The unusual electronic properties and unique reactivity of fulvenes have interested researchers for over a century. The propensity to form dipolar structures at relatively low temperatures and to participate as various components in cycloaddition reactions, often highly selectively, makes them ideal for the synthesis of complex polycyclic carbon scaffolds. As a result, fulvene cycloaddition chemistry has been employed extensively for the synthesis of natural products. More recently, fulvene cycloaddition chemistry has also found application to other areas including materials chemistry and dynamic combinatorial chemistry. This highlight article discusses the unusual properties of fulvenes and their varied cycloaddition chemistry, focussing on applications in organic and natural synthesis, dynamic combinatorial chemistry and materials chemistry, including dynamers, hydrogels and charge transfer complexes. Tables providing comprehensive directories of fulvene cycloaddition chemistry are provided, including fulvene intramolecular and intermolecular cycloadditions complete with reactant partners and their resulting cyclic adducts, which provide a useful reference source for synthetic chemists working with fulvenes and complex polycyclic scaffolds.
The
applications of bioconjugation chemistry are rapidly expanding,
and the addition of new strategies to the bioconjugation and ligation
toolbox will further advance progress in this field. Herein, we present
a detailed study of the Diels–Alder cycloaddition (DAC) reaction
between pentafulvenes and maleimides in aqueous solutions and investigate
the reaction as an emerging bioconjugation strategy. The DAC reactions
were found to proceed efficiently, quantitatively yielding cycloadducts
with reaction rates ranging up to ∼0.7 M–1 s–1 for a series of maleimides, including maleimide-derivatized
peptides and proteins. The absence of cross-reactivity of the pentafulvene
with a large panel of functional (bio)molecules and biological media
further demonstrated the bioorthogonality of this approach. The utility
of the DAC reaction for bioorthogonal bioconjugation applications
was further demonstrated in the presence of biological media and proteins,
as well as through protein derivatization and labeling, which was
comparable to the widely employed sulfhydryl–maleimide coupling
chemistry.
Highly efficient, selective and cytocompatible fulvene–maleimide cycloaddition chemistry was applied for the preparation of injectable, cell encapsulating/releasing hydrogels with tuneable gelation and degradation kinetics.
Diels−Alder chemistry is a well-explored avenue for the synthesis of bioactive materials; however, its potential applications have recently expanded following the development of reactions that can be performed in buffered aqueous environments at low temperatures, including fulvene−maleimide [4 + 2] cycloadditions. In this study, we synthesized two novel amine-reactive fulvene linkers to demonstrate the application of this chemistry for generating mass spectrometry-cleavable labels ("mass tags"), which can be used for the labeling and detection of proteins. Successful conjugation of these linkers to maleimidelabeled peptides was observed at low temperatures in phosphatebuffered saline, allowing the non-destructive modification of proteins with such mass tags. The labile nature of fulvene−maleimide adducts in the gas phase also makes them suitable for both matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) mass spectrometric analysis. Unlike previous examples of MALDI mass tags, we show that fulvene−maleimide cycloaddition adducts fragment predictably upon gas-phase activation without the need for bulky photocleavable groups. Further exploration of this chemistry could therefore lead to new approaches for mass spectrometry-based bioassays.
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