After implantation, the tissue developed blood vessels and became integrated into neuronal networks in the animals’ brains.
A new prototype machine can make the biological molecules of one’s choice from digital DNA sequences.
August 21, 2017|
K.S. BOLES ET AL., “DIGITAL-TO-BIOLOGICAL CONVERTER FOR ON-DEMAND PRODUCTION OF BIOLOGICS,” NAT BIOTECHNOL, DOI:10.1038/NBT.3859, 2017. IMAGE USED WITH PERMISSION FROM DAN GIBSON
Imagine a deadly virus emerging in a part of the world without the resources for vaccine development. Now imagine if researchers on the other side of the world could send local medics an effective vaccine by email.
Dan Gibson and Craig Venter of Synthetic Genomics in La Jolla, California, started to imagine such a scenario shortly after an avian flu outbreak in China in 2013. The company had just developed a prototype DNA synthesizer (the BioXp 3200, now commercially available) that could produce DNA molecules from just a digital sequence and some appropriate oligos—short nucleotide chains for initiating DNA synthesis. So, when Gibson received notice of the H7N9 bird flu threat in Asia, he was ready. Armed with the publicly available sequences of the H7 and N9 genes, he commissioned a local company to make oligos, popped them and the sequence data into the machine, and the next morning the genes were ready to ship to Novartis for RNA vaccine production.
The process was quick, but it could certainly have been quicker, Gibson says. “I thought, ‘Why can’t we just have an instrument that can be strategically placed anywhere in the world, preloaded with the raw materials, and I email the sequence to the instrument and it does everything for me?’”
Now, that’s exactly what Gibson, Venter, and their team have built. Their new digital-to-biological converter (DBC) can, upon receipt of a DNA sequence, prepare appropriate oligos, carry out DNA synthesis, and then, as required, convert that DNA into a vaccine, or indeed into any RNA molecule or protein.
The team has so far programmed the DBC to make fluorescent proteins, antibody polypeptides, an RNA virus (H1N1 influenza), and an influenza vaccine. They’ve also made a full bacteriophage—by synthesizing the DNA and automatically transforming it into E. coli, which supports the phage’s production.
“The authors paint this future where one might be able to, in a completely digital and automated fashion, go from DNA sequence to functional output,” says Michael Jewett, a chemical and biological engineer at Northwestern University who was not involved in the research. “Granted the prototype is a little bulky . . . but the idea that you could connect all these pieces together without human intervention is exciting.” (Nat Biotechnol, doi:10.1038/nbt.3859, 2017.)
|MACHINE||COMMERCIALLY AVAILABLE?||INPUT REQUIRED||MAKES DNA?||MAKES RNA?||MAKES PROTEIN?|
|BioXp 3200||Yes, from Synthetic Genomics||DNA sequence data and oligonucleotides (specifically designed by the company)||Yes, 400 to 1,800bp fragments||No||No|
|DBC||No, prototype only||
DNA sequence data
Yes. Largest DNA molecule made to date is the 5,386-base-pair genome of a bacteriophage created from the automated assembly of smaller fragments
|Yes, by in vitro transcription.||Yes, by in vitro translation.|