Conspectus
Redox-active ligands in coordination
chemistry not only modulate
the reactivity of the bound metal center but also serve as electron
reservoirs to store redox equivalents. Among many applications in
contemporary chemistry, the scope of redox-active ligands in biology
is exemplified by the porphyrin radicals in the catalytic cycles of
multiple heme enzymes (e.g., cytochrome P450, catalase) and the chlorophyll
radicals in photosynthetic systems. This Account reviews the discovery
of two redox-active ligands inspired by oligopyrrolic fragments found
in biological settings as products of heme metabolism.
Linear
oligopyrroles, in which pyrrole heterocycles are linked
by methylene or methine bridges, are ubiquitous in nature as part
of the complex, multistep biosynthesis and degradation of hemes and
chlorophylls. Bile pigments, such as biliverdin and bilirubin, are
common and well-studied tetrapyrroles with characteristic pyrrolin-2-one
rings at both terminal positions. The coordination chemistry of these
open-chain pigments is less developed than that of porphyrins and
other macrocyclic oligopyrroles; nevertheless, complexes of biliverdin
and its synthetic analogs have been reported, along with fluorescent
zinc complexes of phytobilins employed as bioanalytical tools. Notably,
linear conjugated tetrapyrroles inherit from porphyrins the ability
to stabilize unpaired electrons within their π system. The isolated
complexes, however, present helical structures and generally limited
stability.
Smaller biopyrrins, which feature
three or two
pyrrole rings and the characteristic oxidized termini, have been known
for several decades following their initial isolation as urinary pigments
and heme metabolites. Although their coordination chemistry has remained
largely unexplored, these compounds are structurally similar to the
well-established tripyrrin and dipyrrin ligands employed in a broad
variety of metal complexes. In this context, our study of the coordination
chemistry of tripyrrin-1,14-dione and dipyrrin-1,9-dione was motivated by the potential to retain on these compact, versatile
platforms the reversible ligand-based redox chemistry of larger tetrapyrrolic
systems.
The tripyrrindione ligand coordinates several divalent
transition
metals (i.e., Pd(II), Ni(II) Cu(II), Zn(II)) to form neutral complexes
in which an unpaired electron is delocalized over the conjugated π
system. These compounds, which are stable at room temperature and
exposed to air, undergo reversible one-electron processes to access
different redox states of the ligand system without affecting the
oxidation state and coordination geometry of the metal center. We
also characterized ligand-based radicals on the dipyrrindione platform
in both homoleptic and heteroleptic complexes. In addition, this study
documented noncovalent interactions (e.g., interligand hydrogen bonds
with the pyrrolinone carbonyls, π-stacking of ligand-centered
radicals) as important aspects of this coordination chemistry. Furthermore,
the fluorescence of the zinc-bound ...
