Rice Lab Grows Macroscale, Modular Materials from Bacteria


HOUSTON, TX – Engineered living materials promise to support human health, energy and environmental cleanup efforts. Now they can be built large and customized with less effort.

Life scientists and synthetic biologists at Rice University have introduced inch-sized, slimy colonies of man-made bacteria that self-assemble from the bottom up. It can be programmed to suck up pollutants from the environment or catalyze biological reactions, among many potential uses.

The creation of autonomously engineered living materials — or ELMs — was a long-time goal of life scientist Caroline Ajo-Franklin before she joined Rice in 2019 on a grant from the Cancer Prevention and Research Institute of Texas (CPRIT).

“We make material from bacteria that acts like putty,” said Ajo-Franklin. “One of the nice things about it is how easy it is to prepare, it just takes a little exercise, some nutrients and some bacteria.”

A study published inside this week nature communication describes the creation of flexible, adaptable ELMs by the laboratory Caulobacter crescentus as a biological building block. While the bacteria themselves can easily be genetically modified for various processes, designing them to self-assemble has been a long and complicated process.

It involved manipulating the bacteria to represent and secrete the biopolymer matrix that gives the material its shape. C. Crescentus already expresses a protein that covers its outer membrane like scales on a snake. The researchers modified the bacteria to express a version of this protein, which they call BUD (for bottom-up New, as from scratch), with properties that are not only favorable for the formation of ELMs (referred to as BUD-ELMs), but also provide tags for future functionalization.

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“We wanted to prove that it’s possible to grow materials from cells, like a tree grows from a seed,” said the study’s lead author Sara Molinari, a postdoctoral researcher in Ajo-Franklin’s lab who works in Rice’s Systems, Synthetic and Physical Biology PhD program. “The transformative aspect of ELMs is that they contain living cells that allow the material to self-assemble and repair in the event of damage. In addition, they can be further developed to perform non-native functions such as B. the dynamic processing of external stimuli.”

Molinari, who earned her PhD in Rice bioscientist Matthew Bennett’s lab, said BUD-ELM is the most adaptable example of an autonomously formed, macroscopic ELM. “It shows a unique combination of high performance and sustainability,” she said. “Thanks to its modular nature, it could serve as a platform to create many different materials.”

According to the researchers, ELMs grow in a bottle in about 24 hours. First, a thin skin forms at the air-water interface, impregnating the material. Constant shaking of the flask promotes growth of the ELM. Once it expands to a sufficient size, the material sinks to the bottom and stops growing.

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“We found that the shaking process affects how large the material we get gets,” said co-author Robert Tesoriero Jr., a graduate student in systems biology, synthetic and physical biology. “Part of what we’re looking for is the optimal choice of materials that we can get in a piston that’s about 250 millimeters. It is currently about the size of a fingernail.”

“Getting down to the centimeter scale with a sub-micron cell means they organize together over four orders of magnitude, about 10,000 times larger than a single cell,” Molinari added.

Their functional materials are robust enough to survive in a jar on the shelf for three weeks at room temperature, which means they can be transported without refrigeration.

The lab proved that the BUD-ELM could successfully remove cadmium from a solution and perform biological catalysis by enzymatically reducing an electron carrier to oxidize glucose.

Since BUD-ELMs carry tags for attachment, Ajo-Franklin says it should be relatively easy to modify them for optical, electrical, mechanical, thermal, transport, and catalytic applications.

“There’s a lot of room to play around, which I think is the fun part,” Tesoriero said.

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“The other big question is that we love Caulobacter crescentus, it’s not the most popular kid in the neighborhood,” said Ajo-Franklin. “Most people have never heard of it. So we’re really interested in knowing if these rules that we discovered are in there Kaulobacter can be applied to other bacteria.”

She said ELMs could be particularly useful for environmental remediation in resource-poor settings. C. Crescentus is ideal for this as it requires fewer nutrients to grow than many bacteria.

“One of my dreams is to use the material to remove heavy metals from water and then when it reaches the end of its life, to subtract a small portion and grow it in place into fresh material,” he said Ajo Franklin. “That we could do it with minimal resources is really a compelling idea to me.”

The work is co-authored by graduate student Swetha Sridhar, postdoctoral fellow Rong Cai and lab supervisor Jayashree Soman from Rice, Kathleen Ryan from the University of California, Berkeley, and Dong Li and Paul Ashby from Lawrence Berkeley National Laboratory, Berkeley, California. Ajo-Franklin is Professor of Biological Sciences and CPRIT Fellow in Cancer Research.

– This press release was originally published on the Rice University website



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