Locating, tracing and sequencing multiple expanded genetic letters in complex DNA context via a bridge-base approach.

A panel of unnatural base pairs is developed to expand genetic alphabets. One or more unnatural base pairs (UBPs) can be inserted to enlarge the capacity, diversity, and functionality of canonical DNA, so monitoring the multiple-UBPs-containing DNA by simple and convenient approaches is essential. Herein, we report a bridge-base approach to repurpose the capability of determining TPT3-NaM UBPs. The success of this approach depends on the design of isoTAT that can simultaneously pair with NaM and G as a bridge base, as well as the discovering of the transformation of NaM to A in absence of its complementary base. TPT3-NaM can be transferred to C-G or A-T by simple PCR assays with high read-through ratios and low sequence-dependent properties, permitting for the first time to dually locate the multiple sites of TPT3-NaM pairs. Then we show the unprecedented capacity of this approach to trace accurate changes and retention ratios of multiple TPT3-NaM UPBs during in vivo replications. In addition, the method can also be applied to identify multiple-site DNA lesions, transferring TPT3-NaM makers to different natural bases. Taken together, our work presents the first general and convenient approach capable of locating, tracing, and sequencing site- and number-unlimited TPT3-NaM pairs.

Amplification, Enrichment, and Sequencing of Mutagenic Methylated DNA Adduct through Specifically Pairing with Unnatural Nucleobases.

3-Methylthymine (m3T) is a long-known chemically stable but strongly mutagenic DNA base adduct; however, the sequencing method to determine m3T is lacking so far. Two of the main obstacles include the capacity of m3T to stall DNA elongation and its low abundance. To address the challenges, we report an unnatural base pairing strategy in this paper. A new m3T-TPT3 base pair was developed with a Vmax/Km value 82-fold higher than that of the m3T-A pair. The TPT3 nucleobase can be specifically incorporated opposite the m3T base, and the resulting m3T-TPT3 base pair can be effectively extended to give full-length products in the presence of commercial DNA polymerases. Importantly, the feature of the m3T-TPT3 pair enables a replacement PCR amplification to transfer m3T lesions at the exact positions into unnatural base pairs, which permits Sanger sequencings as well as biotin-streptavidin-based enrichments of m3T lesions. Taken together, this work offers a simple, convenient, and practical method for amplification, enrichment, and sequencing of m3T for the first time.

Mechanistic Insight into the Photoinduced Damage of an Unnatural Base Pair.

Chemical- and photostability of unnatural base pairs (UBPs) are important to maintain the genetic code integrity, and critical for developing healthy semisynthetic organisms. As reported, dTPT3 was less stable upon irradiation, and thus might act as a pervasive photosensitizer to induce oxidative damage within DNA, causing harm to living semi-synthetic organisms when exposed to UVA radiation. However, there was no knowledge about molecular-level understanding of this damage process. In this paper, we not only identified four photoproducts of dTPT3, including desulfur-dTPT3 (dTPT3H ), TPT3 sulphinate (TPT3SO2 ), TPT3 sulphonate (TPT3SO3 ) and TPT3-thioTPT3 (TPT3S TPT3), but also established a Type II photosensitized oxidation mechanism. In addition, the antioxidant (sodium ascorbate) was able to effectively inhibit the photoproducts formation of dTPT3 and dTPT3 in DNA, suggesting that a reductive environment might protect DNA bearing dTPT3 against UVA oxidation and ameliorate its adverse biological effects. The comprehensive understanding of TPT3' photochemical stability will give researchers helpful guidance to design more photostable UBPs and construct healthier semisynthetic organisms.

Access to Photostability-Enhanced Unnatural Base Pairs via Local Structural Modifications.

Completing the storage and retrieval of increased genetic information in vivo and producing therapeutic proteins have been achieved by the unnatural base pair dNaM-dTPT3. Up to now, some biological and chemical approaches are implemented to improve the semi-synthetic organism (SSO). However, the photosensitivity of this pair, suggested as a potential threat to the healthy growth of cells, is still a problem to solve. Hence, we designed and synthesized a panel of TPT3 analogues with the basic structural skeletons of TPT3 but modified thiophene rings at variant sites to improve the photostability of unnatural base pairs. A comprehensive screening strategy, including photosensitivity tests, kinetic experiments, and replication in vitro by PCR and in vivo by amplification, was implemented. A new pair, dNaM-dTAT1, which had almost equally high efficiency and fidelity with the dNaM-dTPT3 pair itself both in vivo and in vitro, was proven to be more photostable and thermostable and less toxic to E. coli cells. The discovery of dNaM-dTAT1 represents our first progress for the optimization of this type of bases toward more photostable properties; our data also suggest that less photosensitive unnatural base pairs will be beneficial to build a healthier cellular replication system.