
In this experiment, the researchers genetically engineered a synthetic bacterium named JCVI-syn-3b, or syn-3, which is non-motile. To reconstitute syn-3, the group introduced seven genes that code for proteins that are likely involved in the swimming motion of Spiroplasma bacteria. Spiroplasma is a small bacteria known to “swim” by essentially switching around its cytoskeleton. The proteins introduced evolved from the bacterial actin protein MreB. Actin are multi-functional proteins that are often responsible for motility in cells. In an email to Motherboard, Miyata confirmed that prior to this experiment, nobody had succeeded in making a motile minimal synthetic bacterium. By introducing the proteins responsible for motility in Spiroplasma into syn-3, the researchers were able to make the previously non-motile bacteria swim, as evident in a video published on the University’s YouTube account.
The researchers also wanted to see how the expression of different combinations of the motility genes would affect the genetically engineered bacteria to swim. In doing so, they found that the expression of only two proteins was necessary for promoting motility in syn-3, likely indicating that many of the proteins were redundant and demonstrating a minimal system for motility. “To the best of our knowledge, the motility system comprising only two actin superfamily proteins is the smallest system established till date,” the authors write. “Therefore, we may call this a ‘minimal motile cell.'” Although this study is primarily a proof of concept, it gives scientists a better understanding of how cell motility could have potentially originated and evolved. “In addition to the sheer novelty of creating such a smol swimmer, the new study sheds light on the origin of movement in the first mobile lifeforms that arose on Earth,” adds Motherboard. “For instance, Miyata said that the actin protein MreB is not involved in the motility of many other bacterial species, which confirms that there are multiple different evolutionary pathways that led to microbial movement.” The study has been published in the journal Science Advances.
Read more of this story at Slashdot.