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Bertozzi is the director of Berkeley Lab�s Molecular Foundry, a
faculty scientist with Berkeley Lab�s Materials Sciences and Physical
Biosciences Divisions, the T.Z. and Irmgard Chu Distinguished
Professor of Chemistry, and a professor of Molecular and Cell Biology
at UC Berkeley. She is also an investigator with the Howard Hughes
Medical Institute (HHMI), and a leading authority on glycobiology.
�We are already using our copper-free click chemistry technique to
probe glycan dynamics in living cells and in live zebrafish embryos,
which serve as a standard model of developmental biology,� she said.
Bertozzi is the lead author on a paper published in the Proceedings of
the National Academy of Sciences (PNAS) entitled: �Copper-free Click
Chemistry for Dynamic In Vivo Imaging.� Co-authoring this PNAS paper
were Jeremy Baskin, Jennifer Prescher, Scott Laughlin, Nicholas Agard,
Pamela Chang, Isaac Miller, Anderson Lo and Julian Codelli.
Click chemistry is the popular term for a copper-catalyzed
azide-alkyne reaction that makes it possible for certain chemical
building blocks to �click� together in an irreversible linkage. Since
its introduction in 2001 by the Nobel laureate chemist Karl Barry
Sharpless of the Scripps Research Institute, the copper-catalyzed
azide-alkyne reaction has proven extremely valuable for attaching
small molecular probes to various biomolecules in a test tube or on
fixed cells. However, its use for biomolecule labeling in live cells
or organisms is prohibited by the requirement of a cyotoxic copper
catalyst.
For the past several years, Bertozzi has been developing new
techniques for studying glycans. Even though glycans are ubiquitous on
the surfaces of most cells and play a critical role in intercellular
communications, methods for studying them have lagged behind other
biomolecules.
�Glycans mediate a variety of cell surface recognition events such as
bacterial and viral binding to host cells and leukocyte adhesion
during an inflammatory response,� said Bertozzi. �In addition to their
cell surface roles, glycans can regulate many intracellular processes,
including trafficking of proteins to the lysosome and transcription
and translation.�
There is great scientific interest in monitoring the dynamics of
glycans as they move about within cells and on the cell surface, but
the means to tag glycans with imaging probes has been lacking, thereby
prohibiting such studies. Bertozzi and her coworkers had previously
shown that glycans can be metabolically labeled with azides,
permitting their chemical tagging with imaging probes through click
chemistry, but the cytotoxicity of the click reaction would not allow
dynamic imaging of live cells.
To apply click chemistry to glycans, Bertozzi and her colleagues
designed a new reagent called difluorinated cyclooctyne or DIFO, that
reacts with azides rapidly at physiological temperatures without the
need for a toxic catalyst.
�Our critical reagent, a substituted cyclooctyne, possesses ring
strain and electron-withdrawing fluorine substituents that together
promote the cycloaddition with azides installed metabolically into
biomolecules,� said Bertozzi. �This copper-free click reaction of
azides and DIFO combines the biocompatibility of the Staudinger
ligation [a highly successful labeling reaction previously developed
in Bertozzi�s lab] with the fast reaction kinetics of click chemistry.�
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These time-lapse images of a
single cell over a one hour period were recorded using the
copper-free click chemistry reaction of azides and DIFO developed
by Bertozzi, et. al. The arrow points to the azide probe. |
Bertozzi says their copper-free click chemistry technique can be used
to probe any biomolecule that can be labeled with an azide, including
glycans, proteins and lipids. She and her group are now using this
technique to study glycan trafficking � how glycans and their
associated scaffolds move around inside cells and on cell surfaces.
They have made their DIFO reagents available to other research groups
and are in discussions with potential commercial suppliers to make the
reagents widely available to the bio research community.
�Direct imaging of glycan trafficking under conditions of cell
stimulation or pharmacological intervention can be performed in cells,
tissues, or even whole organisms,� said Bertozzi. �More broadly, other
metabolites, post-translational modifications, enzyme activities, and
site-specific labeled proteins can be monitored in real time and in
living systems with our copper-free click chemistry.�
This work was supported by a grant from the National Institutes of
Health. Jeremy Baskin was supported by a National Defense Science and
Engineering Graduate Fellowship. Baskin and Pamela Chang were
supported by National Science Foundation Predoctoral Fellowships.
Jennifer Prescher was supported by a Howard Hughes Medical Institute
Predoctoral Fellowship.
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