The research, released to the preprint database bioRxiv July 2, has not been peer-reviewed yet. It introduces SpudCell, a new type of artificial cell, and marks a striking step toward creating living cells from scratch. But for study co-author Kate Adamala, a synthetic biologist at the University of Minnesota, that's far from the most interesting part of the work.
The work's announcement has sparked some controversy, with some scientists seeing it as a ploy to gain media attention for the simultaneous launch of the author's nonprofit Biotic, which aims to raise money to further develop the SpudCell platform. Adamala does not take umbrage to that criticism, as she is keen to bring more attention and funding to her field. If a synthetic cell can be perfected, she thinks, it could help humanity generate chemicals without relying as heavily on petroleum products.
According to the preprint, Adamala and her team produced a lifelike system that closely resembles a living cell. To do so, they combined 36 purified enzymes and a fatty membrane with a pared-back genome about 50 times smaller than that of an average bacterial cell. By mixing these human-made elements together, the scientists generated a cell that could feed, grow, and divide — so, in essence, they created a full cell cycle in a petri dish.
The concept of recreating the cell cycle in a dish is not entirely new. The J. Craig Venter Institute's 2016 "minimal cell" paper flirted with the concept by stripping as many genes from a bacterium as possible to leave only a minimal cell that could still replicate. However, the new study is the first time scientists have achieved feeding, growing and division using a "bottom-up" approach.
But there are important caveats. For one, the cells cannot yet create their own energy as our cells do with mitochondria. They also rely on externally provided fats, sugars and enzymes. The cells cannot make their own ribosomes, the machinery that turns genetic instructions into working parts of the cell. That means it relies on proteins being delivered from the outside.
Left: A super-resolution image of SpudCell's liposomes with an encapsulated genome and active protein expression. Right: A SpudCell encapsulates a whole genome. The DNA of the genome and the synthetic cell membrane are stained with fluorescent dyes. (Image credit: Orion Venero, Adamala Lab)"The description of the results leaves me with substantial technical questions regarding the nature and the robustness of the findings," said Cees Dekker, a biophysicist at the Delft University of Technology in the Netherlands who was not involved in the work. "[Its] approach uses some ingenious engineering tricks as shortcuts to achieve complex functions such as growth, but a major challenge remains to create a truly autonomous cell that executes all these functions without external help," he said.
From cell to manufacturing platform
Adamala sees SpudCell as a blank slate for engineering. "We believe that if we make a cell from scratch, that's fully engineerable," she said.
That kind of platform could also be useful for making newer generations of medicines, such as those based on mRNA or peptides. These drugs use molecular building blocks, like amino acids or nucleotides, that have been chemically tweaked to make the molecules more stable or harder for the body to break down. SpudCell could be engineered to produce such modified components directly, rather than scientists having to synthesize them in traditional chemistry labs. This could potentially shorten development timelines and lower costs, the team thinks.
But there's still a long road ahead. For now, SpudCell is only a proof of principle, and many hurdles must be addressed before it could become an industrial platform.
Related stories"[SpudCell] is not an engineering platform that can give you any useful product, but it's step one," Adamala said. "It's probably at least a couple of decades from now when we can actually scale it up to the point where we can replace all the petrochemicals with biology, but I do believe it's doable."
While the technology is promising, "it needs to go through peer review," Rinaldi said. "I expect a lot of the hype and some of the terms that they're using to go away after a couple of years have passed."
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