Increasing the functional density of threose nucleic acid

Chemical strategies that augment genetic polymers with amino acid residues that are overrepresented on the paratope surface of an antibody offer a promising route for enhancing the binding properties of nucleic acid aptamers. Here, we describe the chemical synthesis of α-l-threofuranosyl cytidine nucleoside triphosphate (tCTP) carrying either a benzyl or phenylpropyl side chain at the pyrimidine C-5 position. Polymerase recognition studies indicate that both substrates are readily incorporated into a full-length α-l-threofuranosyl nucleic acid (TNA) product by extension of a DNA primer-template duplex with an engineered TNA polymerase. Similar primer extension reactions performed using nucleoside triphosphate mixtures containing both C-5 modified tCTP and C-5 modified tUTP substrates enable the production of doubly modified TNA strands for a panel of 20 chemotype combinations. Kinetic measurements reveal faster on-rates (kon) and tighter binding affinity constants (Kd) for engineered versions of TNA aptamers carrying chemotypes at both pyrimidine positions as compared to their singly modified counterparts. These findings expand the chemical space of evolvable non-natural genetic polymers by offering a path for improving the quality of biologically stable TNA aptamers for future clinical applications.

Functionally Enhanced XNA Aptamers Discovered by Parallelized Library Screening

In vitro evolution strategies have been used for >30 years to generate nucleic acid aptamers against therapeutic targets of interest, including disease-associated proteins. However, this process requires many iterative cycles of selection and amplification, which severely restricts the number of target and library design combinations that can be explored in parallel. Here, we describe a single-round screening approach to aptamer discovery that relies on function-enhancing chemotypes to increase the distribution of high-affinity sequences in a random-sequence library. We demonstrate the success of de novo discovery by affinity selection of threomers against the receptor binding domain of the S1 protein from SARS-CoV-2. Detailed biochemical characterization of the enriched population identified threomers with binding affinity values that are comparable to aptamers produced by conventional SELEX. This work establishes a highly parallelizable path for querying diverse chemical repertoires and may offer a viable route for accelerating the discovery of therapeutic aptamers.

Parameterizing the Binding Properties of XNA Aptamers Isolated from a Low Stringency Selection

Machine learning offers a guided approach to aptamer discovery, but more information is needed to develop algorithms that can intelligently identify high-performing aptamers to a broad array of targets. Critical to this effort is the need to experimentally parameterize the difference between low and high affinity binders to a given target. Although classical selection experiments help define the upper limit by converging on a small number of tight binding sequences, very little is known about the lower limit of binding that defines the boundary between binders and nonbinders. Here, we apply a quantitative approach to explore the diversity of aptamers isolated from two identical in vitro selections performed under low stringency conditions. Starting from a library of 1 trillion unique threose nucleic acid (TNA) sequences, 7 rounds of selection were performed to enrich binders to a known aptagenic target. High density sequencing of each round of selection followed by a detailed kinetic analysis of 136 TNA aptamers yielded a narrow range of equilibrium dissociation constants (KD = ∼ 1-15 nM) that were consistent between two experimental replicates. These findings offer insights into the lower limit of binding that may be expected for aptamers generated against aptagenic targets and could provide useful constraints for evaluating the results of experimental and computational approaches.

Stability and mechanism of threose nucleic acid toward acid-mediated degradation

Xeno-nucleic acids (XNAs) have gained significant interest as synthetic genetic polymers for practical applications in biomedicine, but very little is known about their biophysical properties. Here, we compare the stability and mechanism of acid-mediated degradation of α-l-threose nucleic acid (TNA) to that of natural DNA and RNA. Under acidic conditions and elevated temperature (pH 3.3 at 90°C), TNA was found to be significantly more resistant to acid-mediated degradation than DNA and RNA. Mechanistic insights gained by reverse-phase HPLC and mass spectrometry indicate that the resilience of TNA toward low pH environments is due to a slower rate of depurination caused by induction of the 2'-phosphodiester linkage. Similar results observed for 2',5'-linked DNA and 2'-O-methoxy-RNA implicate the position of the phosphodiester group as a key factor in destabilizing the formation of the oxocarbenium intermediate responsible for depurination and strand cleavage of TNA. Biochemical analysis indicates that strand cleavage occurs by β-elimination of the 2'-phosphodiester linkage to produce an upstream cleavage product with a 2'-threose sugar and a downstream cleavage product with a 3' terminal phosphate. This work highlights the unique physicochemical properties available to evolvable non-natural genetic polymers currently in development for biomedical applications.

Shorter Is Better: The α-(l)-Threofuranosyl Nucleic Acid Modification Improves Stability, Potency, Safety, and Ago2 Binding and Mitigates Off-Target Effects of Small Interfering RNAs

Chemical modifications are necessary to ensure the metabolic stability and efficacy of oligonucleotide-based therapeutics. Here, we describe analyses of the α-(l)-threofuranosyl nucleic acid (TNA) modification, which has a shorter 3'-2' internucleotide linkage than the natural DNA and RNA, in the context of small interfering RNAs (siRNAs). The TNA modification enhanced nuclease resistance more than 2'-O-methyl or 2'-fluoro ribose modifications. TNA-containing siRNAs were prepared as triantennary N-acetylgalactosamine conjugates and were tested in cultured cells and mice. With the exceptions of position 2 of the antisense strand and position 11 of the sense strand, the TNA modification did not inhibit the activity of the RNA interference machinery. In a rat toxicology study, TNA placed at position 7 of the antisense strand of the siRNA mitigated off-target effects, likely due to the decrease in the thermodynamic binding affinity relative to the 2'-O-methyl residue. Analysis of the crystal structure of an RNA octamer with a single TNA on each strand showed that the tetrose sugar adopts a C4'-exo pucker. Computational models of siRNA antisense strands containing TNA bound to Argonaute 2 suggest that TNA is well accommodated in the region kinked by the enzyme. The combined data indicate that the TNA nucleotides are promising modifications expected to increase the potency, duration of action, and safety of siRNAs.

Highly Parallelized Screening of Functionally Enhanced XNA Aptamers in Uniform Hydrogel Particles

Xeno-nucleic acid (XNA) aptamers based on evolvable non-natural genetic polymers hold enormous potential as future diagnostic and therapeutic agents. However, time-consuming and costly procedures requiring the purification of individual XNA sequences produced by large-scale polymerase-mediated primer extension reactions pose a major bottleneck to the discovery of highly active XNA motifs for biomedical applications. Here, we describe a straightforward approach for rapidly surveying the binding properties of XNA aptamers identified by in vitro selection. Our strategy involves preparing XNA aptamer particles in which many copies of the same aptamer sequence are distributed throughout the gel matrix of a polyacrylamide-encapsulated magnetic particle. Aptamer particles are then screened by flow cytometry to assess target binding affinity and deduce structure-activity relationships. This generalizable and highly parallel assay dramatically accelerates the pace of secondary screening by allowing a single researcher to evaluate 48-96 sequences per day.

Engineering TNA polymerases through iterative cycles of directed evolution

DNA polymerases are important tools for biotechnology, synthetic biology, and chemical biology as they are routinely used to amplify and edit genetic information. However, natural polymerases do not recognize artificial genetic polymers (also known as xeno-nucleic acids or XNAs) with unique sugar-phosphate backbone structures. Directed evolution offers a possible solution to this problem by facilitating the discovery of engineered versions of natural polymerases that can copy genetic information back and forth between DNA and XNA. Here we report a directed evolution strategy for discovering polymerases that can synthesize threose nucleic acid (TNA) on DNA templates. The workflow involves library generation and expression in E. coli, high-throughput microfluidics-based screening of uniform water-in-oil droplets, plasmid recovery, secondary screening, and library regeneration. This technique is sufficiently general that it could be applied to a wide range of problems involving DNA modifying enzymes.

Chemical evolution of an autonomous DNAzyme with allele-specific gene silencing activity

Low activity has been the primary obstacle impeding the use of DNA enzymes (DNAzymes) as gene silencing agents in clinical applications. Here we describe the chemical evolution of a DNAzyme with strong catalytic activity under near physiological conditions. The enzyme achieves ~65 turnovers in 30 minutes, a feat only previously witnessed by the unmodified parent sequence under forcing conditions of elevated Mg²⁺ and pH. Structural constraints imposed by the chemical modifications drive catalysis toward a highly preferred UGUD motif (cut site underlined) that was validated by positive and negative predictions. Biochemical assays support an autonomous RNA cleavage mechanism independent of RNase H1 engagement. Consistent with its strong catalytic activity, the enzyme exhibits persistent allele-specific knock-down of an endogenous mRNA encoding an undruggable oncogenic KRAS target. Together, these results demonstrate that chemical evolution offers a powerful approach for discovering new chemotype combinations that can imbue DNAzymes with the physicochemical properties necessary to support therapeutic applications.

Amplification-Free COVID-19 Detection by Digital Droplet REVEALR

The COVID-19 pandemic, caused by the SARS-CoV-2 virus, exposed a pressing need for new public health tools for pathogen detection, disease diagnosis, and viral genotyping. REVEALR (RNA-encoded viral nucleic acid analyte reporter) is an isothermal DNAzyme-based point-of-care diagnostic that functions with a detection limit of ∼10 copies/μL when coupled with a preamplification step and can be utilized for viral genotyping of SARS-CoV-2 variants of concern through base pair mismatch recognition in a competitive binding format. Here, we describe an advanced REVEALR platform, termed digital droplet REVEALR (ddREVEALR), that can achieve direct viral detection and absolute sample quantitation utilizing a signal amplification strategy that relies on chemical modifications, DNAzyme multiplexing, and volume compression. Using an AI-assisted image-based readout, ddREVEALR was found to achieve 95% positive predictive agreement from a set of 20 nasal pharyngeal swabs collected at UCI Medical Center in Orange, California. We propose that the combination of amplification-free and protein-free analysis makes ddREVEALR a promising application for direct viral RNA detection of clinical samples.

REVEALR-Based Genotyping of SARS-CoV-2 Variants of Concern in Clinical Samples

The SARS-CoV-2 virus has evolved into new strains that increase viral transmissibility and reduce vaccine protection. The rapid circulation of these more harmful strains across the globe has created a pressing need for alternative public health screening tools. REVEALR (RNA-encoded viral nucleic acid analytic reporter), a rapid and highly sensitive DNAzyme-based detection system, functions with perfect accuracy against patient-derived clinical samples. Here, we design REVEALR into a novel genotyping assay that detects single-base mismatches corresponding to each of the major SARS-CoV-2 strains found in the United States. Of 34 sequence-verified patient samples collected in early, mid, and late 2021 at the UCI Medical Center in Orange, California, REVEALR identified the correct variant [Wuhan-Hu-1, alpha (B.1.1.7), gamma (P.1), epsilon (B.1.427/9), delta (B.1.617.2), and omicron (B.1.1.529)] with 100% accuracy. The assay, which is programmable and amenable to multiplexing, offers an important new approach to personalized diagnostics.

Evolution of Functionally Enhanced α-l-Threofuranosyl Nucleic Acid Aptamers

Synthetic genetic polymers (xeno-nucleic acids, XNAs) have the potential to transition aptamers from laboratory tools to therapeutic agents, but additional functionality is needed to compete with antibodies. Here, we describe the evolution of a biologically stable artificial genetic system composed of α-l-threofuranosyl nucleic acid (TNA) that facilitates the production of backbone- and base-modified aptamers termed "threomers" that function as high quality protein capture reagents. Threomers were discovered against two prototypical protein targets implicated in human diseases through a combination of in vitro selection and next-generation sequencing using uracil nucleotides that are uniformly equipped with aromatic side chains commonly found in the paratope of antibody-antigen crystal structures. Kinetic measurements reveal that the side chain modifications are critical for generating threomers with slow off-rate binding kinetics. These findings expand the chemical space of evolvable non-natural genetic systems to include functional groups that enhance protein target binding by mimicking the structural properties of traditional antibodies.

Transliteration of synthetic genetic enzymes

Functional nucleic acids lose activity when their sequence is prepared in the backbone architecture of a different genetic polymer. The only known exception to this rule is a subset of aptamers whose binding mechanism involves G-quadruplex formation. We refer to such examples as transliteration-a synthetic biology concept describing cases in which the phenotype of a nucleic acid molecule is retained when the genotype is written in a different genetic language. Here, we extend the concept of transliteration to include nucleic acid enzymes (XNAzymes) that mediate site-specific cleavage of an RNA substrate. We show that an in vitro selected 2'-fluoroarabino nucleic acid (FANA) enzyme retains catalytic activity when its sequence is prepared as α-l-threofuranosyl nucleic acid (TNA), and vice versa, a TNA enzyme that remains functional when its sequence is prepared as FANA. Structure probing with DMS supports the hypothesis that FANA and TNA enzymes having the same primary sequence can adopt similarly folded tertiary structures. These findings provide new insight into the sequence-structure-function paradigm governing biopolymer folding.

Synthesis and Polymerase Recognition of Threose Nucleic Acid Triphosphates Equipped with Diverse Chemical Functionalities

Expanding the chemical space of evolvable non-natural genetic polymers (XNAs) to include functional groups that enhance protein target binding affinity offers a promising route to therapeutic aptamers with high biological stability. Here we describe the chemical synthesis and polymerase recognition of 10 chemically diverse functional groups introduced at the C-5 position of α-l-threofuranosyl uridine nucleoside triphosphate (tUTP). We show that the set of tUTP substrates is universally recognized by the laboratory-evolved polymerase Kod-RSGA. Insights into the mechanism of TNA synthesis were obtained from a high-resolution X-ray crystal structure of the postcatalytic complex bound to the primer-template duplex. A structural analysis reveals a large cavity in the enzyme active site that can accommodate the side chain of C-5-modified tUTP substrates. Our findings expand the chemical space of evolvable nucleic acid systems by providing a synthetic route to artificial genetic polymers that are uniformly modified with diversity-enhancing functional groups.

Abstract 2332: Modifying bioavailability of ATP and measuring metabolic response in HeLa cells

Introduction: Since studies by Otto Warburg demonstrated that cancer cells had markedly reduced oxidative phosphorylation (OXPHOS) under conditions of high oxygen tension (Warburg Effect/aerobic glycolysis), metabolic reprogramming has become a fundamental hallmark of cancer. While numerous discoveries have revealed highly specific metabolic differences between cancer cells, utilization of aerobic glycolysis as the primary means of ATP generation remains one of the most common metabolic alterations observed across a range of cancers. There is growing interest in understanding the multifaceted role ATP plays in cancer development, progression and chemotherapeutic resistance. Using the man-made protein DX, which chelates ATP with high specificity and affinity, we have begun to untangle these roles by significantly reducing cytosolic ATP and investigating cellular response.

Hypothesis: Delivery of DX into HeLa cancer cells will reduce intracellular bioavailable ATP and induce an adaptive metabolic response.

Methods: A cationic lipid mixture was complexed with active, purified DX protein to generate a DX/lipid complex capable of delivering the protein to the cytoplasm of HeLa cells. To confirm the successful delivery of DX, immunofluorescent microscopy was performed (DYKDDDDK tag monoclonal antibody, Alexa Fluor 647) at various time points following DX transfection. The impact of DX on cell viability was determined using a tetrazolium-based colorimetric cell viability assay and a caspase 3/7 assay. To correlate phenotypic/viability change with DX activity, bioavailable ATP levels were measured at specific time points following DX delivery. Additionally, the relative contribution of glycolysis and OXPHOS to the total ATP production rate was measured using the label-free XF Real Time ATP Rate Assay (XFe96 Seahorse, Agilent Technologies) over time post DX transfection.

Results: In a time- and dose- dependent manner, DX negatively impacted cell growth and induced cell death via apoptosis, at a time concomitant with a decrease in bioavailable ATP. In response to DX over time, the total ATP production rates in HeLa cells significantly decreased. Importantly, this reduction in the rate of ATP production was associated with a metabolic program that was primarily glycolytic (70%) with a smaller contribution from OXPHOS (30%) 24 h post DX transfection.

Conclusion: Advances in protein engineering have made it possible to create artificial proteins with specific functions. In addition to direct clinical applications, synthetic proteins can be developed into powerful experimental tools to resolve biological enigmas. Direct delivery of DX potentiated energy flux in HeLa cells in an unbiased manner, independent of metabolic pathway interference. This work establishes DX as a useful tool for examination of cancer cell metabolism in response to ATP stress.

Citation Format: Taha Muhammad, Ashley Brown, Selina Martinez, John C. Chaput, Jeffrey Norris, Shaleen Korch. Modifying bioavailability of ATP and measuring metabolic response in HeLa cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2021; 2021 Apr 10-15 and May 17-21. Philadelphia (PA): AACR; Cancer Res 2021;81(13_Suppl):Abstract nr 2332.

REVEALR: A Multicomponent XNAzyme-Based Nucleic Acid Detection System for SARS-CoV-2

Isothermal amplification strategies capable of rapid, inexpensive, and accurate nucleic acid detection provide new options for large-scale pathogen detection, disease diagnosis, and genotyping. Here we report a highly sensitive multicomponent XNA-based nucleic acid detection platform that combines analyte preamplification with X10-23-mediated catalysis to detect the viral pathogen responsible for COVID-19. The platform, termed RNA-Encoded Viral Nucleic Acid Analyte Reporter (REVEALR), functions with a detection limit of ≤20 aM (∼10 copies/μL) using conventional fluorescence and paper-based lateral flow readout modalities. With a total assay time of 1 h, REVEALR provides a convenient nucleic acid alternative to equivalent CRISPR-based approaches, which have become popular methods for SARS-CoV-2 detection. The assay shows no cross-reactivity for other in vitro transcribed respiratory viral RNAs and functions with perfect accuracy against COVID-19 patient-derived clinical samples.

Functional Comparison of Laboratory-Evolved XNA Polymerases for Synthetic Biology

Artificial genetic polymers (XNAs) have enormous potential as new materials for synthetic biology, biotechnology, and molecular medicine; yet, very little is known about the biochemical properties of XNA polymerases that have been developed to synthesize and reverse-transcribe XNA polymers. Here, we compare the substrate specificity, thermal stability, reverse transcriptase activity, and fidelity of laboratory-evolved polymerases that were established to synthesize RNA, 2'-fluoroarabino nucleic acid (FANA), arabino nucleic acid (ANA), hexitol nucleic acid (HNA), threose nucleic acid (TNA), and phosphonomethylthreosyl nucleic acid (PMT). We find that the mutations acquired to facilitate XNA synthesis increase the tolerance of the enzymes for sugar-modified substrates with some sacrifice to protein-folding stability. Bst DNA polymerase was found to have weak reverse transcriptase activity on ANA and uncontrolled reverse transcriptase activity on HNA, differing from its known recognition of FANA and TNA templates. These data benchmark the activity of current XNA polymerases and provide opportunities for generating new polymerase variants that function with greater activity and substrate specificity.

Following replicative DNA synthesis by time-resolved X-ray crystallography

The mechanism of DNA synthesis has been inferred from static structures, but the absence of temporal information raises longstanding questions about the order of events in one of life's most central processes. Here we follow the reaction pathway of a replicative DNA polymerase using time-resolved X-ray crystallography to elucidate the order and transition between intermediates. In contrast to the canonical model, the structural changes observed in the time-lapsed images reveal a catalytic cycle in which translocation precedes catalysis. The translocation step appears to follow a push-pull mechanism where the O-O1 loop of the finger subdomain acts as a pawl to facilitate unidirectional movement along the template with conserved tyrosine residues 714 and 719 functioning as tandem gatekeepers of DNA synthesis. The structures capture the precise order of critical events that may be a general feature of enzymatic catalysis among replicative DNA polymerases.

Allele-Specific RNA Knockdown with a Biologically Stable and Catalytically Efficient XNAzyme

Therapeutic targeting of allele-specific single nucleotide mutations in RNA is a major challenge in biology and medicine. Herein, we describe the utility of the XNAzyme X10-23 to knock down allele-specific mRNA sequences in cells. We demonstrate the value of this approach by targeting the "undruggable" mutation G12V in oncogenic KRAS. Our results demonstrate how catalytic XNAs could be employed to suppress the expression of mRNAs carrying disease-causing mutations that are difficult to target at the protein level with small molecule therapeutics.

Redesigning the Genetic Polymers of Life

Genomes can be viewed as constantly updated memory systems where information propagated in cells is refined over time by natural selection. This process, commonly known as heredity and evolution, has been the sole domain of DNA since the origin of prokaryotes. Now, some 3.5 billion years later, the pendulum of discovery has swung in a new direction, with carefully trained practitioners enabling the replication and evolution of "xeno-nucleic acids" or "XNAs"-synthetic genetic polymers in which the natural sugar found in DNA and RNA has been replaced with a different type of sugar moiety. XNAs have attracted significant attention as new polymers for synthetic biology, biotechnology, and medicine because of their unique physicochemical properties that may include increased biological stability, enhanced chemical stability, altered helical geometry, or even elevated thermodynamics of Watson-Crick base pairing.This Account describes our contribution to the field of synthetic biology, where chemical synthesis and polymerase engineering have allowed my lab and others to extend the concepts of heredity and evolution to synthetic genetic polymers with backbone structures that are distinct from those found in nature. I will begin with a discussion of α-l-threofuranosyl nucleic acid (TNA), a specific type of XNA that was chosen as a model system to represent any XNA system. I will then proceed to discuss advances in organic chemistry that were made to enable the synthesis of gram quantities of TNA phosphoramidites and nucleoside triphosphates, the monomers used for solid-phase and polymerase-mediated TNA synthesis, respectively. Next, I will recount our development of droplet-based optical sorting (DrOPS), a single-cell microfluidic technique that was established to evolve XNA polymerases in the laboratory. This section will conclude with structural insights that have been gained by solving X-ray crystal structures of a laboratory-evolved TNA polymerase and a natural DNA polymerase that functions with general reverse transcriptase activity on XNA templates.The final passage of this Account will examine the role that XNAs have played in synthetic biology by highlighting examples in which engineered polymerases have enabled the evolution of biologically stable affinity reagents (aptamers) and catalysts (XNAzymes) as well as the storage and retrieval of binary information encoded in electronic word and picture file formats. Because these examples provide only a glimpse of what the future may have in store for XNA, I will conclude the Account with my thoughts on how synthetic genetic polymers could help drive new innovations in synthetic biology and molecular medicine.

Structural interpretation of the effects of threo-nucleotides on nonenzymatic template-directed polymerization

The prebiotic synthesis of ribonucleotides is likely to have been accompanied by the synthesis of noncanonical nucleotides including the threo-nucleotide building blocks of TNA. Here, we examine the ability of activated threo-nucleotides to participate in nonenzymatic template-directed polymerization. We find that primer extension by multiple sequential threo-nucleotide monomers is strongly disfavored relative to ribo-nucleotides. Kinetic, NMR and crystallographic studies suggest that this is due in part to the slow formation of the imidazolium-bridged TNA dinucleotide intermediate in primer extension, and in part because of the greater distance between the attacking RNA primer 3'-hydroxyl and the phosphate of the incoming threo-nucleotide intermediate. Even a single activated threo-nucleotide in the presence of an activated downstream RNA oligonucleotide is added to the primer 10-fold more slowly than an activated ribonucleotide. In contrast, a single activated threo-nucleotide at the end of an RNA primer or in an RNA template results in only a modest decrease in the rate of primer extension, consistent with the minor and local structural distortions revealed by crystal structures. Our results are consistent with a model in which heterogeneous primordial oligonucleotides would, through cycles of replication, have given rise to increasingly homogeneous RNA strands.

Reading and Writing Digital Information in TNA

DNA has become a popular soft material for low energy, high-density information storage, but it is susceptible to damage through oxidation, pH, temperature, and nucleases in the environment. Here, we describe a new molecular chemotype for data archiving based on the unnatural genetic framework of α-l-threofuranosyl nucleic acid (TNA). Using a simple genetic coding strategy, 23 kilobytes of digital information were stored in DNA-primed TNA oligonucleotides and recovered with perfect accuracy after exposure to biological nucleases that destroyed equivalent DNA messages. We suggest that these results extend the capacity for nucleic acids to function as a soft material for low energy, high-density information storage by providing a safeguard against information loss caused by nuclease digestion.

Programmed Allelic Mutagenesis of a DNA Polymerase with Single Amino Acid Resolution

Most DNA polymerase libraries sample unknown portions of mutational space and are constrained by the limitations of random mutagenesis. Here we describe a programmed allelic mutagenesis (PAM) strategy to comprehensively evaluate all possible single-point mutations in the entire catalytic domain of a replicative DNA polymerase. By applying the PAM strategy with ultrafast high-throughput screening, we show how DNA polymerases can be mapped for allelic mutations that exhibit enhanced activity for unnatural nucleic acid substrates. We suggest that comprehensive missense mutational scans may aid the discovery of specificity determining residues that are necessary for reprogramming the biological functions of natural DNA polymerases.

Synthesis and polymerase recognition of a pyrrolocytidine TNA triphosphate

Synthetic genetics is an area of synthetic biology that aims to extend the properties of heredity and evolution to artificial genetic polymers, commonly known as xeno-nucleic acids or XNAs. In addition to establishing polymerases that are able to convert genetic information back and forth between DNA and XNA, efforts are underway to construct XNAs with expanded chemical functionality. α-L-Threose nucleic acid (TNA), a type of XNA that is recalcitrant to nuclease digestion and amenable to Darwinian evolution, provides a model system for developing XNAs with functional groups that are not present in natural DNA and RNA. Here, we describe the synthesis and polymerase activity of a cytidine TNA triphosphate analog (6-phenyl-pyrrolocytosine, tC^p TP) that maintains Watson-Crick base pairing with guanine. Polymerase-mediated primer extension assays show that tC^p TP is an efficient substrate for Kod-RI, a DNA-dependent TNA polymerase developed to explore the functional properties of TNA by in vitro selection. Fidelity studies reveal that a cycle of TNA synthesis and reverse transcription occurs with 99.9% overall fidelity when tC^p TP and 7-deaza-tGTP are present as TNA substrates. This result expands the toolkit of TNA building blocks available for in vitro selection.

Directed evolution of custom polymerases using droplet microfluidics

DNA polymerases are critical tools for a large number of emerging applications in biotechnology, but oftentimes polymerases with desired functions are not readily available. Directed evolution provides a possible solution to this problem by enabling the creation of engineered polymerases that are better equipped to recognize a given unnatural substrate. Here we report a microfluidic-based method for evolving new polymerase functions that involves ultrahigh throughput sorting of fluorescent water-in-oil (w/o) microdroplets. The workflow entails the expression of a diverse population of polymerase variants in E. coli, production of microfluidic droplets containing one or less E. coli, bacteria lysis to release the polymerase and encoding plasmid into the surrounding droplet, a fluorescence-based activity assay to identify variants with a desired activity, isolation of fluorescent droplets using a fluorescence activated droplet sorting (FADS) device, and plasmid recovery with DNA sequencing to determine the identity of the functional variants. This technique is amenable to any type of unnatural nucleic acid and/or polymerase function, including DNA-templated synthesis, reverse transcription, and replication.

Generating Biologically Stable TNA Aptamers that Function with High Affinity and Thermal Stability

Aptamers are often prone to nuclease digestion, which limits their utility in many biomedical applications. Here we describe a xeno-nucleic acid system based on α-l-threofuranosyl nucleic acid (TNA) that is completely refractory to nuclease digestion. The use of an engineered TNA polymerase permitted the isolation of functional TNA aptamers that bind to HIV reverse transcriptase (HIV RT) with K_D's of ∼0.4-4.0 nM. The aptamers were identified using a display strategy that provides a powerful genotype-phenotype linkage. The TNA aptamers remain active in the presence of nuclease and exhibit markedly higher thermal stability than monoclonal antibodies. The combined properties of biological stability, high binding affinity, and thermal stability make TNA aptamers a powerful system for the development of diagnostic and therapeutic agents.

Orthogonal Genetic Systems

Xenobiology is an emerging area of synthetic biology that aims to safeguard genetically engineered cells by storing synthetic biology information in xeno-nucleic acid polymers (XNAs). Critical to the success of this effort is the need to establish cellular systems that can maintain an XNA chromosome in actively dividing cells. This viewpoint discusses the structural parameters of the nucleic acid backbone that should be considered when designing an orthogonal genetic system that can replicate without interference from the endogenous genome. In addition to practical value, these studies have the potential to provide new fundamental insight into the structure and function properties of unnatural nucleic acid polymers.

Crystal structures of a natural DNA polymerase that functions as an XNA reverse transcriptase

Replicative DNA polymerases are highly efficient enzymes that maintain stringent geometric control over shape and orientation of the template and incoming nucleoside triphosphate. In a surprising twist to this paradigm, a naturally occurring bacterial DNA polymerase I member isolated from Geobacillus stearothermophilus (Bst) exhibits an innate ability to reverse transcribe RNA and other synthetic congeners (XNAs) into DNA. This observation raises the interesting question of how a replicative DNA polymerase is able to recognize templates of diverse chemical composition. Here, we present crystal structures of natural Bst DNA polymerase that capture the post-translocated product of DNA synthesis on templates composed entirely of 2′-deoxy-2′-fluoro-β-d-arabino nucleic acid (FANA) and α-l-threofuranosyl nucleic acid (TNA). Analysis of the enzyme active site reveals the importance of structural plasticity as a possible mechanism for XNA-dependent DNA synthesis and provides insights into the construction of variants with improved activity.

Evaluating the Catalytic Potential of a General RNA-Cleaving FANA Enzyme

The discovery of synthetic genetic polymers (XNAs) with catalytic activity demonstrates that natural genetic polymers are not unique in their ability to function as enzymes. However, all known examples of in vitro selected XNA enzymes function with lower activity than their natural counterparts, suggesting that XNAs might be limited in their ability to fold into structures with high catalytic activity. To explore this problem, we evaluated the catalytic potential of FANAzyme 12-7, an RNA-cleaving catalyst composed entirely of 2'-fluoroarabino nucleic acid (FANA) that was evolved to cleave RNA at a specific phosphodiester bond located between an unpaired guanine and a paired uracil in the substrate recognition arm. Here, we show that this activity extends to chimeric DNA substrates that contain a central riboguanosine (riboG) residue at the cleavage site. Surprisingly, FANAzyme 12-7 rivals known DNAzymes that were previously evolved to cleave chimeric DNA substrates under physiological conditions. These data provide convincing evidence that FANAzyme 12-7 maintains the catalytic potential of equivalent DNAzymes, which has important implications for the evolution of XNA catalysts and their contributions to future applications in synthetic biology.

P(V) Reagents for the Scalable Synthesis of Natural and Modified Nucleoside Triphosphates

Natural and modified nucleoside triphosphates impact nearly every major aspect of healthcare research from DNA sequencing to drug discovery. However, a scalable synthetic route to these molecules has long been hindered by the need for purification by high performance liquid chromatography (HPLC). Here, we describe a fundamentally different approach that uses a novel P(V) pyrene pyrophosphate reagent to generate derivatives that are purified by silica gel chromatography and converted to the desired compounds on scales vastly exceeding those achievable by HPLC. The power of this approach is demonstrated through the synthesis of a broad range of natural and unnatural nucleoside triphosphates (dNTPs and xNTPs) using protocols that are efficient, inexpensive, and operationally straightforward.

Fluorescence-Activated Droplet Sorting for Single-Cell Directed Evolution

Synthetic biology aims to improve human health and the environment by repurposing biological enzymes for use in practical applications. However, natural enzymes often function with suboptimal activity when engineered into biological pathways or challenged to recognize unnatural substrates. Overcoming this problem requires efficient directed evolution methods for discovering new enzyme variants that function with a desired activity. Here, we describe the construction, validation, and application of a fluorescence-activated droplet sorting (FADS) instrument that was established to evolve enzymes for synthesizing and modifying artificial genetic polymers (XNAs). The microfluidic system enables droplet sorting at ∼2-3 kHz using fluorescent sensors that are responsive to enzymatic activity. The ability to evolve nucleic acid enzymes with customized properties will uniquely drive emerging applications in synthetic biology, biotechnology, and healthcare.

Elucidating the Determinants of Polymerase Specificity by Microfluidic-Based Deep Mutational Scanning

Engineering polymerases to synthesize artificial genetic polymers with unique backbone structures is limited by a general lack of understanding about the structural determinants that govern substrate specificity. Here, we report a high-throughput microfluidic-based approach for mapping sequence-function relationships that combines droplet-based optical polymerase sorting with deep mutational scanning. We applied this strategy to map the finger subdomain of a replicative DNA polymerase isolated from Thermococcus kodakarensis (Kod). The enrichment profile provides an unbiased view of the ability of each mutant to synthesize threose nucleic acid, which was used as a model non-natural genetic polymer. From a single round of sorting, we discovered two cases of positive epistasis and demonstrate the near inversion of substrate specificity from a double mutant variant. This effort indicates that polymerase specificity may be governed by a small number of highly specific residues that can be elucidated by deep mutational scanning without the need for iterative rounds of directed evolution.

RNA-Catalyzed Polymerization of Deoxyribose, Threose, and Arabinose Nucleic Acids

An RNA-dependent RNA polymerase ribozyme that was highly optimized through in vitro evolution for the ability to copy a broad range of template sequences exhibits promiscuity toward other nucleic acids and nucleic acid analogues, including DNA, threose nucleic acid (TNA), and arabinose nucleic acid (ANA). By operating on various RNA templates, the ribozyme catalyzes multiple successive additions of DNA, TNA, or ANA monomers, although with reduced efficiency compared to RNA monomers. The ribozyme can also copy DNA or TNA templates to complementary RNAs, and to a lesser extent it can operate when both the template and product strands are composed of DNA, TNA, or ANA. These results suggest that polymerase ribozymes, which are thought to have replicated RNA genomes during the early history of life, could have transferred RNA-based genetic information to and from DNA, enabling the emergence of DNA genomes prior to the emergence of proteins. In addition, genetic systems based on nucleic acid-like molecules, which have been proposed as precursors or contemporaries of RNA-based life, could have been operated upon by a promiscuous polymerase ribozyme, thus enabling the evolutionary transition between early genetic systems.

Ligase-Mediated Threose Nucleic Acid Synthesis on DNA Templates

Ligases are a class of enzymes that catalyze the formation of phosphodiester bonds between an oligonucleotide donor with a 5' terminal phosphate and an oligonucleotide acceptor with a 3' terminal hydroxyl group. Here, we wished to explore the substrate specificity of naturally occurring DNA and RNA ligases to determine whether the molecular recognition of these enzymes is sufficiently general to synthesize alternative genetic polymers with backbone structures that are distinct from those found in nature. We chose threose nucleic acid (TNA) as a model system, as TNA is known to be biologically stable and capable of undergoing Darwinian evolution. Enzyme screening and reaction optimization identified several ligases that can recognize TNA as either the donor or acceptor strand with DNA. Less discrimination occurs on the acceptor strand indicating that the determinants of substrate specificity depend primarily on the composition of the donor strand. Remarkably, T3 and T7 ligases were able to join TNA homopolymers together, which is surprising given that the TNA backbone is one atom shorter than that of DNA. In this reaction, the base composition of the ligation junction strongly favors the formation of A-T and A-G linkages. We suggest that these results will enable the assembly of TNA oligonucleotides of lengths beyond what is currently possible by solid-phase synthesis and provide a starting point for further optimization by directed evolution.

Activation of Innate Immune Responses by a CpG Oligonucleotide Sequence Composed Entirely of Threose Nucleic Acid

Recent advances in synthetic biology have led to the development of nucleic acid polymers with backbone structures distinct from those found in nature, termed xeno-nucleic acids (XNAs). Several unique properties of XNAs make them attractive as nucleic acid therapeutics, most notably their high resistance to serum nucleases and ability to form Watson-Crick base pairing with DNA and RNA. The ability of XNAs to induce immune responses has not been investigated. Threose nucleic acid (TNA), a type of XNA, is recalcitrant to nuclease digestion and capable of undergoing Darwinian evolution to produce high affinity aptamers; thus, TNA is an attractive candidate for diverse applications, including nucleic acid therapeutics. In this study, we evaluated a TNA oligonucleotide derived from a cytosine-phosphate-guanine oligonucleotide sequence known to activate toll-like receptor 9-dependent immune signaling in B cell lines. We observed a slight induction of relevant mRNA signals, robust B cell line activation, and negligible effects on cellular proliferation.

Evolution of a General RNA-Cleaving FANA Enzyme

The isolation of synthetic genetic polymers (XNAs) with catalytic activity demonstrates that catalysis is not limited to natural biopolymers, but it remains unknown whether such systems can achieve robust catalysis with Michaelis-Menten kinetics. Here, we describe an efficient RNA-cleaving 2'-fluoroarabino nucleic acid enzyme (FANAzyme) that functions with a rate enhancement of >10⁶-fold over the uncatalyzed reaction and exhibits substrate saturation kinetics typical of most natural enzymes. The FANAzyme was generated by in vitro evolution using natural polymerases that were found to recognize FANA substrates with high fidelity. The enzyme comprises a small 25 nucleotide catalytic domain flanked by substrate-binding arms that can be engineered to recognize diverse RNA targets. Substrate cleavage occurs at a specific phosphodiester bond located between an unpaired guanine and a paired uracil in the substrate recognition arm. Our results expand the chemical space of nucleic acid enzymes to include nuclease-resistant scaffolds with strong catalytic activity.

Exploring the Role of AUG Triplets in Human Cap-Independent Translation Enhancing Elements

Cap-independent translation is believed to play an important role in eukaryotic protein synthesis, but the mechanisms of ribosomal recruitment and translation initiation remain largely unknown. Messenger RNA display was previously used to profile the human genome for RNA leader sequences that can enhance cap-independent translation. Surprisingly, many of the isolated sequences contain AUG triplets, suggesting a possible functional role for these motifs during translation initiation. Herein, we examine the sequence determinants of AUG triplets within a set of human translation enhancing elements (TEEs). Functional analyses performed in vitro and in cultured cells indicate that AUGs have the capacity to modulate mRNA translation either by serving as part of a larger ribosomal recruitment site or by directing the ribosome to defined initiation sites. These observations help constrain the functional role of AUG triplets in human TEEs and advance our understanding of this specific mechanism of cap-independent translation initiation.

Crystal structures of DNA polymerase I capture novel intermediates in the DNA synthesis pathway

High resolution crystal structures of DNA polymerase intermediates are needed to study the mechanism of DNA synthesis in cells. Here we report five crystal structures of DNA polymerase I that capture new conformations for the polymerase translocation and nucleotide pre-insertion steps in the DNA synthesis pathway. We suggest that these new structures, along with previously solved structures, highlight the dynamic nature of the finger subdomain in the enzyme active site.

DNA molecules consist of two separate strands that spiral around each other to form a structure called the double helix. Each strand contains repeating units, with every unit consisting of a phosphate group and a sugar molecule bound to one of four bases. The two strands are held together by bonds between the bases.

When a cell divides, it needs to make a copy of the DNA, so that each new cell will have an exact replica from the old cell. During this process, the helix unwinds and enzymes called polymerases produce new strands (using the old ones as a template). Each strand is copied by adding new bases one at a time. Every time a new base is added, the polymerases must modify their structures several times. If this process becomes faulty, it can lead to various diseases, including cancer.

Scientist often use a technique called X-ray crystallography to study intermediate structures of frozen polymerase crystals as the enzyme constructs DNA. Yet, to fully understand the mechanisms of DNA synthesis all intermediate structures need to be identified.

Now, Chim, Jackson et al. used a particular method for making frozen polymerase crytals by allowing the enzyme to add new bases in liquid form. The reaction was then frozen and X-ray crystallography was used to take images. This modified method captured different steps in the process and detailed how the enzyme adjusts its structure as it moves along the template strand.

The intermediate structures that Chim, Jackson et al. uncovered may help scientists develop new biotechnologies and medicines. Understanding how polymerases modify their form while making DNA copies could lead to better therapies for diseases in which this process has become faulty, like cancer.

Abstract 452: Direct delivery of a synthetic ATP binding protein reduces ATP and induces apoptosis in Hela cells

Introduction: Reprogramming of cellular metabolism is a hallmark characteristic of cancer cells. As opposed to normal cells, which generate most of their adenine triphosphate (ATP) through oxidative phosphorylation, cancer cells generate ATP less efficiently by aerobic glycolysis (Warburg effect). In addition to deciphering metabolic switches, there is growing interest in understanding the multifaceted role ATP plays in cancer development, progression and chemotherapeutic resistance. One approach to untangling these roles is to significantly reduce intracellular ATP and investigate the cellular response. With that, we designed and created a man-made protein that chelates ATP with high specificity and affinity. This synthetic protein, called DX, has been genetically expressed in a living organism, Escherichia coli, where it reduced intracellular ATP to below the levels of detection. Hypothesis: Delivery of the DX protein into HeLa cancer cells will reduce intracellular bioavailable ATP affecting energy metabolism, viability and drug susceptibility. Methods: A cationic lipid mixture was complexed with active, purified DX protein to generate a DX/lipid complex. The integrity of the complexed protein was verified by western blot analysis. HeLa cells were incubated with the DX/lipid complex to allow efficient delivery of DX into the cytoplasm of the HeLa cells. The impact of DX on cell viability was determined using a tetrazolium-based colorimetric cell viability assay and a caspase 3/7 assay. To correlate phenotypic/viability change with DX activity, bioavailable ATP levels were measured at specific time points following DX delivery. To establish whether DX impacts drug export, the retention of calcein-AM, a substrate of the ATP-dependent p-glycoprotein pump, was measured post DX-delivery. Results: Western blot analysis confirmed the stability of DX prior to- and post- delivery to HeLa cells. In a time- and dose- dependent manner, DX negatively impacted cell growth and induced cell death via apoptosis, at a time concomitant with a decrease in bioavailable ATP. Significantly, HeLa cells treated with DX retained calcein-AM, suggesting reduced p-glycoprotein activity. Conclusion: Advances in protein engineering have made it possible to create artificial proteins with specific functions. In addition to direct clinical applications, synthetic proteins are powerful tools that have the potential to reveal something new about biology. Direct delivery of a synthetic ATP-binding protein potentiated apoptosis in HeLa cells contemporaneous with reduced intracellular ATP. Having established DX activity in a living system, future studies will examine the cancer cell metabolome in response to significant ATP stress. Finally, a reduction in p-glycoprotein activity in DX-treated HeLa cells advocates examination of concurrent DX/chemotherapeutic treatment, principally in drug resistant scenarios.

Citation Format: Selina M. Martinez, Shanika Kingston, Arlene Ngor, John C. Chaput, Nagaraj J. Vinay, Shaleen B. Korch. Direct delivery of a synthetic ATP binding protein reduces ATP and induces apoptosis in Hela cells [abstract]. In: Proceedings of the American Association for Cancer Research Annual Meeting 2018; 2018 Apr 14-18; Chicago, IL. Philadelphia (PA): AACR; Cancer Res 2018;78(13 Suppl):Abstract nr 452.

Visualizing primer extension without enzymes

X-ray crystallography has been used to observe the synthesis of RNA in the absence of enzymes with atomic resolution.

Synthesis and Evolution of a Threose Nucleic Acid Aptamer Bearing 7-Deaza-7-Substituted Guanosine Residues

In vitro selection experiments carried out on artificial genetic polymers require robust and faithful methods for copying genetic information back and forth between DNA and xeno-nucleic acids (XNA). Previously, we have shown that Kod-RI, an engineered polymerase developed to transcribe DNA templates into threose nucleic acid (TNA), can function with high fidelity in the absence of manganese ions. However, the transcriptional efficiency of this enzyme diminishes greatly when individual templates are replaced with libraries of DNA sequences, indicating that manganese ions are still required for in vitro selection. Unfortunately, the presence of manganese ions in the transcription mixture leads to the misincorporation of tGTP nucleotides opposite dG residues in the templating strand, which are detected as G-to-C transversions when the TNA is reverse transcribed back into DNA. Here we report the synthesis and fidelity of TNA replication using 7-deaza-7-modified guanosine base analogues in the DNA template and incoming TNA nucleoside triphosphate. Our findings reveal that tGTP misincorporation occurs via a Hoogsteen base pair in which the incoming tGTP residue adopts a syn conformation with respect to the sugar. Substitution of tGTP for 7-deaza-7-phenyl tGTP enabled the synthesis of TNA polymers with >99% overall fidelity. A TNA library containing the 7-deaza-7-phenyl guanine analogue was used to evolve a biologically stable TNA aptamer that binds to HIV reverse transcriptase with low nanomolar affinity.

Expanding the chemical diversity of TNA with tUTP derivatives that are substrates for a TNA polymerase

Expanding the chemical diversity of threose nucleic acid (TNA) beyond the natural bases would enable the development of TNA polymers with enhanced physicochemical properties. Here, we describe a versatile approach for increasing the chemical diversity of TNA using 5-alkynyl-modified α-l-threofuranosyl uridine triphosphates that are substrates for a TNA polymerase.

A Tool for the Import of Natural and Unnatural Nucleoside Triphosphates into Bacteria

Nucleoside triphosphates play a central role in biology, but efforts to study these roles have proven difficult because the levels of triphosphates are tightly regulated in a cell and because individual triphosphates can be difficult to label or modify. In addition, many synthetic biology efforts are focused on the development of unnatural nucleoside triphosphates that perform specific functions in the cellular environment. In general, both of these efforts would be facilitated by a general means to directly introduce desired triphosphates into cells. Previously, we demonstrated that recombinant expression of a nucleoside triphosphate transporter from Phaeodactylum tricornutum (PtNTT2) in Escherichia coli functions to import triphosphates that are added to the media. Here, to explore the generality and utility of this approach, we report a structure-activity relationship study of PtNTT2. Using a conventional competitive uptake inhibition assay, we characterize the effects of nucleobase, sugar, and triphosphate modification, and then develop an LC-MS/MS assay to directly measure the effects of the modifications on import. Lastly, we use the transporter to import radiolabeled or 2'-fluoro-modified triphosphates and quantify their incorporation into DNA and RNA. The results demonstrate the general utility of the PtNTT2-mediated import of natural or modified nucleoside triphosphates for different molecular or synthetic biology applications.