Researchers, led by chemistry professor
Wilfred Van Der Donk and biochemistry professor Satish K. Nair, at the University
of Illinois at Urbana-Champaign have made a breakthrough discovery in
understanding how a powerful antibiotic agent is made in nature. The research serves
as a breakthrough solving several decades old mystery that opens up new avenues
of research for thousands of other molecules most of which are expected to be useful
medically.
The research team focused on
numerous compounds including those with antibiotic properties. One compound in
particular of note was Nisin. Nisin is a natural product found in milk that is
used to combat food borne pathogens. Researchers have long been able to
understand and assemble the sequence of the nisin gene; however, after it is
made the peptide undergoes several modifications which lead to the peptides
final formation. Several decades of research have been spent trying to
understand how these changes occur.
Peptides are extremely flexible
so in order for them to do their jobs enzymes are put in to make the peptide
cyclical. In nisin, a dehydratase removes water which helps give the antibiotic
the final desired three-dimensional shape which is the first step in converting
the peptide into a five ringed structure. The rings are essential to nisin’s
antibiotic function because of their dual action. Specifically, two of the
rings disrupt the construction of bacterial cell walls while the other three
rings punch holes in the bacterial membrane. The dual action of Nisin makes it
much more difficult for microbes to evolve resistance to the antibiotic.
Previous studies have showed
that the dehydratase enzyme was involved in the modifications of the Nisin
structure. However, no study before this was able to show how the dehydratase
made these modifications. Without this understanding it has not been possible
to discover and understand similar compounds that may also be useful in fighting
food-borne diseases and/or dangerous microbial infections.
The team’s research discovered
that that the amino acid glutamate was essential to nisin's transformation.
Professor Nair stated, “They discovered that the dehydratase did two things. One
is that it added glutamate (to the nisin peptide), and the second thing it did
was it eliminated glutamate. But how does one enzyme have two different
activities?”
Through X-ray crystallography
the team discovered that the dehydratase interacts with the peptide in two
different ways: one part of the enzyme grasps the peptide while a separate part
helps install the ring structures. The other important discovery the team made
was that t-RNA supplies the glutamate which allows the dehydratase to help
shape nisin into its final structure.
This research is very important
because it signals a breakthrough in an area that for decades has not been
understood. I think the discoveries from this research will be the first step
in helping other labs make new discoveries that were not possible before.
Additionally, this research will lead to fighting both food-borne diseases and dangerous
microbial infections more effectively.
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