The oxidative addition of organic electrophiles into
electrochemically
generated Co(I) complexes has been widely utilized as a strategy to
produce carbon-centered radicals when cobalt is ligated by a polydentate
ligand. Changing to a bidentate ligand provides the opportunity to
access discrete Co(III)–C bonded complexes for alternative
reactivity, but knowledge of how ligand and/or substrate structures
affect catalytic steps is pivotal to reaction design and catalyst
optimization. In this vein, experimental studies that can determine
the exact nature of elementary organometallic steps remain limited,
especially for single-electron oxidative addition pathways. Herein,
we utilize cyclic voltammetry combined with simulations to obtain
kinetic and thermodynamic properties of the two-step, halogen-atom
abstraction mechanism, validated by analyzing kinetic isotope and
substituent effects. Complex Hammett relationships could be disentangled
to allow understanding of individual effects on activation energy
barriers and equilibrium constants, and DFT-derived parameters used
to build predictive statistical models for rates of new ligand/substrate
combinations.
Previously our laboratory identified that poly-2'-deoxycytidine (dCn) strands of DNA with lengths greater than 12 nucleotides could adopt i-motif folds, while the pH-dependent stabilities follow a 4n - 1 repeat pattern with respect to chain length (J. Am. Chem. Soc., 2017, 139, 4682-4689). Herein, model i-motif folds in which loop configurations were forced by judiciously mutating dC to non-dC nucleotides allowed a structural model to be proposed to address this phenomenon. The model was developed by systematically studying two i-motifs with either an even or odd number of d(C·C)+ hemiprotonated base pairs in the core. First, a trend in the pH-dependent stability vs. loop nucleotide identity was observed: dC > dT ∼ dU ≫ dA ∼ dG. Next, loops comprised of dT nucleotides in the two different core base pair configurations were studied while systematically changing the loop lengths. We found that an i-motif with an even number of base pairs in the core with a single nucleotide in each of the three loops was the most stable, as well as an i-motif with an odd number of core base pairs having one nucleotide in the two exterior loops and three nucleotides in the central loop. A systematic increase in the central loop from 1-4 nucleotides for an odd number of base pairs in the i-motif core reproduced the 4n - 1 repeat pattern observed in the poly-dCn strands. Additional loop configurations were studied to further support the model. The results are discussed with respect to their biological relevance.
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