The cell structure 2024 dr. manal m. sayed(4).pdf

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The cell structure

is the study of the tissues of the body and how these tissues are
arranged to constitute organs, with the focus on how cells’ structure and arrangement optimize
functions specific to each organ.

ell is the structural and functional unit of the organism and the smallest living parts of the
body. All living organisms are formed of cells.
Despite their great variation in shape, size and functions, the cells share many common
features. The surface of cells is limited by plasma membrane representing the living outer
boundary of the cell.
In the center of the cell there is the controlling center or the nucleus. The remainder of the
cell is the cytoplasm which contains the source of energy together with the various structures
that perform all other required functions.

Fig. 1 showing different cells.

The plasma membrane (PM)

The plasma membrane (cell membrane or plasmalemma) is extremely thin, it cannot be seen
with the light microscope (LM). With the electron microscope (EM) it appears as two dark
lines and one light space in between.
Molecular structure:
The cell membrane is formed of:
1- Lipid: which is formed mainly of
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 a) phospholipids. The phospholipids molecules are arranged into a double layer with
their hydrophobic ends directed inward and their hydrophilic polar head outwards.
b) Cholesterol inserts among the closely packed phospholipids.

Fig. 2 showing the cell membrane structure
2- Protein:
There are two types of proteins:
a- Integral proteins which may embed completely or partially within the lipid bilayer.
b- Peripheral proteins which are associated with the inner lipid bilayer.

3- Carbohydrates:

The carbohydrates are conjugated with the protein to form glycoprotein and with lipid to for
glycolipids both are present in the outer surface of the cell membrane forming the cell coat.

Cell coat or glycocalyx It is a delicate cell surface coating. It is formed of oligosaccharide
chains attached to both lipid and protein components of plasma membrane and exposed at the
external membrane surface. It has many functions such as protection of the outer surface of
plasma membrane, cellular recognition, antigenicity, and filtration.

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 The cytoplasm

The cytoplasm is an amorphous heterogeneous colloidal substance in which various
particles of different sizes are suspended.
Cell organoids or organelles
Cell organoids (organelles) are living structures present in the cytoplasm and are essential for
the life of the cell and perform specific functions inside the cells.
The cell organoids include:
A - Membranous organoids (which are limited by a membrane), they are rough & smooth
endoplasmic reticulum, Golgi apparatus, lysosomes, mitochondria, secretory vesicles, and
coated vesicles.
B- Non-membranous organoids: as ribosomes, centrosome, microtubules, microfilaments,
and intermediate filaments.

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 A-The membranous organelles
1-Endoplasmic reticulum

The endoplasmic reticulum (ER) is an extensive network of intracellular membranes that are
usually anastomose with one another to form a network.
Two types of endoplasmic reticulum are found in cells: Rough endoplasmic reticulum (RER)
and Smooth endoplasmic reticulum (SER).
a) Rough Endoplasmic reticulum (rER)
LM: it is highly basophilic due to the presence of ribosomes on its surface.
The rER is a membranous organelle which has ribosomes on its membranes and appears as
parallel stacks of flattened cisternae.
The function: Synthesis of proteins for exports.

b) Smooth endoplasmic reticulum (sER):
Regions of ER that lack ribosomes make up the smooth endoplasmic reticulum (SER).
LM: cells rich in SER are highly acidophilic due to the absence of ribosomes.
EM: it appears as membrane-bound tubules &vesicles with no ribosomes on their surfaces.
Functions:
1. Lipid synthesis (especially steroids) as in the interstitial cells of the testis
2. Mineral metabolism (especially the formation of HCL) in the gastric glands.
3. Detoxification of toxins as in the liver cell.
4. Muscle contraction: The sarcoplasmic reticulum of striated muscles cells is an example.

Fig. 2 showing smooth and rough endoplasmic reticulum.
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 2-Golgi complex

Golgi complex (Golgi apparatus) is one of the membranous organoids.
With LM: it is negative with H&E stain but after silver or osmic impregnation, it appears as
dark granules or reticular structures taking different shapes and localizations in different cells.
It is perinuclear (around the nucleus) in nerve cells whereas in secretory cells, it lies between
the nucleus and the secretory surface, and in liver cells it is scattered in the cytoplasm.
With the EM: Golgi complex appears to be formed of membrane bound cisternae (or
saccules) as well as small and large vesicles.

Fig. 3 showing GolgiFig. 2 showing
bodies stained smooth
by silverand rough
stain and endoplasmic reticulum. structure
its electron microscopic

Functions of Golgi complex:
1- It is the site for the condensation, packing and modification of proteins.
2- In Golgi complex, carbohydrates are added to proteins to form the proteoglycans which
are then packed in the secretory vesicles.
3. Golgi complex is an important site for packing hydrolytic enzymes of primary lysosomes.

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 4-Lysosomes

Lysosomes are one of the membrane organoids, which are membrane- bound vesicles very
rich in hydrolytic enzymes.
In electron micrographs: Lysosomes appear as spherical bodies limited by membrane and
contain relatively dense materials.
Lysosomes originate from the Golgi region where various enzymes are packed.
Types of lysosomes
1- Primary lysosome: the newly formed lysosome is homogenous in appearance.
2- Secondary lysosome: when foreign materials unite with the primary lysosomes is
heterogenous in appearance.
3- A residual body: After the digestion of the contents of the secondary lysosome and the
diffusion of useful material to the cytoplasm, the remaining vacuole is known as a residual
body. The residual bodies accumulate with age (lipofuscin pigment).

Fig. 4 showing Lysosomes their electron microscopic structure.

Functions of lysosomes:
1. The main function of lysosomes is the digestion of materials entering the cell either by
phagocytosis or pinocytosis, so they are numerous in phagocytic cells as macrophages and
neutrophils.
2. Lysosomes dispose of excess or non-functioning organelles as mitochondria.
3. Lysosomes represent a safe store of digestive enzymes which can be used by the cell in
different ways. - In bones, lysosomes are involved in resorption of old bone matrix.
- The acrosome of the spermatozoon is a large single lysosome, the contents of which are
released on contact with the ovum to make fertilization easy.

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 5-Microbodies or peroxisomes
Microbodies or peroxisomes are small spherical membrane-limited organelles
containing enzymes for various metabolic reactions, especially for oxidation and
detoxification and degradation of fatty acids.

Fig. 5 showing peroxisomes by electron microscope.

6- Mitochondria
Mitochondria are one of the membranous organoids.
LM: mitochondria appear in different shapes e.g., spherules, rods, or filaments.
EM: the mitochondrion is surrounded by two membranes.
The outer is simple, and the inner is thrown into folds called cristae or crests. The space
between the outer and the inner membrane is the outer chamber or inter membranous
space. Inside the inner membrane is the inner chamber which contains the matrix. The
matrix is dense and contains Ca++ particles, DNA, small ribosomes, and enzymes of
kreb's cycle.

Fig. 6 showing mitochondria their electron microscopic structure.

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Function of mitochondria
❑ The most important function of mitochondria is to produce energy, produce ATP
molecules. This process is known as oxidative phosphorylation.
❑ Heat production
They are numerous in liver cells.
B-Non-membranous organoids
1-Ribosomes
Ribosomes are non-membranous small particles present in all animal cells in varying
amounts depending on their activity in protein synthesis.
There are two forms of ribosomes:
1- Attached ribosomes: They are attached to endoplasmic reticulum (rER) and are
involved in the formation of secretory proteins.
2- Free ribosomes: present freely in the cytoplasm and are concerned with the formation
of cytoplasmic proteins.
Each ribosome is formed of two subunits, a small and a large one both formed in the
nucleolus.

Fig. 7 showing diagram of ribosomes.

2-The cytoskeleton
Microtubules, microfilaments, and intermediate filaments are the main components
of the cytoskeleton.
Function:
1-Determines the shapes of cells.

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2-Provides structural support for the cells.
2-Plays an important role in the movements of organelles and cytoplasmic vesicles (intra
cellular transport). Dr. Manal M. Sayed
3- Allows the movement of entire cells.
5-Cell division
a) Microfilaments or actin filaments are 6 to 8 nm in diameter and consist of globular
actin molecules polymerized into long filaments.
Functions:
❑ Actin filaments are found in great abundance in muscle cells. They integrated with
myosin (a motor protein) to permit very forceful contractions.
❑ They are found all non-muscle cells where they play a central role in "cell
locomotion", formation of pseudopodia "maintenance of cell shape", "formation of the
contractile ring in mitosis", and numerous other activities.

Fig. 8 showing diagram of microfilament or actin filaments.

b) Intermediate filaments are approximately 10 nm in diameter.
They are stable and not contractile. Intermediate filaments are made up of fibrous proteins
that are organized into tough, ropelike structures.
They have two major structural functions:
❑ They stabilize cell structure.
❑ They resist tension.
c) Microtubules are tubular or cylindrical structures with an average diameter of 25nm.
They are composed of the protein tubulin arranged in rings stacked end to end making up
the tubules.

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Functions:
❑ Microtubules provide internal support for the cell. Dr. Manal M. Sayed
❑ Microtubules are organized to form dynamic structures such as mitotic spindle of cell
division, centrioles, basal bodies and axoneme of cilia and flagella.
❑ Microtubules guide the movement of secretory vesicles and organelles within the cell.

Fig. 9 showing diagram of microfilament, intermediate filaments, and microtubules.

Cytoplasmic inclusions
Cytoplasmic inclusions are substances present in the cytoplasm as result of
accumulation of cell products and are not involved in the cellular activities.
There are three types of inclusions:
A) Stored food: as fat & glycogen
B) Pigments, e.g., melanin and hemoglobin.
C) Crystals.

Modifications of the cell membrane
Modifications of the plasma membrane at the Lateral surface

I- Intercellular junctions
When cells come into contact with one another, specialized junction may form at
specific sites on the contacting cell membranes. These junctions have important roles in
the differentiation, development, and function of normal cells, tissues, and organs.
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 Fig. 9 showing diagram of plasma membrane modifications.

Classification
1. Occluding Junctions or Tight junction
2. Adhesive or Anchoring Junctions are sites of strong cell adhesion.
i) Zonula adherens
ii) Macula adherens (Desmosome)
3. Communicating (Gap) Junctions

❑ Tight junctions (zonula occludens): form a barrier between cells, regulating the passage
of substances. The adjacent cell membranes at these junctions appear fused with no
intercellular space.
Tight junctions prevent the passage of material through the intercellular spaces.

❑ Anchoring Junctions
They hold the cell together and provide lateral adhesions between epithelial cells using
proteins that link into the cytoskeleton of adjacent cells.
Two types of anchoring cell-to-cell junctions can be identified:
Zonula adherens which interacts with the actin filaments inside the cell.
Macula adherens or desmosome,which interacts with intermediate filaments.
The desmosome consists of two cytoplasmic adhesion plaques formed of special proteins
and placed on the cytosolic face of the two facing cell membranes.
The two plaques are connected by transmembrane linker proteins which extend into the
intercellular space and bind the two cells together. In the region of the desmosome,
intermediate filaments give support to the junction.
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 Fig. 10: showing the structure of the desmosome.

❑ Communicating or Gap junction: Most cells are interconnected by junctional
channels, so, many small ions that pass freely from one cell to the other. These
junctional channels represent regions of low electrical resistance as in between cardiac
muscle fibers.
2- Interdigitations: to give a very wide surface area for intercellular passage of material.
The best example is the cells of the kidney tubules.
3- Intercellular Canaliculi: Secretory material from adjacent cells is accumulated in
channels known as intercellular canaliculi which carry the secretions to ducts. The
intercellular canaliculi between liver cells are examples.

Dr. Manal M. Sayed

Fig. 11 showing interdigitation between cells (a & b) and intercellular canaliculi (c).

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 II-Modifications of the plasma membrane at the apical surface
❑ Cuticle (for protection): a substance rich in protein is deposited on the outer lamina of
the plasma membrane in cells exposed to harmful substances. Example, cells lining the
urinary bladder and ureter.
❑ Cilia (for transportation): the surface of some cells which are involved in
transportation of fluids, particles or cells become modified into ciliated surface e.g.,
ciliated cells lining the respiratory tract.
❑ Microvilli (for absorption): they are slender processes projecting from the surface of
the absorptive cells to increase the surface for absorption. The core of the microvillus is
formed of fine microfilaments.
III-Modifications of the plasma membrane at the cell base
❑ A) Basal infoldings: Membranous infoldings at the base of certain cells are present to
help in increasing the surface of the membrane for effective basal flow of material as in
the cells of kidney tubules.
❑ B) Hemidesmosomes: are present at the basal membrane of cells to bind epithelial cells
to the underlying basal lamina.

Dr. Manal M. Sayed

Fig. 12 showing basal infoldings (a) and hemidesmosome (b).

Self-assessment.
Choose the correct answer.
1. The powerhouse of the cell is
a) The SER
b) The RER
c) Mitochondria
d) Golgi bodies

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2. Modification of proteins occurs in
a) The SER
b) The ribosome
c) Mitochondria
d) Golgi bodies
3. Which of the following organelles contains digestive enzymes that breakdown complex molecules?
a) Golgi bodies
b) Mitochondria
c) Lysosomes
d) Rough endoplasmic reticulum.
4. Which of these are functions of microfilaments?
a) Formation of cellular processes and folds.
b) formation of flagella and cilia
c) protein secretion
d) formation of lysosomes

Enumerate
A) Functions of smooth endoplasmic reticulum.
B) Types of lipids in plasma membrane.
C) Functions of Golgi complex.
D) Types of lysosomes.
E) Non-membranous organelles.

True or false:
a) Lysosomes originate from Golgi bodies. ( )
b) SER has two membranes. ( )
c) Condensation and modification of proteins is the main functions of Golgi bodies. ( )
d) Rough endoplasmic reticulum is deeply basophilic. ( )
e) Silver stain is used for detection of mitochondria. ( )

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