These chips would then be used in all kinds of electronics. The proteins could also form titanium dioxide, used in solar cells.
The process is a bit different from regular genetic engineering because it uses synthetic cells made of the randomly combined genes of two related silicateins replete with random mutations, surrounded by a nucleus of minute plastic beads.
The artificial cells are put through the proverbial wringer, killing many along the way. Those that survive the process have their genes cherry picked by the scientists from either the silicon or titanium dioxide-forming proteins.
The results were somewhat surprising, with researchers finding not just the original silicateins used to form the artificial cell in the first place, but also another, different gene.
Tests on the new gene found it contained a silica-forming protein which has been dubbed silicatein X1, which may prove useful in the making of folded sheets of silica-protein fibers.
Silica skeletons of radiolaria in false color .
While that may sound strange and complicated, it’s worth noting that even in nature, creatures like marine sponges can produce materials like fiberglass, while ARS notes that some bacteria can even build magnetic nanoparticles.
Now that scientists know it’s possible to create entirely different silica proteins, the next step will be to change the conditions in order to achieve things like semiconductor performance.