Micr20010 Lecture 3 2023 PDF

Summary

These lecture notes cover Microscopy and Introduction to Microbial diversity, delving into topics like light microscopy, electron microscopy, and cell structures. The material is from a microbiology lecture and is likely to be relevant at an undergraduate level.

Full Transcript

MICR20010 Lecture 3
Microscopy &
Introduction to Microbial diversity
Dr. Jennifer Mitchell
Microbiology
School of Biomolecular and Biomedical Science

Lecture 2
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How to culture microbes
Difficulties working with microbes
Sterile growth media
Handling microorganisms
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Inoculation
Incubation
Isolation
Inspection
Identification

• Disposal of cultures
• Disinfectants and Antiseptics

Learning Outcomes
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Light Microscopy
Preparing bacterial cells for microscopy
Light microscope resolution
Electron Microscope
– Scanning Electron Microscope
– Transmission Electron Microscope
Domains of Life
Types of microorganism
Eukaryotic Cell Structure
Eukaryotic Versus Prokaryotic Cells

Light Microscopy
Magnification versus resolution

Can be increased without limit

Cannot

Magnification is how much an image is enlarged under a microscope
Resolution is the amount of detail you can see in an image. You can
enlarge a photograph indefinitely using more powerful lenses, but the
image will blur together and be unreadable. Therefore, increasing the
magnification will not improve the resolution. This is also known as the
resolving power.

Light microscope resolution = 0.2m
Electron microscope = 1000x light microscope

Light Microscope
100x, 400x, 1000x
10x

10x, 40x, 100x (oil)

Preparing bacterial cells for microscopy

Resolution
• Light microscope

• Cannot distinguish objects that are smaller than
half the wavelength of light.
• White light has an average wavelength of 0.55
micrometers, half of which is 0.275 micrometers
• Any two lines that are closer together than 0.275
micrometers will be seen as a single line, and
any object with a diameter smaller than 0.275
micrometers will be invisible or, at best, show up
as a blur

Electron Microscopy I
• Uses electrons instead of light photons to image
cells and cell structures
• Electrons provide "illumination" with a shorter
wavelength than light photons
• Electromagnets function as lenses

• Entire system is held in a vacuum

Electron
Microscope

Light Microscopy

Electron Microscopy

Electron Microscopy II
• Electrons are speeded up in a vacuum until their
wavelength is extremely short, only one
hundred-thousandth that of white light.
• Beams of fast-moving electrons are focused on
a cell sample and are absorbed or scattered by
the cell's parts so as to form an image on an
electron-sensitive photographic plate.
• Most electron microscopes can magnify objects
up to 1 million times

• Resolving power of EM = 0.2 nm versus 0.2 m
for light microscope (1000X)

Electron microscope

Electron Microscopy III
• Scanning electron microscopy
– Used to observe external features of cells. Specimen
coated with thin film of metal e.g. gold.
– Electrons scattered by the metal are collected to
produce an image

• Transmission electron microscopy
– Used to observe internal cell structures.
– Unlike light photons, electrons do not penetrate the
cell
– Hence thin sections of the cells are prepared (one
bacterial cell cut into many thin sections)

SEM bacterial cells

E. Coli

Salmonella

Staphylococcus

TEM bacterial cells

E. Coli

Streptococcus

Light versus Electron microscopy
• No living specimen can survive under high
vacuum and chemical fixatives used in EM
• Light microscopes enable the user to see living
cells in action.
– Primary challenge for light microscopists has been to
enhance the contrast between pale cells and their
paler surroundings so that cell structures and
movement can be seen more easily.
– Phase contrast light microscopy

Light versus Electron microscopy
• New strategies involving:
– video cameras,
– polarized light
– Fluorescent dyes
– digitizing computers

• Yields vast improvements in contrast,
fueling a renaissance in light microscopy

Domains of Life

Types of Microorganism
• 1. Prokaryotic microorganisms:
– Bacteria, Archaea

• 2. Eukaryotic microorganisms:
– Fungi, Protozoa, Algae

• 3. Non-cellular microorganisms:
– Viruses, Prions

Prokaryotic Cell Structure

Eukaryotic Cell Structure

Eukaryotic Versus Prokaryotic Cells
Prokaryotic Cell

• No nucleus
• All have cell wall
• No cell organelles

Eukaryotic Cell

• Nucleus
• Some have cell wall,
many do not
• Cell organelles e.g.
– Mitochondria, chloroplasts,
– Endoplasmic reticulum
– Golgi

Eukaryotic Versus Prokaryotic Cells
Nucleic acid
Eukaryotic cell
1. Nucleic acid in organelle called a nucleus. Bounded
by a nuclear membrane.
2. Contains one or more paired, linear chromosomes
composed of DNA associated with histone proteins

Prokaryotic cell
1. Nucleic acid not bounded by a nuclear membrane
2. Usually contains one circular chromosome
composed of DNA associated with histone-like
proteins.

Eukaryotic Versus Prokaryotic Cells
Cell division

Eukaryotic cell
1. By mitosis
2. Sex cells in diploid organisms are produced through
meiosis.

Prokaryotic cell
1. Usually by binary fission. No mitosis.
2. Organisms are haploid. No meiosis needed.

Eukaryotic Versus Prokaryotic Cells
Cytoplasmic membrane

Eukaryotic cell
Cytoplasmic membrane is a fluid phospholipid bilayer
containing sterols

Prokaryotic cell
Cytoplasmic membrane is also a fluid phospholipid
bilayer.

Eukaryotic Versus Prokaryotic Cells
Cytoplasmic structures
Eukaryotic cell
– Ribosomes composed of a 60S and a 40S subunit forming an
80S ribosome.
– Internal membrane-bound organelles e.g. mitochondria,
endoplasmic reticulum, Golgi apparatus, are present
– Chloroplasts serve as organelles for photosynthesis.
– Cytoskeleton responsible for cell shape.

Prokaryotic cell
– 70S Ribosomes composed of a 50S and a 30S subunits
– Internal organelles are absent
– No chloroplasts. Photosynthesis usually takes place in infoldings
of the cytoplasmic membrane.
– Cell wall responsible for cell shape.

Eukaryotic Versus Prokaryotic Cells
Respiratory enzymes & Electron Transport chains
Eukaryotic cell
• Located in the mitochondria.

Prokaryotic cell
• Located at the cytoplasmic
membrane

Eukaryotic Versus Prokaryotic Cells
Cell wall
Eukaryotic cell
– Plant cells, algae, and fungi have cell walls, usually
composed of cellulose or chitin but never containing
peptidoglycan
– Animal cells and protozoans lack cell walls

Prokaryotic cell
– Bacteria and Archaea have cell walls composed of
peptidoglycan, protein or unique molecules
– Obligate intracellular bacteria – mycoplasma, chalmydia,
ureaplasma have no cell walls

Eukaryotic Versus Prokaryotic Cells
Locomotor organelles

Eukaryotic cell
– May have flagella or cilia. Flagella and cilia are
organelles involved in locomotion and in eukaryotic cells.

Prokaryotic cell
– Some have flagella.

Further Reading
• Microbiology an Introduction, Tortora,
Funke and Case 12th Ed.
• Chapter 3 “Observing Microorganisms
through a Microscope”
• Chapter 4 “Functional Anatomy of
Prokaryotic and Eukaryotic Cells”