Metals in enzyme catalysis and visualization methods

Metal ions play essential roles in biological functions including catalysis, protein stability, DNA-protein interactions and cell signaling. It is estimated that 30% of proteins utilize metals in some fashion. Additionally, methods by which metal ions can be visualized have been utilized to study metal concentrations and localizations in relation to disease. Understanding the roles metals play in biological systems has great potential in medicine and technology. Chapters 1 and 2 of this dissertation analyzes the structure and function of the Mn-dependent enzyme oxalate decarboxylase (OxDc) and Chapter 2 presents a bioinformatic analysis of the cupin superfamily that provides the structural scaffold of the decarboxylase. The X-ray crystal structure of the W132F variant was determined and utilized together with EPR data to develop a computational approach to determining EPR spectra of the enzyme’s two metal-binding centers. Furthermore, a variant in which the catalytic Glu162 was deleted revealed the binding mode of oxalate, the first substrate-bound structure of OxDc. OxDc is a member of the cupin superfamily, which comprises a wide variety of proteins and enzymes with great sequence and functional diversity. A bioinformatics analysis of the superfamily was performed to analyze how sequence variation determines function and metal utilization. Chapters 3 and 4 discuss the expansion of lanthanide-binding tags (LBTs) to in cellulo studies. Lanthanide-binding tags are short sequences of amino acids that have high affinity and selectivity for lanthanide ions. An EGF-LBT construct used to quantify EGF receptors on the surface of A431 and HeLa cells. The results from the LBT quantification are consistent with previous studies of EGFR receptors in these cell types, validating the use of this method for future studies. The potential of using LBTs for X-ray fluorescence microscopy (XFM) was also investigated. LBT-labeled constructs were utilized to investigate if membrane bound as well as cytosolic LBT-containing proteins could be visualized and localized to their cell compartments via XFM; both membrane-localized and cytosolic proteins were successfully visualized. With the high resolution (< 150 Å) obtainable with new synchrotron beamline configurations LBTs could be used to study nanoscale biological structures in their near-native state

Assigning the EPR fine structure parameters of the Mn(II) centers in bacillus subtilis oxalate decarboxylase by site-directed mutagenesis and DFT/MM calculations

Oxalate decarboxylase (OxDC) catalyzes the Mn-dependent conversion of the oxalate monoanion into CO2 and formate. EPR-based strategies for investigating the catalytic mechanism of decarboxylation are complicated by the difficulty of assigning the signals associated with the two Mn(II) centers located in the N- and C-terminal cupin domains of the enzyme. We now report a mutational strategy that has established the assignment of EPR fine structure parameters to each of these Mn(II) centers at pH 8.5. These experimental findings are also used to assess the performance of a multistep strategy for calculating the zero-field splitting parameters of protein-bound Mn(II) ions. Despite the known sensitivity of calculated D and E values to the computational approach, we demonstrate that good estimates of these parameters can be obtained using cluster models taken from carefully optimized DFT/MM structures. Overall, our results provide new insights into the strengths and limitations of theoretical methods for understanding electronic properties of protein-bound Mn(II) ions, thereby setting the stage for future EPR studies on the electronic properties of the Mn(II) centers in OxDC and site-specific variants

Substrate Binding Mode and Molecular Basis of a Specificity Switch in Oxalate Decarboxylase

Oxalate decarboxylase (OxDC) catalyzes the conversion of oxalate into formate and carbon dioxide in a remarkable reaction that requires manganese and dioxygen. Previous studies have shown that replacing an active-site loop segment Ser(161)-Glu(162)-Asn(163)-Ser(164) in the N-terminal domain of OxDC with the cognate residues Asp(161)-Ala(162)-Ser-(163)-Asn(164) of an evolutionarily related, Mn-dependent oxalate oxidase gives a chimeric variant (DASN) that exhibits significantly increased oxidase activity. The mechanistic basis for this change in activity has now been investigated using membrane inlet mass spectrometry (MIMS) and isotope effect (IE) measurements. Quantitative analysis of the reaction stoichiometry as a function of oxalate concentration, as determined by MIMS, suggests that the increased oxidase activity of the DASN OxDC variant is associated with only a small fraction of the enzyme molecules in solution. In addition, IE measurements show that C-C bond cleavage in the DASN OxDC variant proceeds via the same mechanism as in the wild-type enzyme, even though the Glu(162) side chain is absent. Thus, replacement of the loop residues does not modulate the chemistry of the enzyme-bound Mn(II) ion. Taken together, these results raise the possibility that the observed oxidase activity of the DASN OxDC variant arises from an increased level of access of the solvent to the active site during catalysis, implying that the functional role of Glu(162) is to control loop conformation. A 2.6 Å resolution X-ray crystal structure of a complex between oxalate and the Co(II)-substituted ΔE162 OxDC variant, in which Glu(162) has been deleted from the active site loop, reveals the likely mode by which the substrate coordinates the catalytically active Mn ion prior to C-C bond cleavage. The "end-on" conformation of oxalate observed in the structure is consistent with the previously published V/K IE data and provides an empty coordination site for the dioxygen ligand that is thought to mediate the formation of Mn(III) for catalysis upon substrate binding