Cytoplasm and Cellular Organisms Lecture Notes PDF

Summary

This document provides lecture notes on various aspects of cell biology, including cytoplasm; cellular organelles like mitochondria, endoplasmic reticulum, and ribosomes; and details of their structure, function, and processes within a cell.

Full Transcript

1 Prof. Hala EL-Tantawi

Cytoplasm and the
cellular organisms
Prof. Hala EL-Tantawi

The cytoplasm:
2 The cytoplasm contains a variety of
organelles, many of which are bounded
by membranes.

The nucleus is the largest organelle, and
its substance is bounded by a membrane
system called the nuclear envelope or
membrane.
The nucleus contains the genetic
material of the cell in the form of
deoxyribonucleic acid (DNA).
3 An extensive system of flattened membrane-bound tubules,
saccules, and flattened cisterns, collectively known as the
endoplasmic reticulum, is widely distributed throughout the
cytoplasm.
A second discrete system of membrane-bound saccules, the
Golgi apparatus, is typically located close to the nucleus.
Scattered free in the cytoplasm are several relatively large,
elongated organelles called mitochondria, which have a
smooth outer membrane and a convoluted inner membrane
system.
Prof. Hala EL-Tantawi
 Prof. Hala EL-Tantawi

In addition to these major organelles, the cell contains a variety
4 of other membrane-bound structures, including intracellular
transport vesicles and lysosomes.
The cytoplasmic organelles, are suspended in a gel-like medium
called the cytosol, in which many metabolic reactions take
place.
Within the cytosol, there is a network of minute tubules and
filaments, collectively known as the cytoskeleton, which
provides structural support for the cell and its organelles, as
well as providing a mechanism for the transfer of materials
within the cell and movement of the cell itself.
 Prof. Hala EL-Tantawi

Thus, the cell is divided into several membrane-bound
5
compartments, each of which has its biochemical
environment.
Membranes, therefore, serve to separate incompatible
biochemical and physiological processes.
In addition, enzyme systems are found anchored in
membranes, so that membranes are themselves the site of
many specific biochemical reactions.
 Prof. Hala EL Tantawi.

All eukaryotic cells start
life with a nucleus.
6 The Nucleus

This double-membraned
sac holds an eukaryotic
cell’s DNA.
 Prof. Hala EL Tantawi. The Nucleus
Nuclear Pore-riddled double membrane that controls
7 envelope which substances enter and leave the nucleus.

Nucleoplasm Semifluid interior portion of the nucleus.

Nucleolus Rounded mass of proteins and copies of genes
for ribosomal RNA used to construct ribosomal
subunits. The subunits pass through nuclear pores
into the cytoplasm, where they join and become
active in protein synthesis.

Chromatin Total collection of all DNA molecules and
associated proteins in the nucleus; all of the cell’s
chromosomes.
Chromosome One DNA molecule and many proteins
associated with it.
 Dr. Hala EL Tantawi

The Chromosomes
8 Chromatin is the name for all the DNA molecules, together with its
associated proteins, in the nucleus.
The genetic material is distributed among a specific number of DNA
molecules.
The number of DNA molecules is characteristic for the type of organism and
the type of cell, but it varies widely among species.
Prof. Hala EL-Tantawi

The chromatin is two types:
9 Heterochromatin, it appears as
aggregation of coarse granules in
the EM, and as basophilic clumps
in the LM. It is condensed
chromatin.
Euchromatin, it appears as finely
dispersed granular materials in
EM, and as lightly stained
basophilic areas in LM. It is
extended, uncoiled chromatin.
Prof. Hala EL-Tantawi

Mitochondria
10 Mitochondria vary considerably in size , shape and
change shape over time but are most often elongated,
sausage-shaped organelles.
Mitochondria are very mobile, moving around the cell
by means of microtubules.
They tend to localize at intracellular sites of
maximum energy requirement.
The number of mitochondria in cells is highly
variable; liver cells contain as many as 2000
mitochondria whereas inactive cells contain very few.
The number of mitochondria in a cell are modified by
mitochondrial division and fusion.
Prof. Hala EL-Tantawi

Structure of Mitochondria
11
The outer membrane is relatively
permeable as it contains a pore-
forming protein known as porin,
which allows free passage of small
molecules. The outer membrane
contains enzymes that convert certain
lipid substrates into forms that can be
metabolized within the mitochondrion.
 Prof. Hala EL-Tantawi

The inner membrane, which is thinner than the outer, is thrown into
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complex folds and tubules called cristae that project into the inner
cavity.

The inner cavity filled by the mitochondrial matrix. The matrix is
the site of the mitochondrial DNA and ribosomes. The matrix also
contains a number of dense matrix granules.
Prof. Hala EL-Tantawi

The intermembranous space between the two membranes also contains a
13 variety of enzymes.

Aerobic respiration takes place within the matrix and on the inner membrane,
a process enhanced by the large surface area provided by the cristae.

The matrix contains most of the enzymes involved in oxidation of fatty acids
and the Krebs cycle.

The inner membrane contains the cytochromes, and the enzymes involved in
ATP production.
Prof. Hala EL-Tantawi

The mitochondrial matrix contains one or more circular strands of DNA
14 resembling the chromosomes of bacteria.

The matrix also contains ribosomes with a similar structure to bacterial
ribosomes.

Mitochondria synthesize thirteen of their own constituent proteins, others
being synthesized by the usual protein synthetic mechanisms of the cell and
imported into the mitochondrion.
In addition, mitochondria undergo self-replication in a manner similar to
bacterial cell division.
 Prof. Hala EL-Tantawi

15 Endoplasmic reticulum
▪Endoplasmic reticulum is a complex network of
membranes/tubules. It considers a transport
system of the cell that surrounds the nucleus. It
is two types: rough (granular) and smooth
(agranular) endoplasmic reticulum.
 Prof. Hala EL-Tantawi

16 Rough Endoplasmic reticulum (RER)
Structure:
It consists of parallel flattened cisternae studded with
ribosomes on its surface. It is connected to the outer layer
of the nuclear envelope.

Function:
Its function is protein synthesis through its ribosomes.
Moreover, it is involved in the glycosylation of protein
(adding certain sugars to proteins).
It is prominent in cells that synthesize high amount of
protein, such as plasma cell (secretes antibodies),
fibroblast (secretes collagen fibers), etc.
 Prof. Hala EL-Tantawi

17 Smooth endoplasmic reticulum (SER):
Structure:
It consists of a branched network of
tubules connected together with no
ribosomes.
Function:
Its function is lipids and steroid synthesis
and destruction of toxic substances.
It is abundant in cells that synthesize lipid
or steroid, such as cells of adrenal gland,
Leydig cells in testis.
 Prof. Hala EL-Tantawi

18 Ribosomes
They are the site of protein synthesis inside the cell.
Structure:
They are small non-membrane-bounded organelle with
granular appearance. They are present on surface of
RER and also free in cytoplasm. They made of 2
subunits (large and small), each one made of proteins
and ribosomal RNA (rRNA). They contain 85% RNA of
cell.
Function: They are the site of protein synthesis inside the
cell.
 Prof. Hala EL-Tantawi

19 Golgi apparatus
Structure:
It is a packaging house of cell. It was
described by Camillo Golgi. It consists of
series of flattened cisternae/sacs and
peripheral vesicles (incoming and
outcoming). The cisternae have two faces
(cis/concave and trans/convex). This
apparatus is continuous with ER.
Function:
They are responsible for packaging and
sorting of protein, formation of lysosomal
enzymes, and glycosylation of proteins.
 Prof. Hala EL-Tantawi

20 Lysosomes
Lysosome are considered recycling center in the cell.
Structure:

They are small membrane bound vesicles containing a variety of
enzymes. The enzymes are synthesized in the RER, modified and
packed in the Golgi apparatus, and bud off small vesicles (lysosomes).
They are three types: 1ry, 2ry, and residual bodies.
Function:

They are responsible for intracellular digestion, killing and removing
foreign bodies, breaking of bacteria and cell debris from dead cells that
have been engulfed by a cell.
They are abundant in cells involved in phagocytic activity such as
macrophage and neutrophils.
 Prof. Hala EL-Tantawi

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Prof. Hala EL-Tantawi

Peroxisomes
22 Structure:
They are small membrane bound organelle
in the cell formed by self-replication or
budding from SER.
They are essentially containing two types
of enzymes: oxidase (active in oxidation of
lipids) and catalase (act on hydrogen
peroxide to liberate oxygen).
Prof. Hala EL-Tantawi

Function:
23 They are responsible for metabolism of lipids, destruction of toxin and drugs
metabolites in the liver and kidney.
They degrade hydrogen peroxide by catalase.
In first, several oxidases combine oxygen and hydrogen to form H2O2. Then this
H2O2 is oxidized by catalase into H2O and O2.
They are very similar to lysosomes; they have digestive enzymes to break down
the toxic materials inside the cells. But the difference is that lysosomes have
enzymes that work in poor- oxygen level and low pH but peroxisomes have
enzymes that require oxygen (oxidative enzymes).
So, it protects cell from toxins. Their enzymes are synthesized by the free
ribosomes in cytoplasm.
Prof. Hala EL-Tantawi

Cytoskeleton
24
Structure:
It is a network of filaments and
tubules. It extends from the
plasma membrane to the nuclear
envelope and even interior of the
nucleus.
It is made of proteins. It has three
types: microfilaments,
intermediate filaments, and
microtubules.
Prof. Hala EL-Tantawi

Function:
25
It provides the shape and support for the cells; it also
provides the organelles to move around them.
Microfilaments:
Thin thread-like structures. They resemble twisted necklace.
Made of a protein called actin.
Contractile, so they are found in motile cells.
They are important in movement, pinocytosis, and
phagocytosis.
Prof. Hala EL-Tantawi

Intermediate filaments:
Intermediate in size between actin filaments and microtubules.
26 Rope-like assembly of fibrous polypeptides (Vimentin, Keratin,
Lamin, Neurofilaments, or glial fibrillary acidic protein (GFAP)).
Vary in nature from tissue to tissue and from time to time.
They support nuclear envelope, and anchor cell-cell junctions.
Microtubules:
Hollow, rigid tube-like structures.
Made of proteins known as tubulin.
Their functions:
▪ Maintain shape of some cells.
▪ Form centrioles and spindle fibers for separating chromosomes during mitosis (animal cells only).
▪ Form projections such as flagella and cilia that enable some cells to move.
Prof. Hala EL-Tantawi
Centrioles
27
Short, hollow cylinders.
Found in pairs near the nucleus in
animal cells.
Made of two bundles of microtubules at
right angle to each other.
Each bundle arranged into nine
overlapping triplets.
Appear during cell division.
May give rise to basal bodies of cilia
and flagella.
Prof. Hala EL-Tantawi

Cilia and flagella
28
They are hair-like structures that project from the
cell.
They assist in movement.
They consist of 9 doublet units of microtubules
arranged as a ring.
Cilia are short, and numerous and hair-like.
They move in coordinated waves. e. g. in trachea
and bronchi to move dust, particles and bacteria
away from the lungs.
Flagella are much longer, fewer, and are whip-like.
They move like a propeller or cork screw. e. g. in
sperm to swim to the egg.
 Prof. Hala EL-Tantawi

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