[ozcad]

I fear a synthetic bug getting out by accident or by design and by gene swapping, enter the human genome and permanently weakening us. We could not stop it from happening. I don't know if there is even a name for such a crime of such import.
To promote the required clinical fastidiousness, the punishment list would have to include everyone along the line from the janitor, coffee-makers, researchers, the lab boss, the directors, the owners or shareholders, the financiers and the customer who initiated the project. No exceptions.
That should get the sane ones to change jobs. Trouble is, the remaining ones will be self-selected pathological optimists, who will be setting the safety standards and doing all the work.

[Tanada]

Researchers Beef Up DNA Storage Density By Adding More Letters - ExtremeTech

We have become very good at storing data with hard drives closing in on 20 terabytes, but even our best 21st-century engineering can’t come close to the elegance and density of DNA. Most of the cells in your body contain a complete genetic copy of what makes you a human being, and DNA is surprisingly durable compared to chips and spinning platters that will probably end up in a landfill inside of a decade. DNA might even be viable for storing digital data, but we’re not limited by the way human DNA works. Researchers from the University of Illinois Urbana-Champaign have expanded the capabilities of DNA data storage by adding more letters to its alphabet.

The genetic information in your cells relies on four primary base pairs, also known as nucleotides or nucleic acid. There’s adenine, guanine, cytosine, and thymine — the A, G, C, and T you’ve seen when genetic information is written out. The human body also uses another base called uracil in place of thymine when translating genetic information into RNA to make proteins.

Even without any modifications, DNA is a very dense storage medium. The researchers note that the world creates several petabytes of new data every day, and a single gram of DNA could store it all. That’s what you get with the standard four-base system from life on Earth, but there are plenty more nucleotides in chemistry that can link up to form a DNA strand. The team created an encoding scheme relying on 11 different bases, which gives the synthetic DNA much higher data density than a system of just four bases.

So why aren’t we all using DNA hard drives? While DNA can last for thousands of years without irreparable data loss, it’s difficult to encode and decode that data. You need advanced laboratory equipment, and most tools can’t even interpret the 11-base DNA strands created in the new study. The team found that ring-like proteins known as MspA nanopores, which are commonly used in DNA sensing, could correctly read the synthetic and natural DNA. Interpreting the recovered data required machine learning and artificial intelligence, but the result is a system that correctly read all 77 different combinations of bases used in the study. They believe this system could roughly double the data density of DNA, which is already much higher than any technology we’ve devised.

This work is still very early, but it’s a fascinating proof of concept. The addition of synthetic chemistry to natural biological storage mechanisms could unlock functionally unlimited data storage. And it works, with just a little AI assistance. Such a technology would be limited to long-term archival storage at first, but no one knows what the future may bring.

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[Tanada]

Expanded alphabet, precise sequencing make DNA the next data storage solution

Imagine Bach’s “Cello Suite No. 1” played on a strand of DNA.

This scenario is not as impossible as it seems. Too small to withstand a rhythmic strum or sliding bowstring, DNA is a powerhouse for storing audio files and all kinds of other media.

Kasra Tabatabaei.“DNA is nature’s original data storage system. We can use it to store any kind of data: images, video, music — anything,” said Kasra Tabatabaei, a researcher at the Beckman Institute for Advanced Science and Technology and a coauthor on this study.

Expanding DNA’s molecular makeup and developing a precise new sequencing method enabled a multi-institutional team to transform the double helix into a robust, sustainable data storage platform.

The team's paper appeared in Nano Letters in February 2022.

In the age of digital information, anyone brave enough to navigate the daily news feels the global archive growing heavier by the day. Increasingly, paper files are being digitized to save space and protect information from natural disasters.

From scientists to social media influencers, anyone with information to store stands to benefit from a secure, sustainable data lock box — and the double helix fits the bill.

“DNA is one of the best options, if not the best option, to store archival data especially,” said Chao Pan, a graduate student at the University of Illinois Urbana-Champaign and a coauthor on this study.

hao Pan.Its longevity rivaled only by durability, DNA is designed to weather Earth’s harshest conditions — sometimes for tens of thousands of years — and remain a viable data source. Scientists can sequence fossilized strands to uncover genetic histories and breathe life into long-lost landscapes.

Despite its diminutive stature, DNA is a bit like Dr. Who’s infamous police box: bigger on the inside than it appears.

“Every day, several petabytes of data are generated on the internet. Only one gram of DNA would be sufficient to store that data. That’s how dense DNA is as a storage medium,” said Tabatabaei, who is also a fifth-year Ph.D. student.

Another important aspect of DNA is its natural abundance and near-infinite renewability, a trait not shared by the most advanced data storage system on the market today: silicon microchips, which often circulate for just decades before an unceremonious burial in a heap of landfilled e-waste.

“At a time when we are facing unprecedented climate challenges, the importance of sustainable storage technologies cannot be overestimated. New, green technologies for DNA recording are emerging that will make molecular storage even more important in the future,” said Olgica Milenkovic, the Franklin W. Woeltge Professor of Electrical and Computer Engineering and a co-PI on the study.

Envisioning the future of data storage, the interdisciplinary team examined DNA’s millennia-old MO. Then, the researchers added their own 21st-century twist.

In nature, every strand of DNA contains four chemicals — adenine, guanine, cytosine, and thymine — often referred to by the initials A, G, C, and T. They arrange and rearrange themselves along the double helix into combinations that scientists can decode, or sequence, to make meaning.

The researchers expanded DNA’s already broad capacity for information storage by adding seven synthetic nucleobases to the existing four-letter lineup.

Charles Schroeder.“Imagine the English alphabet. If you only had four letters to use, you could only create so many words. If you had the full alphabet, you could produce limitless word combinations. That’s the same with DNA. Instead of converting zeroes and ones to A, G, C, and T, we can convert zeroes and ones to A, G, C, T, and the seven new letters in the storage alphabet,” Tabatabaei said.

Because this team is the first to use chemically modified nucleotides for information storage in DNA, members innovated around a unique challenge: not all current technology is capable of interpreting chemically modified DNA strands. To solve this problem, they combined machine learning and artificial intelligence to develop a first-of-its-kind DNA sequence readout processing method.

Their solution can discern modified chemicals from natural ones, and differentiate each of the seven new molecules from one another.

“We tried 77 different combinations of the 11 nucleotides, and our method was able to differentiate each of them perfectly,” Pan said. “The deep learning framework as part of our method to identify different nucleotides is universal, which enables the generalizability of our approach to many other applications.”

This letter-perfect translation comes courtesy of nanopores: proteins with an opening in the middle through which a DNA strand can easily pass. Remarkably, the team found that nanopores can detect and distinguish each individual monomer unit along the DNA strand — whether the units have natural or chemical origins.

“This work provides an exciting proof-of-principle demonstration of extending macromolecular data storage to non-natural chemistries, which hold the potential to drastically increase storage density in non-traditional storage media,” said Charles Schroeder, the James Economy Professor of Materials Science and Engineering and a co-PI on this study.

DNA literally made history by storing genetic information. By the looks of this study, the future of data storage is just as double-helical.

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