A recently proposed oxidative damage protection mechanism in proteins relies on hole hopping escape routes formed by redox-active amino acids. We present a computational tool to identify the dominant charge hopping pathways through these residues based on the mean residence times of the transferring charge along these hopping pathways. The residence times are estimated by combining a kinetic model with well-known rate expressions for the charge-transfer steps in the pathways. We identify the most rapid hole hopping escape routes in cytochrome P450 monooxygenase, cytochrome c peroxidase, and benzylsuccinate synthase (BSS). This theoretical analysis supports the existence of hole hopping chains as a mechanism capable of providing hole escape from protein catalytic sites on biologically relevant timescales. Furthermore, we find that pathways involving the [4Fe4S] cluster as the terminal hole acceptor in BSS are accessible on the millisecond timescale, suggesting a potential protective role of redox-active cofactors for preventing protein oxidative damage.
Understanding molecular signaling mechanisms in cells is critically important to biology and medicine. A prominent case is the search for drug targets in cancer signaling pathways. Recently, it was proposed that charge transfer through DNA may enable signaling between iron-sulfur proteins involved in DNA repair and replication. We show that exclusive DNA mediation is energetically unfavorable and kinetically unfeasible, but redox agents might assist the protein signaling. Our analysis narrows the range of possible charge transfer-based mechanisms for intracellular signaling.
Chemo-and regio-selective catalysis of the C(sp 3 )-H halogenation reaction is a formidable goal in chemical synthesis. 2-Oxoglutarate (2OG)-dependent non-heme iron halogenases catalyze selective chlorination/bromination of C−H bonds and exhibit high sequence and structural similarities with non-heme iron hydroxylases. How the secondary coordination sphere (SCS) of these two enzyme systems differentiate and determine their reactivity is not well understood. In this work, we show that specific positioning of redox-active tyrosine residues in the SCS of non-heme iron halogenases has a huge impact on their structure, function, and reactivity. We discover that a tyrosine residue (F121Y) rationally incorporated to hydrogen bond to iron's chloride ligand in SyrB2 halogenase undergoes post-translational oxidation to dihydroxyphenylalanine (DOPA) physiologically. A combination of spectroscopic, mass-spectrometric, and biochemical studies demonstrate that DOPA modification in SyrB2 renders the enzyme non-functional. Bioinformatic analysis suggests that SyrB2-like halogenases, unlike hydroxylases, have a conserved placement of phenylalanine at position 121 to preclude such unproductive oxidation. Furthermore, molecular dynamics simulations in tandem with experimental demonstration of DOPA incorporation exclusively at position 121 enables us to uniquely identify that an axial-chloro haloferryl isomer is operant in SyrB2. We also identify conserved redox-inactive residues in the SCS of other 2OG-dependent non-heme iron halogenases to avoid DOPA-like unproductive oxidations. Overall, this study demonstrates the importance of the SCS in controlling the structure and enzymatic activity of non-heme iron halogenases and will have significant implications toward the design of small-molecule and protein-based halogenation catalysts.
The 2′-deoxy-2′-fluoro-arabinonucleic acid (2′F-ANA) can be used as a valid alternative to DNA in bioelectronic applications by reason of its similar charge conductivity combined with greater resistance to hydrolysis and nuclease degradation.
Using molecular dynamics simulations and electronic structure theory, we shed light on the charge dynamics that causes the differential interaction of tumor suppressor protein p53 with the p21 and Gadd45 genes in response to oxidative stress. We show that the sequence dependence of this selectivity results from competing charge transfer to the protein and through the DNA, with implications on the use of genome editing tools to influence the p53 regulatory function.
Non-heme iron halogenases (NHFe-Hals) catalyze the direct insertion of a chloride/bromide ion at an unactivated carbon position using a high-valent haloferryl intermediate. Despite more than a decade of structural and mechanistic characterization, how NHFe-Hals preferentially bind specific anions and substrates for C-H functionalization remains unknown. Herein, using lysine-halogenating BesD and HalB enzymes as model systems, we demonstrate strong positive cooperativity between anion and substrate binding to the catalytic pocket. Detailed computational investigations indicate that a negatively charged glutamate hydrogen-bonded to iron's equatorial-aqua ligand acts as an electrostatic lock preventing both lysine and anion binding in the absence of the other. Using a combination of UV-Vis spectroscopy, binding affinity studies, stopped-flow kinetics investigations, and biochemical assays, we explore the implication of such active site assembly towards chlorination, bromination, and azidation reactivities. Overall, our work highlights previously unknown features regarding how anion-substrate pair binding govern reactivity of iron halogenases that are crucial for engineering next-generation C-H functionalization biocatalysts.
Chemo- and regio-selective catalysis of C(sp3)-H halogenation reaction is a formidable goal in chemical synthesis. 2-oxo-glutarate (2OG) dependent non-heme iron halogenases catalyze selective chlorination/bromination of C-H bonds and exhibit high sequence and structural similarities with non-heme iron hydroxylases. How the secondary coordination sphere (SCS) of these two enzyme systems differentiate and determine their reactivity is not understood. In this work, we show that tyrosine placement in the SCS of non-heme iron halogenases have a huge impact on their structure, function, and reactivity. We discover that a tyrosine mutant (F121Y) in SyrB2 halogenase undergoes post-translational oxidation to dihydroxyphenylalanine (DOPA) physiologically. A combination of spectroscopic, mass-spectrometric, and biochemical studies show that the DOPA modification in SyrB2 renders the enzyme non-functional. Further bioinformatics analysis suggests that halogenases, unlike hydroxylases, have a conserved placement of phenylalanine at position 121 to preclude such unproductive oxidation. Overall, this study demonstrates the importance of the SCS in controlling the structure and enzymatic activity of non-heme iron halogenases. Our results will have significant implications towards the design of small-molecule and protein-based halogenation catalysts.
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