DNA photolyases use blue light and fully reduced flavin
cofactor
to repair UV-induced cyclobutane pyrimidine dimers (CPD) formed between
two adjacent thymine bases in DNA. Thymine can form [2 + 2] cyclobutane
adducts with its biological isosteres like toluene upon UV irradiation,
resulting in chemically different analogues of CPD. Here, we investigated
the cycloreversion reactions of two such adducts formed between thymine
and toluene, T<>Tol, catalyzed by a class-I CPD photolyase.
The
photolyase can bind to the T<>Tol adducts efficiently and restore
the constituent bases upon excitation. Using femtosecond spectroscopy,
we systematically characterized all the elementary steps involved
in the enzymatic cycloreversion of the T<>Tol adducts and comprehensively
analyzed the key intermolecular electron-transfer (ET) reactions and
cyclobutane bond splitting steps. The initial electron injection to
the bound adducts happens primarily through a two-step electron hopping
mechanism, unlike in CPD repair where direct electron tunneling is
dominant. After electron injection and ultrafast first-bond splitting,
the delicate competition between the second bond splitting and a futile
back ET dictates the overall reaction quantum yields of the adducts,
influenced by the stability of adduct intermediates and steric crowding
around the constituent bases. The final electron return for the cycloreversion
reactions adopts a different pathway compared to CPD repair. The photolyase
utilizes its conserved photorepair mechanism and allows ET pathway
flexibility to reverse the [2 + 2] cycloaddition reaction of non-natural
analogues of CPD.