Scientists study mussels to make a super strong adhesive
Mussels are nature’s Gorilla Glue. These tasty shellfish, found in both fresh and saltwater, anchor themselves to rocks using sticky threads of liquid protein. The key ingredients of this quick-setting natural cement are called mussel adhesive proteins, or MAPs for short.
For years, scientists have been investigating MAPs to make their own synthetic glues inspired by mussel adhesives. Artificially emulating millions of years of evolution in the lab has proven challenging. But Northwestern University researchers have now found a way to bypass nature’s R D by recreating not MAPs themselves but rearranging their chemical structure. New materials built from these structures exhibit the same kind of tough adhesion as the MAPs themselves, but are much, much easier to derive.
The Northwestern team shows how it created its new synthetic adhesive by hitting on a breakthrough involving something called tandem repeat proteins (TRPs)—long chains of amino acids that repeat over and over again that help build larger proteins like MAPs.
Typically, the structure and function of a protein are determined by its amino acid chain. Chemical interactions influence how the chain folds itself, like how the notches in a Lego dictate the other pieces it can connect with and what shapes it can make.
Northwestern biochemist and study co-author Nathan Gianneschi said the eureka moment came when his team decided to think outside the box: What if instead of replicating a large protein, he and his colleagues isolated its TRPs—the chemical component responsible for adhesive properties—linked them together into a manageable single-file chain, and molded their shape into the final protein they desired?
“Proteins arrange amino acids as chains, but instead, we took them and arranged them in parallel, on a dense synthetic polymer backbone,” Gianneschi said. “The same platform technology that will be used for future therapeutics has really become potentially interesting in materials science.”
The final result is a structure with a synthetic backbone and sticky TRPs attached along the sides—akin to a molecular cleaning brush. The researchers tested the strength of this new synthetic glue against native MAPs, applying a single layer to multiple glass plates, applying a layer of cells from three different cell lines onto the plates, and then washing them.
“We only meant to mimic the mussel’s properties, but when we went and tested several times, we actually got better properties than the native material in these settings.”
There is still much about this new compound yet to be discovered, like how it would work under high temperatures or in environments where the pH can range widely, which could influence its effectiveness as a potential underwater adhesive. Gianneschi’s group plans to continue studying their new material to see how it fares under different conditions and is eager to see its future use in the biomedical field.
“One of the areas of real interest where we know that it functions is, for example, in the kinds of amino acids that are generally present and known to stick to biological tissues,” Gianneschi said. “One of the thoughts is that maybe you could use [this synthetic glue] to stick molecules to tissue or stick them to signs of injury to deliver antibiotics.”
Sources:
- https://youtu.be/wxnK-KQesHI
- https://news.northwestern.edu/stories/2022/03/mussels-synthetic-glue/
- https://www.thedailybeast.com/mussel-proteins-inspired-this-new-synthetic-glue
- https://readloud.net/
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