Cytology Lecture Two PDF

Summary

This document contains lecture notes on cytology, covering the structure and function of cells. It includes diagrams and descriptions of cell components, such as the cell membrane, cytoplasm, organelles, and nucleus.

Full Transcript

Cytology

Lecture two
Cell
 Introduction
Cells are the basic structural and functional unit of the living organism showing a
variety of functional specializations which perform all the activities necessary for the
survival, growth and reproduction of the organism

It is a self replicating, self regulating and self governing biological system
Metabolism (absorption, synthesis, respiration and excretion),
Growth and regeneration
Irritability (excitability)
Movement
Reproduction
Aging and death
 Cont.…
Number (around 100 trillion
(1012) cells
Type (more than 250 named
cell types)
Shape (round, oval, columnar,
multipolar, polygonal,
cylindrical, fusiform, pyramidal,
pyriform, etc.)
Size (5µm - 120µm in
diameter)
Functions
 Cellular Functions in Some Specialized Cells
Function Specialized Cell(s)
Movement Muscle cell
Synthesis and secretion of enzymes Pancreatic acinar cells
Synthesis and secretion of mucous Mucous-gland cells
substances
Synthesis and secretion of steroids Some adrenal gland, testis, and ovary
cells
Ion transport Cells of the kidney and salivary gland
ducts
Intracellular digestion Macrophages and some white blood
cells
Transformation of physical and chemical stimuli into Sensory cells
nervous impulses

Metabolite absorption Cells of the intestine
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Cont.… nucleus circle=cuboid cell
flat=squamous cell
WBCs10,000 under normal condition
exceeds 10,000 when there's an infection
round=cuboid cell
Components of Eukaryotic Cell
1. Cell membrane
2. Cytoplasm
3. Karyoplasm (Nucleus)
 1. Cell membrane dont forget to search up the three types trilaminar laminar
layers
In electron micrographs of osmium-stained tissue, appears as trilaminar layer, each layer
2.5 nm in diameter
Because all membranes have this appearance, it is called the unit membrane
 Cell membrane
about 7.5 nm thick
Biochemically made by the following components
1. Lipids volunme 90% weight 50%
2. Proteins volume 10% weight 50%
3. Carbohydrates
 Phospholipids 75%

Such as phosphatidylcholine (lecithin)
With an amphipathic character (both hydrophobic and hydrophilic)
Arranged in a bilayer, each with:
Hydrophilic polar phosphate-containing head - towards water
Hydrophobic nonpolar pair of fatty acid tails – away from water
 Cholesterol
Modulate the fluidity and movement of all membrane components maintaining the
structural integrity of the plasma membrane
 Proteins
50% w/w in the plasma membrane
Most are globular proteins forming the following two groups:
1. Integral membrane proteins intrinsic
2. Peripheral membrane proteins extrinsic
 Integral membrane proteins
Some protrude from only one membrane surface, while others are transmembrane
proteins and protrude from both sides
 Peripheral membrane proteins
Are more loosely associated, mostly on the inner membrane surface
Bound to the polar groups of the membrane phospholipids or integral membrane proteins
Usually functions as part of the cytoskeleton or an intracellular secondary messenger
proteins of the cell

those which are found inside the cell
 Cell membrane proteins
Functionally there are 6 broad categories of membrane proteins as:
1. Pumps
2. Channels
3. Receptors
4. Linkers
5. Enzymes
6. Structural proteins
 Carbohydrates
Occur as oligosaccharide attached to plasma membrane proteins as glycoproteins and lipid
as glycolipids
Branch and project from the outer surface of the outer leaflet of the plasma membrane
They form a cell coat called glycocalyx that participates in:
Cell adhesion to the extracellular matrix
Binding of enzymes and antigens to the cell surface.
Cell-to-cell recognition and interaction
Organization of the cell membrane
Are asymmetrical because of:
Different composition of lipids
Peripheral proteins are mainly on inner leaflet
Oligosaccharides are on outer leaflet
 Functions of the cell membrane
1. Selective permeability & transportation
2. Communication
3. Physical barrier
4. Intercellular connections
 2. Cytoplasm
It is the cellular material outside the nucleus but within the plasma
membrane; consists of the following:
Cytosol - cellular fluid (mainly water) with dissolved proteins, salts, sugars, and other
solutes
Organelles - ultramicroscopic structures that perform various cellular functions;
ribosomes, ER, mitochondria, etc.
Cytoskeleton - protein filaments and tubules that provide support, movement within
the cell; cellular skeleton
Inclusions - chemicals such as glycogen, fat, and pigments
Cytosol, cytoplasm matrix (or ground substance)
In between the three dimensional cytoskeletal structure
Contains proteins, electrolytes, and metabolites dissolved in water (which makes 75-90%)
Could generally be divided into an inner and outer domains
 Organelles
Metabolically active structures
include:
1. Endoplasmic reticulum
2. Golgi complex (bodies or apparatus)
3. Lysosomes
4. Peroxisomes (microbodies)
5. Mitochondria
6. Endosomes and phagosomes
7. Proteasomes
8. Ribosomes
9. Cytoskeleton
i. Microtubules
ii. Microfilaments
iii. Intermediate filaments
10. Centrioles
 Endoplasmic reticulum
Convoluted network of anastomosing membrane channels (cisternae ) of various shapes
Show transfer vesicles which bud and move to the Golgi complex
Are of two types:
1. Rough or granular endoplasmic reticulum
2. Smooth or agranular endoplasmic reticulum
 Rough or granular endoplasmic reticulum (RER)
Show continuity with the outer nuclear membrane
Have docking proteins as receptors for ribosomes, and glycoprotein ribophorins
Synthesize proteins for sequestration
For export
For proteins of the ER, the Golgi apparatus, Lysosomes or the cell membrane
Transport molecules through cisternal space
Under LM appear as basophilic patches formerly termed as:
– Ergastoplasm in glandular cells
– Nissl bodies in neurons they secret neuro transmiters
 Smooth or agranular endoplasmic reticulum (SER)
Have more tubular or vesicular cisternae than the RER is sacular

Functions in:
o Synthesis of phospholipids and steroids
o Lipid metabolism
o Glycogen breakdown
o Detoxification
o Transport molecules through cisternal space
o Store and release calcium ions in the striated muscle cells as sarcoplasmic reticulum
 Golgi complex (Golgi body or Golgi apparatus)
Stalk of 3-10 discrete flattened and slightly curved bag-like channels or cisternae
surrounded by vesicles
Has the following two surfaces:
a. Forming, convex, entry, cis face
Closest to the nucleus
Surrounded by small transfer vesicles (vesicles in)
b. Maturing, condensing, exit, trans face
Usually concave
Has condensing vacuoles (vesicles out) and secretory granules
 Golgi complex (Golgi body or Golgi apparatus)
Functions in:
Synthesis of polysaccharides

Glycosylate proteins and lipid forming, respectively glycoproteins &
proteoglycans and glycolipids

Sulfate glycosaminoglycans

Packaging of secretory products

Concentration and storage of secretory products
 Lysosomes
Electron dense usually spherical bodies with a diameter of 0.05 - 0.5 μm
Contain more than 40 hydrolytic enzymes (cause hydrolysis of a chemical bonds, breaking
down bigger molecules), most commonly acid hydrolyases such as proteases, nucleases,
phosphatase, phospholipases, sulfatases, and β-glucuronidase
Most active at an acidic pH (5.0)
 Peroxisomes (microbodies)
Are like the lysosomes, but slightly larger in diameter (0.2–0.5 μm)
Contain more than 40 oxidative enzymes that:
– Produce hydrogen peroxide (H2O2) to kill microorganisms and detoxifies toxic agents
Complement certain functions of the SER and mitochondria in the metabolism of lipids
and other molecules
Replicate by budding of precursor vesicles from the ER or fission of preexisting peroxisomes
 Mitochondria
Large spherical, filamentous or rod-shaped with diameters of 0.5-1 μm and 2-7 μm long
Have double membranes
a. Outer porous smooth membrane - containing many transmembrane proteins called
porins that form channels
b. Inner less porous membrane
o Makes cristae
Shelf-like in many cells
Tubular in steroid secreting cells
Able to rapidly changing shape, fusing together and dividing by fission
 Mitochondria
Have two spaces
a. Intermembrane space (outer chamber, intracristal)
b. Matrix space (intercristal space), which contains:
o Enzymes, water, solutes, and granules that bind Ca2+ and Mg2+
o Mitochondrial ribosomes
o mRNA, tRNA and rRNA
o Circular DNA
Like those of prokaryotic cells
Are maternal
 Endosomes and phagosomes
Endosomes are membrane bound structures in the cell

May be released at other side in transcytosis

Phagosomes are found in the forms of:

1. Hetrophagosomes - ingested

2. Autophagosomes – self

3. May fuse with lysosomes forming the
hetrophagolysosomes and autophagolysosomes
 Proteasomes
A cylindrical structure made of four stacked rings, each composed of seven proteins
including proteases
Degrade denatured or nonfunctional polypeptides tagged for degradation with a small
protein called ubiquitin
 Ribosomes
About 20 × 30 nm in size
Composed of :
1. Several types of ribosomal RNA (rRNA)
2. Specific ribosomal proteins
Have large and small subunits
Found in two forms: free ribosomes and polyribosomes (polysomes)
 Polyribosomes or polysomes
Clustered along a single strand of mRNA, and occur as:
1. Free polyribosomes
Found in the cytoplasm
Synthesize structural proteins and enzymes for intracellular use
2. Attached polyribosomes
Attached to the outer nuclear membrane and RER
Produce proteins to be secreted, proteins of the ER, the Golgi apparatus,
Lysosomes or the cell membrane
 Cytoskeleton
Gel-like network of protein filaments
Include:
1. Microtubules
2. Intermediate filaments
3. Microfilaments
 Microtubules
Tubular with 24 nm outer diameter, 5 nm wall thickness and variable length up to many
micrometers
Wall is made by tubulin heterodimers
Each with α-tubulin and β-tubulin protein molecules
Arranged as thread like polymers called protofilaments
13 protofilaments, circumferentially form wall of a microtubule
 Microtubules
Contain microtubule-associated proteins (MAPs), Include:
a. Kinesin
o Transport vesicles towards the plus end
b. Dynein
o Move vesicles towards the minus end
c. Dynamin
o Motor for sliding microtubules in respect to each other, for activities such as
elongation of axon at growth cone
 Microtubules
Functions include
Intracellular transport
Maintaining cell shape
Intracellular compartmentalization
Cell migration
 Intermediate filaments
Are 10-12 nm wide, between microtubules and microfilaments
Unlike microtubules and actin filaments, are stable, conferring increased mechanical
stability to cell structure and tensile strength
Formed of tetramers of rod-like proteins making staggering helical cable-like bundles
Intermediate filaments
Several types, the most common ones include:

1. Lamins - in nuclear lamina of all types of cells

2. Keratin or Cytokeratin - in all epithelial cells

3. Vimentin - in mesenchylly derived cells

4. Desmin - in all muscle cells

5. Neurofilaments - in neurons

6. Glial fibrillary acid protein (glial filament) - in glial cells
 Microfilaments (Actin Filaments)
Measure 5 -7 nm in diameter
Composed of polymers of globular G-actin monomers that assemble into a double-
stranded helix of filamentous F-actin
G-actin is added to preexisting filaments for growth and branching, but new filaments can
also be formed
 Microfilaments (Actin Filaments)
Have various myosin motor transport cargo along F-actin.
Movement is usually toward the (+) ends
Interactions between F-actin and myosins form the basis for various cell
movements, which include:
Transport of organelles, vesicles, and granules in the process of cytoplasmic
streaming
Cytokinesis during mitosis
Endocytosis
Muscle and contractile cells contraction
 Centrioles
Located at the centrosome, near the nucleus and Golgi bodies
Cylindrical shaped, as a pair, perpendicular to each other
Made by 9 triplets of microtubules
Each microtubule in the triplet share portion of its neighbor’s wall
Surrounded by pericentriolar bodies or microtubule-organizing centers (MTOCs)
The MTOCs contain γ-tubulin rings, each of which serves as the nucleation site for the
growth of a single microtubule
 Centrioles
Functions include: dont forget the amount of centrioles in the shaft of flagella and body of cilia

Control microtubule polymerization
Transmit physical organizing forces
Control movements of organelles and vesicles
Form the poles of mitotic spindle apparatus
Form basal bodies of cilia and flagella
 Inclusions
Metabolically inactive materials
Include:
1. Lipid droplets
2. Glycogen granules
3. Various types of pigments
4. Crystals
 Inclusions
1. Lipid droplets
Mainly in the adipose cells, but also in many other cells
Triglycerides as energy source and stored cholesterol for the synthesis of steroids
 Inclusions
2. Glycogen granules
As clusters of electron-dense bodies (rosettes) specially abundant in the hepatocytes
and muscle cells
Converted to glucose
Inclusions
3. Pigments
a. Hemosiderin
Brown colored inclusion that accumulates within the macrophages
Breakdown product of hemoglobin
Inclusions
b. Lipofuscin
Yellowish-brown pigment that increase with increasing age
Are residual bodies of lysosomal activities
Inclusions
c. Melanin
Brownish pigment mainly in the cells of skin and hairs (melanocytes &
keratinocytes), but also in some neurons and in the pigment epithelium
of retina
 Inclusions
e. Carbon particles
Mainly in macrophages located in the lungs
 Inclusions
d. Carotenoid
A yellowish-orange-red pigment obtained from vegetables and fruits
 Inclusions
4. Crystals
May be crystalline form of certain proteins
In humans crystals described include:
Crystals of Reinke in the interstitial cells of Leydig of testis
Crystals of Charcot-Böttcher in the Sertoli cells of testis
 3. Nucleus
Oval, elongated or flattened in shape.
5-10 µm in diameter
Composed of:
1. Nuclear envelope
2. Chromatin
3. Nucleolus
4. Nucleoplasm
 Nuclear envelope
Double membrane separated by perinuclear cisternal space (30-50 nm wide)
1. Outer nuclear membrane
– Shows occasional continuities with the RER and has polyribosomes
– Surrounded by a loose network of intermediate filament vimentin from its cytoplasmic
aspect
 Nuclear envelope
2. Inner nuclear membrane
– Lined internally by nuclear (fibrous) lamina with intermediate filament lamins
Contains specific lamin receptors and several lamina-associated proteins
Functions include:
– Serve as scaffolding for chromatin
– Involved in nuclear organization, cell-cycle regulation, differentiation, and
gene expression
 Chromatin
DNA and associated 5 basic proteins called histone, and nonhistone proteins
Each of the 46 human DNA is about 40,000 μm long in average making a total of 1.8 -
2 meter long
Located in a nucleus with a diameter of only 5 - 10 μm
Undergo a super helical coiling to give repeating nucleosomes connected by short
connecting strands
 Chromatin
A nucleosome is made by:
146-166 base pairs of the DNA strand wrapped twice around a core of a pair of 4 types
of histones (H2A, H2B, H3 and H4) called an octamer
The connecting strand as a 2-nm filament is made by 50-80 DNA base pairs with
another type of histone (H1)
 Chromatin
Undergo further progressive super coiling and looping
 Chromatin
During interphase chromatin is identified as:
1. Heterochromatin transcriptionally inactive
As dense basophilic staining by LM and dense granular regions by EM
2. Euchromatin transcriptionally active
Lightly stained dispersed regions in the nucleus (not evident in the light
microscope)
 Heterochromatin
Is found as:
1. Marginal chromatin – along the inner surface of the nuclear envelope associated with
the fibrous lamina
2. Karyosomal chromatin – dispersed throughout the nucleus
3. Nucleolar associated chromatin – in the nucleolus
4. Bar body (sex chromatin) - one of the X chromosome , appears as drum stick
appendage in the neutrophils
 Nucleolus
Round basophilic & non-membrane bound bodies
Is site of rRNA synthesis and initial assembly of ribosomes
Has a protein named nucleostemin that regulates the cell cycle and influences cell
differentiation
 Nucleoplasm
Nuclear components other than the chromatin and nucleolus
Although appear amorphous medium under microscopy it contains:
Many proteins and other metabolites
Intranuclear lamin-based structures
Protein filaments of the nuclear pore complexes
RNA transcription and processing apparatus
 Cell Renewal
Somatic cells may be classified according to their mitotic activity as:
1. Renewing cells
– Slowly renewing cells
– Rapidly renewing cells
2. Stable cells (quiescent cells)Eg: gamete cell
3. Static cells (permanent cell)Eg: cardiac muscle cells, neurons

mucus cells 5-6 days
skin cell up-to a month
 Cell Cycle
A self-regulated sequential events that controls cell growth and cell division
The cell cycle stops at several checkpoints
Driven by a family of cytoplasmic proteins called cyclins, cyclically synthesized and
degraded during each cycle in response to intracellular or environmental signals
 Cell Cycle
In somatic cell is comprised of:
1. Interphase
a. Gap1 (G1) phase
b. Synthesis (S) phase
c. Gap2 (G2) phase
2. Mitosis
 The G1 (gap 1) phase
Longest and most variable - a few hours to several days
The cell:
Gathers nutrients
RNA and protein synthesis occurs
Grow to the size of the parent cell
Centrioles begin to duplicate
 The G1 (gap 1) phase
Monitored by 2 checkpoints:
1.G1 DNA-damage checkpoint
Monitors the integrity of DNA
If the DNA has irreparable damage it will most likely undergo programmed cell death
(apoptosis)( n e c r o s i s )
 The G1 (gap 1) phase
2. Restriction checkpoint
– Is the most important checkpoint in the cell cycle
– Cell self-evaluates its own replicative potential
If requirements are met enter the S phase
If requirements are not met cell cycle is paused and:
1. Attempt to remedy the problematic condition, or
2. Enter into G0 and awaiting further signals permanently (for static cell) or
temporarily (for stable cells)
 S (synthesis) phase
Takes about 7.5 to 10 hours
Undertake:
DNA replication and doubling
Histone synthesis
Beginning of centrosome duplication
Has S DNA-damage checkpoint
Monitor quality of replicating DNA
 G2 (gap 2) phase
Is a period of :
1. Further cell growth and reorganization of cytoplasmic organelles
2. Examination of the replicated DNA by 2 checkpoints:
a. G2 DNA-damage checkpoint
b. The unreplicated-DNA checkpoint
Prevents entry into the M phase before DNA synthesis is complete
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