Harnessing the power of enzymes to carry out synthetically relevant reactions is rapidly emerging as a powerful tool for sustainable chemistry. Iron-dependent enzymes have been of particular interest to the field because of their ability to facilitate complex reactions with broad substrate scope. Recently, we found that Fe(II) 2-oxoglutarate dependent hydroxylases (Fe(II)/2OGs) exhibit non-native activity towards either epoxidation or allylic hydroxylation. Oxyfunctionalizations are important in chemical synthesis as they allow for diversification to a range of more complex molecular scaffolds from simple olefinic precursors. Because of this, reactions that produce hydroxides or epoxides are of high interest, especially in an asymmetric fashion. However, current methods are not broadly applicable, as they are limited in substrate scope, selectivity, and tolerance towards other functional groups. Enzymes could rival traditional methods, offering greater selectivity and substrate scope while using inexpensive and Earth-abundant reagents. Here, we explore the ability for Fe(II)/2OGs to catalyze non-native asymmetric epoxidations or allylic hydroxylations. First, we will determine whether the reaction taking place is an epoxidation or allylic hydroxylation. Second, we will identify any additional Fe(II)/2OGs capable of oxyfunctionalization beyond our initial hit. Third, we will use directed enzyme evolution to improve oxyfunctionalization activity and enantioselectivity of a selected enzyme candidate. Fourth, we hope to expand substrate scope of an evolved Fe(II)/2OG to develop a general “epoxidase” or hydroxylase capable of reacting with a variety of functionalized olefinic small molecules in an asymmetric fashion. Generally, our lab seeks to use Fe(II)/2OGs mutagenesis libraries and a developed liquid chromatography-mass spectrometry screening platform to exploit the existing wide catalytic diversity of Fe/2OGs into a useful array of synthetically relevant transformations.