Chapter 9 – Emerging Biophysics Techniques 411
electrical resistance in this way could have significantly very high electrical resistances for
wires whose width is of the nanometer length scale, resulting in a highly inefficient gen
eration of heat. Nonbiophysical methods for tackling this issue include the use of super
conductive materials whose electrical resistance can be made exceptionally low. Currently,
these are limited in their use at relatively low temperatures (e.g., liquid nitrogen); however,
it is likely that viable room-temperature superconductive material will be available in the
near future.
Biophysics-inspired research into this area has included fabricating nanowires from
single DNA molecule templates that are spatially periodically labeled with alternating
electron-donor and electron-acceptor probes. These enable electrical conduction through
a series of quantum tunneling processes, rather than by conventional electron drift.
Similarly, using molecular photonics wires that use a DNA molecule containing multiple
FRET acceptor–donor pairs along its length enables the transfer of optical information
through space via FRET, thus acting as an optical switch at the nanometer length scale
(Heilemann et al., 2004).
In 2012, the estimated average total power consumption of the human world was ~18
TW (1 TW = 1 terawatt = 1012 W), equivalent to the output of almost 10,000 Hoover
Dams. The total power production estimated from global photosynthesis is more like
2000 TW, which may indicate a sensible strategy forward to develop methods to harness
the energy transduction properties of natural photosynthetic systems. However, the total
power available to the Earth from the sun is ~200 PW (1 PW = 1 petawatt = 1015 W)—in
this sense, natural photosynthesis is arguably relatively inefficient at only extracting ~1%
of the available solar energy. Solar energy that is not reflected/scattered away from plant
leaves is mainly transformed to heat as opposed to being locked in high-energy chemical
bonds in molecules of sugars.
One route being developed to harness this process more controllably is in the modifi
cation of natural cyanobacteria (photosynthetic bacteria), potentially to develop synthetic
chloroplasts by introducing them into other more complex organisms. These cyanobacteria
contain carboxysomes, which have a protein shell similar in size and shape to the capsid coat
of viruses but contain the enzyme RuBisCo that catalyzes photosynthesis. The application
of these carboxysomes to different organisms has not yet been clearly demonstrated, but
chloroplasts have been imported into foreign mammalian macrophage cells and zebrafish
embryos, to increase their photosynthetic yield (Agapakis et al., 2011).
Modification of bacteria has also been applied in the development of synthetic strains,
which can generate alcohols as fuels, for example, butanol. This method manipulates the
natural fermentation process by adapting the acetyl-CoA complex that forms an essential
hub between many metabolic pathways, most importantly in the Krebs cycle (see Chapter 2).
The key challenge is that the alcohol is toxic to the cell, so achieving commercially feasible
concentrations is difficult. However, biophysics tools such as fluorescence microscopy and
mass spectrometry can be used to assist in understanding how the molecular homeostasis of
the acetyl-CoA is achieved and potentially can be manipulated.