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The Cell
Cell Biology
A discipline of biology:
1. Cell structure
2. Cellular processes
3. Cell division
Tight connection with
1. Molecular biology
2. Biochemistry
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2
Cell theory
1838, 1839
Theodor Schwann
Matthias J. Schleiden
1. All living things are composed of one or more cells
2. Cells are the basic units of structure and function in living things
Cell theory
3. Omnis cellula e cellula
All cells are derived from cells
(by means of multiplication)
Rudolph Virchow
2
Germ theory
3
Louis Pasteur
1860’s
Microorganisms are not generated from inanimate material
but rather as a result of biogenesis (from other microbes)
- The discovery that a prokaryotic cell stems from another prokaryotic cell
5
Prokaryotes
Eukaryotes
Classification of living beings
Plants
III.
Eubacteria
I.
Animals
Fungi
Protista
Archaebacteria
II.
What about the viruses?
They are not living beings, since they are not
capable for independent life (cell parasites)
Origin:
I. Simplified cells
II. Derived from the DNA of host cell
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The origin of cells
7
DNA
RNA
DNA
nucleus
cytoplasmic
DNA
RNA cells
prokaryotic cell
eukaryotic cell
The origin of DNA
„DNA world”
RNA world
The virus hypothesis:
- viruses discovered the DNA
8
9
The origin of proteins
RNA world
„protein world”
Origin of nucleus
The arhaezoa hypothesis
Thomas
Cavalier-Smith
Origin of ER andGolgi
10
11
Origin of mitochondrion
- Endosymbiotic theory
Lynn Margulis
Origin of chloroplast
- Endosymbiotic theory
Lynn Margulis
Elysia chlorotica
A plant-animal
12
Prokaryotic cell
plasmid
Prokaryotic cell
Spherical cells
e.g. Streptococcus
Rod-shaped cells
e.g. Escerichia coli
Spiral cells
e.g. Treponema pallidum
Multicellular prokaryotes
Nitrogen fixation spore photosynthesis
Anabaena cylindrica
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Compartmentalization
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Nucleus
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Mitochondrion
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Cytoskeleton
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Ribosomes
Rough ER
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Golgi apparatus
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Smooth ER
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Extracellular space
Intracellular
space
Cell membrane
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Ribosomes
bound to rough ER
Figure 4.7 Eukaryotic Cells (Part 1)
Animal cell
Centrioles
Plant cell
Plant cell
Free ribosomes
Plant cell
Nucleus
Nucleolus
Plant cell
Golgi apparatus
Plant cell
Plasmodesm
Plant cell
Chloroplast
Plant cell
Mitochondrion
Plant cell
Cell wall
Plant cell
Peroxisome
Plant cell
Cell
membrane
Plant cell
Smooth ER
Plant cell
Rough ER
Plant cell
Inclusion body
Animal cell – Plant cell
Inclusion body
chloroplast
cell wall
Prokaryotic cells
vs. eukaryotic cells
Differences
Only in eukaryotes:
1. Cell nucleus
2. Membrane-bound organelles
Only in prokaryotes
1. Proteoglycan cell wall
2. Capsule
Eukaryotic (animal) cell
Prokaryotic cell
Cell membrane
1. Separation – selective transport
2. Communication
Cell membrane
- fluid mosaic model
1.
lipid
double layer
1.
Phospholipid
molecules Protein molecules
2.
Phospholipid
molecule
1.
3.
Protein
Phospholipids
Cholesterol:
decreases fluidity
phosphatidyl choline
Glycocalyx
glycocalyx
cytoplasm
nucleus
cell membrane
22
Membrane microdomains
- lipid rafts
phospholipids and membrane proteins are not randomly distributed in cell membranes
Nucleus
Outer membrane
Nucleoplasm
Inner membrane
Nucleolus
Chromatin
Nuclear
lamina
Nuclear
membrane
Pore
Nuclear membrane
importin
exportin
Nuclear membrane
inner
outer ER membrane
ER lumen
protein
protein
protein
Nuklear lamina
RNA
perinuclear space
Nuclear pore
NLS: nuclear localization signal
NES: nuclear export signal
Signal peptides
Chromosomes
Human: haploid chromosome set
Giemsa staining
Chromatin
Metaphase chromosome
8 histone core
Histone H1
DNA
Solid form
Relaxed form
DNA
DNA and nucleosomes
H1 H2A
H3
H4
NUCLEOSOME
H2B
DNA and nucleosomes
DNA
8 histone core
Ribosomes
Ribosomes are complexes of proteins and RNA molecules. They carry out
the synthesis of proteins. Soluble proteins are synthesized by cytoplasmic
ribosomes, while membrane and exported proteins are produced by
ribosomes of the rough endoplasmic reticulum.
30S subunit
Proteins: blue
RNAs: orange
Endoplasmic reticulum
Rough ER
Rough ER
Smooth ER
Smooth ER
ribosomes
FUNCTION
1.
2.
3.
4.
Lysosomal enzymes
Secreted proteins
Trans-membrane proteins
Glycosylation
1.
2.
3.
4.
Lipid and steroid synthesis
Carbohydrate metabolism
Calcium storage
etc.
Protein maturation
in the rough ER
Golgi apparatus
FUNCTION:
1. Proteins and lipids
(a) chemical modification (glycosylation and phosphorylation)
(b) packaging and
(c) sorting
2. Carbohydrate synthesis
3. Proteoglycan synthesis
cisterns
incoming (from ER)
Transport vesicles
outgoing
Golgi apparatus
Inside of cell
Nucleus
Rough endoplasmic reticulum
cis region
medial
region
trans
region
Golgi apparatus
Proteins for use
within the cell
Plasma membrane
Proteins for use
outside the cell
Outside of cell
Peroxysomes, lysosomes
peroxysome
lysososome
- Small membrane vesicles, containing enzymes
that degrade peroxides and free radicals
- Metabolism of fatty acids
- Enzymes of the peroxisomes are found in
crystalline form
Acidic vesicles full of enzymes (they digest:
proteins, nucleic acids, lipids, polysaccharides)
Lysosomes
Inside of cell
Primary
lysosome
Phagosome
Secondary
lysosome
Food particles
taken in by
phagocytosis
Outside of cell
Plasma membrane
Proteasomes
Proteasomes are enzyme complexes degrading proteins
Proteins are degraded for several reasons:
- misfolded (abnormal) proteins are destroyed
- some proteins are made only for short periods of time
- enzymes, regulatory proteins are degraded, when not needed
- when cells are starving for amino acids
There are labels (ubiquitin peptide), which identify protein molecules to be degraded.
lysosome
Mitochondrion
outer membrane
matrix
Inter-membrane space
inner membrane
Chloroplast
Chloroplast
Granum
- stacks of thylakoids
Cytoskeleton
Cytoskeleton
Microtubule
Intermediate filament
Microfilaments
rough ER
Cytoskeleton
1. Maintains cell shape
2. Provides for various types of cell movement
3. Helps move things within the cell
Microtubules
Intermediate filament
rough ER
cell membrane
Microfilament
Microfilaments
• Made up of strands of the protein actin and often interact with strands of other proteins
• They change cell shape and drive cellular motion, including contraction, cytoplasmic streaming, and the
“pinched” shape changes that occur during cell division
• Microfilaments and myosin strands together drive muscle action
Actin monomer
Intermediate filaments
• Made up of fibrous proteins organized into tough, ropelike assemblages that stabilize a cell’s structure
and help maintain its shape
• Some intermediate filaments help to hold neighboring cells together
• Others make up the nuclear lamina
Fibrous subunit
• Long, hollow cylinders made up of many molecules of the protein tubulin.
Tubulin consists of two subunits, -tubulin and -tubulin
• Microtubules lengthen or shorten by adding or subtracting tubulin dimers
• Microtubule shortening moves chromosomes
• Interactions between microtubules drive the movement of cells
• Microtubules serve as “tracks” for the movement of vesicles
Microtubules
-Tubulin
monomer
Tubulin dimer
-Tubulin
monomer
Cytoskeleton
- Cell division