Denis A. Malyshev

A semi-synthetic organism with an expanded genetic alphabet

Organisms are defined by the information encoded in their genomes, and since the origin of life this information has been encoded using a two-base-pair genetic alphabet (A–T and G–C). In vitro, the alphabet has been expanded to include several unnatural base pairs (UBPs). We have developed a class of UBPs formed between nucleotides bearing hydrophobic nucleobases, exemplified by the pair formed between d5SICS and dNaM (d5SICS–dNaM), which is efficiently PCR-amplified and transcribed in vitro, and whose unique mechanism of replication has been characterized. However, expansion of an organism’s genetic alphabet presents new and unprecedented challenges: the unnatural nucleoside triphosphates must be available inside the cell; endogenous polymerases must be able to use the unnatural triphosphates to faithfully replicate DNA containing the UBP within the complex cellular milieu; and finally, the UBP must be stable in the presence of pathways that maintain the integrity of DNA. Here we show that an exogenously expressed algal nucleotide triphosphate transporter efficiently imports the triphosphates of both d5SICS and dNaM (d5SICSTP and dNaMTP) into Escherichia coli, and that the endogenous replication machinery uses them to accurately replicate a plasmid containing d5SICS–dNaM. Neither the presence of the unnatural triphosphates nor the replication of the UBP introduces a notable growth burden. Lastly, we find that the UBP is not efficiently excised by DNA repair pathways. Thus, the resulting bacterium is the first organism to propagate stably an expanded genetic alphabet.

PCR with an expanded genetic alphabet.

Expansion of the genetic alphabet with a third base pair would lay the foundation for a semisynthetic organism with an expanded genetic code and also have immediate in vitro applications. Previously, the unnatural base pairs formed between d5SICS and either dNaM or dMMO2 were shown to be well-replicated by DNA polymerases under steady-state conditions and also transcribed by T7 RNA polymerase efficiently in either direction. We now demonstrate that DNA containing either the d5SICS-dNaM or d5SICS-dMMO2 unnatural base pair may be amplified by PCR with fidelities and efficiencies that approach those of fully natural DNA. These results further demonstrate that the determinants of a functional unnatural base pair may be designed into predominantly hydrophobic nucleobases with no structural similarity to the natural purines or pyrimidines. Importantly, the results reveal that the unnatural base pairs may function within an expanded genetic alphabet and make possible many in vitro applications.

Efficient and sequence-independent replication of DNA containing a third base pair establishes a functional six-letter genetic alphabet

The natural four-letter genetic alphabet, comprised of just two base pairs (dA-dT and dG-dC), is conserved throughout all life, and its expansion by the development of a third, unnatural base pair has emerged as a central goal of chemical and synthetic biology. We recently developed a class of candidate unnatural base pairs, exemplified by the pair formed between d5SICS and dNaM. Here, we examine the PCR amplification of DNA containing one or more d5SICS-dNaM pairs in a wide variety of sequence contexts. Under standard conditions, we show that this DNA may be amplified with high efficiency and greater than 99.9% fidelity. To more rigorously explore potential sequence effects, we used deep sequencing to characterize a library of templates containing the unnatural base pair as a function of amplification. We found that the unnatural base pair is efficiently replicated with high fidelity in virtually all sequence contexts. The results show that, for PCR and PCR-based applications, d5SICS-dNaM is functionally equivalent to a natural base pair, and when combined with dA-dT and dG-dC, it provides a fully functional six-letter genetic alphabet.

KlenTaq polymerase replicates unnatural base pairs by inducing a Watson-Crick geometry

Many candidate unnatural DNA base pairs have been developed, but surprisingly, some of the best replicated adopt intercalated structures in free DNA that are difficult to reconcile with known mechanisms of polymerase recognition. Here we present crystal structures of KlenTaq DNA polymerase at different stages of replicating one of the more promising pairs, dNaM-d5SICS, and show that efficient replication results from the polymerase itself inducing the required natural-like structure.

The Expanded Genetic Alphabet

All biological information, since the last common ancestor of all life on Earth, has been encoded by a genetic alphabet consisting of only four nucleotides that form two base pairs. Long-standing efforts to develop two synthetic nucleotides that form a third, unnatural base pair (UBP) have recently yielded three promising candidates, one based on alternative hydrogen bonding, and two based on hydrophobic and packing forces. All three of these UBPs are replicated and transcribed with remarkable efficiency and fidelity, and the latter two thus demonstrate that hydrogen bonding is not unique in its ability to underlie the storage and retrieval of genetic information. This Review highlights these recent developments as well as the applications enabled by the UBPs, including the expansion of the evolution process to include new functionality and the creation of semi-synthetic life that stores increased information.

Natural-like Replication of an Unnatural Base Pair for the Expansion of the Genetic Alphabet and Biotechnology Applications

We synthesized a panel of unnatural base pairs whose pairing depends on hydrophobic and packing forces and identify dTPT3-dNaM, which is PCR amplified with a natural base pair-like efficiency and fidelity. In addition, the dTPT3 scaffold is uniquely tolerant of attaching a propargyl amine linker, resulting in the dTPT3(PA)-dNaM pair, which is amplified only slightly less well. The identification of dTPT3 represents significant progress toward developing an unnatural base pair for the in vivo expansion of an organisms genetic alphabet and for a variety of in vitro biotechnology applications where it is used to site-specifically label amplified DNA, and it also demonstrates for the first time that hydrophobic and packing forces are sufficient to mediate natural-like replication.

Site-Specific Labeling of DNA and RNA Using an Efficiently Replicated and Transcribed Class of Unnatural Base Pairs

Site-specific labeling of enzymatically synthesized DNA or RNA has many potential uses in basic and applied research, ranging from facilitating biophysical studies to the in vitro evolution of functional nucleic acids and the construction of various nanomaterials and biosensors. As part of our efforts to expand the genetic alphabet, we have developed a class of unnatural base pairs, exemplified by d5SICS-dMMO2 and d5SICS-dNaM, which are efficiently replicated and transcribed, and which may be ideal for the site-specific labeling of DNA and RNA. Here, we report the synthesis and analysis of the ribo- and deoxyribo-variants, (d)5SICS and (d)MMO2, modified with free or protected propargylamine linkers that allow for the site-specific modification of DNA or RNA during or after enzymatic synthesis. We also synthesized and evaluated the α-phosphorothioate variant of d5SICSTP, which provides a route to backbone thiolation and an additional strategy for the postamplification site-specific labeling of DNA. The deoxynucleotides were characterized via steady-state kinetics and PCR, while the ribonucleosides were characterized by the transcription of both a short, model RNA as well as full length tRNA. The data reveal that while there are interesting nucleotide and polymerase-specific sensitivities to linker attachment, both (d)MMO2 and (d)5SICS may be used to produce DNA or RNA site-specifically modified with multiple, different functional groups with sufficient efficiency and fidelity for practical applications.

Solution Structure, Mechanism of Replication, and Optimization of an Unnatural Base Pair

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 by means of a unique intercalative mechanism. Here, we report the synthesis and characterization of three novel derivatives of the nucleotide analogue dMMO2, which forms an unnatural base pair with the nucleotide analogue d5SICS. Replacing the para-methyl substituent of dMMO2 with an annulated furan ring (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.

Structural Insights Into DNA Replication without Hydrogen Bonds.

The genetic alphabet is composed of two base pairs, and the development of a third, unnatural base pair would increase the genetic and chemical potential of DNA. d5SICS-dNaM is one of the most efficiently replicated unnatural base pairs identified to date, but its pairing is mediated by only hydrophobic and packing forces, and in free duplex DNA it forms a cross-strand intercalated structure that makes its efficient replication difficult to understand. Recent studies of the KlenTaq DNA polymerase revealed that the insertion of d5SICSTP opposite dNaM proceeds via a mutually induced-fit mechanism, where the presence of the triphosphate induces the polymerase to form the catalytically competent closed structure, which in turn induces the pairing nucleotides of the developing unnatural base pair to adopt a planar Watson-Crick-like structure. To understand the remaining steps of replication, we now report the characterization of the prechemistry complexes corresponding to the insertion of dNaMTP opposite d5SICS, as well as multiple postchemistry complexes in which the already formed unnatural base pair is positioned at the postinsertion site. Unlike with the insertion of d5SICSTP opposite dNaM, addition of dNaMTP does not fully induce the formation of the catalytically competent closed state. The data also reveal that once synthesized and translocated to the postinsertion position, the unnatural nucleobases again intercalate. Two modes of intercalation are observed, depending on the nature of the flanking nucleotides, and are each stabilized by different interactions with the polymerase, and each appear to reduce the affinity with which the next correct triphosphate binds. Thus, continued primer extension is limited by deintercalation and rearrangements with the polymerase active site that are required to populate the catalytically active, triphosphate bound conformation.

Systematic exploration of a class of hydrophobic unnatural base pairs yields multiple new candidates for the expansion of the genetic alphabet

We have developed a family of unnatural base pairs (UBPs), which rely on hydrophobic and packing interactions for pairing and which are well replicated and transcribed. While the pair formed between d5SICS and dNaM (d5SICS-dNaM) has received the most attention, and has been used to expand the genetic alphabet of a living organism, recent efforts have identified dTPT3-dNaM, which is replicated with even higher fidelity. These efforts also resulted in more UBPs than could be independently analyzed, and thus we now report a PCR-based screen to identify the most promising. While we found that dTPT3-dNaM is generally the most promising UBP, we identified several others that are replicated nearly as well and significantly better than d5SICS-dNaM, and are thus viable candidates for the expansion of the genetic alphabet of a living organism. Moreover, the results suggest that continued optimization should be possible, and that the putatively essential hydrogen-bond acceptor at the position ortho to the glycosidic linkage may not be required. These results clearly demonstrate the generality of hydrophobic forces for the control of base pairing within DNA, provide a wealth of new structure–activity relationship data and importantly identify multiple new candidates for in vivo evaluation and further optimization.