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Topic Name: A New Fluorescent Probe for Protein Interactions
Category: Polymer Interfaces and Macromolecular Assemblies
Research persons: Haishi Cao, Yijia Xiong, Ting Wang, Baowei Chen, Thomas Squier, and M. Uljana Mayer
Location: 902 Battelle Boulevard, Richland, WA 99352, United States
Details
Scientists at Pacific Northwest National Laboratory (PNNL) have created a new
red fluorescent probe to label proteins and quantitatively monitor their
interactions in living cells. This probe adds to a toolkit of biarsenical dyes
developed into multiuse affinity probes (MAPs) at PNNL to study macromolecular
machines and protein networks.
The research, published in the Journal of the American Chemistry
Society, appears as a research highlight in the July 5 issue of
Nature.
Methods: The PNNL team, led by biochemist
M. Uljana Mayer,
made a new fluorescent affinity probe, AsCy3, targeted to a small tag that can
be engineered onto a protein of interest. This new probe can then be used in
conjunction with the first-generation probe, called FlAsH, to study
macromolecular machines and protein networks. The small tags are especially
useful because, for example, proteins that need to be exported across the inner
membrane of bacteria cannot be engineered to contain large tags such as
fluorescent proteins.
This new probe is in a class of small-molecule compounds called biarsenical
MAPs. The researchers derivatized Cy3, a fluorescent dye that has good
photostability and quantum yield, low pH sensitivity and high absorbance.
Quantum yield measures the efficiency with which absorbed light produces
effects. "Biarsenical" refers to the two arsenics used in the derivatization
because of their ability to bind to cysteines-sulfur—containing amino acids.
AsCy3 is directed specifically to a peptide containing four cysteines,
Cy3TAG, in the presence of other tetracysteine tags. The new probe is a partner
to the previously developed green MAP. This discovery is an important step
toward a whole toolkit of colored probes directed to different small
peptides—strings of amino acids, which form specific structural elements.
Why it matters: Small-molecule biarsenical MAPs, in
conjunction with complementary protein tags, are important new tools for
analyzing cellular function through live-cell imaging, targeted protein
inactivations, and the measurement of protein dynamics and binding. In addition,
MAPs serve as affinity reagents for isolating intact protein complexes for
complementary structural measurements.
The work is part of a long-term goal to develop the necessary reagents and
technology to rapidly identify a substantial fraction of the multi-protein
complexes in an organism. This will lead to a systems-level understanding of
microbial pathways. Knowledge of real-time changes in enzyme interactions will
permit the reengineering of microbial pathways for improved biofuel production,
mitigation of climate change, and for bioremediation. Critical to this goal is
the development of new affinity reagents and protein tags that permit the rapid
identification and validation of protein complexes.
What's next: There is increased demand for cell-permeable
fluorescent dyes that can bind to relatively small tags and do not hinder
protein export. The PNNL team has expanded the
biarsenical toolkit and is working toward developing a whole color palette of
targetable probes for studying protein-protein interaction networks. Such
studies can be applied to environmental remediation, national security, and
energy problems.
Researcher Team Members Acknowledgments: Team members are
Haishi Cao, Yijia Xiong, Ting Wang, Baowei Chen, Thomas Squier, and M. Uljana
Mayer, all at PNNL. This research was supported by the Genomics: GTL program of
the U.S. Department of Energy's Office of Biological and Environmental Research.
Some of the work was conducted in the
Environmental Molecular Sciences Laboratory, a DOE national scientific user
facility located at PNNL.
Contact Details
Mailing address:
P.O. Box 999
Richland, WA 99352
Street address:
902 Battelle Boulevard
Richland, WA
References
Cao H, Y Xiong, T Wang, B Chen, TC Squier, and MU Mayer. 2007. "A red
Cy3-based biarsenical fluorescent probe targeted to a complementary binding
peptide." Journal of the American Chemical Society 129(28):8672
-8673.
Cao H, B Chen, TC Squier, and MU Mayer. 2006. "CrAsH: A Biarsenical Multi-use
Affinity Probe with low non-specific fluorescence." Chemical
Communications (24):2601-2603.
Mayer MU, L Shi, and TC Squier. 2005. "One-step, non-denaturing isolation of
an RNA polymerase enzyme complex using an improved multi-use affinity probe
resin." Molecular Biosystems 1(1):53-56.
Learn more by scientists in PNNL's
Biological Sciences Division.
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