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Minitransposons developed at Rice University have the ability to create "circularly permuted" proteins by joining the "N" terminus and "C" terminus of proteins and creating new terminals in other locations along the amino acid strands. Image: Silberg Laboratory/Rice University |
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A Rice University undergraduate will depart
with not only a degree but also a possible patent for his invention of an
efficient way to create protein libraries, an important component of
biomolecular research.
Rice senior Manan Mehta discovered a method to create libraries of
"circularly permuted" proteins at the suggestion of his mentor,
bioengineer Jonathan Silberg. The research was reported in Nucleic Acids Research.
In a process Manan calls "permutation using transposase
engineering" (PERMUTE for short), he created variations of a protein, in
this case, adenylate kinase, that have their amino acids rearranged. The
library of mutant proteins was then mined for variants that retained the
ability to function by introducing them into Escherichia coli bacteria.
Libraries are particularly useful for scientists who study the rules
governing the adaptation of proteins during molecular evolution; they also are
useful for designing biosensors and molecular switches with novel functions for
synthetic biology, according to the authors.
Creating such a library has traditionally required painstaking processes,
said Silberg, an assistant professor of biochemistry and cell biology at Rice.
"Existing methods for rearranging the bits of information in a protein
are slow and arduous to use," he said. "In addition, they are
non-ideal because they simultaneously create multiple types of mutations, the
desired rearrangements and undesired deletions of important amino acids.
"But with our method, you only generate mutants with rearranged
sequences, and you don't need to be an expert in biomolecular engineering. All
you need is the DNA that encodes your gene of interest, the artificial
minitransposon we engineered and an enzyme. Mix them all together and you get a
library of every possible variant.
"It's a way of making, with great control, all of the diversity of this
type of mutation that could exist in a protein."
Proteins, strings of amino acids that regulate biological processes, are
created in cells. They have a beginning—the "N" terminus—and an end—the
"C" terminus. "The 'N' comes off the ribosome first and builds
up from there," Silberg said. "Then the proteins fold, like a ball of
string. We connect the two ends of the string and break it elsewhere."
"There's already an enzyme that does most of the work for you,"
Mehta said. "It's called a transposase, and it inserts the transposon. The
hard part is making the transposon itself, which is really just a big piece of
DNA."
Since beginning the project last spring, Mehta has spent half his time in
Silberg's laboratory modeling his minitransposon at the computer and half implementing
his ideas on the bench. The long process of creating the minitransposon
involved building his designed DNA and debugging it so that it functioned as
intended.
"We ended up with 15 unique variants of permuted adenylate kinase after
sequencing 220 or so, about half of which were active and half not. It's quite
an ordeal," he said, citing the patient assistance of co-author Shirley
Liu, a research technician in Silberg's laboratory.
"The synopsis is, it's a new way of mutating protein in a controlled way,"
Silberg said. "I want to make it simple. It's clear when you make the
libraries that there's going to be useful diversity in there, but we're not
smart enough to know which mutations to make—so we still need to make the
libraries. Making a better library makes it more likely that we'll find what we
want."
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