Chapter 5 – Detection and Imaging Tools that Use Nonoptical Waves 169
dynamic biological processes to a precision of single molecules. However, the diffraction-
limited lateral spatial resolution of conventional far-field fluorescence microscopes
is ~200–300 nm. This can be improved by an order of magnitude by superresolution
techniques but is still another order of magnitude inferior to TEM. But TEM, in turn,
suffers the prime disadvantage of being a dead sample technique. CLEM has made
important advances in developing methods to combine some of the advantages of both
the approaches.
CLEM can utilize a variety of different stains, which can specifically label a biological
structure in the sample but be visible in both fluorescence microscopy and TEM. These
stains include novel hybrid probes such as fluorescent derivatives of nanogold particles and
also quantum dots, since the cadmium atoms at the QD core are electron dense. FlAsH and
ReAsH can also be utilized by using a specific photon-induced oxidation reaction with a
chemical called “diaminobenzidine” (DAB), which causes the DAB to polymerize. In its poly
meric state, it can react rapidly with osmium used in negative staining. Secondary antibodies
used for immunofluorescence can also be labeled with a fluorophore called “eosin,” which is
also a substrate that is sensitive to photooxidation of DAB.
The most promising developments involve the use of cryo-EM and genetically encoded
fluorescent protein labels. The use of chemical fixation affects the ability of fluores
cent proteins to fluoresce; although some fixative recipes exist, which affect fluorescent
proteins less, there is still a drop in fluorescence efficiency. However, the rapid freezing
methods of cryofixation methods have shown promise in preserving the photophysics
of fluorescent proteins. Although fluorescent proteins show no clear direct sensitivity to
DAB, there have been some positive results using secondary immunolabeling of green
fluorescent protein (GFP) itself. The state of the art is the mini-singlet oxygen generator
(miniSOG), which is a fluorescent flavoprotein engineered from a phototropin protein
from the plant of genus Arabidopsis (used as a common model organism, see Chapter 7).
MiniSOG contains only 106 amino acids, roughly half as many as GFP, and illumination
generates enough singlet oxygen to locally catalyze the polymerization of DAB, which is
then resolvable by EM.
The ability to image the same region of a sample is facilitated by gridded or patterned
coverslips, which aid in pattern recognition between light and electron microscopes. But a
key development for CLEM has been the reduction in the time taken to transfer a sample
between the two modes of microscopy. Automated fast-freezing systems can now allow
samples to be imaged by fluorescence microscopy, cryofixed within ~4 s, and then imaged
immediately afterward using TEM.
KEY POINT 5.1
Although EM was historically one of the pioneering modern biophysical tools, the
potential for generating experimental artifacts is high, compared to many other modern
techniques. However, both TEM and SEM still are powerful tools and are regularly
used in biophysical research laboratories. One useful modern method to increase the
confidence in interpretation of EM images is to utilize fluorescence imaging and EM
on the same sample. Also, revolutionary recent advances have been made in cryo-EM
to rival the spatial resolution of traditional atomistic-level tools such as NMR and x-ray
crystallography.