The 91传媒 Factor
Now at Princeton, a chemist is pursuing hard research with real-world applications.
When Doug Gisewhite, Ph.D. 鈥17, arrived on campus, Chemistry Professor Sharon Burgmayer took notice. Burgmayer specializes in bioinorganic chemistry, and she was looking for someone with expertise in organic chemistry to help with her research on the molybdenum cofactor (aka Moco), an enzyme critical to human health. In Gisewhite, she found her man.
Burgmayer鈥檚 work with molybdenum focuses on atomic-level reactions, particularly in the case of pterin, an aromatic heterocycle that is bound to the metal center of Moco via a dithiolene.
As Gisewhite explains, 鈥淲e were doing a lot of modeling work, specifically trying to understand the pterin鈥檚 contributions and how it did or didn鈥檛 control what was going on at the molybdenum metal center鈥攂ecause that鈥檚 where all the action is.鈥
Fast forward and you鈥檒l find Gisewhite in the Princeton chemistry lab of Professor John T. Groves, who works at the interface of organic, inorganic, and biological chemistry. In 1976, he coined the term 鈥渙xygen rebound鈥 to describe the mechanism by which
iron-containing enzymes called oxygenases introduce a hydroxyl group (one that contains oxygen bonded to hydrogen) into substrates.
鈥淗is focus is on heme proteins and carbon-hydrogen bond activation,鈥 Gisewhite explains. 鈥淭hat is, replacing hydrogen with another functional group, maybe hydroxyl or azide or chlorine. And I want to learn more about that kind of organic work.鈥
More recently, Groves鈥檚 lab has upped the game and experimented with the transfer of more interesting functional groups like 18F, fluorine, chlorine, bromine, azide, and isocyanate.
If that sounds like nothing but pure research to you, think again. The answers to the questions Gisewhite is studying have real-world applications. As Gisewhite explains, 鈥淔or example, 18F鈥攁 fluorine radioisotope鈥攈as interesting implications for PET imaging.鈥 (Positron emission tomography, or PET, is a nuclear imaging technology used to observe metabolic processes in the body.)
The Princeton lab鈥檚 work shows potential for other medical applications. 鈥淏romine and chlorine are useful in coupling reactions,鈥 says Gisewhite, 鈥渁nd azide and isocyanate are building blocks in synthetic organic chemistry, especially medicinal chemistry.鈥
The work can be challenging though. 鈥淲ith a manganese porphyrin catalyst, we can insert functional groups at late stages of synthetic development,鈥 he says. 鈥淏ut that鈥檚 not very easy鈥攁s I鈥檝e been finding out with the number of failures I鈥檝e observed in my last three months.鈥
But Gisewhite is philosophical about setbacks: 鈥淚n chemistry, as in life, you observe failure, but you never let it get you down. You persevere and try something else. You observe another failure, and you try again鈥攐ur greatest successes come after our greatest disappointments. These failures should be considered guidelines, not stop signs.鈥
Published on: 05/15/2018