Daniel Hutter

Artificially expanded genetic information system: a new base pair with an alternative hydrogen bonding pattern

To support efforts to develop a ‘synthetic biology’ based on an artificially expanded genetic information system (AEGIS), we have developed a route to two components of a non-standard nucleobase pair, the pyrimidine analog 6-amino-5-nitro-3-(1′-β-D-2′-deoxyribofuranosyl)-2(1H)-pyridone (dZ) and its Watson–Crick complement, the purine analog 2-amino-8-(1′-β-D-2′-deoxyribofuranosyl)-imidazo[1,2-a]-1,3,5-triazin-4(8H)-one (dP). These implement the pyDDA:puAAD hydrogen bonding pattern (where ‘py’ indicates a pyrimidine analog and ‘pu’ indicates a purine analog, while A and D indicate the hydrogen bonding patterns of acceptor and donor groups presented to the complementary nucleobases, from the major to the minor groove). Also described is the synthesis of the triphosphates and protected phosphoramidites of these two nucleosides. We also describe the use of the protected phosphoramidites to synthesize DNA oligonucleotides containing these AEGIS components, verify the absence of epimerization of dZ in those oligonucleotides, and report some hybridization properties of the dZ:dP nucleobase pair, which is rather strong, and the ability of each to effectively discriminate against mismatches in short duplex DNA.

Reconstructed evolutionary adaptive paths give polymerases accepting reversible terminators for sequencing and SNP detection

Any system, natural or human-made, is better understood if we analyze both its history and its structure. Here we combine structural analyses with a “Reconstructed Evolutionary Adaptive Path” (REAP) analysis that used the evolutionary and functional history of DNA polymerases to replace amino acids to enable polymerases to accept a new class of triphosphate substrates, those having their 3′-OH ends blocked as a 3′-ONH2 group (dNTP-ONH2). Analogous to widely used 2′,3′-dideoxynucleoside triphosphates (ddNTPs), dNTP-ONH2s terminate primer extension. Unlike ddNTPs, however, primer extension can be resumed by cleaving an O-N bond to restore an -OH group to the 3′-end of the primer. REAP combined with crystallographic analyses identified 35 sites where replacements might improve the ability of Taq to accept dNTP-ONH2s. A library of 93 Taq variants, each having replacements at three or four of these sites, held eight variants having improved ability to accept dNTP-ONH2 substrates. Two of these (A597T, L616A, F667Y, E745H, and E520G, K540I, L616A) performed notably well. The second variant incorporated both dNTP-ONH2sand ddNTPs faithfully and efficiently, supporting extension-cleavage-extension cycles applicable in parallel sequencing and in SNP detection through competition between reversible and irreversible terminators. Dissecting these results showed that one replacement (L616A), not previously identified, allows Taq to incorporate both reversible and irreversible terminators. Modeling showed how L616A might open space behind Phe-667, allowing it to move to accommodate the larger 3′-substituent. This work provides polymerases for DNA analyses and shows how evolutionary analyses help explore relationships between structure and function in proteins.

Labeled Nucleoside Triphosphates with Reversibly Terminating Aminoalkoxyl Groups

Nucleoside triphosphates having a 3′-ONH2 blocking group have been prepared with and without fluorescent tags on their nucleobases. DNA polymerases were identified that accepted these, adding a single nucleotide to the 3′-end of a primer in a template-directed extension reaction that then stops. Nitrite chemistry was developed to cleave the 3′-ONH2 group under mild conditions to allow continued primer extension. Extension-cleavage-extension cycles in solution were demonstrated with untagged nucleotides and mixtures of tagged and untagged nucleotides. Multiple extension-cleavage-extension cycles were demonstrated on an Intelligent Bio-Systems Sequencer, showing the potential of the 3′-ONH2 blocking group in “next generation sequencing.”

Recombinase-based isothermal amplification of nucleic acids with self-avoiding molecular recognition systems (SAMRS).

Recombinase polymerase amplification (RPA) is an isothermal method to amplify nucleic acid sequences without the temperature cycling that classical PCR uses. Instead of using heat to denature the DNA duplex, RPA uses recombination enzymes to swap single‐stranded primers into the duplex DNA product; these are then extended using a strand‐displacing polymerase to complete the cycle. Because RPA runs at low temperatures, it never forces the system to recreate base‐pairs following Watson–Crick rules, and therefore it produces undesired products that impede the amplification of the desired product, complicating downstream analysis. Herein, we show that most of these undesired side products can be avoided if the primers contain components of a self‐avoiding molecular recognition system (SAMRS). Given the precision that is necessary in the recombination systems for them to function biologically, it is surprising that they accept SAMRS. SAMRS‐RPA is expected to be a powerful tool within the range of amplification techniques available to scientists.

Autonomous assembly of synthetic oligonucleotides built from an expanded DNA alphabet. Total synthesis of a gene encoding kanamycin resistance.

Summary Background: Many synthetic biologists seek to increase the degree of autonomy in the assembly of long DNA (L-DNA) constructs from short synthetic DNA fragments, which are today quite inexpensive because of automated solid-phase synthesis. However, the low information density of DNA built from just four nucleotide “letters”, the presence of strong (G:C) and weak (A:T) nucleobase pairs, the non-canonical folded structures that compete with Watson–Crick pairing, and other features intrinsic to natural DNA, generally prevent the autonomous assembly of short single-stranded oligonucleotides greater than a dozen or so. Results: We describe a new strategy to autonomously assemble L-DNA constructs from fragments of synthetic single-stranded DNA. This strategy uses an artificially expanded genetic information system (AEGIS) that adds nucleotides to the four (G, A, C, and T) found in standard DNA by shuffling hydrogen-bonding units on the nucleobases, all while retaining the overall Watson–Crick base-pairing geometry. The added information density allows larger numbers of synthetic fragments to self-assemble without off-target hybridization, hairpin formation, and non-canonical folding interactions. The AEGIS pairs are then converted into standard pairs to produce a fully natural L-DNA product. Here, we report the autonomous assembly of a gene encoding kanamycin resistance using this strategy. Synthetic fragments were built from a six-letter alphabet having two AEGIS components, 5-methyl-2’-deoxyisocytidine and 2’-deoxyisoguanosine (respectively S and B), at their overlapping ends. Gaps in the overlapped assembly were then filled in using DNA polymerases, and the nicks were sealed by ligase. The S:B pairs in the ligated construct were then converted to T:A pairs during PCR amplification. When cloned into a plasmid, the product was shown to make Escherichia coli resistant to kanamycin. A parallel study that attempted to assemble similarly sized genes with optimally designed standard nucleotides lacking AEGIS components gave successful assemblies of up to 16 fragments, but generally failed when larger autonomous assemblies were attempted. Conclusion: AEGIS nucleotides, by increasing the information density of DNA, allow larger numbers of DNA fragments to autonomously self-assemble into large DNA constructs. This technology can therefore increase the size of DNA constructs that might be used in synthetic biology.

Incorporation of Multiple Sequential Pseudothymidines by DNA Polymerases and Their Impact on DNA Duplex Structure

Thermal denaturation and circular dichroism studies suggested that multiple (up to 12), sequential pseudothymidines, a representative C-glycoside, do not perturb the structure of a representative DNA duplex. Further, various Family A and B DNA polymerases were found to extend a primer by incorporating four sequential pseudothymidine triphosphates, and then continue the extension to generate full-length product. Detailed studies showed that Taq polymerase incorporated up to five sequential C-glycosides, but not more. These results constrain architectures for sequencing, quantitating, and analyzing DNA analogs that exploit C-glycosides, and define better the challenge of creating a synthetic biology using these with natural polymerases.

Helicase‐Dependent Isothermal Amplification of DNA and RNA by Using Self‐Avoiding Molecular Recognition Systems

Assays that detect DNA or RNA (xNA) are highly sensitive, as small amounts of xNA can be amplified by PCR. Unfortunately, PCR is inconvenient in low‐resource environments, and requires equipment and power that might not be available in these environments. Isothermal procedures, which avoid thermal cycling, are often confounded by primer dimers, off‐target priming, and other artifacts. Here, we show how a “self avoiding molecular recognition system” (SAMRS) eliminates these artifacts and gives clean amplicons in a helicase‐dependent isothermal amplification (SAMRS‐HDA). We also show that incorporating SAMRS into the 3′‐ends of primers facilitates the design and screening of primers for HDA assays. Finally, we show that SAMRS‐HDA can be twofold multiplexed, difficult to achieve with HDA using standard primers. Thus, SAMRS‐HDA is a more versatile approach than standard HDA, with a broader applicability for xNA‐targeted diagnostics and research.

Synthetic Biology for Improved Personalized Medicine

Tools to re-sequence the genomes of individual patients having well described medical histories is the first step required to connect genetic information to diagnosis, prognosis, and treatment. There is little doubt that in the future, genomics will influence the choice of therapies for individual patients based on their specific genetic inheritance, as well as the genetic defects that led to disease. Cost is the principle obstacle preventing the realization of this vision. Unless the interesting parts of a patient genome can be resequenced for less than

Synthesis of Pyrophosphates for In Vitro Selection of Catalytic RNA Molecules

10,000 (as opposed to

Nucleoside analogs to manage sequence divergence in nucleic acid amplification and SNP detection

100,000 or more), it will be difficult to start the discovery process that will enable this vision. While instrumentation and biology are important to reducing costs, the key element to cost-effective personalized genomic sequencing will be new chemical reagents that deliver capabilities that are not available from standard DNA. Scientists at the Foundation for Applied Molecular Evolution and the Westheimer Institute have developed several of these, which will be the topic of this talk..