I describe how we direct the evolution of non-natural enzyme activities, using chemical intuition and information on structure and mechanism to guide us to the most promising reaction/enzyme systems. With synthetic reagents to generate new reactive intermediates and just a few amino acid substitutions to tune the active site, a cytochrome P450 can catalyze a variety of carbene and nitrene transfer reactions. The cyclopropanation, N–H insertion, C–H amination, sulfimidation, and aziridination reactions now demonstrated are all well known in chemical catalysis but have no counterparts in nature. The new enzymes are fully genetically encoded, assemble and function inside of cells, and can be optimized for different substrates, activities, and selectivities. We are learning how to use nature's innovation mechanisms to marry some of the synthetic chemists’ favorite transformations with the exquisite selectivity and tunability of enzymes.

The tumor suppressor p53 is conformationally unstable at physiological temperature. Even the activated p53Δ30 variant, which lacks the self-inhibiting carboxy terminal domain, has a half-life of only 8 min at 37 °C in vitro. We have developed a genetic approach to identify p53 variants that stabilize the active conformation. The human p53Δ30 gene was randomly mutated, and the resulting library was expressed in Escherichia coli under conditions that apparently denatured the parental protein. Stable p53 variants were identified based on their ability to specifically bind a p53 consensus site. The initial thermostable variants were randomly recombined by DNA shuffling, and substitutions that were functionally additive or synergistic were identified in a second more stringent round of screening. The DNA binding activity of N239Y/N268D/E336V p53Δ30 variant has a half-life of 100 min at 37 °C, 12 times longer than that of the parental protein. The thermostable variants should be more amenable to crystallographic studies and more effective in gene therapies than the wild-type protein.