286 7.5 Making Crystals
Many functional biomolecular complexes may be formed from multiple separate
components. Obtaining crystals from these is harder since it requires not only a mixture
of highly pure separate components but also one in which the relative stoichiometry of the
components to each other is tightly constrained. Finding optimum temperature and pH
conditions that avoid premature precipitation in the separate components is a key challenge
often requiring significant experimental optimization. The use of microorganisms such as
bacteria and unicellular eukaryotes to grow such crystals has shown recent promise, since
the small volume of these cells can result in very concentrated intracellular protein concen
tration. Crystals for viral capsids (see Chapter 2) have been generated in this way, with the
caveat that the crystal size will be limited to just a few microns length due to the small size
of the cells used.
7.5.3 �TREATMENT AFTER CRYSTALLIZATION
The precision of an x-ray crystal diffraction pattern is affected significantly by the homo
geneity of the crystal, and its size. Controlled, gradual dehydration of crystals can result in
an ultimate increase in crystal size, for example, using elevated concentration levels of PEG
to draw out the water content, which in some cases can alter the shape of the crystal unit
cell, resulting in more efficient packing in a larger crystal structure. Also, small seed crystals
placed in the undersaturated solution can be efficient sites for nucleation of larger growing
larger crystals.
The use of crystallization robots has significantly improved the high-throughput nature
of crystallization. These devices utilize vapor diffusion methods to automate the process of
generating multiple crystals. They include multiple arrays of microwell plates, resulting in
several tens of promising crystals grown in each batch under identical physical and chemical
conditions using microfluidics (see later in this chapter). These methods also utilize batch
screening methods to indicate the presence of promising small crystals that can be used as
seed crystals. The detection of such small crystals, which may have a length scale of less than
a micron, by light microscopy is hard but may be improved by UV excitation and detection
of fluorescence emission from the crystals or by using polarization microscopy. Second har
monic imaging (see Chapter 4) can also be used in small crystal identification, for example, in
a technique called second-order nonlinear optical imaging of chiral crystals. The use of such
high-throughput technologies in crystallization with robotized screening has enabled the
selection of more homogeneous crystals from a population.
7.5.4 �PHOTONIC CRYSTALS
A special type of crystal, which can occur naturally both in living and nonliving matter and
also which can be engineered synthetically for biophysical applications, is photonic crystals.
Photonic crystals are spatially periodic optical nanostructures that perturb the propagation
of transmitted photons. This is analogous to the perturbation of electrons in ionic crystal
structures and semiconductors, for example, there are certain energy levels that are forbidden
in terms of propagation of photons, in the same manner that there are forbidden energy levels
for electron propagations in certain spatially periodic solids.
Photonic crystals are spatially periodic in terms of dielectric constant, with the period
icity being comparable to the wavelength of visible or near visible light. This results in dif
fractive effects only for specific wavelengths of light. An allowed wavelength of propagation
is a mode, with the summation of several modes comprising a band. Disallowed energy bands
imply that photons of certain wavelengths will not propagate through the crystal, barring
small quantum tunneling effects, and are called “photonic bandgaps.”
Natural nonbiological photonic crystals include various gemstones, whereas biological
photonic crystals include butterfly wings. Butterfly wings are composed of periodic scales
made from fibrils of a protein called chitin combined with various sugar molecules in a matrix
of other proteins and lipids that, like all crystals, appear to have many self-assembly steps