Chapter 3 Cells (1).pptx

Transcript

Cells
Cells are small, but huge from a biological
perspective of their importance for us to
understand the structure of living
organisms!!!!!!!!!!!!!!

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 Cells are…
…the smallest unit of life capable
of living independently.

Robert Hooke was one of the
first people to study cells
through his self made
microscope.

Robert Hooke looked at a wide
variety of objects including bee
stingers, feathers, fish scales,
insects, and cork.
Cork consists of
dead plant cells,
which Robert Hooke
coined as “cells”,
because they looked
like the cubicles
where monks would 2
 Protists and Bacteria
Antony van Leeuwenhoek
improved the lenses found
in microscopes and
managed to look at protists
and bacteria for the first
time. He called these
organisms animalcules.
These were new
organisms which no one
ever knew existed before

I am so jealous,
because at parties
they use to look at
A sample of pond
organisms under the
water under the
microscope. My
microscope.
nerdy self would
have been so “cool”
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in the 17th
 Cell Theory
Mathias Schleiden and Theodor Schwann
proposed the Cell Theory. The Cell theory
started off as two components.. Rudolf Virchow added a
third component to the cell
) All organisms are made of 1 or more cells theory, that all living cells
come from preexisting
2.) the cell is the fundamental unit of life cells.

An amoeba. The pointer is Amoebas doing what amoebas
pointing at the nucleus. do on a Saturday night,
reproducing asexually baby!!!
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 Multicellular organisms cells are a
lot like…
…Legos.

Individual
Legos can
be put
together to
build a
construct
like a…. …castle!!!
Cells can
…or multicellular, like the
exist as …colonial…
castle is made of multiple
unicellular
Legos
structures… Rod Woodson is
the result of a 40
trillion cells,
about the same
for each of us. 
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 Microscopy…
…is the ability to amplify human
vision to see the really small by using Light microscopes
human technology. And when I say work by
really small, I mean REALLY small. streaming light…
…(the light source)…
…through the
object you are
The light looking at and
microscope can one or more
magnify up to lens…
1600 times and
resolve objects …which bend
that are 200 light so light
nanometers will scatter
apart. Meaning more widely
you can see the increasing the
difference of apparent size
…(there
structures which are two lenses in of the object.
are 200 this microscope)… 6
nanometers in
 Microscopy improves with….
Transmission electron
microscopes (TEM) send a
beam of electrons through a
thin piece of object. TEM
microscopes can magnify
objects up to 50 million times
their actual size and resolve
objects less than 1 angstrom Side note and not
apart (10-10 meters). important for test:
The most powerful
Scanning Electron microscope ever
Microscope (SEM) sends called a quantum
microscope took the
the electrons over a first image of a
metal-coated three hydrogen's electron
orbit.
dimensional specimen.
Magnification isn’t as
great as TEM, but it can
discern textures and
crevices on an object. 7
 All Cells (whether bacteria,
archaebacteria, or eukarya)
include these six components…
…2.) RNA, which is involved
…1.) DNA, the with carrying DNA
molecule information to the site of
which protein formation.
establishes
inheritance.
…3.) Ribosomes:
The site of …5.) Cell Membrane:
The structure which
protein acts as a barrier
formation. …4.) Proteins
between the internal
and external
Note: The
environment.cell
membrane is
also known
as the
plasma
membrane.
…and 6.)
Cytoplasm which
is the liquid
interior of the
cell. 8
 Cells have a…
In the picture to the left..minimum size. Their you have a SEM image of
mycoplasma bacteria.
minimum size is These are the smallest
dependent upon their bacteria. They have a cell
ability to contain all membrane, a little
cytoplasm, a little piece of
the cellular structures
DNA and RNA, one
and to be able to ribosome, and some
contain the proteins and other
biochemical reactions molecules.
necessary for cell
…maximum size in their
functions. Cell also
surface area to volume
have a ….
ratio. An increase in 3
dimensional size means
a more rapid increase in
volume to surface area.
The picture to the left is of an episode of the 80’s
cartoon GI Joe. In this episode a giant bacteria
which grew to city size was eating everything.
The problem is a single cell of this size does not
have enough surface area to diffuse enough food, 9
Three domains of life are characterized
by three different types of cells
Prokaryotes are the The third
simplest and the domain consists
most ancient cells. of Eukaryotes.
Consist of the two The domain is
domains Bacteria and called Eukarya
Archaebacteria.

Pro = Before
Eu = True
Karyon = Kernel,
refering to the
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nucleus
 Three Domains
Domains Nucleus Mebrane Membrane Cell Wall
Bound Chemistry Chemistry
Organelles
Bacteria Absent Absent Fatty Acid Peptidoglcyan

Archaebacteria Nonfatty Pseudopeptidoglycan
Absent Absent
Acid lipids Or protein

Usually cellulose ,chitin
Eukarya Present Present Fatty Acids
or none

Bacteria and Archaebacteria
are typically 1-10 micrometers
in size. Eukaryotes are
typically 1-100 micrometers in
size
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 Domain Bacteria

Bacteria are the most
abundant and diverse
group of organisms on the
face of the earth.
The bacteria also have a The nucleoid region is the
cell wall which keeps the area where the single circular
cell from exploding if it piece of DNA is present
takes on too much water which controls the day to day
and also maintain the operations of the cell.
shape of the bacteria. Some bacteria have And other bacteria have
no flagella and some numerous flagella
have one flagella
Flagella are tail like
appendage which allow
the bacteria to move
through water.
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 Domain Archaea
Archaea (Archaebacteria) are superficially
like that of bacteria.
Both lack a nucleus and membrane
bound organelles.
Have simple structural components.
Have a more diverse array of
metabolism and environments they
can survive in than that of eukaryotes.

Archaeabacteria were the first extremophiles
discovered.
Extremophiles are organisms which can
live in extreme environments In the picture above boiling
Extreme heat, cold, salinity, acidity, or water from a geyser contain
alkalinity to name a few thermophiles, which are
Later discovered a lot of Bacteria are also organisms which thrive in
extreme heat. These
extremophiles as well. organisms are capable of
Expanded how we hypothesize life maybe surviving boiling water!!!! 13
on other planets.
 Ribosomes
Ribosomes are structures
found in both prokaryotes
and eukaryotes.
Prokaryotic ribosomes
are smaller than
eukaryotic ribosomes.

Ribosome are the site where protein formation
(translation) takes place.
They consist of a small unit and a large
unit which come together when protein
synthesis occurs.
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 Domain Eukarya
(this includes us!!!! )
The domain eukarya includes
unicellular organisms (a lot of the
protists and a few fungi) and the
multicellular organisms (plants, fungi,
animals, and a few algae).
This domain includes the most complex
The picture above is a
cells. paramecium taken through a
You can see structures of the cell light microscope. Notice that
you can make out structures
Thisunder
domain a light microscope.bound
has membrane The first within the cell.
structure observed was the The picture below is
organelles. an artist impression of
nucleus
These are structures within the the structures.
cell which have a membrane,
like the plasma membrane,
surrounding the structure.
Includes the nucleus (protects
the DNA), vacuoles, lysosomes,
and the endomembrane system,
too name a few.
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 Membranes
Membranes separate surroundings.
Cell membranes separates the
external and internal
environments of the cell
Organelle membranes separate
the volume of the organelle
from the cytoplasm

Membranes consist of a phospholipid bi-
layer
Two layers of phospholipid
Each phospholipid consist of a
negatively charged phosphate head
and a hydrophobic tail
The bi-layer consists of two layers of
phospholipids with the tails of each
phospholipid facing each other and
the negatively charged heads facing
outwards and inwards towards the 16
 Fluid Mosaic Model
The fluid mosaic model is a model used to
describe the structure of the cell
membrane.
The “fluid” component of the model is a description of the fluid nature
of the cell membrane.
The individual molecules found within the cell membrane and make
up the structure of the membrane are not solidified in place and
can move around the membrane in a fluid like nature.
The “mosaic” component of the model
is a description of the components of
a cell membrane.
The phospholipids make up the
general structure of the
membrane.
Proteins create the other functions
for the membrane
Sterols, including cholesterol, are
involved with keeping the
membrane in a fluid structure. 17
 Membrane Proteins
include…..Transport proteins which allow matter
to enter and exit the cell.
Certain transport proteins allow
certain molecules to enter and/or …Enzymes: facilitate
exit. chemical reactions along
the membrane.
…Receptor proteins take
chemical signals and use it
for information to trigger a
reaction within the cell.

…Recognition proteins serve as …Adhesion proteins
nametags to allow for a cell to be able allow for cells to stick
to identify another cell as part of the together.
same structure (organ) or a part of the
same organism.
Recognition proteins often couple
with a carbohydrate. 18
 Division of Labor
Organelles found within the
eukaryotic cell allow the cell
to divide the labor.
Organelles come in a
variety of different types
which do different
functions within the cell.

The rest of the power
point will be about
structures in the cell.

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 Endomembranous System
Endomembranous system consists of…
the endoplasmic reticulum…

…Golgi aparatus…

…cell membrane…

…the nuclear envelope…..Lysosomes are found in animals, while different kinds of
vacuoles are found in plants and protists. The endomebranous
system helps to differentiate labor out in the cell. 20
 The Nucleus
One of the most prominent
organelles is the nucleus. You
can see it under a light
microscope. The nuclear envelope acts as the
“cell membrane” of the nucleus
separating the nucleoplasm from
the cytoplasm.

Nuclear pores allow for
mRNA molecules to leave
the nucleus carrying the
information to build new
proteins.

The nucleolus appears as a
darker area within the
nucleus and is the site of
Fig. 3.14 construction of ribosome
subunits 21
 Endoplasmic Reticulum
There are two types of endoplasmic reticulum…

Rough Endoplasmic Reticulum is a site
of protein manufacturing. Proteins
made here will be secreted out of the
cell.
Proteins kept in the cell are
manufactured by ribosomes in the
cytoplasm.
Smooth Endoplasmic Reticulum synthesizes
lipids.
Enzymes which detoxify poisons and drugs
are found here.
Smooth ER is found in high abundance Fig. 3.15
in liver cells.
Special Smooth ER in muscle cells store
and release Calcium ions, which are
necessary for muscle contraction;. 22
 Golgi Apparatus
The Golgi Apparatus: A structure of pancake like…
Vesicles which have..I said detached from the ER.
pancake
like!!! Now
I am
hungry!!
…That’s better!!

…structures which accept vessicles which break off of the ER.
They take proteins (made in the rough ER) and lipids (made in the
smooth ER) and complete their construction. It also sorts and
packages their products to have them moved to the proper place.
Finalized improvements on proteins can include lipid or
carbohydrate attachment and final folding of the shape of the 23
protein.
The NUCLEUS….

…The Endoplasmic Reticulum…

…The Golgi Apparatus
Are a part of a endomembranous system which
secretes materials out of the cell.
The role of the nucleus though is more to protect
the DNA from molecular oxygen and other
hazards. I am coming to
get your DNA!!
Oxygen our friend
and our enemy. We
need for ATP
production, but is
also a carcinogen.
Want to avoid
cancer, stop 24
 Cellular Digestion

Heterotroph
s consume
food!!!

Autotrophs
harness
raw
energy
and
produce
Cellular digestion is the ability food.
of cells to break down organic
molecules into smaller
molecules so they can be
reused. The next set of slides
are going to be about parts of
the cell involved with cellular 25
digestion.
 Legos (yes once again)
Legos can be...
…and rebuilt....taken apart…

The same as a starch grain… …and then built into..gets broken down into
(found in corn) glycogen in animals.
glucose…

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 Lysosomes Fig. 3.17

Lysosomes are organelles which
contain digestive enzymes. Look it is a cute
Break down food, capture bacteria, “baby” lysosome!!
old organelles, and debris/waste
Can be used in the destruction of
the cell.
Enzymes are produced in the
Rough Endoplasmic Reticulum
Golgi bodies recognize the
enzymes by a particular sugar
molecule
Golgi body absorbs the
protein and construct a
lysosome with the enzymes
Lysosomes
produced by a
have thelower pH than the rest of the cell.
endoplasmic
pH 4.8 versusreticulum.
a general pH of 7 in the rest of the cell.
The lower pH allows the lysosome to break down molecular
structures
When a cell needs to be terminated all of their lysosomes will burst
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releasing their digestive enzymes.
 Vacuoles
It’s a picture of
Plant cells generally lack lysosomes, but
our plant cell
often have a large central vacuole. model!!
Contains enzymes which helps the
plant digest molecules and
organelles.
Vacuoles have a low pH
(acidic) which helps it to
digest molecules.
Plant cells grow with the
growth of their central
vacuole.
Growth stimulated by
Someincreases
protists in water
have a different
kindpressure (turgor
of vacuole called a
pressure).
contractile vacuole. Helps
pump out excessive water.

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 Peroxisomes
Fig. 3.18

All eukaryotic cells contain
peroxisomes.
Contain enzymes which break
down toxic
Peroxisomes substances.
originate in the
endoplasmic reticulum.
Peroxisomes protect the cell from
toxic byproducts.
Some chemical reactions
within the cell produce
hydrogen peroxide (H2O2)
Liver and kidney cells have
peroxisomes that help break
down toxins found in blood.
Peroxisomes also break down fatty acids to produce cholesterols

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 Photosynthesis produces food. Fig. 3.19

Chloroplasts are the site of
photosynthesis in eukaryotes.
Chloroplasts consist of two outer
membranes.
They have a liquid interior called
the stroma.
They have a third type of
internal membrane (within the
stroma) which are called
thylakoids.
Thylakoids are stacked in
structures called grana.
Photosynthetic pigments are
found embedded in the
Chloroplasts are a type of plastid. Plastids come in a variety of types
thylakoids.
which synthesize different substances.
Plastids are different from most other organelles because they
contain their own DNA and ribosomes.
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 Mitochondria extract energy from
food (fig. 3.20)

Mitochondria are organelles
which break down
molecules to extract energy
which is used to produce
ATP.
Glucose molecules are
already broken down in
the cytoplasm. The
remnant of the glucose
molecules left over are
further broken down in
mitochondria
Mitochondria have two membranes, with the inner membrane creating
folds called cristae.
The chemical reactions which occur in mitochondria use oxygen. This
process not only helps produce more ATP, but also helps protect us from
molecular oxygen found in the atmosphere.

Mitochondria, like plastids/chloroplasts, have their own DNA and
ribosomes.
Mitochondria and plastids are theorized to be living organisms which
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have become a part of the eukaryotic cell in the past.
 Cytoskeleton System
Cytoskeleton is a structural
framework for the cell to maintain
the shape of the cell.
The
flagella
cytoskeleto
n system is
also a part The cytoskeleton system provides transportation
of cell of internal components of the cell and also
division and provides a framework
flagella, and
cilia, and motion for
pseudopods.
the motion
of
chromosom
es.

Cilia pseudopod
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 Three general types of Cytoskeletal
structures Fig. 3.23

Microfilament
Allow cells to survives
stretching and
compression actions
Help cells anchor to each
other Intermediate filaments
Smallest of the three Form an internal scaffolding for the cell.
Also play a part in binding cells together.

Microtububule
Composed of a protein called tubule.
This
Pull DNA apart during cell division.
Giardia
Form a “rail system” for organelles to
sp. has
move along. multiple
Think of like a rail road track
flagella.
Centrosomes are important
components in animal cells for the
creation of flagella and cilia. 33
Fig. 3.24
 Cell walls
Cell walls provide structural
support for the cell.
Plant cells have Fungi have
cellulose as a chitin in their
major part of their cell wall.
cell walls.

Bacteria have
peptidoglycan in
their cell wall. Animal cells have no cell walls.

Animals have what I
call “cell wall envy”.

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 Cell Junctions
Multi-cellular and colonial organisms have to
have structures which hold the cells together.
Tight Junctions are junctions
which create impermeable
barriers between cells.
Create barriers between the
blood and the brain; the
digestive
Anchoring tract;
junction thecells
hold kidney
tubules.
together like the skin cells. Gap junctions
Gap Junction allow for
exchange of chemicals
between cells.
Animal cells
Plasmodesmata provide
channels between plant
cells.

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Table 3.3 p. 66

Table 3.23 p. 66 provides a brief summary
of the structures of a eukaryotic cell.

Just wanted to mention that. 

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