Transcript Lecture 6

Overview of the cell structure
Eucaryotic cell Organelles
Readings and Objectives
• Reading
– Cooper: Chapter 1, 9, 10 (p.408), 11(p.464)
• Objectives
– Basic properties of eucaryotic cells
– Eucaryotic organelles
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Nucleus
Ribosomes
ER and Golgi
Lysosomes and peroxisomes
Note: Cell membrane, endosomes, mitochondria, and cytoskeleton are separate lectures
Eucaryotic Organelles
The Nucleus
• 5-10 µm diameter: largest organelle; contains the linear DNA
molecules
• nucleus separated from the cytoplasm by the nuclear membrane.
• nuclear pores : import and export of RNA and proteins
• Nucleolus: sites of rRNA synthesis and ribosomal subunits
maturation
Nucleus and Ribosomes
• Nucleus contains chromatin
within a semifluid
nucleoplasm.
• Chromatin: composed of
DNA, protein, and some
RNA, is usually a network of
fine strands.
• condense during cell
division to form visible
chromosomes
Nuclear Envelope
• Nuclear envelope separates nuclear
content from the cytoplasm
• selective traffic of proteins and RNAs
• critical in regulating eukaryotic gene
expression
• Consists: two membranes,
underlying nuclear lamina, and
nuclear pore complexes
• outer membrane- continuous with
the endoplasmic reticulum, has
membrane proteins that bind the
cytoskeleton
• inner membrane has proteins that
bind the nuclear lamina
• Each nuclear membrane is a
phospholipid bilayer permeable only
to small nonpolar molecules.
Nuclear Lamina
• Nuclear lamina- fibrous mesh
that provides structural support.
• fibrous proteins called lamins
• Mammalian cells have three
lamin genes, (A, B, and C)
• Two lamins interact to form a
dimer in which the α-helical
regions of two polypeptide
chains wind around each other to
form a coiled coil
• The lamin dimers associate with
each other to form the nuclear
lamina
Lamina
Nuclear Pore complex
• Nuclear pore- sole channels for
small polar molecules, ions,
proteins, and RNA to pass
through the nuclear envelope
• Nuclear pore complexescomposed of ~30 different pore
proteins (nucleoporins).
• Two mechanisms:
– Passive transport- small
molecules pass freely in
either direction
– Active transportMacromolecules (proteins
and RNAs), energydependent
Nuclear Pore complex
• pore complex consists of
eight spokes connected to
rings at the nuclear and
cytoplasmic surfaces.
• The spoke-ring assembly
surrounds a central channel.
• Protein filaments extend
from the rings, forming a
basketlike structure on the
nuclear side.
• Proteins that must enter the
nucleus have amino acid
sequences called nuclear
localization signals.
• These are recognized by
nuclear transport
receptors (importins)
Nuclear importation
• importin binds to the NLS
of cargo protein
• complex binds to the
cytoplasmic filaments of
the pore complex
• Transport proceeds
through pore complex by
binding to nucleoporins
• cargo/importin complex is
disrupted by binding of
Ran/GTP.
• conformation change in
the importin, releases the
cargo into the nucleus
Nuclear importation
• importin-Ran/GTP
complex exported back to
the cytoplasm where the
GTP is hydrolyzed to GDP
• The importin is released
and can participate in
another round of
transport.
• Ran/GDP is transported
back to the nucleus by its
own import receptor
(NTF2), where Ran/GTP is
regenerated.
Ran/GTP Gradient
• Activity of importins
regulated by Ran, a GTPbinding protein.
• Ran GAP: a GTP hydrolysis
to GDP are on the
cytoplasmic side of the
nuclear envelope
• enzymes for exchange of
GDP for GTP are on the
nuclear side.
• This leads to higher
concentration of Ran/GTP
in the nucleus, and
determines the
directionality of transport.
Nuclear Export
• Proteins are targeted for export from
the nucleus by specific amino acid
sequences, called nuclear export
signals.
• These signals are recognized by
receptors in the nucleus (exportins),
which direct protein transport to the
cytoplasm.
• Ran is required for nuclear export as
well as import.
• Ran/GTP promotes binding of
exportins and their cargo proteins,
but dissociates complexes between
importins and their cargos.
Protein Import and Export through the Nuclear Pore Complex
Ribosomes
5S rRNA
16S rRNA
• Ribosome subunits, one large
and one small, are assembled
in the cytoplasm and used to
make proteins
tRNA
23S rRNA
• found in both prokaryotes
and eukaryotes
– A nucleoprotein complex
– Assembled in two
subunits
– Eukaryotic: 80S (60S+40S
subunits)
– Prokaryotic: 70S
(50S+30S)
Bacterial 70S ribosome
Components of Eucaryotic and Procaryotic Ribosomes
80S; 4 RNA + 83 proteins
(in 2 subunits)
70S; 4 RNA + 55
proteins (in 2 subunits)
Want to read more? In Slide show Click to go to the book section
Ribosomes
• In eukaryotic cells, ribosomes can be
found in different locations and forms.
• Single free-ribosomes in the cytoplasm
– Grouped into polyribosomes, make
cytosolic proteins
• Attached to the endoplasmic
reticulum, rough ER (RER), make
proteins targeted to membranes and
organelles
• mRNA, produced in the nucleus
• Transported to cytoplasm by
carrier proteins, pass through
nuclear pore
Ribosomes, ER and protein synthesis
Ribosomes are the protein synthesis machinary
Ribosomes, ER and protein synthesis
• Proteins translated on
RER
• Post-translationally
modified in golgi eg.
glycosylation
• Targetted to other
organelles
• Cell membrane
• Vesicular
compartments
Endomembrane system: ER and Golgi
Endomembrane system
• ER: tubular membranes and
cisternae
• Smooth ER-lipid and steroid
synthesis
• RoughER- protein synthesis
• Together with Golgi
form the cellular
secretory machinary
Golgi Complex
• Flattened membranous sacs
• Chemically modifies proteins from rough ER, Sorts finished proteins to their destiny
• site of lipid synthesis, and (in plant cells) the site of synthesis of some
polysaccharides that compose the cell wall
movement of materials
cis face associated with ER
Golgi Complex
• Flattened membranous sacs
• Chemically modifies proteins from rough ER, Sorts finished proteins to their destiny
• site of lipid synthesis, and (in plant cells) the site of synthesis of some
polysaccharides that compose the cell wall
Vesicular compartments
Lysosomes
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Golgi derived membrane-bound vesicles (0.1-1.5 um)
found in most eucaryotes
involved in intracellular digestion and recycling of macromolecules
contain about 40 acid hydrolases
– proteases, nucleases, and phopholipases, amaylases
maintain an acidic environment by pumping protons into their interior
(pH,5.0)
Digest worn out cellular molecules, engulfed bacteria and viruses
– Fuse with phagosomes (eg engulfed bacteria) to form phagolysosomes
Lysosomes also participate in apoptosis, or programmed cell death
Tay-Sachs disease: lysosomal disfunction, autosomal recessive
– Defective Hexosamidase A, a hydrolase involved in breakdown of phospholipids
– Accumulation of lipids in neurons, infantile death
Vesicular compartments
Peroxisomes
• single-membrane-enclosed microbodies
• Originate form ER, cytosolic proteins are imported to
peroxisomes (no golgi origin)
• contain enzymes involved in variety of oxidative
reactions
• peroxisomal proteins (peroxins) are metabolic
enzymes
• lipids broken down by oxidative reactions H2O2
• Peroxisomes also contain catalase
• Involved in synthesis of amino acids
• Synthesis of cholesterol, bile acids
• Detoxification rxn, eg alcohol
Peroxisomes: assembly
• Peroxisome assembly begins on
the rough ER, where two
peroxins, Pex3 and Pex19,
initially localize.
• Their interaction causes
Pex3/Pex19-containing vesicles
to bud off the ER.
• The vesicles may then fuse with
preexisting peroxisomes or with
one another to form new
peroxisomes.
Peroxisomes
• peroxins synthesized on free ribosomes and imported
• Protein import and the addition of lipids from the rough ER
results in peroxisome growth, and division
• Enzyme content and metabolic activities of peroxisomes
changes as they mature
• Zellweger syndrome, named after Hans Zellweger (1964)
• Pex1,2,3,5,6,12,14 and 26 mutated (1:50,000)
• Inefficient peroxisomal protein import
• Long fatty acid chains accumulate in liver and neurons
• Neurological disorders, glaucoma, hepatic enlargement, mental
incapacity, seizure, loss of muscular tone, facial deformities
and Jaundice
• lethal within a few years
See website literature section for a review article
Proteosomes and protein degradation
• after release some
vesicles deliver their
contents to
lysosomes while
others deliver to cell
membrane
• Quality assurance
mechanism
– Unfolded or
misfolded proteins
are secreted into
cytosol, targeted for
destruction by
ubiquitin
polypeptides
– proteasomes destroy
targeted proteins
Proteosomes and protein degradation