Post- and Pre-Radiolabeling Assays for anti Thymidine Cyclobutane Dimers as Intrinsic Photoprobes of Various Types of G-Quadruplexes, Reverse Hoogsteen Hairpins, and Other Non-B DNA Structures.

G-quadruplexes are thought to play an important role in gene regulation and telomere maintenance, but developing probes for their presence and location is challenging due to their transitory and highly dynamic nature. The majority of probes for G-quadruplexes have relied on antibody or small-molecule binding agents, many of which can also alter the dynamics and relative populations of G-quadruplexes. Recently, it was discovered that ultraviolet B (UVB) irradiation of human telomeric DNA and various G-quadruplex forming sequences found in human promoters, as well as reverse Hoogsteen hairpins, produces a unique class of non-adjacent cyclobutane pyrimidine dimers (CPDs). Therefore, one can envision using a pulse of UVB light to irreversibly trap these non-B DNA structures via CPD formation without perturbing their dynamics, after which the CPDs can be identified and mapped. As a first step toward this goal, we report radioactive post- and pre-labeling assays for the detection of non-adjacent CPDs and illustrate their use in detecting , T=(T) CPD formation in a human telomeric DNA sequence. Both assays make use of snake venom phosphodiesterase (SVP) to degrade the , T=(T) CPD-containing DNA to the tetranucleotide pT=(pT) corresponding to CPD formation between the underlined T's of two separate dinucleotides while degrading the adjacent TT CPDs to the trinucleotide pGT=T. In the post-labeling assay, calf intestinal phosphodiesterase is used to dephosphorylate the tetranucleotides, which are then rephosphorylated with kinase and [P]-ATP to produce radiolabeled mono- and diphosphorylated tetranucleotides. The tetranucleotides are confirmed to be non-adjacent CPDs by 254 nm photoreversion to the dinucleotide p*TT. In the pre-labeling assay, radiolabeled phosphates are introduced into non-adjacent CPD-forming sites by ligation prior to irradiation, thereby eliminating the dephosphorylation and rephosphorylation steps. The assays are also demonstrated to detect the stereoisomeric , T=(T) CPD.