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The Cell

Cell Theory
Robert Hooke invented the first microscope and noticed the microstructures of a cork.
Leeuwenhoek viewed a living cell
1. All things are composed of cells
These were a part of the original form of cell theory
2. The cell is the basic functional unit of life
3. Cells arise only from preexisting cells
4. Cells carry genetic information in the form of deoxyribonucleic acid (DNA). This info is
passed on from parent to daughter cell.
Viruses are not considered living organisms since they violate tenet 3 & 4.

Eukaryotic Cells
The most general distinction made between living organisms is if the organism is composed of
eukaryotic or prokaryotic cells
Eukaryotic Cells contain a true nucleus enclosed in a membrane, while Prokaryotic Cells
do not contain a nucleus.
Membrane Bound Organelles
Every cell has a cell membrane enclosing a semifluid cytosol in which the organelles are
suspended. For eukaryotic cells, the organelles are protected by a membrane, which typically
consist of a phospholipid bilayer.
Phospholipid Bilayers have a hydrophilic (like water) surface, and a hydrophobic (repel
water) inner wall.
The Cytosol allows for the diffusion of molecules throughout the cell
The Nucleus encodes genetic material into DNA which is organized into chromosomes.
Eukaryotic cells are reproduced by mitosis.
The Nucleus
The control center of the cell, and contains all the genetic information needed for replication.
The nucleus is surrounded by the Nuclear Membrane (Envelope): A double membrane
that maintains a nuclear environment separate and distinct form the cytoplasm.
o Nuclear Pores allow for the selective two-way exchange of material
DNA contains Genes which are genetic coding regions. The initially linear DNA is wound
around organizing proteins known as Histones.
The histones are further wound into chromosomes
o This setup permits the compartmentalization of DNA transcription and RNA
translation.
The Nucleolus is where the ribosomal RNA (rRNA) is created. Takes up 25% of the
nucleus volume and is identified by a dark spot.
Mitochondria
Are considered the power plant of the cell and contain a dual layer membrane
Outer Layer of membrane is a barrier between the cytosol and the inner environment
 Inner Layer of membrane has numerous folds known as cristae. This membrane contains
the molecules and enzymes necessary for the electron transport chain.
o Intermembrane Space: the space between inner and outer membrane
Matrix: The space inside the inner membrane.
Mitochondria are semi-autonomous. Contain their own genes and replicate
independently of the nucleus through binary fission.
o Main example of Cytoplasmic or Extranuclear inheritance: means that
transmission of genetic material is independent of the nucleus.
Is also capable of killing the cell by releasing enzymes which starts apoptosis.
Lysosomes
Are membrane-bound that contain enzymes which break down many substrates
Function in conjunction with endosomes. Endosomes transport material to the trans-
Golgi, to the membrane or to the lysosomal pathway for degradation.
The membrane is used to ensure that encased enzymes do not cause damage to the cell
o Autolysis: is when the enzymes are released into the cell which results in
apoptosis. The enzymes directly kill the cell (different from mitochondria)
Endoplasmic Reticulum
Series of interconnected membranes that continue from the nuclear envelope.
Double membrane is folded to create complex structures, but there is a central lumen.
Rough ER is studded with ribosomes that permit the translation of proteins.
Smooth ER is for lipid synthesis and for the detoxification of certain drugs/poisons.
o The SER transports proteins from the RER to the Golgi Apparatus
Golgi apparatus
Consists of stacked membrane-bound sacs. The material is transferred from the ER in vesicles
The cellular products are sometimes modified once in the G.A.
o Various groups such as carbohydrates, phosphates and sulfates can be added.
o May also use signal sequences that direct the delivery of the product to a specific
cellular location.
Once the cellular products are modified and sorted in the G.A, they are repackaged in
vesicles and transferred to the appropriate cell location
o If the product is for secretion then the vesicle merges with the membrane, and
the contents are released via exocytosis
Peroxisomes
These contain hydrogen peroxide and are meant to breakdown very long chain fatty acids via
oxidation. They also participate in the synthesis of phospholipids.
Cytoskeleton
Provides structure to the cell and helps it maintain its shape. Also a conduit for transport of
material around the cell.
Microfilaments: Made up of solid rods of actin. These filaments can resist both
compression and fracture. Provide protection for the cell.
o If Actin interacts with Myosin and uses ATP, force will be generated to move cell.
 o Play a role in Cytokinesis. The cleavage furrow is formed from microfilaments
organized as a ring at the site of division. As actin filaments contract, the ring
gets smaller and the connection is eventually pinched off.
Microtubules: hollow polymers of tubulin proteins.
o Are found throughout the cell and form the pathways for motor proteins (kinesin
and dynein) to carry vesicles
o Cilia & flagella are composed of microtubules
▪ Cilia are projections from the cell primarily used for in movement of
materials along the cell
▪ Flagella are involved in the movement of the cell itself (like sperm).
Both structures have a characteristic 9+2 Structure. (9 pairs on
outside and two microtubules on center).
o Centrioles: found in the centrosome and are the organizing center of
microtubules. Have a structure of nine triplets with a hollow center.
▪ Are involved in mitosis. Organize mitotic spindle, use kinetochores to
attach to chromosomes and exert force to pull them apart.
Intermediate Filaments: filamentous proteins including keratin, desmin, vimentin and
lamins.
o Involved in cell-cell adhesion or maintain overall integrity of cytoskeleton.
o Are able to withstand tension and make the cell structure more rigid
o Anchor other organelles.

Tissue formation
Epithelial tissue: covers the body and line the cavities. Provide protection from
pathogen invasion and desiccation. Can also be involved in absp, secr, and sensation.
o Basement Membrane: cells tightly joined to each other on this layer of
connective tissue. Maintain cohesiveness.
o In most organs, tissue constitutes the parenchyma (the functional parts of the
organ).
 o Are often Polarized: one side faces a lumen (hollow inside or the outside world),
while other side interacts with underlying blood vessels and cells.
o Classifications based on:
▪ Number of Layers: Simple Epithelia have one layer of cells, Stratified
epithelia have multiple layers, and Pseudostratified epithelia have a
difference in cell height of one layer causes the illusion of multiple layers.
▪ Shape: Cuboidal are cube shaped, Columnar are long and thin; and
Squamous cells are flat and scale like.
Connective Tissue: supports the body and provides framework for epethilial cells to
carry out functions.
o Are main contributors to the Stroma (support structures).
o Bone, cartilage, tendons, ligaments, adipose tissue, and blood
o Most cells produce and secrete materials such as collagen and elastin to form
the extracellular matrix

Classification and Structure of Prokaryotic Cell
Simplest of all organisms and include all bacteria. Do not contain any membrane bound
organelles.
DNA is a single circular molecule concentrated in the nucleoid region
Prokaryotic Domains
Three overarching domains of life: Archaea, Bacteria, and Eukarya. Archaea and Bacteria are
prokaryotic and were initially classified together.
Archaea: Single celled organisms that are visually similar to bacteria.
o Contain genes and several metabolic pathways similar to eukaryotic cell
o Extremophiles: originally classified as cells which were only found in harsh
environments of high temperature, high salt and no light.
▪ Have now been found in human body
o Have the ability to use alternative sources of energy. Use photosynthesis or
chemosynthesis (able to generate energy from non-organic compounds)
o Similarities to Eukaryotes: start translation with methionine, contain similar RNA
polymerase, and associate DNA with histones
▪ Differences: contain single circular chromosome. Use binary fission for
division and share an overall structure similar to bacteria.
Bacteria: contain cell membrane and cytoplasm and some have flagella or fimbriae (like
cilia). As such they have similar structures to eukaryotes, which makes it difficult to
develop medicine that specifically treats bacteria.
o However, some structures are different enough to allow for targeting. E.g –
bacterial flagella are different or bacterial ribosome (smaller).
o Bacteria outnumber human cells in the body by 10:1. Some are Mutualistic
symbiotes: both human and bacteria benefit (Vit K in human gut). Other bacteria
are pathogens or parasites in that they provide no benefit to the host human
body.
Classification of Bacteria by Shape
Cocci: Spherical shaped bacteria. E.G – common pathogens
Bacilli: Rod-Shaped. E.G – E.Coli
Spirilli: Spiral shaped bacteria. E.g – syphilis bacteria. Very few are shaped this way
Aerobes and Anaerobes
Bacteria that require oxygen for survival are termed obligate aerobes. Bacteria that use
fermentation or other forms of cellular metabolism without oxygen are termed anaerobes.
Obligate Anaerobes: cannot survive in an environment containing oxygen. Causes
production of radicals which result in cell death
Facultative Anaerobes: can toggle between oxygen-dependent metabolic processes and
anaerobic metabolism.
Aerotolerant anaerobes: Are not able to use Oxygen but are not harmed by its presence.
Prokaryotic Cell Structure
Do not have a nucleus or membrane bound organelles and are single-celled organisms. Means
that each cell must be able to perform all necessary life functions on its own.
Cell Wall: forms outer barrier of the cell. Cell membrane is composed of phospholipids
is the next layer. These two structures are known as the envelope. Responsible for the
protection.
o Provides structure and controls the movement of solutes into and out of the
bacterium.
o Gram-Positive Cell Wall: If envelope appears dark purple after crystal violet stain
▪ Thick layer of peptidoglycan (made up of sugars and amino acids).
Provides structural barrier functions. May also aid a pathogen by
providing protection from a host organisms immune system.
▪ Contain lipteichoic acid: function unknown but may be used in immune.
o Gram-Negative Cell Wall: much thinner than positive and contain small amount
of peptidoglycan.
▪ Peptidoglycan cells beside cell membrane and separated by Periplasmic
Space.
▪ Outer Membrane: contains phospholipids and lipopolysaccharides.
These saccharides are what triggers an immune response in humans
Flagella: Long, whiplike structures that are used for propulsion.
o Chemotaxis: ability of cell to detect chemical stimuli and move towards or away.
o Filament: hollow, helical structure composed of flagellin
o Basal Body: anchors flagellum to the cytoplasmic membrane and is also the
motor of the flagellum.
o Hook: connects filament and basal body so that when the basal body rotates, it
exerts a tourque on the filament.
o Slight differences in flagella between different cell wall types. Also present in
Archae but not commonly tested due to complexity.
Other Organelles: concentrate DNA in nucleoid region (do not contain nuclear envelope.
DNA is carried on single circular protein which is coiled around histone-like proteins.
However, only archaea contain true histones.
 o Plasmids carry DNA that is not necessary for survival of the prokaryote.
▪ DNA from external sources, not apart of genome of bacterium.
o Lack mitochondria, complex cytoskeleton (have a primitive one).
▪ Contain ribosomes but are different size as compared to eukaryotes
(30S/50S and 40S/60S respectively)

Genetics and Growth of Prokaryotic Cells
Binary Fission
Simple form of asexual reproduction. Circular chromosome attaches to cell wall and replicates
while the cell continues to grow in size. Plasma membrane and cell wall begin to grow inwards
along middle (invagination). Two identical daughter cells are produced. This proceeds more
rapidly than mitosis.
Genetic Recombination
Involves the replication and integration of the extrachromosomal material on the plasmids.
These genes often impart benefits to the bacterium. Plasmids can also carry virulence factors
that increase how pathogenic a bacterium is. Subset of plasmids are called episomes and are
capable of integrating into the genome of the bacterium. This helps increase diversity and
permits the evolution of the species over time.
Transformation: integration of foreign genetic material into the host genome. Material
most often comes from other bacteria that spill their contents after lysing.
Conjugation: bacterial form of mating.
o Conjugation Bridge: facilitates transfer of genetic material between two cells.
Transfer is unidirectional from donor male (+) to recipient female (-).
▪ Sex Pili: Bridge is made out of these appendages that come from male.
Sex Factors: Plasmids which are needed to for Pili. Bet studied sex
factor is F (Fertility) Factor in E. coli.
o This process allows for rapid acquisition of antibiotic resistance or virulence
factors.
o If the donor cell attempts to transfer entire copy of genome to recipient. The
recipient cells are referred to as Hfr (high frequency of recombination).
Transduction: requires a Vector which is a virus that carries genetic material
o Viruses are obligate intracellular pathogens which means that they cannot
reproduce outside of a host cell.
o Bacteriophages (viruses that infect bacteria) can accidently trap a segment of
host DNA. When this bacteriophage infects another bacterium, it releases the
trapped DNA into the new host cell, which could sub-sequentially allow for the
integration of the transferred DNA into the genome.
Transposons: genetic elements capable of inserting or removing themselves from the
genome. Not limited to prokaryotes.
Growth
As bacteria first adapt to new conditions, they go through a lag phase. As adaptation occurs,
more rapid binary fission takes place and the exponential/log phase occurs. The resources are
often reduced during this period and rate of reproduction is slowed in the stationary phase.
After the bacteria have exceeded the ability of the environment to support the number of
bacteria, a death phase occurs.

Viruses and Subviral Particles
Viral Structure
Composed of genetic material, a protein coat and sometimes an envelope containing lipids.
Genetic info may be circular or linear, single- or double-stranded, and composed of either DNA
or RNA.
Protein coat is known as a capsid. Envelope surrounds the capsid and is composed of
phospholipids and virus-specific proteins.
o Envelope is sensitive to heat, detergents and dessication. Thus are easier to kill.
Obligate intracellular parasites: must express and replicate genetic info within a host cell
since they lack ribosomes to carry out protein synthesis.
Virions: cell replicates and produces this viral progeny (replication). Virion can be
released to infect other cells
Bacteriophages: Don’t enter bacteria, instead inject their genetic material inside the cell.
o Contain a tail sheath and tail fibers in addition to capsid
▪ Tail Sheath: acts like a syringe, injects genetic material
▪ Tail fibers: help recognize and connect to the host cell
Viral Genomes
Single stranded RNA viruses may be positive sense or negative sense
o Positive Sense implies that the genome may be directly translated to functional
proteins by the ribosomes of the host cell like mRNA.
o Negative Sense require synthesis of an RNA strand complementary, which can
then be used as a template for protein synthesis.
▪ These must carry an RNA replicase in the virion to ensure that the
complementary strand Is synthesized.
Retroviruses: Enveloped, single-stranded RNA viruses. Virion contains two identical RNA
molecules.
o Carry an enzyme known as reverse transcriptase that synthesizes DNA from a
single stranded RNA. DNA enters host cell genome, where it is replicated and
transcribed as if it the host cells own DNA.
▪ Allows cell to be infected indefinitely (think HIV) until cell is killed.
Viral Life cycle
Infection: viruses can only infect specific cells. The cell must have specific receptors for
the virus to bind to. Otherwise the cell is basically invisible to the virus.
o Once the virus binds to the correct receptor, the virus and cell are brought into
close proximity.
o Enveloped viruses fuse with the plasma membrane of the cell
o Sometimes a cell may misinterpret a virus and will bring it using endocytosis.
o Bacteriophages inject their viral genome into the cell after anchoring
Translation and Progeny Assembly: translation must occur after infection in order for
the virus to reproduce. This means that the material needs to be translocated to the
correct location in the cell. A single cirus can create up to many thousands of new
virions within single host cell.
o Most DNA viruses must be taken to the nucleus in order to be transcribed to
mRNA. The mRNA then goes to the cytoplasm where it is translated to proteins
▪ For positive-sense RNA viruses, the genetic material stays in the
cytoplasm where it can be directly translated to protein by ribosomes
▪ Negative-sense RNA viruses require synthesis of a complementary RNA
strand (using RNA replicase) which is then translated to form proteins.
▪ Retroviruses use reverse transcription, which needs to travel to the
nucleus where it is integrated into the host genome.
o Using the ribosomes, tRNA, amino acids, and enzymes from the host cell, the
viral RNA is translated into protein. Many proteins form capsid which allow for
the creation of new virions in the host cell’s cytoplasm.
o Once the viral genome has been replicated, it can be packaged with capsid.
Progeny Release:
1. Viral invasion may initiate cell death. Viral progeny is spilled
2. Host Cell may lyse (destruction of cell membrane by excessive volume of virions):
causes progeny to be spilled out, Disadvantage since virus can no longer use host
cell.
3. Extrusion: virus leaves cell by fusing with plasma membrane. Known as the
productive cycle since host cell does not die.
Lytic and Lysogenic Cycles: the growth cycle determines if a bacteriophage will a lytic or
lysogenic cycle.
o Lytic cycle: maximal use of cell’s machinery. Cell becomes swollen with new
virions, cell lyses and other bacteria can be infected. Bacteria in this phase are
termed virulent.
o Lysogenic Cycle: if bacterium is not lysed, the virus may integrate into the host
genome as a provirus or prophage. May be integrated indefinitely, however,
environmental factors (radiation, light, chemicals) will eventually cause the
provirus to enter the Lytic cycle.
▪ May be some advantages for bacterium: allows for transduction of genes
from one bacterium to another when provirus leaves the genome; if
infected by one strain, it makes the bacterium less susceptible to
 superinfection; proviruses are relatively harmless so it could be seen as
beneficial.
Prions and Viroids
Prions are infectious proteins are non-living things. Cause disease by triggering the
misfolding of other proteins. This drastically reduces the solubility of the protein.
Eventually more of these disfigured proteins are formed and the cell functionality is
reduced.
Viroids: small pathogens consisting of very short single-stranded RNA that infect pants.
Can bind to large number of RNA sequences and will silence genes in that genome.
Consequentially, this prevents synthesis of necessary proteins and can cause metabolic
and structural derangements in the plant cell.
o Can be found in humans (Hep D)