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Oxygen activation by non-heme iron complexes and proteins
OXYGEN
DO12 OXYGEN COMPLEXES
ACTIVATION BY AND PROTEINS
NON-HEME
279
IRON
Stephen J. Lippard Department of Chemistry, Massachusetts Insfitute of Technology, Cambridge, MA, 02139, USA. A dinuclear iron center bridged by at least one protein derived carboxylate ligand comprises the functional core of hemerythrin, the R2 protein of ribonucleotide reductase, and the hydroxylase of methane monooxygenase (MMO). A comprehensive study of the structure, physical properties, and reaction chemistry of the MM0 hydroxylase has been carried out. In addition, we have prepared model complexes for the diiron cores in the diiron carboxylate proteins and have investigated their physical and chemical properties. Results to be discussed include stopped flow kinetics results for the reaction of the reduced hydroxylase with dioxygen in the presence and absence ofits natural partner proteins; ENDOR experiments that establish a bridging hydroxide ligand for the mixed valence form of the hydroxylase; progress on the crystal structure determination of the hydroxylase protein; radical clock experiments
that address mechanistic questions concerning the
hydroxylation characterization
reaction
mechanism;
the
synthesis
and
of a bioinorganic chip for kinetically stabilized
diiron carboxylate-bridged
cores; preparation of a Qt.-oxo)diiron
complex having pendant phenoxyl radical ligands as a model for the R2 protein core; and kinetics and mechanistic investigations of the reaction of dioxygen with a variety of diiron(II) model complexes. Many co-workers
and collaborators
have contributed
to these
investigations, which were supported by a grant from the National Institute of General Medical Sciences.
DO12 OXYGEN COMPLEXES
ACTIVATION BY AND PROTEINS
NON-HEME
279
IRON
Stephen J. Lippard Department of Chemistry, Massachusetts Insfitute of Technology, Cambridge, MA, 02139, USA. A dinuclear iron center bridged by at least one protein derived carboxylate ligand comprises the functional core of hemerythrin, the R2 protein of ribonucleotide reductase, and the hydroxylase of methane monooxygenase (MMO). A comprehensive study of the structure, physical properties, and reaction chemistry of the MM0 hydroxylase has been carried out. In addition, we have prepared model complexes for the diiron cores in the diiron carboxylate proteins and have investigated their physical and chemical properties. Results to be discussed include stopped flow kinetics results for the reaction of the reduced hydroxylase with dioxygen in the presence and absence ofits natural partner proteins; ENDOR experiments that establish a bridging hydroxide ligand for the mixed valence form of the hydroxylase; progress on the crystal structure determination of the hydroxylase protein; radical clock experiments
that address mechanistic questions concerning the
hydroxylation characterization
reaction
mechanism;
the
synthesis
and
of a bioinorganic chip for kinetically stabilized
diiron carboxylate-bridged
cores; preparation of a Qt.-oxo)diiron
complex having pendant phenoxyl radical ligands as a model for the R2 protein core; and kinetics and mechanistic investigations of the reaction of dioxygen with a variety of diiron(II) model complexes. Many co-workers
and collaborators
have contributed
to these
investigations, which were supported by a grant from the National Institute of General Medical Sciences.