Engineered proteins stick like
glue — even in water
New adhesives based
on mussel proteins could be useful for naval or medical applications.
Anne Trafton | MIT News Office, September 21, 2014
Shellfish such as mussels and
barnacles secrete very sticky proteins that help them cling to rocks or ship
hulls, even underwater. Inspired by these natural adhesives, a team of MIT
engineers has designed new materials that could be used to repair ships or help
heal wounds and surgical incisions.
To create their new waterproof
adhesives, the MIT researchers engineered bacteria to produce a hybrid material
that incorporates naturally sticky mussel proteins as well as a bacterial
protein found in biofilms — slimy layers formed by bacteria growing on a
surface. When combined, these proteins form even stronger underwater adhesives
than those secreted by mussels.
This project, described in the
Sept. 21 issue of the journal Nature Nanotechnology, represents a new
type of approach that can be exploited to synthesize biological materials with
multiple components, using bacteria as tiny factories.
“The ultimate goal for us is to set
up a platform where we can start building materials that combine multiple
different functional domains together and to see if that gives us better
materials performance,” says Timothy Lu, an associate professor of biological
engineering and electrical engineering and computer science (EECS) and the
senior author of the paper.
The paper’s lead author is Chao
Zhong, a former MIT postdoc who is now at ShanghaiTech University
Complex adhesives
The sticky substance that helps
mussels attach to underwater surfaces is made of several proteins known as
mussel foot proteins. “A lot of underwater organisms need to be able to stick
to things, so they make all sorts of different types of adhesives that you
might be able to borrow from,” Lu says.
Scientists have previously
engineered E. coli bacteria to produce individual mussel foot proteins, but
these materials do not capture the complexity of the natural adhesives, Lu
says. In the new study, the MIT team wanted to engineer bacteria to produce two
different foot proteins, combined with bacterial proteins called curli fibers —
fibrous proteins that can clump together and assemble themselves into much
larger and more complex meshes.
Lu’s team engineered bacteria so
they would produce proteins consisting of curli fibers bonded to either mussel
foot protein 3 or mussel foot protein 5. After purifying these proteins from
the bacteria, the researchers let them incubate and form dense, fibrous meshes.
The resulting material has a regular yet flexible structure that binds strongly
to both dry and wet surfaces.
“The result is a powerful wet
adhesive with independently functioning adsorptive and cohesive moieties,” says
Herbert Waite, a professor of chemistry and biochemistry at the University of California
at Santa Barbara
The researchers tested the
adhesives using atomic force microscopy, a technique that probes the surface of
a sample with a tiny tip. They found that the adhesives bound strongly to tips
made of three different materials — silica, gold, and polystyrene. Adhesives
assembled from equal amounts of mussel foot protein 3 and mussel foot protein 5
formed stronger adhesives than those with a different ratio, or only one of the
two proteins on their own.
These adhesives were also stronger
than naturally occurring mussel adhesives, and they are the strongest
biologically inspired, protein-based underwater adhesives reported to date, the
researchers say.
More adhesive strength
Using this technique, the
researchers can produce only small amounts of the adhesive, so they are now
trying to improve the process and generate larger quantities. They also plan to
experiment with adding some of the other mussel foot proteins. “We’re trying to
figure out if by adding other mussel foot proteins, we can increase the
adhesive strength even more and improve the material’s robustness,” Lu says.
The team also plans to try to
create “living glues” consisting of films of bacteria that could sense damage
to a surface and then repair it by secreting an adhesive.
The research was funded by the
Office of Naval Research, the National Science Foundation, and the National
Institutes of Health.
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