2 bio265 prokaryotes vs eukaryotes_dr di bonaventura
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Prokaryotes versus
Eukaryotes
Cell morphology, structure,
and function
Chicken
egg
Human red
blood cell
Large
protozoan
(Euglena) Chloroplasts
Flea Typical bacteria
and archaea Diameter
of DNA
Viruses Proteins
Ribosomes
Amino
acids
Atoms
Scanning tunneling microscope
(STM) 0.01 nm–10 nm
Scanning electron microscope (SEM)
0.4 nm–1 mm
Transmission electron microscope (TEM)
0.078 nm–100 µm
Atomic force
microscope (AFM)
1 nm–10 nm
Compound light microscope (LM)
200 nm–10 mm
Unaided human eye
200 µm–
Mitochondrion
Coccus
Coccobacillus
Bacillus
Vibrio
Spirillum
Spirochete
Pleomorphic
Morphology of bacterial cells
Multicellular
Arrangements
Multicellular
Arrangements
Staining bacterial cells
Staining bacterial cells: simple stain
One dye is used: crystal violet
The Gram stain
The Gram stain is based on structural differences in the cell
walls of bacteria
One of the first steps a medical laboratory technologist
performs to identify bacterial pathogens
Gram positive (purple/blue)
Gram negative bacteria (pink)
The Ziehl-Neelsen acid-fast stain
Mycobacterium (rod shaped cells – pink/red)
Staphylococcus (cluster of cocci - blue)
Used to detect
Mycobacterium
M. tuberculosis
(tuberculosis)
M. leprae (leprosy)
Schaeffer-Fulton endospore stain of Bacillus
anthracis
Resting structures, resistant to
desiccation, heat, chemicals
Survival during adverse
environmental conditions
Sporulation: endospore
formation
Germination: return to
vegetative state
Bacillus
Clostridium Green-dyed endospores inside red-dyed
rod shaped bacteria
Endospores and medical significance
Negative stain of Klebsiella pneumoniae to detect
the capsule
Background stain
Bacterium
Capsule
Eosin, nigrosin or india ink can be used to stain the background
Crystal violet to stain bacterial cells
Flagellar stain of Proteus vulgaris
Flagella Presence
Number
Arrangement
on the cell
Help identify
pathogens
Dyes are used to build up layers on flagella to make them visible
when using an optical microscope
Streptococcus
pneumoniae causes
pneumonia and
meningitis
S. pneumoniae grown from
a blood culture
Apply your knowledge to understand ….
This arrangement is also seen in Neisseria gonorrhoeae, which causes
the sexually transmitted disease called gonorrhea
Streptococcus
pyogenes and strep
throat
A sputum smear showing
the typical arrangement
in chains of cocci
Apply your knowledge to understand …..
Sputum sample from a
patient with staphylococcal
pneumonia
Methicillin resistant Staphylococcus
aureus (MRSA)
Apply your knowledge to understand …..
Bacterial cells
Within a bacterial cell there is the cytoplasm: a fluid
component surrounded by an envelope called the plasma
membrane
Nucleoid
Bacterial chromosome
Ribosomes
Synthesis of proteins
Inclusions
Reserve of polysaccharides, lipids, nitrogen, phosphate
Plasmids (Not always present)
Extrachromosomal genetic elements
Inclusions
Nucleoid
Ribosomes
Plasmid
Figure 4.14b
The Plasma Membrane
Phospholipid bilayer
Integral proteins
Peripheral proteins
Proteins carry out several functions including transport across the
plasma membrane
Thick peptidoglycan found
on the outer side of the
plasma membrane
Gram-positive
bacteria
Thin peptidoglycan found in
the periplasmic space
Gram-negative bacteria
The cell wall provides structure, shape, and protects the cell from osmotic lysis
Cell wall of Gram positive bacteria
Peptidoglycan (also called murein): NAG, NAM
Teichoic acids
Cell wall of Gram negative bacteria
LPS (lipopolysaccharide)
Lipid A is an endotoxin
O polysaccharide functions as an antigen (E. coli O157:H7)
Atypical Cell Walls
Acid-fast cell walls
Waxy lipid (mycolic acid) bound to the peptidoglycan
Mycobacterium
Glycocalyx: Capsule or Slime layer
• Capsule: Organized and firmly attached to the cell wall
• Slime layer: Unorganized and loosely attached to the cell wall
Protects from desiccation
Confers adherence
capability
Allows pathogens to
escape or survive
phagocytosis
Sticky substance surrounding the outside of the bacterial cell
Made of polysaccharides, polypeptides, or both
Streptococcus pneumoniae, Klebsiella pneumoniae, Bacillus
anthracis
Fimbriae and Pili
Escherichia coli
Fimbriae allow
attachment
Fimbriae of E.
coli O157 enable
the bacterium to
adhere to the
lining of the small
intestine
Causing
a severe watery
diarrhea
Proteus species
are involved in
nosocomial
urinary tract
infections
Proteus vulgaris
Fimbriae
Flagella
Neisseria gonorrhoeae, the pathogen colonizes the mucous
membrane of the reproductive tract by attaching with fimbriae
Fimbriae and Pili
Pili are involved in motility
and genetic exchange in the
process of conjugation
Through conjugation bacteria
acquire new capabilities
Toxin production
Resistance to antibiotics
Flagella (locomotion)
Composed of filament, hook, and basal body, which anchors the flagellum to the cell wall/membrane(s)
Motile cells move toward or away from stimuli (taxis)
Flagellar proteins are H antigens (E. coli O157:H7)
Arrangements of bacterial flagella
Flagella allow movement, which in turn can allow escape from
host defense
Axial filaments are
flagellum-like structures
found in spirochetes
Causes the bacterial cell
to rotate like a corkscrew
(corkscrew motion)
Treponema pallidum (syphilis)
Axial filaments
Comparative analysis between prokaryotic
and eukaryotic cells
Eukaryotic cells
We are eukaryotes!!
The Nucleus
The nucleus contains almost all of the cell’s hereditary
information (DNA)
The nucleus of human cells can be the site of viral replication
Certain viruses such as HIV integrate their genome into our
DNA, becoming proviruses
The Endoplasmic reticulum (ER)
Systems of flattened
membranous sacs or tubules
(cisternae)
The rough ER (with ribosomes)
Synthesis of secretory
proteins and components of
cell membranes
The smooth ER carries out
various functions
Synthesis of lipids (steroids)
Detoxification - drugs or
alcohols
Ribosomes
Ribosomes are the intracellular site of protein synthesis
Eukaryotic ribosomes (80S) differ from those of bacteria
(70S) - though both types are made of proteins and
ribosomal RNA
Bacterial ribosomes
are the target of
antibiotics
The Golgi apparatus
Modifies, sorts, and ships proteins from the ER, including
those secreted by the cells
Produces lysosomes
The Golgi Apparatus
Lysosomes are filled
with digestive
enzymes that break
down various
molecules
Intracellular digestion
of macromolecules in
animal cells
Lysosomes are
involved in
phagocytosis
Lysosomes
Details of the figure will not be
part of the exam!
Peroxisomes
Oxidize organic substances (amino acids, fatty acids, toxic
substances such as alcohol)
Contain catalase, an enzyme that converts H2O2 (by-
product of the oxidation reactions) into H2O and O2
Mitochondria
Sites of cellular
respiration, a metabolic
process by which cells
form ATP
Mitochondria contain
DNA and ribosomes
(similar to those of
bacteria)
Mitochondria evolved
from bacteria
Plasma Membrane
“Fluid mosaic model” of the membrane
Three types of cytoskeleton
components
Microtubules
Microfilaments
Intermediate filaments
Cytoskeleton, Cilia, and Flagella
i.e., Keratin
Shigella and
actin filaments
Bordetella pertussis
and the ciliary escalator
of the respiratory tract
Cilia and flagella are
made up of microtubules
projected outward from
the cell surface
Cilia are not found in
prokaryotes
Cytoskeleton, Cilia, and Flagella
Endocytosis and Exocytosis
Endocytosis, a process by which eukaryotic cells take in the
“material” through formation of vesicles
Endocytosis includes
Phagocytosis
Pinocytosis
Exocytosis involves moving “material” out of the cell which
is also done through the formation of vesicles
Phagocytosis is a defense mechanism of our
body
Phagocytosis is a
process our body
uses against
pathogens
Many pathogens
have found ways to
escape or survive
phagocytosis
Bacteria
A human cell (blue)
engulfing a yeast cell (green)
Keep in mind that eukaryotic organisms you will study
include
Filamentous fungi
Yeasts
Protozoa
Helminths
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