Chemists Synthesize Millions
of .
Proteins not Found in Nature
New technology could lead to development of novel
“xenoprotein” drugs against infectious diseases
By Anne Trafton | MIT News Office
Proteins not Found in Nature
New technology could lead to development of novel
“xenoprotein” drugs against infectious diseases
By Anne Trafton | MIT News Office
May 21, 2018 -- MIT chemists
have devised a way to rapidly synthesize and screen millions of novel proteins
that could be used as drugs against Ebola and other viruses.
All
proteins produced by living cells are made from the 20 amino acids that are
programmed by the genetic code. The MIT team came up with a way to assemble
proteins from amino acids not used in nature, including many that are mirror
images of natural amino acids.
These
proteins, which the researchers call “xenoproteins,” offer many advantages over
naturally occurring proteins. They are more stable, meaning that unlike most
protein drugs, they don’t require refrigeration, and may not provoke an immune
response.
“There
is no other technological platform that can be used to create these
xenoproteins because people haven’t worked through the ability to use
completely nonnatural sets of amino acids throughout the entire shape of the
molecule,” says Brad Pentelute, an MIT associate professor of chemistry and the
senior author of the paper, which appears in the Proceedings of the National Academy of Sciences the
week of May 21.
Zachary
Gates, an MIT postdoc, is the lead author of the paper. Timothy Jamison, head
of MIT’s Department of Chemistry, and members of his lab also contributed to
the paper.
Nonnatural proteins
Pentelute
and Jamison launched this project four years ago, working with the Defense
Advanced Research Projects Agency (DARPA), which asked them to come up with a
way to create molecules that mimic naturally occurring proteins but are made
from nonnatural amino acids.
“The
mission was to generate discovery platforms that allow you to chemically
manufacture large libraries of molecules that don’t exist in nature, and then
sift through those libraries for the particular function that you desired,”
Pentelute says.
For
this project, the research team built on technology that Pentelute’s lab had
previously developed for rapidly
synthesizing protein chains. His tabletop machine can perform all of
the chemical reactions needed to string together amino acids, synthesizing the
desired proteins within minutes.
As
building blocks for their xenoproteins, the researchers used 16 “mirror-image”
amino acids. Amino acids can exist in two different configurations, known as L
and D. The L and D versions of a particular amino acid have the same chemical
composition but are mirror images of each other. Cells use only L amino acids.
The
researchers then used synthetic chemistry to assemble tens of millions of
proteins, each about 30 amino acids in length, all of the D configuration.
These proteins all had a similar folded structure that is based on the shape of
a naturally occurring protein known as a trypsin inhibitor.
Before
this study, no research group had been able to create so many proteins made
purely of nonnatural amino acids.
“Significant
effort has been devoted to development of methods for the incorporation of
nonnatural amino acids into protein molecules, but these are generally limited
with regard to the number of nonnatural amino acids that can simultaneously be
incorporated into a protein molecule,” Gates says.
After
synthesizing the xenoproteins, the researchers screened them to identify
proteins that would bind to an IgG antibody against an influenza virus surface
protein. The antibodies were tagged with a fluorescent molecule and then mixed
with the xenoproteins. Using a system called fluorescence-activated cell
sorting, the researchers were able to isolate xenoproteins that bind to the
fluorescent IgG molecule.
This
screen, which can be done in only a few hours, revealed several xenoproteins
that bind to the target. In other experiments, not published in the PNAS paper, the researchers have
also identified xenoproteins that bind to anthrax toxin and to a glycoprotein
produced by the Ebola virus. This work is in collaboration with John Dye,
Spencer Stonier, and Christopher Cote at the U.S. Army Medical Research
Institute of Infectious Diseases.
“This
is an extremely important first step in finding a good way of rapidly screening
complex mirror image proteins,” says Stephen Kent, a professor of chemistry at
the University of
Chicago
Built on demand
The
researchers are now working on synthesizing proteins modeled on different
scaffold shapes, and they are searching for xenoproteins that bind to other
potential drug targets. Their long-term goal is to use this system to rapidly
synthesize and identify proteins that could be used to neutralize any type of
emerging infectious disease.
“The
hope is that we can discover molecules in a rapid manner using this platform,
and we can chemically manufacture them on demand. And after we make them, they
can be shipped all over the place without refrigeration, for use in the field,”
Pentelute says.
In
addition to potential drugs, the researchers also hope to develop “xenozymes” —
xenoproteins that can act as enzymes to catalyze novel types of chemical
reactions.
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