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Metalloproteins tune the electronic properties of metal active sites through a combination of primary and secondary coordination sphere effects (PCS and SCS) to efficiently perform an array of redox chemistry, including electron transfer (ET) and catalysis. A major influence of these effects is the anisotropic spatial distribution of redox-active molecular orbitals (RAMOs), which in turn dictates redox chemistry of the metalloproteins. While much progress has been made in understanding the SCS effects on RAMOs in individual native metalloproteins, it has been difficult to experimentally examine the influence of the same SCS effects on RAMOs with different spatial distributions. Taking advantage of our recent studies of SCS effect on blue copper azurin from Pseudomonas aeruginosa (Blue CuAz) and its M121H/H46E variant that closely mimic the red copper protein (Red CuAz), in which their RAMOs are dominated by either Cu-S or Cu-S interactions, respectively, we herein compare and contrast how the same SCS modifications impact the electronic and geometric structures of blue and red Cu center in the same protein scaffold. Specifically, we expand our understanding of unpaired electron distribution at the Cu-binding site of Red CuAz and its SCS N47S, F114P, and F114N mutations using 1H and 14N electron-nuclear double resonance (ENDOR) spectroscopy, and then further combine these data sets with recent studies and DFT calculations to provide insight into how these mutations differentially (or similarly) impact electronic structure in Red vs. Blue CuAz. We find that electrostatics produce similar effects in both Red and Blue CuAz, where the introduction of dipole moments in the vicinity of Cu and S produce changes in spin density distribution and of the same sign and comparable magnitude. However, disruption of H-bonding with S through the F114P mutation leads to opposing effects in Red vs. Blue CuAz, which we propose arise from differences in the conformation of Cys112 sidechain adapted in the absence the stabilizing SC112•••H-N backbone interaction.
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A Binuclear Cu A Center Designed in an All α-Helical Protein Scaffold
The primary and secondary coordination spheres of metal binding sites in metalloproteins have been investigated extensively, leading to the creation of high-performing functional metalloproteins; however, the impact of the overall structure of the protein scaffold on the unique properties of metalloproteins has rarely been studied. A primary example is the binuclear CuA center, an electron transfer cupredoxin domain of photosynthetic and respiratory complexes and, recently, a protein co-regulated with particulate methane and ammonia monooxygenases. The redox potential, Cu–Cu spectroscopic features, and a valence delocalized state of CuA are difficult to reproduce in synthetic models, and every artificial protein CuA center to-date has used a modified cupredoxin. Here we present a fully functional CuA center designed in a structurally non-homologous protein, cytochrome c peroxidase (CcP), by only two mutations (CuACcP). We demonstrate with UV-visible absorption, resonance Raman, and MCD spectroscopy that CuACcP is valence delocalized. CW and pulsed (HYSCORE) X-band EPR show it has a highly compact gz area and small Az hyperfine principal value with g and A tensors that resemble axially perturbed CuA. Stopped-flow kinetics found that CuA formation proceeds through a single T2Cu intermediate. The reduction potential of CuACcP is comparable to native CuA and can transfer electrons to a physiological redox partner. We built a structural model of the designed Cu binding site from EXAFS and validated it by mutation of coordinating Cys and His residues, revealing that a triad of residues (R48C, W51C, and His52) rigidly arranged on one α-helix is responsible for chelating the first Cu atom and that His175 stabilizes the binuclear complex by rearrangement of the CcP heme-coordinating helix. This design is a demonstration that a highly conserved protein fold is not uniquely necessary to induce certain characteristic physical and chemical properties to a metal redox center.
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- PAR ID:
- 10173723
- Date Published:
- Journal Name:
- Journal of the American Chemical Society
- ISSN:
- 0002-7863
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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Accepted Manuscript1.0
- Journal Article:
- https://doi.org/10.1021/jacs.0c04226
