5-Bromo-2'-deoxycytidine-a potential DNA photosensitizer.

A double-stranded oligonucleotide, 80 base pairs in length, was multiply labeled with 5-bromo-2'-deoxycytidine (BrdC) using polymerase chain reaction (PCR). The modified oligonucleotide was irradiated with 300 nm photons and its damage was assayed by employing DHPLC, LC-MS and denaturing polyacrylamide gel electrophoresis (PAGE). Two types of damage were demonstrated, namely, single strand breaks (SSBs) and intrastrand cross-links (ICLs); the ICLs were in the form of d(G^C) and d(C^C) dimers. The former species are probably formed due to photoinduced electron transfer between the photoexcited BrdC and the ground state 2'-deoxyguanosine (dG), whereas the latter is a result of a cycloaddition reaction. Since SSBs and ICLs are potentially lethal to the cell, BrdC could be considered as a nucleoside with possible clinical applications.

Photoinduced single strand breaks and intrastrand cross-links in an oligonucleotide labeled with 5-bromouracil.

5-Bromouracil (BrU) is photoreactive toward near UVB photons and can be introduced into genomic DNA during its biosynthesis in cells. However, PCR seems to be a simpler approach, which can be used to obtain labeled DNA similar to that synthesized within the cell. In the current work, PCR has been employed and optimized in order to substitute all thymines (besides those present in starters) with BrU in the dsDNA fragment of 80 base pairs (bp) in length. The modified oligonucleotide was irradiated with 300 nm photons in a buffered aqueous solution (pH = 7) and digested with a cocktail of enzymes specific to the phosphodiester bond cleavage. Initially, the extent of damage in the intact photolyte was measured with DHPLC. Then, the digested reaction mixture was subjected to HPLC and MS analyses and, in addition to the formation of 5-bromo-2'-deoxuyridine, which proves the occurrence of single strand breaks (SSBs) due to irradiation, U∧U and U∧C dimers were found, whose molecular structure was confirmed by MS/MS analysis. Although the abundance of such tandem lesions is lower than that of the SSB type, they pose a potent threat to genome integrity. Thus, our findings shed new light on the photosensitizing properties of BrU toward DNA.

PCR synthesis of double stranded DNA labeled with 5-bromouridine. A step towards finding a bromonucleoside for clinical trials.

Incorporation of 5-bromouridine (5BrdU) into DNA makes it sensitive to UV and ionizing radiation, which opens up a prospective route for the clinical usage of 5-bromouridine and other halonucleosides. In the present work the polymerase chain reaction (PCR) protocol, which enables a long DNA fragment (resembling DNA synthesized in the cell in the presence of halonucleosides) to be completely substituted with 5BrdU, was optimized. Using HPLC coupled to enzymatic digestion, it was demonstrated that the actual amounts of native nucleosides and 5BrdU correspond very well to those calculated from the sequence of PCR products. The synthesized DNA is photosensitive to photons of 300nm. HPLC analysis demonstrated that the photolysis of labeled PCR products leads to a significant decrease in the 5BrdU signal and the simultaneous occurrence of a uridine peak. Agarose and polyacrylamide gel electrophoresis suggest that single strand breaks and cross-links are formed as a result of UV irradiation. The PCR protocol described in the current paper may be employed for labeling DNA not only with BrdU but also with other halonucleosides.