Cell Physiology PDF

Summary

This document provides an overview of cell physiology, covering cell definitions, major cell regions, and their functions. It also discusses the historical context and composition of cells, emphasizing their role in overall organismal function.

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CELL PHYSIOLOGY

Prof. Dr. Senol DANE
LEARNING OBJECTIVES
At the end of this
lecture, you will be
able to:

 Define a cell

 List the three major
regions of a
generalised cell and
their functions
CELLS
 Just as bricks are the structural units of a
house, cells are the structural units of all living
things, from one-celled like amoebas to
multicellular organisms such as humans

 The human body has approximately 100
trillion of cells
THE CELL
 The English scientist Robert Hooke first observed
plant cells with a crude microscope in the late
1600s

 Then, in the 1830s two German scientists,
Matthias Schleiden and Theodor Schwann,
proposed that all living things are composed of
cells

 German pathologist Rudolf Virchow extended this
idea by contending that cells arise only from other
cells.
CELL
 A cell is the basic structural and functional
unit of living organisms

 When you define cell properties, you define
the properties of life

 The activity of an organism depends on both
the individual and collective activities of its’
cells

 Continuity of life from one generation to
another has a cellular basis
CELL
 The cell is the microscopic package that
contains all the parts necessary to survive.

 Therefore, loss of cellular homeostasis
underlies virtually every disease.

 Homeostasis means ‘health’.
CELLS
 The trillions of cells in the human body include
over 200 different cell types that vary in shape,
size, and function.
 The disc-shaped red blood cells, branching
nerve cells, and cube-like cells of kidney
tubules are just a few examples.
 Cells also vary in length-ranging from 2 µm in
the smallest cells to over a meter in the nerve
cells.
 A cell’s shape reflects its function.
CELLS
 Regardless of type, all cells are composed
chiefly of carbon, hydrogen, nitrogen, oxygen,
and trace amounts of several other elements.

 In addition, all cells have the same basic parts
and some common functions.
CELLS
 A human cell has three main parts:

1. The plasma membrane: the outer boundary
of the cell.
2. The cytoplasm: the intracellular fluid packed
with organelles, small structures that
perform specific cell functions.
3. The nucleus: an organelle that controls
cellular activities. Typically, the nucleus lies
near the cell’s center.
THE PLASMA MEMBRANE
LEARNING OBJECTIVES
 Describe the chemical composition of the
plasma membrane and relate it to membrane
functions.
PLASMA MEMBRANE
 The flexible plasma membrane defines the
extent of a cell, separating two of the body’s
major fluid compartments-the intracellular fluid
and the extracellular fluid.
 The term cell membrane is commonly used as a
synonym for plasma membrane.
 All organelles are enclosed in the same
membrane.
 The plasma membrane is not a passive
envelope.
 Its unique structure allows it to play a dynamic
role in cellular activities.
THE FLUID MOSAIC MODEL
 The fluid mosaic model of membrane
structure depicts the plasma membrane as an
exceedingly thin (7–10 nm) structure
composed of a double layer, or bilayer, of lipid
molecules with protein molecules “plugged
into” or dispersed in it.

 The proteins, many of which float in the fluid
lipid bilayer, form a constantly changing
mosaic pattern. The model is named for this
characteristic, the fluid mosaic model.
MEMBRANE LIPIDS
 The lipid bilayer forms the basic “fabric” of the
membrane.

 It is constructed largely of :
 phospholipids,
 with smaller amounts of glycolipids,
 cholesterol, and
 areas called lipid rafts.
PHOSPHOLIPIDS
 Each lollipop-shaped phospholipid molecule has a polar
“head” that is charged and is hydrophilic, and an
uncharged, nonpolar “tail” that is made of two fatty
acid chains and is hydrophobic.
 The polar heads are attracted to water and so they lie
on both the inner and outer surfaces of the membrane.
 The nonpolar tails, being hydrophobic, avoid water and
line up in the center of the membrane.
 All plasma membranes share a sandwich-like structure
 They are composed of two parallel sheets of
phospholipid molecules lying tail to tail, with their polar
heads exposed to water on either side of the
membrane or organelle.
GLYCOLIPIDS
 Lipids with attached sugar groups.
 Found only on the outer plasma membrane
surface, account for about 5% of total
membrane lipids.
 Their sugar groups, like the phosphate-
containing groups of phospholipids, make that
end of the glycolipid molecule polar, whereas
the fatty acid tails are nonpolar.
CHOLESTEROL
 Some 20% of membrane lipid is cholesterol.
 Like phospholipids, cholesterol has a polar
region (its hydroxyl group) and a nonpolar
region (its fused ring system).
 It wedges its platelike hydrocarbon rings
between the phospholipid tails, stabilizing the
membrane, while decreasing the mobility of
the phospholipids and the fluidity of the
membrane.
MEMBRANE PROTEINS
 Plasma membrane proteins allow the cell to
communicate with its environment.
 Proteins make up about half of the plasma
membrane by mass and are responsible for
most of the specialized membrane functions.
 Some membrane proteins float freely. Others
are “tethered” to intracellular structures that
make up the cytoskeleton and are restricted in
their movement.
 There are two distinct populations of
membrane proteins, integral and peripheral.
INTEGRAL PROTEINS
 Integral proteins are firmly inserted into the
lipid bilayer.
 Some protrude from one membrane face only,
but most are trans-membrane proteins that
span the entire membrane and protrude on
both sides.
 All integral proteins have both hydrophobic
and hydrophilic regions.
 This feature allows them to interact with both
the nonpolar lipid tails and the water inside
and outside the cell.
INTEGRAL PROTEINS
 Transmembrane (integral) proteins may be:
 Channels through which small, water-soluble
molecules or ions can move, thus bypassing the
lipid part of the membrane.
 Carriers that bind to a substance and then move
it through the membrane.
 Enzymes
 Receptors for hormones or other chemical
messengers and relay messages to the cell
interior—a process called signal transduction.
PERIPHERAL PROTEINS
 Peripheral proteins are not embedded in the lipid
bilayer.
 They attach loosely to integral proteins and are easily
removed without disrupting the membrane.
 Peripheral proteins include a network of filaments that
helps support the membrane from its cytoplasmic side.

 Peripheral proteins may
 Act as enzymes
 Act as motor proteins involved in mechanical functions,
such as changing cell shape during cell division and
muscle cell contraction.
 link cells together
LIPID RAFTS
 About 20% of the outer membrane surface contains
lipid rafts.
 They are dynamic assemblies of saturated
phospholipids associated with unique lipids called
sphingolipids and lots of cholesterol.

 Lipid rafts are more stable and less fluid than the
rest of the membrane, and they can include or
exclude specific proteins.
 Lipid rafts are concentrating platforms for certain
receptor molecules or for protein molecules needed
for cell signaling, membrane invagination, or other
functions.
LIPID RAFTS
THE GLYCOCALYX
 Glycocalyx is the fuzzy, sticky, carbohydrate-rich
area at the cell surface. Our cells are sugar-
coated.
 Is enriched both by glycolipids and by
glycoproteins secreted by the cell.
 Because every cell type has a different pattern of
sugars in its glycocalyx, the glycocalyx provides
highly specific biological markers by which
approaching cells recognise each other.
 For example, a sperm recognises an ovum by the
ovum’s unique glycocalyx. Cells of the immune
system identify a bacterium by binding to certain
membrane glycoproteins in the bacterial
glycocalyx.
APPLIED PHYSIOLOGY
 Definite changes occur in the glycocalyx of a
cell that is becoming cancerous.

 A cancer cell’s glycocalyx may change almost
continuously, allowing it to keep ahead of
immune system recognition mechanisms and
avoid destruction.
CYTOPLASM
LEARNING OBJECTIVES
By the end of this lecture, you will be able to:
 Describe the composition of the cytosol.
 Discuss the structure and function of
mitochondria.
 Discuss the structure and function of
ribosomes, the endoplasmic reticulum, and
the Golgi apparatus, including functional
interrelationships among these organelles.
 Compare the functions of lysosomes and
peroxisomes.
CYTOPLASM
 Is the cellular material between the plasma
membrane and the nucleus

 Is the site of most cellular activities

 The electron microscope reveals that it
consists of three major elements:
 the cytosol,
 inclusions, and
 organelles.
CYTOSOL
 The cytosol is the viscous, semitransparent fluid
in which the cytoplasmic elements are
suspended.
 It is a complex mixture with properties of both a
colloid and a true solution.
 Dissolved in the cytosol, which is largely water,
are proteins, salts, sugars, and a variety of other
solutes.
 The organelles are the metabolic machinery of
the cell.
 Each type of organelle carries out a specific
function.
INCLUSIONS
 Inclusions are chemical substances that may
or may not be present, depending on cell
type.
 Examples include stored nutrients, such as
the glycogen granules in liver and muscle
cells; lipid droplets in fat cells; pigment
(melanin) granules in certain skin and hair
cells; and crystals of various cell types.
CYTOPLASMIC ORGANELLES
 The organelles are specialized cellular compartments or
structures, each performing its own job to maintain the
life of the cell.
 Some organelles, the nonmembranous organelles, lack
membranes (cytoskeleton, centrioles, and ribosomes).
 Most organelles are bounded by a membrane like the
plasma membrane. This membrane enables the
membranous organelles (peroxisomes, lysosomes,
endoplasmic reticulum, and Golgi apparatus) to maintain
an internal environment different from that of the
surrounding cytosol.
 This compartmentalization is crucial to cell functioning.
Without it, thousands of enzymes would be mixed, and
biochemical activity would be chaotic.
MITOCHONDRIA
 Mitochondria are membranous organelles.
They elongate and change shape
continuously.
 They are the power plants of a cell, providing
most of its ATP supply.
 The density of mitochondria in a particular cell
reflects its energy requirements, and
mitochondria generally cluster where the
action is.
 Busy cells like kidney and liver cells have
hundreds of mitochondria, whereas relatively
inactive cells have just a few.
MITOCHONDRIA
 A mitochondrion is enclosed by two membranes.
 The outer membrane is smooth, but the inner
membrane folds inward, forming shelf-like cristae that
protrude into the matrix.
 Food fuels (glucose and others) are broken down to
water and CO2 by enzymes, some dissolved in the
mitochondrial matrix and others forming part of the
crista membrane.
 As the metabolites are broken down and oxidized, some
of the energy released is captured and used to attach
phosphate groups to ADP molecules to form ATP.
 This mitochondrial process is called aerobic cellular
respiration (oxidative phosphorylation) because it
requires oxygen.
MITOCHONDRIA
 Mitochondria contain their own DNA, RNA, and
ribosomes and can reproduce themselves.
 Mitochondrial genes direct the synthesis of 1%
of the proteins required for mitochondrial
function, and the DNA of the cell’s nucleus
encodes the remaining proteins needed to carry
out cellular respiration.
 If cellular requirements for ATP increase, the
mitochondria synthesise more cristae or simply
pinch in half (a process called fission) to
increase their number, then grow to their former
size.
RIBOSOMES
 Ribosomes are small, dark-staining granules
composed of proteins and a variety of RNAs
called ribosomal RNAs.
 Ribosomes are sites of protein synthesis.
 Some ribosomes float freely in the cytoplasm.
 Others are attached to membranes, forming a
complex called the rough (granular)
endoplasmic reticulum.
RIBOSOMES
 Free ribosomes float freely in the cytoplasm.
They make soluble proteins in the cytosol, as
well as those imported into mitochondria and
some other organelles.
 Membrane-bound ribosomes are attached to
membranes, forming a complex called the
rough endoplasmic reticulum.
 They synthesize proteins destined either for
incorporation into cell membranes or lysosomes,
or for export from the cell.
ENDOPLASMIC RETICULUM (ER)
 ER is an extensive system of interconnected
tubes and parallel membranes enclosing fluid
filled cavities, or cisterns.
 The ER is continuous with the outer nuclear
membrane and accounts for about half of the
cell’s membranes.
 There are two distinct varieties:
 Granular (rough) ER
 Agranular (smooth) ER.
ENDOPLASMIC RETICULUM
ROUGH ENDOPLASMIC RETICULUM
 The external surface of the rough ER is
studded with ribosomes.
 Proteins assembled on these ribosomes
thread their way into the fluid-filled interior of
the ER cisterns.
 When complete, the newly made proteins are
enclosed in vesicles for their journey to the
Golgi apparatus where they undergo further
processing.
THE ROUGH ER HAS SEVERAL
FUNCTIONS:
 Its ribosomes manufacture all proteins secreted
from cells. For this reason, the rough ER is
particularly abundant and well developed in most
secretory cells, antibody-producing plasma cells,
and liver cells, which produce most blood proteins.
 It is also the cell’s “membrane factory” where
integral proteins and phospholipids that form part
of all cellular membranes are manufactured.
 The enzymes needed to catalyse lipid synthesis
have their active sites on the external (cytosolic)
face of the ER membrane, where the needed
substrates are readily available.
SMOOTH ENDOPLASMIC RETICULUM
 The smooth ER is continuous with the rough
ER and consists of tubules arranged in a
looping network.
 Its enzymes play no role in protein synthesis.
 Instead, the enzymes catalyse reactions
involved with the following tasks:
1. Metabolise lipids, synthesise cholesterol, and
synthesise the lipid components of lipoproteins
(in liver cells)
SMOOTH ENDOPLASMIC RETICULUM
2. Synthesise steroid-based hormones such as
sex hormones (testosterone-synthesising cells of
the testes are full of smooth ER)
3. Absorb, synthesise, and transport fats (in
intestinal cells)
4. Detoxify drugs, certain pesticides, and
cancer-causing chemicals (in liver and kidneys)
5. Break down stored glycogen to form free
glucose (in liver cells especially)
SARCOPLASMIC RETICULUM
 Skeletal and cardiac
muscle cells have an
elaborate smooth ER
(sarcoplasmic
reticulum) that plays
an important role in
storing and releasing
calcium ions during
muscle contraction.
 Except for the prior
examples, most body
cells contain relatively
little smooth ER.
GOLGI APPARATUS
 The Golgi apparatus consists of stacked and
flattened membranous sacs, shaped like
hollow dinner plates.
 The Golgi apparatus is the principal “traffic
director” for cellular proteins.
 Its major function is to modify, concentrate,
and package the proteins and lipids made at
the rough or smooth ER and destined for
export from the cell.
 Transport vesicles that bud off from the rough
ER move to and fuse with the membranes of
the Golgi apparatus.
 Inside the apparatus, the proteins are
modified.
 Some sugar groups are trimmed while others
are added, and in some cases, phosphate
groups are added.
GOLGI APPARATUS
GOLGI APPARATUS
 The various proteins are “tagged” for delivery to
a specific address, sorted, and packaged in
vesicles:
 Vesicles containing proteins destined for export
pinch off from the trans face as secretory vesicles,
which migrate to the plasma membrane and
discharge their contents from the cell by exocytosis.
 Specialised secretory cells, such as the enzyme-producing
cells of the pancreas, have a lot of Golgi apparatus.
 The Golgi apparatus pinches off other vesicles
containing lipids and transmembrane proteins
destined for the plasma membrane or for other
membranous organelles.
 The Golgi apparatus also packages digestive
enzymes into lysosomes.
GOLGI APPARATUS
PEROXISOMES

Peroxisomes are spherical membranous sacs
containing a variety of powerful enzymes, the most
important of which are oxidases and catalases.

It neutralizes free radicals, highly reactive chemicals
with unpaired electrons that can damage the
biological molecules

Oxidases use molecular oxygen (O2) to detoxify
harmful substances, including alcohol and
formaldehyde.

Oxidases convert free radicals to hydrogen peroxide,
which is also reactive and dangerous but which the
catalases quickly convert to water.

Free radicals and hydrogen peroxide are normal by-
products of cellular metabolism

They have devastating effects on cells if allowed to
accumulate.
PEROXISOMES
 Peroxisomes are numerous in liver and kidney
cells, which are very active in detoxification.
 They also play a role in energy metabolism by
breaking down and synthesizing fatty acids.
 Peroxisomes look like small lysosomes
 Peroxisomes form by budding off the smooth
endoplasmic reticulum.
LYSOSOMES
 They are spherical membranous organelles
containing activated digestive enzymes.
 Lysosomes are large and abundant in
phagocytes, the cells that dispose of invading
bacteria and cell debris.
 Lysosomal enzymes can digest almost all
kinds of biological molecules.
 They work best in acidic conditions and so are
called acid hydrolases.
LYSOSOMES
 The lysosomal membrane is adapted to serve
lysosomal functions in two important ways.
1. It contains H+ (proton) “pumps,” which are
ATPases that gather hydrogen ions from the
surrounding cytosol to maintain the organelle’s
acidic pH.
2. It retains the dangerous acid hydrolases while
permitting the final products of digestion to
escape so that they can be used by the cell or
excreted.
In this way, lysosomes provide sites where
digestion can proceed safely within a cell.
LYSOSOMES
 Lysosome functions:
 Digest particles taken in by endocytosis,
particularly ingested bacteria, viruses, and toxins
 Degrade worn-out or nonfunctional organelles
 Perform metabolic functions, such as glycogen
breakdown and release
 Break down non-useful tissues, such as the webs
between the fingers and toes of a developing fetus
and the uterine lining during menstruation
 Breaking down bone to release calcium ions into
the blood
 The lysosomal membrane is ordinarily quite
stable, but it becomes fragile when the cell is
injured or deprived of oxygen and when
excessive amounts of vitamin A are present.
 When lysosomes rupture, the cell digests
itself, a process called autolysis.
 Autolysis is the basis for desirable destruction
of cells.
REGRESSION OF TISSUE
 Tissues often regress to a smaller size.

 This occurs in the uterus after pregnancy; in
muscles during long inactivity and in mammary
glands after lactation.

 Lysosomes are responsible for this regression.

 Lack of activity increases lysosomal activity

 Lysosomes contain bactericidal agents that can kill
bacteria: lysozyme, lysoferrin, acid at a pH 5.0
APPLIED PHYSIOLOGY
 Lysosomes degrade glycogen and certain lipids in
the brain at a relatively constant rate. In Tay-
Sachs disease, an inherited condition seen mostly
in Jews from Central Europe, the lysosomes lack
an enzyme needed to break down a glycolipid
abundant in nerve cell membranes. As a result,
the nerve cell lysosomes swell with undigested
lipids, which interfere with nervous system
functioning. Affected infants typically have doll-
like features and pink translucent skin. At 3 to 6
months of age, the first signs of disease appear
(motor weakness). These symptoms progress to
mental retardation, seizures, blindness, and
ultimately death within 18 months.
THE ENDOMEMBRANE SYSTEM
 The endomembrane system is a system of
organelles that work together mainly to:
1. produce, degrade, store, and export biological
molecules, and
2. degrade potentially harmful substances.
 It includes the ER, Golgi apparatus, transport
and secretory vesicles, and lysosomes, as well
as the nuclear membrane.
 There are continuities
between the nuclear
envelope and the rough
and smooth ER.
 The plasma membrane,
which is not an
endomembrane, is also
functionally part of this
system.
 Some of the vesicles
“born” in the ER migrate to
and fuse with the Golgi
apparatus or the plasma
membrane, and vesicles
arising from the Golgi
apparatus can become part
of the plasma membrane,
secretory vesicles, or
lysosomes.
The
Endomembr
ane System
CYTOSKELETON
LEARNING OBJECTIVES
By the end of this
lecture, you should
be able to:
 Name and describe
the structure and
function of
cytoskeletal
elements.
CYTOSKELETON
 The cytoskeleton is a network of rods running
through the cytosol and accessory proteins that
link these rods to other cell structures.
 It acts as a cell’s “bones,” “muscles,” and
“ligaments” by supporting cellular structures
and providing the machinery to generate
various cell movements.
 The 3 types of rods in the cytoskeleton:
 microfilaments,
 intermediate filaments, and
 microtubules.
 None of these are membrane covered.
CYTOSKELETON
 MICROFILAMENTS
 The thinnest elements of the
cytoskeleton are semiflexible actin
strands
 Each cell has its own unique
arrangement of microfilaments.
 All cells have a dense cross-linked
network of microfilaments, called
the terminal web, attached to the
cytoplasmic side of their plasma
membrane.
 The web strengthens the cell
surface, resists compression, and
transmits force during cellular
movements and shape changes.
MICROFILAMENTS
 Most microfilaments are involved in cell motility or
changes in cell shape.
 For example, actin filaments interact with another
protein, myosin, to generate contractile forces in a
cell.
 This interaction also forms the cleavage furrow
that pinches one cell into two during cell division.
 Microfilaments attached to cell adhesion
molecules are responsible for amoeboid motion,
and for the membrane changes like endocytosis
and exocytosis.
 Except in muscle cells, actin filaments are
constantly breaking down and re-forming from
smaller subunits.
 Cell Division

Amoeboid Motion
with Endo- and
Exocytosis
 INTERMEDIATE FILAMENTS
 Intermediate filaments are tough,
insoluble protein fibers.
 They are the most stable and
permanent.
 They attach to desmosomes, and their
job is to act as wires to resist the forces
exerted on the cell.
 Because their protein composition varies
in different cells, they have numerous
names-for example, they are called
neurofilaments in nerve cells and keratin
MICROTUBULES
 The elements with the largest diameter,
hollow tubes made of spherical protein
subunits called tubulins.
 They radiate from a small region of
cytoplasm near the nucleus called the
centrosome.
 They are dynamic organelles, constantly
growing out from the centrosome,
disassembling, and then reassembling.
 The stiff but bendable microtubules
determine the shape of the cell, as well as
the distribution of cellular organelles.
MICROTUBULES
 Mitochondria, lysosomes, and secretory vesicles
attach to the microtubules.
 Tiny protein machines called motor proteins
(kinesins, dyneins, and others) continually move
and reposition the organelles along the
microtubules.
 Motor proteins work by changing their shapes.
Powered by ATP, some motor proteins appear to
act like train engines moving substances along
on the microtubular “railroad tracks.”
 Others move “hand over hand” somewhat like
an orangutan-gripping, releasing, and then
gripping again at a new site further along the
microtubule
MOVEMENT AND REPOSITION OF THE ORGANELLES
ALONG THE MICROTUBULES
 https://www.youtube.com/watch?
v=9RUHJhskW00
CENTROSOMES, CENTRIOLES
AND CELLULAR EXTENSIONS
CENTROSOME
 Microtubules are anchored at one end to
the centrosome.
 The centrosome acts as a microtubule
organizing center.
 It has a matrix that contains paired
centrioles, small, barrel-shaped
organelles oriented at right angles to
each other.
 The centrosome matrix generates
microtubules and organizes the mitotic
spindle in cell division.
CENTRIOLES
 Each centriole consists of a pinwheel array of
nine triplets of microtubules, each connected
to the next by nontubulin proteins and
arranged to form a hollow tube.
 Centrioles are known as basal bodies form the
bases of cilia and flagella.
 The “9 + 2” pattern of microtubules in the
cilium or flagellum itself (nine doublets, or
pairs, of microtubules encircling one central
pair) differs from that of a centriole (nine
microtubule triplets).
CILIA
 Cilia are motile extensions on the surfaces of
certain cells.
 Ciliary action moves substances in one
direction.
 For example, ciliated cells that line the
respiratory tract propel mucus laden with dust
particles and bacteria upwards, away from the
lungs.
 When a cell is about to form cilia, the centrioles
multiply and line up beneath the plasma
membrane at the cell’s surface.
 Microtubules then “sprout” from each centriole,
forming the ciliary projections.
CILIATED CELLS THAT LINE THE
RESPIRATORY TRACT
CILIA
 The cilium has flexible cross-linking proteins,
and motor proteins (dynein arms) that
promote its movement.
 The dynein arms of one microtubule doublet
grips its adjacent doublet, and powered by
ATP, pushes it up, releases, and then re-grips.
 Because the doublets are physically restricted
by other proteins, they cannot slide far and
are forced to bend.
 The collective bending of all the doublets
causes the cilium to bend.
 As a cilium moves, it alternates
rhythmically between a propulsive power
stroke, when it is nearly straight and
moves in an arc, and a recovery stroke,
when it bends and returns to its initial
position.
 The cilium produces a pushing motion in a
single direction that repeats some 10 to 20
times per second.
 The bending of one cilium is quickly
followed by the bending of the next and
then the next, creating a current at the cell
FLAGELLA
 Flagellum is projections formed by centrioles
but is longer than cilia.

 The only flagellated cell in the human body is
sperm, which has one propulsive flagellum,
commonly called a tail.

 Cilia propel other substances across a cell’s
surface, whereas a flagellum propels the cell
itself.
FLAGELLA OF THE SPERM CELL
MICROVILLI
 Microvilli are minute, fingerlike extensions of
the plasma membrane that project from an
exposed cell surface.
 They increase the plasma membrane surface
area and are found on the surface of
absorptive cells such as intestinal and kidney
tubule cells.
 Microvilli have a core of bundled actin
filaments that extend into the terminal web of
the cytoskeleton.
 Actin is a contractile protein, but in microvilli it
functions as a mechanical “stiffener.”
MICROVILLI
 Ciliary action
 https://www.youtube.com/watch?v=xQG3QHM
xoTA

 Sperm action
 https://www.youtube.com/watch?v=qz7uLX-A
Olk

 https://www.youtube.com/watch?
v=_5OvgQW6FG4