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1.1 | The Discovery of Cells (1 of 3)
 Cells are the topic of intense study.
 The study of cells requires creative instruments and
techniques.
 Cell biology is reductionist, based on the premise that
studying the parts of the whole can explain the character
of the whole.

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1.1 | The Discovery of Cells (2 of 3)
Microscopy
 Microscopes allowed cell
visualization:
 Robert Hooke
Termed pores inside cork cells
because they reminded him of
the cells inhabited by
monastery monks
 Antonie van Leeuwenhoek
Examine a drop of pond water
and observed teeming
microscopic “animalcules”
Saw bacteria from peppercorn
Fig. 1.1 The discovery of
water and dental plaque cells
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1.1 | The Discovery of Cells (3 of 3)
Cell Theory
 The cell theory was articulated in the mid-1800s by
Matthias Schleiden, Theodor Schwann and Rudolf Virchow.
All organisms are composed or one or more cells.
The cell is the structural unit of life.
Cells arise only by division from a pre-existing cell.
 Added since:
Cells contain genetic information (DNA) passed to next cell
generation

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1.2 | Basic Properties of Cells (1 of 11)
Cells are Highly Complex and Organized
 Life is the most basic
property of cells.
 Cells can grow and
reproduce in culture for
extended periods.
 HeLa cells are cultured
tumor cells isolated
from a cancer patient
(Henrietta Lacks)
 Cultured cells are an
essential tool for cell
biologists. Fig. 1.2 HeLa cells

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1.2 | Basic Properties of Cells (2 of 11)
Cells are Highly Complex and Organized
 Cellular processes are
highly regulated.
 Cells from different
species share similar
structure,
composition, and
metabolic features.

Fig. 1.3 Levels of cellular
and molecular organization

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1.2 | Basic Properties of Cells (3 of 11)
Cells Possess a Genetic Program and the Means
to Use It
 Information for building an organism is encoded in genes
(constructed from DNA) and packaged into a set of
chromosomes within the cell nucleus.
 Genes store information and instructions for:
 Constructing cellular structures, the directions for
 Running cellular activities, and the program for
 Making more of themselves.
 Genetic information can be haploid or diploid in cells

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1.2 | Basic Properties of Cells (4 of 11)
Cells Are Capable of Producing More of
Themselves
 Cells reproduce by
division, a process in
which the contents of
a “mother” cell are
distributed into two
“daughter” cells.

Fig. 1.4 Cell Reproduction

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1.2 | Basic Properties of Cells (5 of 11)
Cells Acquire and Utilize Energy
 Photosynthesis
provides fuel for all
living organisms.
 Animal cells derive
energy from the
products of
photosynthesis,
mainly in the form of
glucose.
 Cells can store Fig. 1.5 Acquiring energy
glucose bond energy
in ATP—a molecule
with readily available
energy.
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1.2 | Basic Properties of Cells (6 of 11)
Cells Carry Out a Variety of Chemical Reactions
 Cells function like miniaturized chemical plants.
 A bacterial cell is capable of hundreds of different
chemical transformations.
 Virtually all chemical changes that take place in cells
require enzymes to increase the rate at which a chemical
reaction occurs.
 The sum total of the chemical reactions in a cell
represents that cell’s metabolism.

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1.2 | Basic Properties of Cells (7 of 11)
Cells Engage in Mechanical Activities
 Cells are very active, they can: transport materials,
assemble and disassemble structures, and sometimes
move itself from one site to another.
 Activities are based on dynamic, mechanical changes
within cells, many of which are initiated by changes in the
shape of “motor” proteins.

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1.2 | Basic Properties of Cells (8 of 11)
Cells Are Able to Respond to Stimuli
 A single-celled protest can move away from an object in
its path or toward nutrients.
 Cells in plants or animals are covered with receptors that
interact with substances in the environment.
 Hormones, growth factors, extracellular materials, and
substances on the surfaces of other cells can interact with
these receptors.
 Cells may respond to stimuli by altering their metabolism,
moving from one place to another, or even committing
suicide.

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1.2 | Basic Properties of Cells (9 of 11)
Cells Are Capable of Self-Regulation
 Cells are robust and are
protected from dangerous
fluctuations in composition
and behavior.
 Feedback circuits serve to
return the cell to the
appropriate state.
 Maintaining a complex,
ordered state requires
constant regulation.

Fig. 1.6 Self-regulation
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1.2 | Basic Properties of Cells (10 of
11) Cells Are Capable of Self-Regulation
 Information for product
design resides in the
nucleic acids, and the
construction workers are
primarily proteins.
 Each step of a process
must occur
spontaneously so that
the next step is
automatically triggered.

Fig. 1.7 Cellular activities
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1.2 | Basic Properties of Cells (11 of
11) Cells Evolve
 Whereas the origin of cells is shrouded in near-total
mystery, the evolution of cells can be studied by
examining organisms that are alive today.
 Cells share many features, including a common genetic
code, a plasma membrane, and ribosomes.
 According to a tenet of modern biology, all living
organisms evolved from a single, common ancestral cell
that lived more than three billion years ago.
 This ancient cell is often referred to as the last universal
common ancestor (or LUCA).

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1.3 | Two Fundamentally Different
Classes of Cells (1 of 19)
 Two basic classes of cells,
Prokaryotic – bacteria
Eukaryotic – plants,
animals, protists, fungi
 These different classes are
distinguished by their size
and the types of organelles
they contain.
 Both types of cells share an
identical genetic language,
a common set of metabolic
pathways, and many Fig. 1.8a The structure of cells
common structural
features.
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1.3 | Two Fundamentally Different
Classes of Cells (2 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Both bounded by plasma
membranes of similar
construction, serving as a
selectively permeable
barrier.
 Both may be surrounded
by a rigid cell wall that
protects the cell.
 Genetic material is
membrane-bound in
eukaryotes (nucleus), in
Fig. 1.8b The structure of cells
nuclear area of cytosol in
prokaryotes
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1.3 | Two Fundamentally Different
Classes of Cells (3 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Eukaryotic cells are
much more
complex, both
structurally and
functionally, than
prokaryotic cells.

Fig. 1.8c The structure of cells
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1.3 | Two Fundamentally Different
Classes of Cells (4 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Prokaryotes – relatively
small amounts of DNA;
600-8,000 Mb
 Eukaryotes – simple yeast
cells have 12 Mb DNA,
most eukaryotic cells
possess more
 Complex multicellular
animals appear rather
suddenly in the fossil
record approximately 600
million years ago. Fig. 1.9 Earth’s biogeologic clock
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1.3 | Two Fundamentally Different
Classes of Cells (5 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells
 Cytoplasm: Eukaryotes have
membrane-bound organelles and
complex cytoskeletal proteins. Both
have ribosomes but they differ in
size.
 Cellular reproduction:
Eukaryotes divide by mitosis;
prokaryotes divide by simple
fission.
 Locomotion: Eukaryotes use both
cytoplasmic movement, and cilia
and flagella; prokaryotes have
flagella, but they differ in both form
and mechanism.
Fig. 1.10 The structure of a eukaryotic cell

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1.3 | Two Fundamentally Different
Classes of Cells (6 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 The cytoplasm of a
eukaryotic cell is extremely
crowded:
Near the cell membrane is a
region where membrane-
bound organelles tend to be
absent.
The cytoskeleton and other
large macromolecular
complexes, mostly
ribosomes,
Fig.are
1.11found
The cytoplasm
of athe
throughout eukaryotic cell is a
cytoplasm.
crowded compartment
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1.3 | Two Fundamentally Different
Classes of Cells (7 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Eukaryotic cells divide by a
complex process of
mitosis.
 Duplicated chromosomes
condense into compact
structures that are
segregated by an
elaborate microtubule-
containing apparatus.
 This apparatus, the Fig. 1.12 Cell division in eukaryotes
mitotic spindle, allows
each daughter cell to
receive an equivalent array
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1.3 | Two Fundamentally Different
Classes of Cells (8 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Prokaryotes contain one copy of their
single chromosome and have no
processes comparable to meiosis,
gamete formation, or true
fertilization.
 Some are capable of conjugation, in
which a piece of DNA is passed to
another cell.
 Prokaryotes are more adept at picking
up and incorporating foreign DNA
from their environment, which has
had considerable impact on microbial
evolution Fig. 1.13 Bacterial conjugation
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1.3 | Two Fundamentally Different
Classes of Cells (9 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Locomotion in prokaryotes is
relatively simple.
 Can be accomplished by a thin
protein filament, called a
flagellum, which protrudes
from the cell and rotates.
 The rotations exert pressure
against the surrounding fluid,
propelling the cell through the
medium.
Fig. 1.14 The different between
prokaryotic and eukaryotic
flagella
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1.3 | Two Fundamentally Different
Classes of Cells (10 of 19)
Characteristics That Distinguish Prokaryotic and Eukaryotic Cells

 Certain eukaryotic cells,
including many protists
and sperm cells, also
possess flagella.
 Eukaryotic versions are
much more complex than
the simple protein
filaments of bacteria, and
they generate movement
Fig. 1.14 The
by a different mechanism.
difference between
prokaryotic and
eukaryotic flagella
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1.3 | Two Fundamentally Different
Classes of Cells (11 of 19)
Types of Prokaryotic Cells: Domain Archaea and Domain Bacteria

 Archaea are evolutionarlity related species that live in
extremely inhospitable environments, often referred to as
“extremophiles.”
Methanogens: Convert CO2 and H2 gases into methane
Halophiles: Live in extremely salty environments, like the
Dead Sea or deep sea brine pools with salinity equivalent to
5M MgCl2.
Acidophiles: Acid-loving prokaryotes that thrive at a pH as
low as 0.
Thermophiles: Live at very high temperatures.
Hyperthermophiles: Live in the hydrothermal vents of the
ocean floor up to a temperature of 121˚C, the temperature
used to sterilize surgical
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1.3 | Two Fundamentally Different
Classes of Cells (12 of 19)
Types of Prokaryotic Cells: Domain Archaea and Domain Bacteria
 Bacteria are present in every
conceivable habitat on Earth,
even found in rock layers
kilometers beneath the Earth’s
surface.
 Cyanobacteria contain arrays of
cytoplasmic membranes that
serve as sites of photosynthesis.
 Cyanobacteria gave rise to green
plants and an oxygen-rich
atmosphere, and some are
capable of nitrogen fixation.
Fig. 1.15 Cyanobacteria
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1.3 | Two Fundamentally Different
Classes of Cells (13 of 19)
Types of Prokaryotic Cells: Prokaryotic Diversity
 6000 species of prokaryotes have been identified, less
than one-tenth of 1 percent of the millions of prokaryotic
species thought to exist.
 DNA sequencing is so rapid and cost-efficient that virtually
all of the genes present in the microbes of a given habitat
can be sequenced, generating a collective genome, or
metagenome.
 These same molecular strategies are being used to
explore the collection of microbes living on us, known as
the human microbiome.

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1.3 | Two Fundamentally Different
Classes of Cells (14 of 19)
Types of Prokaryotic Cells: Domain Archaea and Domain Bacteria

Environment
No. of prokaryotic Pg of C in
Environment cells, x 1028 prokaryotes*
Aquatic habitats 12 2.2
Oceanic subsurface 355 303
Soil 26 26
Terrestrial subsurface 25–250 22–215
Total 415–640 353–546
*1 petagram (Pg) = 1015g.
Source: W. B. Whitman et al., Proc. Nat’l. Acad. Sci. U.S.A. 95: 6578, 1998
Copyright (1998) National Academy of Sciences, U.S.A. Reproduced with
permission of National Academy of Sciences.

Number and Biomass of Prokaryotes in the World
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1.3 | Two Fundamentally Different
Classes of Cells (15 of 19)
Types of Eukaryotic Cells
 The most complex eukaryotic cells
are found among the single-celled
Protists.
 The machinery needed for sensing
the environment, trapping food,
expelling excess fluid, and evading
predators is found in a single cell.
 Vorticella have a contractile ribbon
in the stalk and a large
macronucleus that contains
Fig. 1.16 Vorticella, a
multiple copies of itscomplex
genes.ciliated
protist
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1.3 | Two Fundamentally Different
Classes of Cells (16 of 19)
Types of Eukaryotic Cells: Cell Differentiation
 Multicellular eukaryotes have
different cell types for different
functions.
 Differentiation – the
formation of specialized cells
 The numbers and
arrangements of organelles
relate to the function and
activity of the cell.
 Despite differentiation, cells
have many features in common
most being composed of the
same organelles.
Fig. 1.17 Pathways of cell differentiation

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1.3 | Two Fundamentally Different
Classes of Cells (17 of 19)
Types of Eukaryotic Cells: Model Organisms

Fig. 1.18 Six model organisms
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1.3 | Two Fundamentally Different
Classes of Cells (18 of 19)
The Sizes of Cells and Their Components

 Cells are commonly measured in
units of micrometers (1 μm = 10–6
meter) and nanometers (1 nm = 10–
9
meter).
 The cell size is limited by:
Volume of cytoplasm that can be
supported by the genes in the nucleus.
Volume of cytoplasm that can be
supported by exchange of nutrients.
Distance over which substances can
efficiently travel
Fig. 1.19 through
Relative sizes the cytoplasm
of cells and cell
via diffusion. components
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1.3 | Two Fundamentally Different
Classes of Cells (19 of 19)
Types of Eukaryotic Cells: Model Organisms
 Synthetic Biology is a field
oriented to create a living cell
in the laboratory.
 A more modest goal is to
develop novel life forms,
beginning with existing
organisms.
 Possible applications to
medicine, industry, or the
environment.
 Prospect is good after replacing
the genome of one bacterium
with that of a closely related Fig. 1.20 The synthetic biologist
species. toolkit of the future?

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1.4 | Viruses and Viroids (1 of 3)
 Viruses are pathogens and
intracellular obligate parasites.
 A virion is a virus particle outside
the host cell. Contains genetic
material plus protein subunits
(capsids). Some virions are also
encased by a lipid membrane-
derived envelope
 Viruses that infect bacteria are
bacteriophages – complex
infection cycles and medicinal
potential
 Viroids are pathogens, each
consisting of a small, naked RNA
molecule, which can cause disease
by interfering with gene expression
in host cells.
Fig. 1.21 Tobacco mosaic virus (TMV)

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1.4 | Viruses and Viroids (2 of 3)
 Viral capsids are generally made up of subunits from only
one or a few proteins to conserve genome size.
 Viral specificity for a certain host is determined by the
virus’ surface proteins, since infection requires those
proteins to bind surface proteins of the host cell.

Insert Fig. 1.22 Virus
Diversity
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1.4 | Viruses and Viroids (3 of 3)
 Viral infection types:
1. Lytic infection: the virus redirects the host into making
more virus particles, the host cell lyses and releases the
viruses.
2. Integration: the virus integrates its DNA (called a provirus)
into the host cell’s chromosomes.

Fig. 1.23 A virus infection
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1.5 | Green Cells: Volvox, an
Experiment in Multicellularity
 Multicellularity has arisen from a single-celled organism.
 An example is the Volvox which takes the form of a
spherical group of thousands of cells embedded in a
gelatinous matrix.
 Volvox and its relatives evolved from unicellular green
algae.

Fig. 1.24 Evolutionary experiments in multicelluarity
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1.6 | Engineering Linkage: Tissue Engineering
 Biocompatibility is the major
challenge in artificial organ
development.
 To increase biocompatibility we
need to find a way to build an
organ or tissue from living
cells.
 Major strategies:
1. Tissue engineering - enhanced
cell culture, where cells are
grown on a 3D patterned Fig. 1.25 Replacement blood
substrate (scaffold) vessel that incorporates living
cells, created using tissue
2. Making replacement organs -
engineering models
relies on the ability of cells to
self-assemble into 3D
aggregates known as
organoids

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