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13.8
�Using the Language of Life Technically with the Help
of Synthetic Biology
These are all promising properties for our new nanocellulose chips. But it is not at all
important to produce this new generation of bio-enhanced computer chips exactly the
same way, but the great direction should be explored as intensively as possible in research
to solve current problems of computer technology and electronics in a very sustainable,
environmentally friendly, flexible, faster and better way than before. A current, simpler
example than the nanocellulose chip shown above with new optogenetically switched
enzymes and DNA as the storage medium is to achieve sustainable electronics by continu
ing to use commercially available electronic components and memory chips, but printing
them thinly on nanocellulose paper in a much more environmentally friendly way than
before (but still using electronic waste as opposed to above) (Jung et al. 2015). Another
interesting marriage of electronics and proteins is electrically modifiable proteins (Ganesan
et al. 2016; Hekstra et al. 2016). Even more generally, this is called synthetic biology,
which we have already learned about. Biological molecules are recombined, allowing
them to achieve new, technically desirable properties. As mentioned above, it can be prob
lematic to create new organisms with new properties, since such organisms are capable of
reproduction. On the one hand, beer as well as bread and cheese have been produced with
biotechnologically bred organisms for centuries, i.e. with the help of organisms systemati
cally genetically modified through breeding. But since this has been going on for centu
ries, it is perceived by the population as “natural” (a bit irrational). On the other hand,
however, the potential danger posed by radically new synthetic organisms (such as new
viruses, fusion of very different cell types, etc.) is already significantly higher than that
posed by centuries-old biotechnology. However, since typical synthetic biology processes
focus on design rather than on a whole organism, there are of course ways and means of
keeping the risks within limits. The safest way is simply to use parts of an organism. These
can then achieve new properties, but are not themselves capable of reproduction. One can
also deliberately incorporate further control steps (as explained above with the BLUF
domains).
Some useful links on the topic of synthetic biology are presented again below (see box).
This shows above all that there are many efforts in this field that are innovative and often
already relatively successful.
13.8 �Using the Language of Life Technically with the Help of Synthetic Biology