Chapter 3 Cellular Form and Function PDF

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This document is a chapter on cellular form and function from a textbook. It discusses the structure and function of cells in the human body. It covers different cell types, cell shapes and the relationship between surface area and volume, cell division and cell destiny.

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Chapter 3

Cellular Form and Function

ANATOMY & PHYSIOLOGY
The Unity of Form and Function
NINTH EDITION
KENNETH S. SALADIN

© 2021 McGraw Hill. All rights reserved. Authorized only for instructor use in the classroom.
No reproduction or further distribution permitted without the prior written consent of McGraw Hill.
 Introduction to a Cell

The cell is the basic, living, structural, and functional unit of the body.
Cytology is the study of cell structure.
Cell physiology is the study of cell function.

© McGraw Hill 2
 Cells: many different types
Introduction to a Cell
Neurons
Red blood cells
Oocytes

Simple Squamous Epithelium
Muscle cells
Sperm cell

http://faculty.washington.edu/chudler/ca1pyr.html
http://www.worldofstock.com/closeups/PHE1014.php

© McGraw Hill http://www.cytochemistry.net/microanatomy/blood/blood_cells.htm 3
 Cell Shapes

Note: A cell’s shape can appear different if viewed Figure 3.1
in a different type of section (longitudinal versus cross section)
© McGraw Hill 4
 The Relationship Between Cell Surface Area and Volume

Human cell size
Most cells about 10 to 15 μm in diameter
Egg cells (very large) 100 μm diameter
Some nerve cells over 1 m long

Limit on cell size: an overly large cell cannot support
itself, may rupture

For a given increase in diameter, volume increases
more than surface area

Volume proportional to cube of diameter
Surface area proportional to square of diameter

Why does this matter?
Figure 3.2
Access the text alternative for slide images.

© McGraw Hill 5
The cell can be divided into three
principal parts:
1. Plasma membrane (cell membrane)
- flexible barrier.
2. Cytoplasm
a. Cytosol - fluid portion.
b. Organelles - internal cellular
structures other than the nucleus.
3. Nucleus - contains DNA or genetic
material..

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7

Along with cells, another important component of the body are the body fluids, mostly
watery solutions.

1. The fluid within body cells is the intracellular fluid (ICF).

2. The fluid outside of body cells is the extracellular fluid (ECF) (also called
intercellular fluid) found as:
a. Extracellular fluid (ECF) filling the narrow spaces between cells of
tissues is called interstitial fluid.
b. Extracellular fluid (ECF) in blood vessels is called plasma.
c. Other types of ECF's include lymph in lymphatic vessels and
cerebrospinal fluid (CSF) in the meninges of the nervous system).

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 The Plasma Membrane

Plasma membrane—border of the cell
- a flexible yet sturdy barrier that
surrounds the cytoplasm of the cell.
The fluid mosaic model describes its
structure. The membrane consists of
a "sea of lipids", with proteins afloat or
anchored,

Has intracellular and extracellular
faces
- Intracellular side of membrane
faces cytoplasm and extracellular
face faces outwards.

Figure 3.4
Access the text alternative for slide images.

© McGraw Hill a: © Don Fawcett/Science Source 8
 The Plasma Membrane 3

The functions of the plasma
membrane include:

Physical barrier.

Regulation of exchange of
molecules and ions with the
environment.

Sensitivity to the environment.

Structural support.

Figure 3.5b
Access the text alternative for slide images.

© McGraw Hill 9
10
Lipid Bilayer

98% on membrane
molecules are lipids

The phospholipid bilayer forms the basic
framework of the cell membrane.
The membrane consists of two
phospholipid layers.

Within these layers are also two other
types of lipid molecules, cholesterol
(lipid with a ring structure) and
glycolipids (lipid with attached
carbohydrate groups).

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11

The phospholipid bilayer forms because of the amphipathic nature of the phospholipid molecules.

The phospholipids orient themselves within the bilayer by positioning themselves with the
hydrophilic "heads" directed outwards and the hydrophobic "tails" directed inwards. About 75% of
the lipids making up the lipid potion of the membrane are phospholipid molecules.

The hydrophilic, polar heads face the polar watery fluid on two sides:
1) intracellular fluid (ICF, cytosol) on the inside
2) extracellular fluid (ECF) on the outside.

The hydrophobic, nonpolar fatty acid tails are directed towards the inside of the plasma
membrane, forming the nonpolar, hydrophobic region in the phospholipid membrane's interior.

Cholesterol molecules make up about 20% of lipid potion of membrane. Cholesterol molecules are
interspersed among phospholipids and provide some rigidity to the membrane. Higher concentrations of
cholesterol molecules can increase membrane fluidity by preventing the phospholipid molecules from
packing too closely together.

Glycolipids appear only on the side of the membrane that faces the extracellular fluid. They make up the
remaining 5% of membrane lipids. They contribute to the glycocalyx.
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 Membrane Proteins
Make up about 2% on membrane molecules, but are much larger and constitute
about 50% of the weight of the membrane.

Proteins float in the “sea of lipid” (i.e., phospholipid bilayer); some are anchored by
cytoskeleton and some are able to move freely (like ice cubes floating in water). They are
divided into two categories:

1. Integral proteins – these proteins are embedded in the plasma membrane, and may be
exposed on both of the ECF (ICF) sides, or only one side of the plasma
membrane. Because integral proteins are amphipathic, they also may interact with both
the hydrophilic extracellular region, and the hydrophobic interior of the phospholipid
membrane. Some integral proteins are transmembrane proteins, which means the
pass completely through the phospholipid bilayer.
2. Peripheral proteins – These proteins are loosely attached to either the inside or outside
of the plasma membrane. The peripheral proteins on the intracellular side are usually
attached to a transmembrane protein as well as the cytoskeleton inside the cell.
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13
Many membrane proteins are glycoproteins. These are integral or peripheral proteins that have chains of
sugar molecules attached to them and are located on the outside surface of the plasma
membrane. Collectively, glycoproteins and glycolipids form a carbohydrate-enriched coat, called the
glycocalyx, around the outside of a cell. The glycocalyx has several functions:

1. Act as signature sequences that allow cells to recognize one another, and is important in immune
function.
2. Adherence.
3. Protection from digestion.
4. Attracts water molecules.

© McGraw Hill 13
 Functions of Membrane Proteins

Figure 3.7
Access the text alternative for slide images.

© McGraw Hill 14
 Membrane Transport
Transport of material across the cell membrane is essential as some substances are needed in the cell for
metabolism and other substances must be moved out as waste or for export. The plasma membrane is
selectively permeable – it allows some things to move across easily and not other things.
It is generally permeable to small solutes that are soluble in lipids, nonpolar or hydrophobic (e.g., O2,
CO2, lipid-based hormones).
It is impermeable to water-soluble, polar or hydrophilic substances (e.g., ions, glucose). These
substances can only cross the membrane through carrier or channel proteins.

Substances move across the cell membrane by three types of transport processes:
1. Diffusion – random movement of a substance down its concentration gradient. It does not require
energy (passive).
2. Carrier-mediated transport – movement of a substance that requires the presence of specialized
integral proteins. It may or may not require energy (passive or active).
3. Vesicular transport – movement of large amounts of material across a membrane. In this process,
the material becomes enclosed and is transported within a tiny membrane-surrounded sac called a
vesicle. It does require energy.
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1. Diffusion – concentration gradients

Because the membrane is selectively permeable, some substances occur in higher concentration
inside, while others occur in higher concentration outside (e.g., [Na+] and [O2] are higher outside,
[K+] and [CO2] are higher inside). This results in a concentration gradient across the cell
membrane called a chemical gradient.
Also, more anions end up inside the cell, and more cations outside the cell. This results in a
charge difference across the cell membrane called a charge gradient. The inner surface of the
membrane is more negatively charged and the outer surface is more positively charged.

Together these two gradients form the electrochemical gradient, which helps move substances
across the membrane. This is very important to a cell's function, especially an excitable cell like a
neuron or muscle cell.

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 Diffusion across Cell Membranes

Diffusion is the movement of molecules by random motion (Brownian motion) from areas of high
concentration to areas of low concentration. E.g., a sugar cube in a cup of coffee: sugar molecules
move away from the cube, and eventually equilibrium is reached.
The diffusion rate across plasma membranes is influenced by several factors:
1. Diffusion distance
2. Size or mass of the diffusing substance
3. Temperature
4. Steepness of the concentration gradient
5. Electrical forces
6. Surface area

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Two Types of Diffusion

1.Simple diffusion – small nonpolar
and hydrophobic molecules (e.g.,
O2, CO2, steroids, short-chain fatty
acids, fat-soluble vitamins) can
diffuse through the lipid
bilayer. Large nonpolar molecules
can get stuck in the membrane.

2. Channel-mediated diffusion –
mostly for small, inorganic ions and
water. Each ion channel is specific
for a particular ion.

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 Osmosis: A Special Case of Diffusion

Osmosis is the movement (diffusion) of
water through a selectively permeable
barrier from an area of higher concentration
of water to an area of lower concentration
of water across the membrane.

Alternately, water moves from an area of
lower solute concentration (hypotonic) to an
area of higher solute concentration
(hypertonic).

Figure 3.14
Access the text alternative for slide images.

© McGraw Hill 19
20

Water moves through cells in two ways:

1. Through special channel proteins called
aquaporins.

2. By slipping through temporary spaces
between membrane lipids caused by their
movement.

https://healthjade.com/wp-content/uploads/2019/04/aquaporins.jpg

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© 2018 Pearson Education, Inc.

a Isotonic solution b Hypotonic solution c Hypertonic solution

In an isotonic saline solution, no In a hypotonic solution, the water In a hypertonic solution, water
osmotic flow occurs, and the red flows into the cell. The swelling moves out of the cell. The red
blood cells appear normal in size may continue until the plasma blood cells crenate (shrivel).
and shape. membrane ruptures, or lyses.

Water
molecules

Solute
molecules

SEM of a normal RBC SEM of swollen RBC in SEM of crenated RBCs
in an isotonic solution a hypotonic solution in a hypertonic solution

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Tonicity of a solution relates to how the solution influences the shape of body cells

Tonicity is important in intravenous (IV) solutions. A solution can be:
Isotonic – the concentrations of solutes are the same on both sides of the membrane and
water molecules enter and exit at the same rate. A red blood cell immersed in an isotonic
solution maintains its normal shape.
o Isotonic IV solutions – isotonic saline solution (0.9% NaCl).
Hypotonic – the concentration of solutes is higher inside the cell and water moves into the
cell, where it occurs in low concentration. A red blood cell immersed in a hypotonic solution
undergoes hemolysis (i.e., it bursts).
Hypertonic – the concentration of solutes is lower inside the cell and water moves out of
the cell, where it occurs in higher concentration. A red blood cell immersed in a hypertonic
solution undergoes crenation (i.e., it shrinks).

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 Effects of Tonicity on RBCs

Figure 3.15a Figure 3.15b Figure 3.15c

Hypotonic, isotonic, and hypertonic solutions affect the fluid
volume of a red blood cell. Notice the crenated and swollen cells.
Access the text alternative for slide images.

© McGraw Hill (a-c): © David M. Philips/Science Source 23
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2. Carrier-Mediated Transport

In carrier-mediated transport, integral proteins bind
specific ions or organic substances and carry them
across the plasma membrane. All forms of carrier-
mediated transport have the following characteristics:
1. Specificity – each carrier protein binds and
transport only certain substances. For example, a
glucose transporter only carries glucose.
2. Saturation limits – the rate of substance transport is
limited by the availability of carrier proteins.
3. Regulation – the cell can control (regulate) the
activity of carrier proteins, especially through the
action of hormones.
There are two types of carrier-mediated transport:
facilitated diffusion and active transport.

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 Facilitated Diffusion
Many nutrients (e.g., amino acids, glucose) are highly charged or too large to diffuse through channels. These
substances can be passively transported across the plasma membrane by carrier proteins in a process called
facilitated diffusion.

In facilitated diffusion, substances move down their concentration gradient, so that no energy is required
(passive).

The molecule to be transported binds to a specific receptor site on the carrier protein. The binding alters the
shape of the protein, which then releases the molecule on the other side of the plasma membrane.

Figure 3.17

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Active transport

Active transport is an energy-requiring process in which carrier proteins move
solutes regardless of concentration gradient. There is two types of active
transport depending on the source of energy used to drive the process:

1. Primary active transport – energy from the hydrolysis of ATP changes the
shape of a transport protein. The most common primary active transport
mechanism in the body is called the sodium-potassium exchange pump (also
called the Na+/K+ ATPase).

Up to 40% of our body's energy is spent just making this pump run. Each cell of
our body has thousands of these pumps in its membrane, working all the time.

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 The Na+/K+ pump The sodium-potassium exchange pump maintains
the concentration gradients of Na+ (high outside)
and K+ (high inside) across the cell membrane. It
works like this:
1. Three Na+ in the cytosol bind to the pump.
2. This causes ATP to be hydrolyzed to ADP, and
the phosphate group removed from ATP is
attached to the pump protein. The pump protein
changes shape, causing it to release the Na+ into
the ECF.
3. In its new shape, two spots are available for K+
ions to bind to the pump. When they bind, they
make the pump release the phosphate group,
and the pump springs back to its original shape.
4. The two K+ are released into the cytosol. The
pump is now back to its original state, ready to
Figure 3.19 bind more Na+ and go again. Each cycle uses
one ATP molecule.

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 Secondary Active Transport

2. Secondary active transport – energy comes from
an ionic concentration gradient that was established
by primary active transport. The energy stored in a
Na+ gradient is used to drive other substances
across the membrane (i.e., the other substances
gets a "free ride").

As Na+ leaks into the cell, another substance can be
simultaneously transported in the same direction by
cotransport/symport (e.g., glucose and amino acids
enter the cell with Na+) or in the opposite direction
by countertransport/antiport (e.g., H+ and Ca2+ exit
the cell while Na+ enters the cell). Such transporters
are especially important in the kidneys.

Figure 3.18

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3. Vesicular Transport
Molecules that are too large to be moved by passive or active transport cross the membrane in
vesicles. A vesicle is a small membrane-bound sac, formed when a bit of cell membrane pinches
off. All types of transport using vesicles (also called bulk transport) require energy supplied by ATP.
Vesicles can move in two directions:

Exocytosis is movement of
substances out of a cell.
o Exocytosis is used by cells that
produce secretions (e.g.,
secretory cells, nerve
cells). Products meant to go
outside of the cell are packaged in
carrier vesicles and brought to the
plasma membrane. The
membrane of the vesicle fuses
with the plasma membrane and
the cargo is delivered to the
extracellular fluid.

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 Phagocytosis

Endocytosis is movement of substances into
a cell. There are three types of endocytosis:

1. Phagocytosis or "cell eating" – uptake of
large particles (e.g., worn-out cells, bacteria,
viruses) (Figure 3-22). When taken into the
cell, the particles are enclosed in a
phagosome, which then fuses with a
lysosome (a type of organelle). Lysosomes
contain acids and enzymes that can digest
large particles.

Figure 3.20
Access the text alternative for slide images.

© McGraw Hill 30
 2. Pinocytosis or "cell drinking" – non-selective uptake of fluid surrounding the cell, which allows
the cell to sample its surroundings. Whatever is taken up in pinocytic vesicles is digested by
lysosomes and delivered into the cell (e.g., amino acids, fatty acids). What is not useful to the
cell is collected in a residual body and dumped outside the cell.

3. Receptor-mediated endocytosis – highly specific type of endocytosis by which cells take up
specific ligands
For example, the HIV virus attach to the CD4 receptor on helper T cells (a type of white blood
cells) and are transported in by receptor-mediated endocytosis.

Figure 3.21

© McGraw Hill (1-3): Courtesy of the Company of Biologists, Ltd. 31
 Transcytosis

Transcytosis is a method by
which substances can cross the
cell.

Substances enter the cell by
endocytosis, and cross the cell
within a vesicle to exit the
opposite side of the cell by
exocytosis.

Figure 3.22
Access the text alternative for slide images.

© McGraw Hill © Don Fawcett/Science Source 32
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Cytoplasm

The cytoplasm has two components: (1) the cytosol and (2) a variety of organelles
that perform different functions in the cell.
The cytosol is the intracellular fluid portion of the cytoplasm that surrounds
organelles (Figure 3-1). It is composed mostly of water, but is thick and jelly-like
due to dissolved proteins, carbohydrates, lipids and inorganic
substances. Functionally, the cytosol is the medium in which many metabolic
reactions occur.
Organelles are specialized structures that have characteristic shapes and that
perform specific functions in cellular metabolism.

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 Structure of a Representative Cell

Figure 3.4
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© McGraw Hill 34
 The Cytoskeleton

Cytoskeleton—network of protein filaments
and cylinders
Determines cell shape, supports
structure, organizes cell contents, directs
movement of materials within cell,
contributes to movements of the cell as a
whole

Composed of: microfilaments, intermediate
fibers, microtubules

Figure 3.24
Access the text alternative for slide images.

© McGraw Hill b: © Dr. Torsten Wittmann/Science Source 35
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Ribosomes

Ribosomes—small granules of protein and RNA
Found in nucleoli, in cytosol, and on outer surfaces of rough ER, and nuclear
envelope

They “read” coded genetic messages (messenger RNA) and assemble amino
acids into proteins specified by the code

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Endoplasmic Reticulum

Endoplasmic reticulum—system of
channels (cisterns) enclosed by membrane

Rough endoplasmic reticulum—parallel,
flattened sacs covered with ribosomes
Continuous with outer membrane of
nuclear envelope, often largest
organelle
Produces phospholipids and proteins of
nearly all cell membranes
Synthesizes proteins that are packaged
in other organelles or secreted from cell

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38

Smooth endoplasmic reticulum
Lack ribosomes
Cisterns more tubular and branching
Cisterns thought to be continuous with
rough ER
Synthesizes steroids and other lipids
Detoxifies alcohol and other drugs
Calcium storage
Rough and smooth ER are functionally
different parts of the same network

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Golgi complex—a system of cisterns that
synthesizes carbohydrates and puts
finishing touches on protein synthesis
Receives newly synthesized proteins
from rough ER
Sorts proteins, splices some, adds
carbohydrate moieties to some, and
packages them into membrane-bound
Golgi vesicles

Figure 3.29
Access the text alternative for slide images.

© McGraw Hill © David M. Phillips/Science Source 39
 Lysosomes—package of enzymes bound
by a membrane
Generally round, but variable in shape

Functions
Intracellular hydrolytic digestion of
proteins, nucleic acids, complex
carbohydrates, phospholipids, and other
substances
Autophagy—digestion of cell’s surplus
organelles
Autolysis—“cell suicide”: digestion of a
Figure 3.30a surplus cell by itself
Access the text alternative for slide images.

© McGraw Hill (a-b): © Don Fawcett/Science Source 40
41

Peroxisomes—resemble lysosomes but contain
different enzymes and are produced by
endoplasmic reticulum
Function is to use molecular oxygen to oxidize
organic molecules
Reactions produce hydrogen peroxide (H2O2)
Catalase breaks down excess peroxide to H2O
and O2
Neutralize free radicals, detoxify alcohol, other
drugs, and a variety of blood-borne toxins
Break down fatty acids into acetyl groups for
mitochondrial use in ATP synthesis
In all cells, but abundant in liver and kidney Figure 3.30b

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 Mitochondria Mitochondria—organelles specialized for
synthesizing ATP
Surrounded by a double membrane
Inner membrane has folds called cristae
Spaces between cristae called matrix
Matrix contains ribosomes, enzymes used for
ATP synthesis, small circular DNA molecule
Multiple molecules of mitochondrial DNA
(mtDNA)
“Powerhouses” of the cell
Energy is extracted from organic
molecules and transferred to ATP

Figure 3.32
Access the text alternative for slide images.

© McGraw Hill © Keith R. Porter/Science Source 42
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Cilia and Flagella

Cilia function to move
fluid an material along
the cell’s surface (e.g.
airways).

Flagella generate
forward motion (sperm
cells only).

https://rep.bioscientifica.com/view/journals/rep/159/2/images/REP-19-0096fig1.jpeg

https://upload.wikimedia.org/wikipedia/commons
/3/33/Blausen_0750_PseudostratifiedCiliatedCol
umnar.png

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 Nucleus

The nucleus is usually the most prominent feature of a cell when you look under a microscope
(Figure 3-10). Most body cells have a single nucleus; some (red blood cells) have none, whereas
others (skeletal muscle fibers) have several.
The parts of the nucleus include:
Nuclear envelope – membrane similar to the plasma membrane.
Genes – the cell’s hereditary units consisting of the genetic material (DNA).
o Each gene represents a set of directions (i.e., blueprint) to make a specific polypeptide or
protein.

o Genes are arranged in single file along chromosomes. Each chromosome is a long
molecule of DNA that is coiled together with several proteins (Figure 3-11).

▪ Human somatic cells (body cells, not reproductive cells) have 46 chromosomes
arranged in 23 pairs (2 copies of each) and are diploid.
▪ Human reproductive cells have 23 chromosomes (single copy) and are haploid.

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 Structure of the Nucleus

Figure 3.27
Access the text alternative for slide images.

© McGraw Hill 45
 The Nucleus as Seen by Electron Microscope

Figure 3.26a Figure 3.26b

© McGraw Hill a: © Richard Chao; b: © E.G. Pollock 46
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Control of Cell Destiny

A cell in our body has three possible destinies:
1. Maintain itself without dividing – many nerve and muscle cells have long
lifespan without dividing.
2. Grow and divide – cell division is necessary to replace worn-out cells or to
grow. Generally, the longer the life expectancy of a cell, the slower its mitotic rate.
Stem cells continuously divide and give rise to more daughter cells.
o

3. Die – cell death is also necessary during embryonic development (some cells
are only needed at some stages of development), and to eliminate body cells,
such as cancer cells or virally-infected cells.
o Apoptosis – genetically controlled cell death where "suicide" enzymes kill the
cell. Apoptosis is a normal type of cell death, whereas necrosis is a
pathological type of cell death due to tissue injury.

© McGraw Hill 47
 Because learning changes everything. ®

Chapter 4

Genes and Cellular Function
ANATOMY & PHYSIOLOGY
The Unity of Form and Function
NINTH EDITION
KENNETH S. SALADIN

© 2021 McGraw Hill. All rights reserved. Authorized only for instructor use in the classroom.
No reproduction or further distribution permitted without the prior written consent of McGraw Hill.
 Cell Division

Cell division is the process by which cells
reproduce themselves. It consists of
nuclear division (mitosis or meiosis) and
cytoplasmic division (cytokinesis).

Copyright © McGraw Hill LLC. All rights reserved. No reproduction or distribution without the prior written consent of McGraw Hill LLC. 49
 Mitosis

Cell division that results in an increase in the
number of body cells (two new cells per dividing cell)
is called somatic cell division, and it involves mitosis
and cytokinesis.

Produces two daughter cells that are identical to the
parent cell (and each other) and have the same
number of chromosomes (diploid daughter cells).

This type of division occurs in billions of our body
cells each day.

The DNA of the cell is duplicated, and one copy
goes to each cell.

Sometimes, in this process, errors or mutations Figure 4.15 parts 3 & 4
occur.
© McGraw Hill (both): © Ed Reschke 50
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Meiosis

Cell division that results in the production of
sperm and eggs is called reproductive cell
division (occurs only in testes and ovaries),
and it consists of a meiosis and cytokinesis.

In reproductive cell division, a cell undergoes
two divisions which result in four
reproductive or germ cells that have half of
the normal number of chromosomes (haploid
daughter cells)

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 Cancer

Cancer is a group of diseases characterized by
uncontrolled cell proliferation.
We are constantly subject to mutations in
genes.

Sometimes these mutations are caused by
exposure to carcinogens, which are substances
or agents that have been shown to cause
cancer

Also, as we age, DNA replication becomes less
error-proof, and we gradually accumulate
mutations in our cells.

Mutagens cause mutations in cells
Mutations do not always have serious consequences
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53

A large proportion of our DNA serves as "filler" or "repeat", and does not
contain essential genes. A mutation in these regions is unlikely to have
significant consequences.

Many genes code for proteins involved in either suppressing cell division
when it should not occur, or making cell death happen when it should. If
these genes are mutated, a tumor may grow. These modified genes are
called an oncogenes.

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Tumors are masses of cells that are dividing uncontrollably.

A tumor can be benign or malignant. The study of tumours is called
oncology.

Benign tumors are relatively harmless, except that their size may interfere
with normal body function (e.g., a tumor in the brain) or they may be
disfiguring. Benign tumors are not cancerous.
Malignant tumors are cancerous. They are made up of cells that have not
only lost track of their growth, but have also lost track of their place in the
body and the normal controls that keep cells in the organs where they
belong. The movement of cancerous cells throughout the body is called
metastasis.

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 Cancer
Carcinogens
Mutagens oncogene

Tumor
(cell mass)
Tumors (oncology) Melanoma

Benign (non-cancerous)
Malignant tumors
metastasis
http://www.meddean.luc.edu/lumen/MedED/medicine/dermatology/melton/melan1.htm
© McGraw Hill http://www.medscape.com/viewarticle/461106_3 http://www.aans.org/education/journal/neurosurgical/may03/14-5-nsf-toc.asp 55
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Cancers are named for the tissue that they develop in:
Carcinomas (the most common cancer type) arise from epithelial cells.
o E.g., lung cancer (various types), breast and prostate cancer
(adenocarcinomas - cancerous glandular cells), skin cancer (melanoma -
cancerous skin cells that produce the pigment melanin).
Sarcomas arise from connective tissue – e.g., osteosarcoma is cancer of bone
tissue.
Leukemias arise from blood-forming organs – e.g., lymphocytic leukemia affect
blood-forming stem cells in the bone marrow.
Lymphomas originate in the lymphatic system – e.g., Hodgkin and non-Hodgkin
lymphoma results in uncontrolled growth of lymphocytes (a type of white blood
cells).
Cancer cells divide rapidly and continuously, and trigger angiogenesis, the growth
of new networks of blood vessels, to provide nourishment for themselves.

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Treatment of Cancer
Treating cancer is a subject of a lot of medical research, and we lack really effective ways of
specifically killing only cancer cells. Cancer cells differ from normal body cells only in that they are
not controlling their growth and their location. This makes it difficult to kill them, as there is nothing
dramatically different about them that makes them easy to target with drugs and other treatments.

Various treatments include:
Surgery removes a tumor, but does not always remove metastasized cells, so follow-up therapy
with chemicals or radiation may be necessary to kill those.
Chemotherapy and radiation therapy – both target cells that are in the process of
dividing. Unfortunately, these methods also kill other dividing cells in the body, particularly
developing blood cells, and cause illness and discomfort in patients (e.g., nausea, hair loss).
Immunotherapy uses substances made by the body or in a laboratory to boost the immune
system and help the body find and destroy cancer cells.

Further information on cancer (description, risk factors, diagnosis, treatment, support, research,
etc.) can be obtained from the Canadian Cancer Society website.

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