Sequencing by avidity enables high accuracy with low reagent consumption.

We present avidity sequencing, a sequencing chemistry that separately optimizes the processes of stepping along a DNA template and that of identifying each nucleotide within the template. Nucleotide identification uses multivalent nucleotide ligands on dye-labeled cores to form polymerase-polymer-nucleotide complexes bound to clonal copies of DNA targets. These polymer-nucleotide substrates, termed avidites, decrease the required concentration of reporting nucleotides from micromolar to nanomolar and yield negligible dissociation rates. Avidity sequencing achieves high accuracy, with 96.2% and 85.4% of base calls having an average of one error per 1,000 and 10,000 base pairs, respectively. We show that the average error rate of avidity sequencing remained stable following a long homopolymer.

New codons for efficient production of unnatural proteins in a semisynthetic organism.

Natural organisms use a four-letter genetic alphabet that makes available 64 triplet codons, of which 61 are sense codons used to encode proteins with the 20 canonical amino acids. We have shown that the unnatural nucleotides dNaM and dTPT3 can pair to form an unnatural base pair (UBP) and allow for the creation of semisynthetic organisms (SSOs) with additional sense codons. Here, we report a systematic analysis of the unnatural codons. We identify nine unnatural codons that can produce unnatural protein with nearly complete incorporation of an encoded noncanonical amino acid (ncAA). We also show that at least three of the codons are orthogonal and can be simultaneously decoded in the SSO, affording the first 67-codon organism. The ability to incorporate multiple, different ncAAs site specifically into a protein should now allow the development of proteins with novel activities, and possibly even SSOs with new forms and functions.

Optimization of Replication, Transcription, and Translation in a Semi-Synthetic Organism.

Previously, we reported the creation of a semi-synthetic organism (SSO) that stores and retrieves increased information by virtue of stably maintaining an unnatural base pair (UBP) in its DNA, transcribing the corresponding unnatural nucleotides into the codons and anticodons of mRNAs and tRNAs, and then using them to produce proteins containing noncanonical amino acids (ncAAs). Here we report a systematic extension of the effort to optimize the SSO by exploring a variety of deoxy- and ribonucleotide analogues. Importantly, this includes the first in vivo structure-activity relationship (SAR) analysis of unnatural ribonucleoside triphosphates. Similarities and differences between how DNA and RNA polymerases recognize the unnatural nucleotides were observed, and remarkably, we found that a wide variety of unnatural ribonucleotides can be efficiently transcribed into RNA and then productively and selectively paired at the ribosome to mediate the synthesis of proteins with ncAAs. The results extend previous studies, demonstrating that nucleotides bearing no significant structural or functional homology to the natural nucleotides can be efficiently and selectively paired during replication, to include each step of the entire process of information storage and retrieval. From a practical perspective, the results identify the most optimal UBP for replication and transcription, as well as the most optimal unnatural ribonucleoside triphosphates for transcription and translation. The optimized SSO is now, for the first time, able to efficiently produce proteins containing multiple, proximal ncAAs.

Eight-Letter DNA.

Steve Benner and collaborators have recently reported an analysis of DNA containing eight nucleotide letters, the four natural letters (dG, dC, dA, and dT) and four additional letters (dP, dZ, dS, and dB). Their analysis demonstrates that the additional letters do not perturb the structure or stability of the base pairs formed between the natural letters and, remarkably, that the new base pairs, dP-dZ and dS-dB, behave virtually identically to the natural base pairs. This unprecedented result convincingly demonstrates that the thermodynamic and structural behavior previously thought to be the purview of only natural DNA is in fact not unique and can be imparted to suitably designed synthetic components. In addition, the first evidence that the eight-letter DNA can be transcribed into RNA by a mutant RNA polymerase is presented, paving the way for the transfer of more information from one biopolymer to another. Along with others working to develop unnatural DNA base pairs for both in vitro and in vivo applications, this work represents an important step toward the expansion of the genetic alphabet, a central goal of synthetic biology, and has profound implications for our understanding of the molecules and forces that can make life possible.

Progress Toward a Semi-Synthetic Organism with an Unrestricted Expanded Genetic Alphabet.

We have developed a family of unnatural base pairs (UBPs), exemplified by the pair formed between dNaM and dTPT3, for which pairing is mediated not by complementary hydrogen bonding but by hydrophobic and packing forces. These UBPs enabled the creation of the first semisynthetic organisms (SSOs) that store increased genetic information and use it to produce proteins containing noncanonical amino acids. However, retention of the UBPs was poor in some sequence contexts. Here, to optimize the SSO, we synthesize two novel benzothiophene-based dNaM analogs, dPTMO and dMTMO, and characterize the corresponding UBPs, dPTMO-dTPT3 and dMTMO-dTPT3. We demonstrate that these UBPs perform similarly to, or slightly worse than, dNaM-dTPT3 in vitro. However, in the in vivo environment of an SSO, retention of dMTMO-dTPT3, and especially dPTMO-dTPT3, is significantly higher than that of dNaM-dTPT3. This more optimal in vivo retention results from better replication, as opposed to more efficient import of the requisite unnatural nucleoside triphosphates. Modeling studies suggest that the more optimal replication results from specific internucleobase interactions mediated by the thiophene sulfur atoms. Finally, we show that dMTMO and dPTMO efficiently template the transcription of RNA containing TPT3 and that their improved retention in DNA results in more efficient production of proteins with noncanonical amino acids. This is the first instance of using performance within the SSO as part of the UBP evaluation and optimization process. From a general perspective, the results demonstrate the importance of evaluating synthetic biology "parts" in their in vivo context and further demonstrate the ability of hydrophobic and packing interactions to replace the complementary hydrogen bonding that underlies the replication of natural base pairs. From a more practical perspective, the identification of dMTMO-dTPT3 and especially dPTMO-dTPT3 represents significant progress toward the development of SSOs with an unrestricted ability to store and retrieve increased information.

Expansion of the genetic code via expansion of the genetic alphabet.

Current methods to expand the genetic code enable site-specific incorporation of non-canonical amino acids (ncAAs) into proteins in eukaryotic and prokaryotic cells. However, current methods are limited by the number of codons possible, their orthogonality, and possibly their effects on protein synthesis and folding. An alternative approach relies on unnatural base pairs to create a virtually unlimited number of genuinely new codons that are efficiently translated and highly orthogonal because they direct ncAA incorporation using forces other than the complementary hydrogen bonds employed by their natural counterparts. This review outlines progress and achievements made towards developing a functional unnatural base pair and its use to generate semi-synthetic organisms with an expanded genetic alphabet that serves as the basis of an expanded genetic code.

Chemical Stabilization of Unnatural Nucleotide Triphosphates for the in Vivo Expansion of the Genetic Alphabet.

We have developed an unnatural base pair (UBP) and a semisynthetic organism (SSO) that imports the constituent unnatural nucleoside triphosphates and uses them to replicate DNA containing the UBP. However, propagation of the UBP is at least in part limited by the stability of the unnatural triphosphates, which are degraded by cellular and secreted phosphatases. To circumvent this problem, we now report the synthesis and evaluation of unnatural triphosphates with their ß,γ-bridging oxygen replaced with a difluoromethylene moiety, yielding dNaMTPCF2 and dTPT3TPCF2. We find that although dNaMTPCF2 cannot support in vivo replication, likely due to poor polymerase recognition, dTPT3TPCF2 can, and moreover, its increased stability can contribute to increased UBP retention. The data demonstrate the promise of this chemical approach to SSO optimization, and suggest that other modifications should be sought that confer phosphatase resistance without interfering with polymerase recognition.

CalFluors: A Universal Motif for Fluorogenic Azide Probes across the Visible Spectrum.

Fluorescent bioorthogonal smart probes across the visible spectrum will enable sensitive visualization of metabolically labeled molecules in biological systems. Here we present a unified design, based on the principle of photoinduced electron transfer, to access a panel of highly fluorogenic azide probes that are activated by conversion to the corresponding triazoles via click chemistry. Termed the CalFluors, these probes possess emission maxima that range from green to far red wavelengths, and enable sensitive biomolecule detection under no-wash conditions. We used the CalFluor probes to image various alkyne-labeled biomolecules (glycans, DNA, RNA, and proteins) in cells, developing zebrafish, and mouse brain tissue slices.