Despite xanthommatin’s fantastic color properties, it is poorly understood due to a persistent supply challenge. Harvesting the pigment from animals isn’t scalable or efficient, and traditional lab methods are labor intensive, reliant on chemical synthesis that is low yielding. Researchers in the Moore Lab at Scripps Oceanography sought to change that, working with colleagues across UC San Diego and at the Novo Nordisk Foundation Center for Biosustainability in Denmark to design a solution, a sort of growth feedback loop they call “growth coupled biosynthesis.” The way in which they bioengineered the octopus pigment, a chemical, in a bacterium represents a novel departure from typical biotechnological approaches. Their approach intimately connected the production of the pigment with the survival of the bacterium that made it. “We needed a whole new approach to address this problem,” said Leah Bushin, lead author of the study, now a faculty member at Stanford University and formerly a postdoctoral researcher in the Moore Lab at Scripps Oceanography, where her work was conducted. “Essentially, we came up with a way to trick the bacteria into making more of the material that we needed.” Typically, when researchers try to get a microbe to produce a foreign compound, it creates a major metabolic burden. Without significant genetic manipulation, the microbe resists diverting its essential resources to produce something unfamiliar.
First seen: 2025-11-14 13:51
Last seen: 2025-11-14 19:52