412 9.3 Synthetic Biology, Biomimicry, and Bionanotechnology
are those of standard molecular cloning (Chapter 7). Similarly, genetic modifications can
include encoding tags next to genes at the level of the DNA sequence, for example, fluor
escent proteins.
Modified proteins have been used in genuine bottom-up synthetic assays to build
devices that utilize protein pattern formation. For example, the bacterial proteins MinC,
MinD, and MinE, which are responsible for correctly determining the position of cell
division in growing E. coli bacterial cells (see Chapter 8), have been reconstituted in an
artificial noncellular system involving just microwells of different sizes and shapes. These
systems require an energy input, provided by the hydrolysis of ATP, but then result in fas
cinating pattern formation depending on the size and shape of the microwell boundaries,
even in the complete absence of cells. These systems have yet to be exploited for “useful”
ends, but show enormous potential at being able to develop controllable patterns in solu
tion from just a few protein components, which could have implications for templating of
more complexing synthetic devices.
Similarly, other bacterial cell division proteins such as FtsZ have been artificially
reconstituted. FtsZ is responsible for the actual constriction of the cell body during the pro
cess of cell division, through the formation of a tightening Z-ring. FtsZ can be reconstituted
and fluorescently labeled in artificial liposomes with no cells present and fueled by GTP
hydrolysis in this case, which can result in controlled liposome constriction that can be
monitored in real time using fluorescence microscopy imaging.
The degron system is also a good example of genetic and protein-based bioengineering.
As discussed previously (see Chapter 7), this uses genetic modification to insert degron tags
onto specific proteins. By inducing the expression of the sspB adapter protein gene, these
tagged proteins can then be controllably degraded in real time inside living bacterial cells.
This facilitates the investigation of the biological function of these proteins using a range of
biophysical techniques, but also has potential for exploitation in synthetic biology devices.
A range of unnatural amino acids have also been developed, which utilize different
substituent groups to optimize their physical and chemical properties catered for specific
binding environments, which require a combination of genetic and chemical methods to
integrate into artificial protein structures. A subset of these is genetically encoded synthetic
fluorescent amino acids, used as reporter molecules. These are artificial amino acids that
have a covalently bound fluorescent tag engineered into the substituent group. The method
of tagging is not via chemical conjugation but rather the amino acid is genetically coded
directly into the DNA that codes for a native protein that is to be modified. This essentially
involves modifying one of the nonsense codons that normally do not code for an amino acid
(see Chapter 2). Currently, the brightness and efficiency of these fluorescent amino acids is
still poor for low-light biophysical applications such as single-molecule fluorescence micros
copy studies, as well as there being a limitation of the colors available, but there is certainly
scope for future development.
Larger length scale synthetic biology devices also utilize macromolecular protein
complexes. For example, the protein capsid of virus particles has been used. One such device
has used a thin layer of M13 bacteriophage virus particle to construct a piezoelectric gener
ator that is sufficient to operate a liquid crystal display.