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June 30, 2004
Bacterial Protein Recycling Factor Possible Key to New
Class of Antibiotics
(Philadelphia,
PA) – Understanding the last step of protein synthesis – the basic
process of translating DNA into its final protein product – just became
more clear both literally and figuratively. This final phase, called recycling,
is essential for the proper function of all cells. Using a three-dimensional
cryo-electron microscope to directly observe protein structure, investigators
at the University of Pennsylvania School of Medicine and the
State University of New York, Albany can now visualize the exact configuration
of a molecule called ribosome recycling factor (RRF) in the common bacteria
Escherichia coli. (Click on thumbnail above to view full-size image).
This image – reported in the June 15 issue of the Proceedings of the
National Academy of Sciences – may help guide the design of new antibiotics
aimed at inhibiting RRF-related steps of protein synthesis.
“Every living organism has to have this last step, the recycling of spent
protein synthesis machinery for the next round of translation,” says Akira
Kaji, PhD, Professor of Microbiology at Penn. “Strangely, at
this day and age, this most fundamental process remained vague until we launched
our studies of RRF.”
Most antibiotics influencing protein synthesis act by stopping its molecular
machinery. However, none as yet target the recycling step. “We believe
RRF is one of the best candidates for a new antibiotics target because the mechanism
involved in recycling of the protein-making machinery is different in eukaryotes
versus prokaryotes, that is humans versus bacteria,” says Kaji. “With
the emergence of antibiotic-resistant pathogens, this will be the best avenue
of devising new antibiotics.”
Thirty Years of Searching
The ribosome is the structure within cells on which amino acids are strung together
to make proteins with the aid of transfer RNA (tRNA) and messenger RNA (mRNA).
Kaji has spent the past 30 years working out the last step of protein synthesis.
RRF, in conjunction with elongation factor G (EF-G), moves along the ribosome
removing mRNA and tRNA, readying it to make more proteins. In this latest chapter,
Kaji and colleagues report the three-dimensional image of RRF bound to the E.
coli ribosome.
In an earlier paper by Kaji and colleagues from Sweden, the crystal structure
of RRF showed that RRF mimics the L-shape and dimension of tRNA. Chemical probing
by Kaji and colleagues at the University of California, Santa Cruz showed the
approximate ribosomal binding site of RRF. In the current PNAS paper,
direct observation of the RRF-ribosome structure revealed the exact ribosomal
position of bound RRF. It further showed that part of the ribosome contorts
by a significant amount – molecularly speaking – when RRF binds
to it.
More precisely, the position of the key helices of the ribosomal small and large
subunits that hold mRNA move inward, suggesting that this movement may be essential
for the release of mRNA from the ribosome. In addition, the RRF binding sites
are very close to where the two ribosomal subunits are held together, which
explains an earlier observation that the disassembly reaction by RRF may be
followed by dissociation of the two subunits.
In short, the recycling process goes like this: RRF, along with EF-G, binds
to the ribosome. This promotes the release of tRNAs by the movement of RRF,
similar to tRNA movement. “This is the first example of a functional mimic
of tRNA by a protein,” adds Kaji. After the tRNAs leave, RRF, EF-G, and
mRNA also detach from the ribosome. The released ribosome is now empty and free
to start a new session of translating mRNA into protein. Where RRF binds is
near the key ribosomal spot holding mRNA. “Since the main function of
RRF is to release mRNA, this makes sense in terms of function,” explains
Kaji.
Humans have an RRF analogue in the mitochondria, the respiratory organelle within
cells. “One may argue that proposed antibiotics against RRF may influence
mitochondrial protein synthesis,” notes Kaji. However, commonly used antibiotics
such as erythromycin and tetracycline kill bacteria but are virtually harmless
to humans, showing little side effect despite their influence on mitochondrial
protein synthesis. “With rational drug design it is even possible to design
anti-RRF which would only influence bacterial RRF,” says Kaji.
His lab is currently identifying the ribosomal site to which RRF is moved from
the currently identified position. “It is from this position where RRF
performs the final and the most important act – release of mRNA,”
says Kaji. “The fourth step of protein synthesis within human cells is
shrouded in complete mystery and nothing is known. This fundamental step must
be elucidated before we can take advantage of the fact that the same step is
catalyzed by RRF in bacteria.”
Other scientists contributing to this work are: Rajendra K. Agrawal, Manjuli
R. Sharma, and Timothy M. Booth from the New York State Department of Health;
Michael C. Kiel and Go Hirokawa from Penn; and Christian M.T. Spahn, Robert
A. Grassucci, and Joachim Frank from the Howard Hughes Medical Institute. Agrawal
and Frank are also affiliated with the State University of New York, Albany.
This research was funded in part by the National Institutes of Health and the
National Science Foundation.
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Release available online at http://www.uphs.upenn.edu/news/News_Releases/june04/BacterialRRF.html