RCSI FUNBIO 10 Cell Structure PDF

Summary

These lecture notes cover cell ultrastructure, focusing on centrioles, cilia, and cell junctions. The document details the structure and function of microtubules, microfilaments, and intermediate filaments, and includes information on centrioles' role in cell division and centrosomes. It also describes various cell junctions and their significance.

Full Transcript

Cell Ultrastructure: Centrioles,
Cilia, Cell Junctions

Class Foundation Year
Course Fundamentals of Human Biology
Code FUNBIO 10
Lecturer Dr Adrian Dervan
Date
Learning outcomes
At the end of this lecture, the learner will be able to

Explain the importance of the cytoskeleton in the cell
Describe in detail the molecular structure and the function of microtubules,
microfilaments and intermediate filaments differentiating clearly between these
structures.
Describe the microtubular structure of centrioles in the animal cell.
Explain the role of centrioles in cell division and centrosome formation.
Show the origin of the microtubular spindle fibres from gamma-tubulin rings in the
centrosome.
Discuss the significance of the intercellular junctions noting the three main types.
Describe the structure and function of adhering, gap and tight junctions.

2
Cytoskeleton
 Cytoskeleton
Animal cells maintain their shape
by the existence of a three
dimensional network in the
cytoplasm called the cytoskeleton
This consists of a system of
tubular and filamentous
structures
Three elements make up this
system:
1. Microtubules
2. Microfilaments
3. Intermediate filaments
All are readily assembled from
soluble pools of cytoplasmic
proteins
Cytoskeleton
 Microtubules
Microtubules - Structure
Appear to exist as hollow cylinders, 25 to 30nm
diameter
They are composed of 13 subunits in a left-
handed helix
Each subunit is a heterodimer of two proteins
- and ß-tubulin
Protofilament
The heterodimer runs parallel to the long axis of
the tubule
They are the thickest filaments and are rigid
They have a + and a - end

https://www.youtube.com/watch?v=ZpEKOH4LBAc
 Microtubules
Function

Microtubules have a structural and
functional role
1. They form the axoneme of the cilium
and flagellum
2. They form the components of the
centrioles
3. They also form the spindle fibres of
cell division
4. Associated with intracellular
movement in the axons of nerve cells
Microtubules
Motile Non- Motile

9+2 9+0

Nasal olfactory
Airway neuron
Sperm flagellum epithelial cell
 Cytoskeleton - Microfilaments

Also known as Actin
filaments
Apart from the microtubules
more solid filaments may be
seen under high EM
magnifications
In cross section they could
be confused with small
ribosomes though they are
only 33% of their diameter

https://www.youtube.com/watch?v=pyEVmWLOePw
 Cytoskeleton - Microfilaments
Structure
These are solid filaments, 5-7nm
diameter
Largely formed of the protein actin
They are found in most animal cells and
in some plant cells
They are concentrated in networks or
bundles just below the plasma
membrane
Intestinal microvilli are produced by
the microfilaments
Microfilaments
 Intermediate Filaments

Structure
Heterogeneous in composition
Any given cell will have more than one type
One type of filament usually predominates

Five main types based on the protein involved

Type I & II- keratins divided into acidic and basic types
Type III - vimentin-like proteins, found in cells of
mesodermal origin
Type IV - neurofilaments, found in nerve axons
Type V - nuclear lamins - forming the nuclear lamina
 Intermediate Filaments
File:Intermediate filament.svg

This is a separate system of rope-like
filaments found in most cells
Size is intermediate to actin filaments
and microtubules
Form solid filaments between 7-11nm
in diameter
Non-alpha-helical (globular) domain at
the N and C-termini which surrounds
the alpha-helical rod domain.
Basic building block is parallel dimer.
Dimer is formed through interaction of
the rod domain to form a coiled coil
Intermediate Filaments

8 tetramers form a single intermediate filament
 Centrioles
Characteristically found in all
animal cells and ciliated plant cells

Usually found in the cytoplasm in
an area near the nucleus

Often associated with the Golgi
apparatus

This area is called the Microtubule
Organizing Centre
 Centrioles - Structure

Usually found as two cylindrical
structures at right angles to one
another,

Typically one pair per cell during
interphase

Composed of 9 sets of triplets
arranged as a cylinder - Tubulin Triplet

Called a 9x3 structure (9+0
structure) of microtubules
 Centrioles - Structure

In each triplet:

Set A, is closest to the centre and is a
complete microtubule

Set B and C share portions of their walls

‘9+3’ configuration
 Centrioles - Structure
Cartwheel:
In the centre of the centriole there is a
cartwheel structure

Additional material that protrudes from
the outer surface at proximal end of a
mature centriole
Fibrous structures connecting the two
centriole cylinders
 Centrioles - Function

Prior to cell division the centrioles replicate
and move to the opposite poles of the cell

Most cells’ centrioles duplicate by the growth
of new daughter centriole at right angles to
the 'old' centriole

One new centriole and one old centriole at
each pole

Form areas known as centrosomes
 Centrosomes
The centrosome is the main
microtubule organizing centre of
the cell

Composed of:
Two orthogonally arranged
centrioles

Pericentriolar material (pale
blue).
Contains proteins
responsible for microtubule
nucleation and anchoring
 Centrosomes
Because microtubules radiate from the
centrosome area it was thought that the
centrioles were involved in organizing the
microtubules

Microtubules originate from -tubulin rings
in the centrosomal matrix (Distal
appendages) not from the centrioles

Each -tubulin ring serves as the
nucleation site (starting point) for one
microtubule
 Centrosomes

An aster of microtubules (fibres)
extends to form the visible
spindle fibres of cell division

Some spindle fibres bind to the
chromosomes at the centromere
Cell Junctions
 Cell Junctions
Most cells in tissues are attached to other cells

only a small number of cells in the body, such as the blood
cells, lead relatively independent lives

the cells in tissues are separated by an intercellular space
of between 20-30nm wide

but in some areas of specialized intercellular junction
more direct contact is maintained between adjacent parts of
the two membranes

Three types of cell junction occur:
1. Adhering (Anchoring) Junctions
2. Tight Junctions
3. Gap Junctions
 Cell Junctions

Adhering (Anchoring) Junctions:
Principal mechanical interlinks between cells
Strong junctions that tightly bind adjacent epithelial cells, such as
those found in outer layer of mammalian skin

Two types:
Desmosomes
Adhering junctions

The intercellular space is normal (30nm) but filled with
transmembrane proteins called cadherins
 Cadherins
Cadherins form links to cytoplasmic
structures
Link membrane to cytoskeleton
3 types
E-cadherin – epithelial
N-cadherin – neuronal
P-cadherin – placental

Cadherins are lost in cancer & metastases
 Adhering (Anchoring) Junctions

The cadherin attachment is via linker
proteins to actin microfilaments in the
cytoplasm.

Serve as a bridge connecting the actin
cytoskeleton of neighbouring cells
through direct interaction
 Adhering (Anchoring) Junctions

Desmosomes - disc-like plaques in cytoplasm, 20nm thick, 0.2-
0.3µm diameter

There are two types of desmosome:
Spot desmosomes (Macula adherens), which are like spot rivets
These connect cells to each other
Hemidesmosomes connect the basal surface of epithelial cells to
the underlying basal lamina
The transmembrane linker proteins here again are cadherins
Desmosomes
Hemidesmosome
 Gap Junctions

Involved in the interchange of small
inorganic ions and molecules between
adjacent cells.
Connexin
The intercellular space is reduced to channel
Hexagonal
array
between 2-4nm

Hexagonal array of proteins in each
membrane

The transmembrane proteins are called
connexins
 Gap Junctions

Each array is aligned to an array in the
opposing face

This results in the formation of a
hydrophilic channel with a pore size of
about 1.5nm diameter
Hydrophilic
channel
Gap junctions are associated with the
intercalated discs in cardiac muscle where
they facilitate the transmission of electrical
impulses between cardiac muscle cells.
 Tight Junctions
In the cells lining the mammalian
intestine, the kidney and those lining
the urinary bladder the plasma
membranes form close connections

These appear as a fusion of
the plasma membranes of two
cells

These are called tight
junctions (zonula occludens)
 Tight Junctions

Form a belt-like structure of branching
sealing strands

Function is to seal off the intercellular
space, forming almost impermeable barrier

Have a role in the maintenance of
concentration gradients between the
exterior lumen and the intercellular space
Plasma Protein Connexin
Rows of
filaments Plasma molecules
membranes tight junction Channel
membranes
proteins

Desmosome

Intercellular Intermediate
Intercellular space filaments c
a space
Disc of dense
b protein material
Pemphigus Vulgaris Involves the Desmosomes

Pemphigus vulgaris is an autoimmune,
intraepithelial, blistering disease affecting
the skin and mucous membranes.

Autoantibodies target proteins of the
desmosome leading to disruption of cell
adhesion.

Adjacent layers of the skin can pull apart
and allow abnormal movements of fluid
within the skin, resulting in blisters and
other tissue damage.

A potentially life-threatening disease, it has
a mortality rate of approximately 5-15%
 Questions?

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