Timothy W. Yokley scite author profile

Phosphatidylinositol (PI) lipids control critical biological processes, so aberrant biosynthesis often leads to disease. As a result, the capability to track the production and localization of these compounds in cells is vital for elucidating their complex roles. Herein, we report the design, synthesis, and application of clickable myo-inositol probe 1 a for bioorthogonal labeling of PI products. To validate this platform, we initially conducted PI synthase assays to show that 1 a inhibits PI production in vitro. Fluorescence microscopy experiments next showed probe-dependent imaging in T-24 human bladder cancer and Candida albicans cells. Growth studies in the latter showed that replacement of myo-inositol with probe 1 a led to an enhancement in cell growth. Finally, fluorescence-based TLC analysis and mass spectrometry experiments support the labeling of PI lipids. This approach provides a promising means for tracking the complex biosynthesis and trafficking of these lipids in cells.

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Hydrogen Activation and Hydrogenolysis Facilitated By Late-Transition-Metal–Aluminum Heterobimetallic Complexes

Charles

Yokley

Schley

et al. 2019

Inorg. Chem.

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Previously reported heterobimetallic rhodium−aluminum and iridium−aluminum alkyl complexes are shown to activate hydrogen, generating the corresponding alkane. Kinetic data indicate a mechanistic difference between the iridium-and rhodium-based systems. In both cases the transition metal is an active participant in the release of alkane from the aluminum center. For iridium− aluminum species, experimental mechanistic data suggest that multiple pathways occur concomitantly with each other: one being the oxidative addition of hydrogen followed by proton transfer resulting in alkane generation. Computational data indicate a reasonable barrier to formation of an iridium dihydride intermediate observed experimentally. In the case of the rhodium−aluminum species, hydrides are not observed spectroscopically, though a reasonable barrier to formation of this thermodynamically unstable species has been calculated. Alternative mechanistic possibilities are discussed and explored computationally. Cooperative hydrogenolysis mechanisms are computed to be energetically unfeasible for both metal centers.

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CO₂ Capture by 2‐(Methylamino)pyridine Ligated Aluminum Alkyl Complexes

et al. 2020

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Timothy W. Yokley

Labeling of Phosphatidylinositol Lipid Products in Cells through Metabolic Engineering by Using a Clickable myo‐Inositol Probe

Hydrogen Activation and Hydrogenolysis Facilitated By Late-Transition-Metal–Aluminum Heterobimetallic Complexes

CO₂ Capture by 2‐(Methylamino)pyridine Ligated Aluminum Alkyl Complexes

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Timothy W. Yokley

Labeling of Phosphatidylinositol Lipid Products in Cells through Metabolic Engineering by Using a Clickable myo‐Inositol Probe

Hydrogen Activation and Hydrogenolysis Facilitated By Late-Transition-Metal–Aluminum Heterobimetallic Complexes

CO2 Capture by 2‐(Methylamino)pyridine Ligated Aluminum Alkyl Complexes

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CO₂ Capture by 2‐(Methylamino)pyridine Ligated Aluminum Alkyl Complexes