protein’s C-terminus
Importins are the transport
proteins that bind the NLS
and transport the NLS
containing cargo into the
Immunofluorescence shows fusing a
nucleus
NLS to a cytoplasmic protein causes
the protein to enter the nucleus.
Mechanism for Nuclear Import

Free cytosolic importin
binds NLS of cargo protein
Complex moves through
NPC, interacting w/
nucleoporins
Once in nucleoplasm,
conformational change of
importin (via interaction w/
Ran-GTP) results in lower
affinity for NLS and
release of cargo
Transporters are recycled
 Export out of the Nucleus
Similar mechanism used to export proteins, tRNAs and
ribosomal subunits from the nucleus to the cytoplasm.
Exportin: transport cargo proteins containing nuclear-export
signals (NES) out of the nucleus
Export mechanism:
In nucleoplasm, exportin
binds to NES of cargo
protein and Ran-GTP
Complex diffuses
through NPC via
interactions w/
nucleoporins
Dissociation from
complex after Ran-GTP
hydrolysis
Transporters recycled
 Summary:
Import & Export of Proteins through NPC
Cargo proteins bear an NES or NLS, translocate thru NPC
– Some proteins shuttle b/w nucleus & cytoplasm, and must have
both NLS & NES
Both processes require Ran, a G protein that exists in
different conformations when bound to GTP or GDP
 GTP Switch Proteins
Guanine nucleotide-binding proteins:
– switch “on” when GTP bound
– switch “off” when GDP bound
Signal induced conversion
of inactive to active state is
mediated by GEF, releasing
GDP, allowing GTP to bind
– GEF: guanine nt
exchange factors
Conversion from active to
inactive form by hydrolysis
of GTP, accelerated by GAP
– GAP: GTPase-activating
proteins
Fig 3-32