DNA is inherently limited by its four natural nucleotides. Efforts to expand the genetic alphabet, by addition of an unnatural base pair, promise to expand the biotechnological applications available for DNA as well as being an essential first step towards expansion of the genetic code. We have conducted two independent screens of hydrophobic unnatural nucleotides to identify novel candidate base pairs that are well recognized by a natural DNA polymerase. From a pool of 3600 candidate base pairs, both screens identified the same base pair, dSICS:dMMO2, which we report here. Using a series of related analogs, we performed a detailed structure-activity relationship analysis, which allowed us to identify the essential functional groups on each nucleobase. From the results of these studies, we designed an optimized base pair, d5SICS:dMMO2, which is efficiently and selectively synthesized by Kf within the context of natural DNA.
Predominantly hydrophobic unnatural nucleotides that selectively pair within duplex DNA as well as during polymerase-mediated replication have recently received much attention as the cornerstone of efforts to expand the genetic alphabet. We recently reported the results of a screen and subsequent lead hit optimization that led to the identification of the unnatural base pair formed between the nucleotides dMMO2 and d5SICS. This unnatural base pair is replicated by the Klenow fragment of E. coli DNA polymerase I with better efficiency and fidelity than other candidates reported in the literature. However, its replication remains significantly less efficient than a natural base pair, and further optimization is necessary for its practical use. To better understand and optimize the slowest step of replication of the unnatural base pair, the insertion of dMMO2 opposite d5SICS, we synthesized two dMMO2 derivatives, d5FM and dNaM, which differ from the parent nucleobase in terms of shape, hydrophobicity, and polarizability. We find that both derivatives are inserted opposite d5SICS more efficiently than dMMO2 and that overall the corresponding unnatural base pairs are generally replicated with higher efficiency and fidelity than the pair between dMMO2 and d5SICS. In fact, in the case of the dNaM and d5SICS heteropair, the efficiency of each individual step of replication approaches that of a natural base pair, and the minimum overall fidelity ranges from 10 3 to 10 4 . In addition, the data allow us to propose a generalized model of unnatural base pair replication, which should aid in the further optimization of the unnatural base pair, and possibly in the design of additional unnatural base pairs that are replicated with truly natural-like efficiency and fidelity.
As part of an ongoing effort to expand the genetic alphabet for in vitro and eventual in vivo applications, we have synthesized a wide variety of predominantly hydrophobic unnatural base pairs and evaluated their replication in DNA. Collectively, the results have led us to propose that these base pairs, which lack stabilizing edge-on interactions, are replicated via a unique intercalative mechanism. Here, we report the synthesis and characterization of three novel derivatives of the nucleotide analog dMMO2, which forms an unnatural base pair with the nucleotide analog d5SICS. Replacing the para-methyl substituent of dMMO2 with a furanyl substituent (yielding dFMO) has a dramatically negative effect on replication, while replacing it with a methoxy (dDMO) or with a thiomethyl group (dTMO), improves replication in both steady-state assays and during PCR amplification. Thus, dTMO-d5SICS, and especially dDMO-d5SICS, represent significant progress toward the expansion of the genetic alphabet. To elucidate the structure-activity relationships governing unnatural base pair replication, we determined the solution structure of duplex DNA containing the parental dMMO2-d5SICS pair, and also used this structure to generate models of the derivative base pairs. The results strongly support the intercalative mechanism of replication, reveal a surprisingly high level of specificity that may be achieved by optimizing packing interactions, and should prove invaluable for the further optimization of the unnatural base pair.
DNA-encoded library technology (DELT) was introduced to our medicinal chemistry society more than 20 years ago. The application of DELT in the development of clinical candidates has been actively reported in the literature recently. A few representative examples include RIP1K inhibitors for inflammatory diseases and sEH inhibitors for endothelial dysfunction or abnormal tissue repair, among many others. Here, the authors would like to recall the recent developments in on-DNA synthetic methodologies for DEL construction and to analyze recent examples in the literature of DELT-based drug development efforts pursued in both the academic and industrial sectors. With this perspective, we hope to provide a useful summary of recent DELT-based drug discovery research and to discuss the future scope of DELT in medicinal chemistry.
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