Transmission Electron Microscopy
Visualization Techniques
Bob Ashley AAS SMFW
7-13-2013
Reading List
• Reading List • Negative Staining 1990 Hayat and Miller• Baker, T. S., and R. Henderson (2006). Electron
cryomicroscopy. In "International Tables for Crystallography", Vol. F, ch. 19, pp. 451-463. Baker, T. S., and R. Henderson (2006).
• Baker, T. S., N. H. Olson, and S. D. Fuller (2000) Erratum: Adding the third dimension to virus life cycles: Three-Dimensional reconstruction of icosahedral viruses from cryo-electron micrographs. Microbiol. Molec. Biol. Reviews 64:237.
Overview
• Free will vs. Determinism in electron microscopy
• Two methods of viewing in TEM• Cryo and Negative Stain
Grids and Support Film
• Usually Copper• How does it react with the specimen?
• Mesh indicates amount of open area• Higher number less open 50-1000• We use 400 mesh square• Very thin films and specimens
• Hexagonal shape openings
• Very delicate• Even mild bend or buckle can cause distortion of specimen or focus aberration
Grid Types• Supports used must be strong yet electron transparent
• Plastic (formvar)• Carbon• Holey carbon• Quantifoil• C-flat
Support Film Concerns
• Mass thickness influences contrast while mechanical stability increases image clarity• Films in general must have• High transparency• Adequate strength to withstand
E- beam and support specimen
• Carbon coated only (6-10 nm)• Uniformly amorphous• More elastic scattering events
with e- beam• Can be stable very thin 1-2nm • More stable than plastic alone• Hydrophobic, fragile, time
consuming to make
• Plastic only 10-20nm (10-20 nm)• Formvar• More clarity with less
background than Carbon alone
• Not as thermally stable and can cause charging and drift
• Carbon Coated with Plastic• Stability of carbon but will
have a thickness that may impede resolution
All Sides Being Equal?• Dull Side (coppery)
• More area for film to adhere
• Shiny side (polished)• Not as much surface
area for films to adhere• Can cause movement
under e- beam exposure
To Glow or NotGlow Discharge renders continuous carbon coated grids hydrophilic by applying a negative charge.
• Aids stain spread more uniformly (increases wettability)• Helps particles in specimen to adhere to the substrate• Decreases likelihood of the virus particles being held in
aggregates as a result of the interaction between the virus particles and the surface charge of film
Contrast• Two types in electron microscopy• Amplitude contrast (scattering contrast)• Subtractive effect where various shades are evident by
loss of electrons • Main source of most electron microscope contrast (except
cryo)
• Phase Contrast (interference contrast)• Interference of diffracted waves cause intensity
differences due to loss of energy and the corresponding shorter focal points• Appear as bright ring or halo around the edge of an object• Fresnel ‘freh-nell’ fringe
The Concept of Negative Stain• Heavy metal atoms act as barrier to the e- beam• Allows passage through specimen
• Stain penetration into hydrophilic specimen• Dries faster than specimen• Mostly hydrated regions replacing water• Lipoproteins and proteins
• Stains form around hydrophobic regions including lipid• Contrast dependent on stain thickness • Resolution range 20-40 Å
Negative Contrast• Dense areas are bright also exclude stain
• Amplitude contrast• Areas with no stain appear light because there is nothing for the electron beam to hit and the transmitted electrons shine through
Simple Microscopy
• Lighter areas have more protein and exclude stain• Darker areas are where the stain pools
• Indent in support mechanism
Stain Film and Particle Interactions
A. Hydrophilic specimen hydrophilic film
B. Hydrophilic specimen on hydrophobic film
C. Hydrophobic specimen on hydrophilic film
D. Hydrophobic specimen on hydrophobic film
Negative and Positive Staining
A. 4% PTA Negative Stained B. 4% UA Positive StainedC. 4% UA Negative Stained
• Three types of staining visible• Negative staining appearing
white• Negative staining appearing
grey• Positive staining appearing
black• Severe structural
distortion
Staining Methods
Factors Controlling Appearance
• Specimen• pH• Isoelectric Point• Fixation• Concentration
• Stain • pH• Charge• Buffer and specimen
interaction• Osmolarity• Can influence structure
and volume of particle
• Interaction with the support mechanism• Grid film• Thickness of stain on film• Charge and beam
interactions
The Effect of the Isoelectric Point of Protein and Stain
• Isoelectric point (pI) or (IEP)
• The pH at which a particular molecule or surface carries no net electrical charge
• Can be time dependent and is not absolute
• Fixation with glutaraldehyde increases net negative charge
• The presence of a fixed negative or positive charge influences the deposition of any given stain• In general proteins• Combine (positive stain) with cations (UA+) on the alkaline side of the
pI• Combine with anions (PTA-) on the acidic side of the pI
• Protein pI• Stain pH greater than pI applies negative charge• Stain pH lower than pI applies positive charge• Ex. Protein with a pI of 5.0 is negatively charged at pH 7.0 with PTA-
which is higher than the pI of the protein therefore the stain repels and is excluded by the protein
Other Effects of pH• Optimal pH for stains is not known but each has a
satisfactory range• At high pH the stain penetration is usually enhanced
with long stain time• At low pH the surface detail is usually highlighted due to
acidic environment
• May change with stain storage and with stain drying• Use fresh stain preferable and check before staining
specimen Ex. stained with PTA at 5.0 pH, influenza virus surface spikes well preserved same sample stained with 7.5 pH PTA stain penetrates virus envelopeEx. PTA with pH of 4.5 recommended for resolving antibody particles bound to rotavirus
Negative Stains
• Negative stain should:• Have minimal interaction with specimen (pos. stain)• High solubility in solution (precipitates and crystalizes in
e- beam)• High density (must be at least twice the density of the
specimen to be visualized)• High melting point to avoid beam damage• Small grain size• Chemical pH stability
Types of Stains• Uranyl Acetate+ (cation)
• Most widely used• Density of 2.87 g/cm^3• Ion diameter .4-.8 nm• pH of 4.0-5.5 (usually used at
4.5 unstable at 6.0)• Concentrations .5-5% ideal as
1%• Can act as fixative• Higher contrast than PTA• Stabilizes lipids therefore may
minimize drying effect of virus particles
• Uranyl Oxalate+(cation)• Can be used in pH from 5.0-7.0
(ideal at 6.5-6.8)• Desirable for pH sensitive
specimens• Provides the contrast and
penetration of UA without the acidity
• Desirable for virus proteins below the pI or low molecular weight
• Uranyl Formate+(cation)• Smallest grain size for better
penetration of interstices of sample• Useful for high-res• pH of 4.0-5.5 (usually used around
4.5)• Density of 3.68 g/cm^3• Ideal as .75%
Types of Stains Continued• PTA-(anion)
• Along with UA most widely used• Density 4 g/cm^3• Grain size of 1.2 nm (not useful for high res work)• At neutral pH very little interaction with the specimen (avoids most positive
staining)• Very stable in e- beam• Will not fix a specimen• Not stable over time with storage <1 month• May dissociate quaternary proteins into small units
• Ammonium Molybdate• Used for osmotically sensitive specimens• pH from 5.0-8.0 useful at 7.0-7.4• Higher contrast than PTA
• Methylamine Tungstate (NanoW)• pH 6.4-7.0• Tolerates concentrated buffers
Drawbacks of Negative Stain• Fixation
• Tends to concentrate sample
• Cellular debris and other junk
• Positive staining
• Beam irradiation• Lower kV=more damage potential
• Drying• Leads to distortion of particle
• Flattening• Will usually happen perpendicular to support mechanism• Makes sample typically larger in diameter to known size
Cryo EM• Negative Stain • Cryo
Contrast reversal of negative stain, dark areas indicate density- Phase Contrast
Light areas indicate density
• Cryo Fixation Advantages• Keeps sample in near native state
Higher resolution – 8-15 Å• No artifacts from stain
Types of Ice
• Amorphous or glassy ice • Target state of cryoEM samples• Liquid nitrogen -195° C• Heat capacity too low- Liedenfrost Effect• Liquid ethane • Liquid propane
• Cubic ice• Water in crystalline lattice obscures beam• Usually around -140° C
• Vanilla Ice• Too hot to handle yet too cold to hold
The Grid in Cryo
The Mechanism• Plunge Freezing • Manual Blotting
Advanced Grid Freezing- Gatan CP3
Visualizing Ice on the Grid
Search for suitable area on grid
Low Dose
• Ice is beam sensitive• E- cause irradiated sample• High res data can be lost in a matter of seconds
• Focus on area that is not photographed and correct for astigmatism
• Keep levels to around 5-20 E/A^2• Can be a software automated process
Visibility of Particles
Irradiation Damage
Defocus Tradeoff• Focus adjacent region of interest to true focus• No inherent contrast from sample in ice• No tone ring visible in FFT• Reset to range desirable -2 to -5 ųm
Drawbacks of Cryo EM
• Low contrast
• Expensive
• Time intensive
• Labor intensive
• Beam irradiation• Lower kV=more
damage potential
• Low signal to noise ratio
• Size limitation• Must be > 400kD for proper
resolution• Smallest published to date is 260kD• Cryo negative stain as possible
solution• Phase plates
The End Result
Thank You
Try the best you can to achieve your EM dreams!