The broad purpose of the research in this proposal is to understand how microenvironments (secondary coordination spheres) about metal ions control function. A bio-inspired synthetic approach is utilized that incorporates principles of molecular architecture found in the active sites of metalloproteins into synthetic systems. Multidentate ligands will be developed that create rigid organic structures around metal ions and place hydrogen bond donors or acceptors proximal to the metal centers, forming specific microenvironments. One distinguishing attribute of these systems is the ability to make site-specific modifications to the structure in order to evaluate correlations between the microenvironment and reactivity. A focus of this research is the examination of transient intermediates that are formed from the activation of dioxygen and the oxidation of water - processes that are directly linked to the maintenance of human health and aging. Long-term goals include developing structure-function relationships in metal- assisted oxidative catalysis. Metalloproteins perform functions not yet achieved in synthetic systems. Our hypothesis is that the lack of control of the secondary coordination sphere in synthetic compounds is a major obstacle in establishing the desired functions. Results from structural biology show that hydrogen bonds within the secondary coordination spheres of metalloproteins are instrumental in regulating function. Therefore, the function and dysfunction of health-related metalloproteins can be understood in the context of changes in their microenvironments. However, it is still unclear, even in biomolecules, how non-covalent interactions influence metal-mediated processes. Investigations into these effects require fundamental reactivity and mechanistic studies in which the contributions of single components can be analyzed individually. We have developed synthetic hydrogen bonding systems in which the molecular components that define the structure around the metal ion are specifically controlled; in turn, this permits the formation of systems whose activity can be tailored to a particular function. This ability to regulate the microenvironment allows for systematic studies into structure-function relationships that lead to fundamental understanding of chemical processes. Ultimately, this research will provide insights into the properties of biological catalysts and lead to new classes of synthetic catalysts that exhibit the exquisite control over reactivity that is characteristic of metalloenzymes.

Public Health Relevance

Dioxygen binding and activation by metalloproteins are processes that are directly linked to the maintenance of human health and aging. The protein-induced microenvironments surrounding the active metal center(s) are instrumental in regulating these functions, and the function and dysfunction of health-related metalloproteins can therefore be understood in the context of changes in their microenvironments. Non-covalent interactions, including hydrogen bonds, are acknowledged as the major forces that control microenvironmental effects, but it is still unclear how they are able to influence metal-mediated processes. Thus, understanding the influence of these effects requires fundamental reactivity and mechanistic studies in which the contributions of single components can be analyzed individually, as described in this research.

Agency
National Institute of Health (NIH)
Institute
National Institute of General Medical Sciences (NIGMS)
Type
Method to Extend Research in Time (MERIT) Award (R37)
Project #
5R37GM050781-26
Application #
9402081
Study Section
Macromolecular Structure and Function A Study Section (MSFA)
Program Officer
Anderson, Vernon
Project Start
1994-04-01
Project End
2020-12-31
Budget Start
2018-01-01
Budget End
2018-12-31
Support Year
26
Fiscal Year
2018
Total Cost
Indirect Cost
Name
University of California Irvine
Department
Chemistry
Type
Schools of Arts and Sciences
DUNS #
046705849
City
Irvine
State
CA
Country
United States
Zip Code
92617
Weitz, Andrew C; Hill, Ethan A; Oswald, Victoria F et al. (2018) Probing Hydrogen Bonding Interactions to Iron-Oxido/Hydroxido Units by 57 Fe Nuclear Resonance Vibrational Spectroscopy. Angew Chem Int Ed Engl 57:16010-16014
Lau, Nathanael; Sano, Yohei; Ziller, Joseph W et al. (2018) Modular bimetallic complexes with a sulfonamido-based ligand. Dalton Trans 47:12362-12372
Oswald, Victoria F; Weitz, Andrew C; Biswas, Saborni et al. (2018) Manganese-Hydroxido Complexes Supported by a Urea/Phosphinic Amide Tripodal Ligand. Inorg Chem 57:13341-13350
Mann, Samuel I; Heinisch, Tillmann; Ward, Thomas R et al. (2018) Coordination chemistry within a protein host: regulation of the secondary coordination sphere. Chem Commun (Camb) 54:4413-4416
Cook, Sarah A; Bogart, Justin A; Levi, Noam et al. (2018) Mononuclear complexes of a tridentate redox-active ligand with sulfonamido groups: structure, properties, and reactivity. Chem Sci 9:6540-6547
Kubin, Markus; Kern, Jan; Gul, Sheraz et al. (2017) Soft x-ray absorption spectroscopy of metalloproteins and high-valent metal-complexes at room temperature using free-electron lasers. Struct Dyn 4:054307
Lau, Nathanael; Sano, Yohei; Ziller, Joseph W et al. (2017) Terminal NiII-OH/-OH2 complexes in trigonal bipyramidal geometries derived from H2O. Polyhedron 125:179-185
Sano, Yohei; Lau, Nathanael; Weitz, Andrew C et al. (2017) Models for Unsymmetrical Active Sites in Metalloproteins: Structural, Redox, and Magnetic Properties of Bimetallic Complexes with MII-(?-OH)-FeIII Cores. Inorg Chem 56:14118-14128
Jones, Jason R; Ziller, Joseph W; Borovik, A S (2017) Modulating the Primary and Secondary Coordination Spheres within a Series of CoII-OH Complexes. Inorg Chem 56:1112-1120
Mallin, Hendrik; Hestericová, Martina; Reuter, Raphael et al. (2016) Library design and screening protocol for artificial metalloenzymes based on the biotin-streptavidin technology. Nat Protoc 11:835-52

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