Visualizing Cells: Chapter 9 PDF

Summary

These lecture notes cover various microscopy techniques, including light, fluorescent, and electron microscopy, for visualizing cells. The notes detail different types of microscopy and how to choose the optimal method for specific situations, emphasizing the advantages and disadvantages.

Full Transcript

Molecular Biology
of the Cell
Seventh Edition

Visualizing Cells: Chapter 9

Not for sale or distribution; property of York University
This lecture will cover:

Important concepts in microscopy
Types of Light Microscopy
Using fluorescent molecules in cell biology
Types of Electron Microscopy

What you should be able to do:
Describe/explain each
Compare critically (how they differ,
advantages/disadvantages)
Choose optimal type of microscopy given a
particular situation/need
Light Microscopy

Bright-field shining white light
Phase-contrast phase-shifting of wavelengths
phase-shifting and
Differential Interference interference of light
Dark-field light is emmitted at an angle and
scattered by cell parts
Fluorescence fluorecent
cell parts
chrome to detect
With Bright-field Microscopy most cells and cell structures have very little contrast
Bright-field microscopy uses unmanipulated transmitted light

BFM generates a dark image on
a light backround -- using
unmanipulated transmitted light
Since most of the cell is mafe up of water, the
light is just passing through, it is not disrupted --
most organelles are not visible using BFM
because they don't absorb enough light to
generate contrast relative to the backround

- little contrast
- little detail
- some magnification
- some resolution

Source: https://www.thermofisher.com/ca/en/home/life-science/cell-analysis/cell-analysis-learning-center/molecular-probes-school-of-
fluorescence/imaging-basics/fundamentals-of-fluorescence-microscopy/how-fluorescence-microscopy-works.html
 Processing of tissue samples is required for
Making tissue sections can help to
generate more contrast/detail
staining

Fixation: covalent cross-linking locks glutaraldehyde forms covalent bonds with
proteins into place. free amino groups of our proteins to lock
them into place

Embedding: wax permeates and then
solidifies to harden and stabilize tissue.

Sectioning: tissue is thinly sliced with a
microtome for observation under a light
microscope.

after these processes, the sample could potentially
be damaged, killed, or portray a distorted image

Molecular Biology of the Cell (© Garland Science 2008)
Cell components can be stained to create contrast and make them visible

Urinary Collecting Duct Plant Root

hematoxylin and eosin (H&E)
Is this the perfect solution?
Hematoxylins stains the ECM (extracellular matrix) Fast green stain
- produces a dark blue dye - stains cellulose in plant cells
- has an affinity for negative charged molecules
- DNA, RNA, acidic amino acids

Eosin stains the nuclei
- produces a red dye
- has an affinity for basic components
- basic amino acids (lysine, arginine)

The stains allow individual cellular
components to stand out which
provides more detail about the cell
compared to the image using BFM

depending on your purpose of
examining a sample, you may need the
detail the staining provides
Phase Shifts in Light

Phase Contrast microscopy

In phase waves are percieved as light Out of phase waves are percived dark
-- they can somewhat cancel each
other out
Phases can be affected differently as
light passes though different parts of
the sample (different densities)

When light is in different phases, they
can interfere with eachother

combining different phases of light to manipulating light, expoliting
generate contrast differences in light behaviour can
generate contrast
Fig. 9.3, Molecular Biology of the Cell
Light passing through a specimen can be absorbed, slowed, transmitted, reflected, scattered…

unmanipulated out of phase
light passing waves combine
through the to create contrast
sample

BFM PCM

Fig. 9.6, Molecular Biology of the Cell
Phase Contrast Microscopy converts small differences in phase into contrast to generate an image

Bright Field Phase Contrast

▪ Generates a dark image Visualize living cells
of an object over a light Not all structures are visible
background (what can you see /not see?)
BFM can be used for live PCM can show more in camparision to
cells but are hard to see BFM but it is still not detailed

Fig. 9.7, Molecular Biology of the Cell
 Paramecium ▪ exploits differences in refractive index
Can see between the cytoplasm and the
- nucleus surrounding medium or between
- cillia
different organelles.
can be used to view live cells and
cellular organelles

Didinium eating Paramecium

https://www.youtube.com/watch?v=rZ7wv2LhynM

Copyright © 2020 W. W. Norton & Company
Differential Interference Microscopy manipulates Phase Differences to visualize edges or boundaries

Used to view unstained living cells produces a 3D
appearance (optical slice)

DIM uses phase
shifting and
interference of light Both PCM and DIM
are used to view
Used to visusalize live cells
living cells and can
view unstainsatained
cells

Figure 9-7
 DFM produces an image using scattered light

▪ Dark-field optics enable microbes to be
visualized as halos of bright light against
darkness.
▪ Allows the detection of objects that are
unresolved by bright-field microscopy
Very narrow cells (0.1 mm), such as
Treponema pallidum Produces a bright image on a
dark backround
Cell components, such as flagella

Copyright © 2020 W. W. Norton & Company
Which type of light microscope
do you think would be most
useful and why?
hard to visualize specific parts/
molecules/proteins of the cell when
using light microscopy

Limitations of light microscopy

Solutions: dyes, fluorescent probes, digitization, different types of
microscope
Specific Molecules/Ions Can Be Located in
Cells by Fluorescence Microscopy

labelled different RNAs with fluorescently labelled probes -- each
probe can only detect a specific RNA target

Identification of different RNA in the developing Drosophila embryo
Electrons can absorb photons and move to an excited state.
Excited electrons can release energy as light when they return
to the ground state: fluorescence
when a photon encounters an electron, the photon
provides the electron with energy to move the electron
from the ground state to the excited state -- the excited
electrons release the energy as light when they get
back to the ground state -- emmited as fluorescence
Fluorescent probes will be excited by one wavelength and emit another, longer, wavelength.

fluorophore is some
How do fluorescent probes work? fluorescent chemical
compound that re-emits
light upon light excitation

▪ The specimen
absorbs light of
a specific
wavelength,
then emits light
fluorescence at a longer
wavelength
a specimen will absorb light
at a specific wavelength
(excitation wavelength) and it
will emit light at a longer
wavelength (emmision
wavelength
Figure 9-10a
Fluorescent probes are Fluorescent probes are
used to detect certain excited at a higher
structures in samples by energy and emit light at
absorbing and emitting light a lower energy

Fluorescent
molecules absorb
higher energy
(shorter wavelength)
photons and emit
lower energy (longer
wavelength) photons.
rhodamine B
DAPI absorbs GFP absorbs absorbs green
light at the UV blue light and and fluorese
level and fluorese red - stains
fluorese blue - green - stains various
stains DNA, proteins structures
nuclei

Figure 9-12 Molecular Biology of the Cell (© Garland Science)
Fluorescence Microscopy
▪ the specimen absorbs light of a defined wavelength and then
emits light of lower energy, thus longer wavelength; that is, the
specimen fluoresces.
▪ e.g. can be used to view marine bacteria and gut bacteria
Fluorescence Microscopy allows you to visualize fluorescent molecules.
Fluorescence microscopes excite the fluorescent molecules
with the excitation wavelength, then focus the emitted
fluorescent light to your eye.

By Howard Vindin CC BY-SA 4.0

Figure 9-10
 How do you make
cells/molecules fluorescent?
Some things are naturally fluorescent
(autofluorescence)
e.g. Chlorophyll

Source: Photosynthesis lab manual York University

Source: https://commons.wikimedia.org/wiki/User:Dietzel65
This file is licensed under the Creative Commons Attribution-Share Alike 4.0
International license.
 Fluorophores for Labeling
▪ fluorophore is a fluorescent chemical compound.
Its cell specificity can be determined by:
– Chemical affinity
– Labeled antibodies
– DNA hybridization
– Gene fusion reporter

Copyright © 2020 W. W. Norton & Company
 Fluorescent Dyes can stain specific structures

e.g. DAPI (4′,6-diamidino-2-
phenylindole) – binds and
labels DNA

Dyes such as DAPI emit
blue -- bind to specif
regions of our DNA --
ATregions -- impermient
(need higher
concentrations of it to
eneter a live cell) cant
permeate through a semi
permeable membrane

Source: Hieronim Golezyk http://www.golczyk.cal.pl/golczyk.htm
 Immunocytochemistry uses antibodies and
ICC = labelling a cell using
fluorescent probes SA is
antibodies SA is carrying markers/ more
PA directed against fluoreescent dye -- general
antigen A marker is recognizing PA and
Antibodies amplifies
are the signal
immune
proteins
that work
against
invading
antigens PI binds to
antigen A

Antigen/target
molecule
Antibody binds specifically Can be quantitative or
to the antigen qualitative
(concentrations of
antigen)
Figure 9-15 Molecular Biology of the Cell (© Garland Science)
The downside of immunocytochemistry

Usually cells must be fixed (dead), permeabilized and often
partially extracted (leads to artifacts)
Fixed cells (cells that have been chemically prepared) provide
only a snapshot of what is going on or present in the cell.
Sometimes it is easy to tell from a
snapshot photo what just happened
But not always
Green Fluorescent Protein (GFP)
GFP gene and protein
isolated from jelly fish
Aequoria victoria

GFP is a tag that can be
used to visualize
proteins in live cells
 History: Green Fluorescent Protein (GFP)

The Nobel Prize in Chemistry
2008

Osamu Shimomura, Martin
Chalfie, Roger Y. Tsien

Douglas Prasher
cloned/sequenced the gene for GFP
cellular marker

Roger Tsien
constructed many GFP mutants
 Green Fluorescent Protein (GFP)
chromophore responsible for GFPs
fluorescence is shielded from quenching by
aqueous solvent chromaphore
composed of 3 AA at
the center of the
42 Å long and 24 Å in structure
diametersheilded from
quenching from any
aqueous solvent
serine-tyrosine-glycine
light handling
machinery
11 beta strands,
pleasted sheet
arrangement, beta
barrel arrangement
(beta can), 5 alpha
helixes -- structural
GFP can be taken and a
protein of intrest, and can be
recombined -- generates a chromphore can
fusion protein be added to
protein of intrest
Figure 9-16 Molecular Biology of the Cell (© Garland Science)
and GFP will start
 The gene for GFP can be inserted and expressed in
GFP can
prokaryotic and eukaryotic cells
be
engineere
d to the
protein of
intrest

GFP is
only active
in certain
nuerons

GFP expressed under a neuronal promoter in Drosophila

Figure 9-17 Molecular Biology of the Cell (© Garland Science)
GFP as a tool to study gene expression
1. GFP gene can be fused to any GFP can be used to study the cellular
promoter sequence loaction of a protein given that we can
express our fusion protein at any level,
and by adding GFP the cell can retain its
2. Promoters drive gene expression normal function

3. This indicates where, when and how
much of a protein is made
 The gene for GFP can be fused with other genes to
study the expression and localization of specific
proteins.

bsp.med.harvard.edu
Molecular Biology of the Cell (© Garland Science)
 Summary: Green fluorescent protein (GFP) is a bioluminescent
protein isolated from jellyfish Aequorea victoria

Beta strands form the beta barrel (beta can),
chromaphore in the center composed of 3 AA --
structure is important to anable it to fluoresce

Ser65–Tyr66–Gly67

Figure 9-16 Molecular Biology of the Cell (© Garland Science)
 Variants of GFP

the key is to make small mutations that change the stability of the chromophore
Making small mutation to GFP --
replase tyrosine with typrophan
 Rachel Glinsman

Source: https://www.ebi.ac.uk/pdbe/about/news/dressed-fluoresce
 Confocal fluorescence microscopes allow you
to take optical sections through a cell.
In confocal
microscopy, a
microscopic laser
light source scans
across the
specimen.

taking multiple
images to generate a
3D representation -- Regular fluorescent Confocal 3-D
can take images of image optical section reconstruction
subcellular levels

Confocal microscopes remove the out of focus light from parts of the
cell above and below the focal point, generating an optical section
Multiple sections can be digitally combined to create a 3-D image
Figure 9-25 Molecular Biology of the Cell (© Garland Science)
New techniques generate images with
improved resolution

Super sensitive digital cameras
Averaging multiple images
Requires computing power and
sophistication

low levels limit of
of staining, resolution
superress = 200 nm
olution -- 2nm
with
improved
resolution
Seeing cells without Light: solving the
resolution problem
 Transmission Electron Microscope
Transmission EM allows you to visualize
molecular structure LOR =
0.002 nm

LIGHT ELECTRON
MICROSCOPE MICROSCOPE
theoretical
LOR = resolution
200nm 0.002 nm
electrons
travels
through
the electron
specimen beam
tungsten is
the source
of
Figure 9-40 Molecular Biology of the Cell (© Garland Science)
 Transmission Electron Microscopy (TEM)
+
-high resolution
(~1nm)
-see lots of internal
structure
-molecular structure

BUT – requires thin
sections (25-100nm)
~200 to go through
a cell
Stained mith an electron- Sample
dense material, electrons will needs to
pass though the spcimen, be fixed
stained areas will appear
darker

Molecular Biology of the Cell, Fifth Edition (© Garland Science)
TEM
Different Views of a Single Object Can Be Combined to Give a Three-Dimensional Reconstruction

Multiple thick sections of
the Golgi apparatus which
have been digitally
reconstruction

White
speres =
lysosomes

Figure 9-47
Sample Processing for Electron Microscope

1. Fixation with glutaraldehyde to cross-link proteins in place
used to staballize membranes
and proteins
2. Treatment with osmium tetroxide to ___________________
Other heavy-atom salts can be used (lead and uranium) to
increase electron contrast
3. Dehydration and embedding in resin
4. Sliced into 50-100 nm thick slices
frazen to
maintain
Often samples are flash-frozen (liquid helium) integrity
before
the cell
of
treatment
structure
Thought to better maintain integrity of cell structure
 Transmission Electron Microscopy (TEM)

What’s the
Downside?

Cells fixed
Embedded in resin
Sectioned
Stained with
electron dense
material
Just see where the
stain sticks

TEM
Figure 1-42 Molecular Biology of the Cell, Fifth Edition (© Garland Science 2008)
 Transmission electron microscope image of
yeast cell

Darker areas =
electrons were
blocked by dense
material

Lighter areas =
electrons passed
through the sample
because of less
density

Molecular Biology of the Cell (© Garland Science)
 Immunogold Electron Microscopy

1. Detect specific molecules (like immunocytochemistry)
2. Stain thin slices with primary antibody against protein of
interest
3. Follow with secondary antibody conjugated with gold-particles
4. Gold-particles are electron dense and can be 5-20 nm in size.
5. Can do dual staining using different secondary antibodies
conjugated with different sized-particles
 Immunogold localization of Rubisco and a carbonic
anhydrase enzyme -CcmM in a cyanobacteria: Nostoc

b

Fig 1a. Sections of Nostoc were immunolabelled with Rubsico antibody. Gold
particles (15 nm) are predominantly localized in the carboxysome.
a
de Araujo et al., 2014
 Scanning Electron Microscopy (SEM)
Surface is coated scanning accross the
specimen and
with heavy metal produce surface
informatio

Measures quantity
of electrons
scattered over
surface

Figure 9-49 (part 1 of 2) Molecular Biology of the Cell (© Garland Science 2008)
Transmission Electron Microscopy (TEM) and Scanning
Electron Microscopy (SEM)

SEM TEM
Figure 1-42 Molecular Biology of the Cell, Fifth Edition (© Garland Science 2008)
 Transmission Electron Microscopy (TEM)
Good for visualizing internal features of cell
Preparation fixed, stained with electron dense material (e.g. heavy
metal), embedded in resin, thinly sliced
Electrons (instead of light) pass through specimen and electron
stained areas appear dark
Resolution up to 0.3 nm

Scanning Electron Microscopy (SEM)
Good for visualizing external features
Heavy metals added to outside of specimen
Uses scattered electrons to produce 3D image
Resolution 3-20 nm
LOOKING AT CELLS AND MOLECULES
IN THE ELECTRON MICROSCOPE
Images of Surfaces Can Be Obtained by Scanning Electron
Microscopy

Scanning electron
microscopy (SEM) can
provide a high resolution
3 dimensional surface
images. However, the
resolution is not as great
as TEM.

Stereocilia from a hair cell
A) SEM
B) Light microscopy
C) TEM
 X-Ray Diffraction Analysis
▪ X-ray data undergo digital analysis to
generate sophisticated molecular models.
▪ For samples that can be crystallized, X-ray diffraction
makes it possible to fix the position of individual
atoms in a molecule.
A beam of X-rays is shot at a crystallized
sample.

e.g., the anthrax lethal factor
– A toxin produced
by Bacillus anthracis

the pattern
allows us to fix
of the x-
the posion of
rays can
the atom in a X-rays diffracts at the
be used to
molecule posiotion of the atoms
predict the
structure which are used to ma
of proteins the protein structure
Cells are packed full of molecules!
How does everything find its place
and do its job(s)?
 In the bright-field microscopic image below the
dark green areas represent regions where

A. Less light travelled
through the specimen

B. More light traveled
through the specimen
 The ________ microscope relies on the principle of interference to produce
images of the specimen without staining or damaging it.

a) Bright-field

b) Dark-field

c) Phase-contrast

d) Transmission electron

e) Scanning probe

Copyright © 2020 W. W. Norton & Company
 All of the following statements apply to scanning electron microscopy
EXCEPT:

a) The specimen is usually fixed and embedded.

b) The embedded specimen is cut into thin sections with a microtome.

c) It cannot be used to view live specimens.

d) It provides 3D images of the specimen.

Copyright © 2020 W. W. Norton & Company
 You want to study the structure of a particular protein in bacteria.
Which technique would you use?

a) Light microscopy

b) Electron microscopy

c) Ultracentrifugation

d) X-ray crystallography

e) Cryo-electron tomography

Copyright © 2020 W. W. Norton & Company
 Summary: The Light Microscope
Detection vs. Magnification vs. Resolution
Magnification: apparent “visual” increase in the size of an
object. There is no limit to magnification.
Resolution: “visual” separation of the individual components
of an object, which previously appeared as one; quality of the
image.
Resolution limit: is reached when additional magnification
does not separate further detail. The result is simply an
enlarged blurry image.
Detection: able to visualize light signals from objects much
smaller than 0.2 mm, including a single molecule. However,
objects appear like they are 0.2 mm in size (due to diffraction).