2. History
Robert Brown
1773-1858
Discovered in 1831 by
scottish botanist Robert Brown
Suggested the nucleus played a
key role in fertilization and
development of the embryo in
plants
Name (nucleus) derived from the
Latin word for kernel/nut
3. Characteristics of nucleus
Membrane-enclosed organelle
found in eukaryotic cells
Generally found in the central
region of the cell (in animal
cells)
Roughly spherically shaped
Largest and most easily seen
organelle
4. Functions of nucleus
Stores genetic information (DNA & RNA)
DNA replication occurs in the nucleus which is
then passed to daughter cells
Enables the synthesis of nearly all proteins
through the synthesis of RNA.
Houses the nucleolus which is the site of
production of ribosomes
Selective transportation of regulatory factors and
energy molecules through nuclear pores
5. Nuclear organization in
eukaryotes
Nucleus occupies approximately 10 % of the total cell
volume. Structural component of nucleus are:
Nuclear envelope
Nuclear matrix and nuclear lamina
Nucleoplasm
Nucleolus
Chromatin
6. Nuclear Envelope
Boundary of the nucleus that
separates the contents of the
nucleus from the cytoplasm
Provides structural framework of
the nucleus
Act as a barrier that prevent the
free passage of molecules between
nucleus and cytoplasm
Consist of two membranes : outer
and inner membrane
7. Nuclear Envelope (contd
Thickness of each membrane is around 7-8 nm,
encloses a perinuclear space between them (20-40
nm thick)
Outer membrane continues with ER membrane has
ribosomes attached on it
Inner membrane have proteins which bind the
underlying nuclear lamina.
Have number of pores called as nuclear pore
comples, required for transport of molecules between
nucleus and cytoplasm.
8. Nuclear lamina
A fibrous network underlying the inner
nuclear membrane
Provides structural support to nucleus
Composed of fibrous proteins (60-80 kd)
lamins
Mammalian cells have 3 lamin genes: A,
B and C
Lamin proteins associate with each
other to form higher order structure.
Binds to inner nuclear membrane
through lamin binding proteins such as
emerin and LaminB receptor.
Mutations in lamin genes is responsible
for various disease such as progeria.
10. Progeria
Caused by a mutation in gene
LMNA (Lamin-A)
LMNA gene produces the Lamin A
protein, which is the structural
scaffolding that holds the nucleus
of a cell together
Defective Lamin A protein makes
the nucleus unstable. That nuclear
instability appears to lead to the
process of premature aging in
Progeria.
11. Nuclear Pores Complex
Only channels for the transport of
different molecules between
nucleus and cytoplasm
Have a diameter of 120 nm and
approx. molecular mass of 125
million daltons
Composed of 30 different proteins
, present in multiple copies called
nucleoporins
Nucleoporins lining the central
channel have multiple FG repeats
Small molecules(20-40kd) diffuse
Large molecules are transported
through central channel
12. Nuclear Pores Complex (contd.)
Consists of eight spokes arranged around a central
channel
spokes are connected to rings at the nuclear and
cytoplasmic surface
Spoke ring assembly is anchored in nuclear envelope
at the site of fusion of inner and outer nuclear membrane
Protein filaments extend from both sides giving a
basket like apperance on the nuclear side
13. Transport of proteins to and from the nu
Proteins needs to be transported to nucleus have a
specific amino acid sequence known as nuclear
localization signal (NLS)
NLS is recognized by the nuclear transport receptor
which directs their transport through nuclear pore complex
NLS first identified in SV 40 by Alan Smith and
colleagues in 1984
NLS are short sequence of amino acids rich in basic
amino acids( lysine and arginine)
Could be present as a single stretch (eg. SV40), or as a
bipartite sequence(eg. Nucleoplasmin)
14. Import of proteins to the nucleu
1. NLS of cargo protein is recognized by nuclear transport receptor
importins, resulting in formation of cargo-impotin complex.
2. The complex of cargo protein and importins docks with the
cytoplasmic filament of NPC and complex moves through nuclear
pore complex
3. Once inside the nucleus RanGTP binds to the complex and fascilitate
the release of cargo protein
4. Importin-Ran/GTP complex than exported back through nuclear pore
complex
5. In the cytoplasm GTP is hydrolyzed to GDP by Ran GAP releasing the
importin which can be used again
6. Ran GDP is transported back to nucleus by its own transporter NTF2
16. Export of proteins from nucleus
1.Proteins to be exported from nucleus have nuclear export signals
(NES), they bind to exportins and RaGTP forming a complex.
2. The complex moves to cytoplasm where GTP is hydrolyzed to GDP
fascilitating the release of cargo protein and exportin
3. Exporins and Ran GDP are transported back to the nucleus
17. Regulation of nuclear protein im
Import of proteins such as transcription factor is
regulated in by two mechaisms:
1.In one mechanism transcription factors such as
NF-kB bound to some inhibitory proteins (IkB) which
masks their NLS, so they remain in cytoplasm,
whenever some signal is their ,inhibitory protein is
phosphorylated and degraded and the protein can be
transorted to nucleus
2. In another mechanism transcription factor is itself
posphorylated (eg. Pho4), which prevents its
transport to the nucleus.
19. Internal organization of
nucleus
Loose network of nuclear lamina extends to the
interior of nucleus
These lamins serves as site of chromatin
attachment
Chromatin within the nucleus is organized into
large loops of DNA
Specific region of loops are bound to lamin matrix
bylamin binding proteins in chromatin
20. Chromosome and chromatin
Highly condensed chromatin-
hetro chromatin, transcriptionally
inactive
Decondensed chromatin-
euchromatin, distributed throughout
the nucleus, transcriptionally active
Each chromosome occupies a
distinct teritory, with cetromere and
telomere attached to opposite sides
of nuclear evelope
21. Sub-compartments within nu
Have distinct region for various processes
Contains multiple clustered site for DNA replication
Speckles: storage site for splicing comonents
PML bodies: site for transcriptionaly regulatory proteins
Involved in acute promyelocytic leukemia
Cajal bodies: enriched in small RNPs, functions as site
of RNP assembly and processing
Nucleolus: site for ribosome synthesis
22. Nucleolus
Largest structure present inside the boundaries of the
nucleus
Dark staining zone in center of nucleus
Site of rRNA trascription and processing
Main components are ribonucleic acid (RNA),
deoxyribonucleic acid (DNA) and proteins
Known as ribosome production factory
23. Ribosomal rRNA genes
Nucleolus has genes for 5.8s, 18s and 28s rRNA
Ribosomal rRNA genes are present in tandom arrray
Around 200 copies of genes coding for 5.8s, 18s and 28s rRNA,
present on chromosome 13, 14, 15, 21 and 22
5s rRNA gene is present outside nucleolus on chromosome1 in a
tandom array
5.8s, 18s and 28s are transcribed as a single unit by RNA
polymerase 1, yielding 45s pre-rRNA.
Pre-rRNA is processed to 18s rRNA of 40s subunit and 5.8s, 28s
rRNA of 60 s subunit of ribosomes
