Chemical modifications to DNA, such as 2' modifications, are expected to increase the biotechnological utility of DNA; however, these modified forms of DNA are limited by their inability to be effectively synthesized by DNA polymerase enzymes. Previous efforts have identified mutant Thermus aquaticus DNA polymerase I (Taq) enzymes capable of recognizing 2'-modified DNA nucleotides. While these mutant enzymes recognize these modified nucleotides, they are not capable of synthesizing full length modified DNA; thus, further engineering is required for these enzymes. Here, we describe comparative biochemical studies that identify useful, but previously uncharacterized, properties of these enzymes; one enzyme, SFM19, is able to recognize a range of 2'-modified nucleotides much wider than that previously examined, including fluoro, azido, and amino modifications. To understand the molecular origins of these differences, we also identify specific amino acids and combinations of amino acids that contribute most to the previously evolved unnatural activity. Our data suggest that a negatively charged amino acid at 614 and mutation of the steric gate residue, E615, to glycine make up the optimal combination for modified oligonucleotide synthesis. These studies yield an improved understanding of the mutational origins of 2'-modified substrate recognition as well as identify SFM19 as the best candidate for further engineering, whether via rational design or directed evolution.
Chemical modifications can enhance the properties of DNA by imparting nuclease resistance and generating more-diverse physical structures. However, native DNA polymerases generally cannot synthesize significant lengths of DNA with modified nucleotide triphosphates. Previous efforts have identified a mutant of DNA polymerase I from Thermus aquaticus DNA (SFM19) as capable of synthesizing a range of short, 2'-modified DNAs; however, it is limited in the length of the products it can synthesize. Here, we rationally designed and characterized ten mutants of SFM19. From this, we identified enzymes with substantially improved activity for the synthesis of 2'F-, 2'OH-, 2'OMe-, and 3'OMe-modified DNA as well as for reverse transcription of 2'OMe DNA. We also evaluated mutant DNA polymerases previously only tested for synthesis for 2'OMe DNA and showed that they are capable of an expanded range of modified DNA synthesis. This work significantly expands the known combinations of modified DNA and Taq DNA polymerase mutants.
Complex carbohydrates shape the gut microbiota, and the collective fermentation of resistant starch by gut microbes positively affects human health through enhanced butyrate production. The keystone species Ruminococcus bromii (Rb) is a specialist in degrading resistant starch; its degradation products are used by other bacteria including Bacteroides thetaiotaomicron (Bt). We analysed the metabolic and spatial relationships between Rb and Bt during potato starch degradation and found that Bt utilizes glucose that is released from Rb upon degradation of resistant potato starch and soluble potato amylopectin. Additionally, we found that Rb produces a halo of glucose around it when grown on solid media containing potato amylopectin and that Bt cells deficient for growth on potato amylopectin (∆sus Bt) can grow within the halo. Furthermore, when these ∆sus Bt cells grow within this glucose halo, they have an elongated cell morphology. This long-cell phenotype depends on the glucose concentration in the solid media: longer Bt cells are formed at higher glucose concentrations. Together, our results indicate that starch degradation by Rb cross-feeds other bacteria in the surrounding region by releasing glucose. Our results also elucidate the adaptive morphology of Bt cells under different nutrient and physiological conditions.
Bilin-binding fluorescent proteins like UnaG–bilirubin are noncovalent ligand-dependent reporters for oxygen-free microscopy but are restricted to blue and far-red fluorescence. Here we describe a high-throughput screening approach to provide a new UnaG–ligand pair that can be excited in the 532 nm green excitation microscopy channel. We identified a novel orange UnaG–ligand pair that maximally emits at 581 nm. Whereas the benzothiazole-based ligand itself is nominally fluorescent, the compound binds UnaG with high affinity (K d = 3 nM) to induce a 2.5-fold fluorescence intensity enhancement and a 10 nm red shift. We demonstrated this pair in the anaerobic fluorescence microscopy of the prevalent gut bacterium Bacteroides thetaiotaomicron and in Escherichia coli. This UnaG–ligand pair can also be coupled to IFP2.0-biliverdin to differentiate cells in mixed-species two-color imaging. Our results demonstrate the versatility of the UnaG ligand-binding pocket and extend the ability to image cells at longer wavelengths in anoxic environments.
DNA Polymerase, which is required for enzymatic DNA synthesis, does not recognize or incorporate 2’ modified substrates although they are useful in a number of biotechnology applications. Through directed evolution, mutant polymerases have been identified with the ability to incorporate 2’ modified substrates; however, they are incapable of full primer extension limiting their use. Here we compare the ability of 5 previously evolved enzymes to extend with 2’OH and 2’OMe modified nucleotides. Comparative studies reveal stark differences in activity amongst previously evolved mutants. In particular, we observe that while all of the enzymes are capable of incorporating a modified nucleotide onto an unmodified primer with moderate to high efficiency, there are significant differences between enzymes in the rate of incorporation of additional modified nucleotides onto the modified primers. Understanding the limitations of modified substrate incorporation, in conjunction with other mutant polymerase characterization currently being done, will help guide future endeavors to rationally design mutant polymerases that can overcome these extension limitations.
Mutant Taq DNA Polymerases with the ability to recognize modified nucleotides at the 2’ sugar position have been isolated through directed evolution; these nucleotide modifications increase DNA’s utility by preventing degradation in biological systems. However, these previously identified mutants are only capable of extending DNA templates by two to six base pairs with modified nucleotides. This project focuses on characterizing the increased promiscuity of these enzymes and their ability to recognize a greater substrate range beyond the nucleotides used for their selection. Three previously evolved mutants are able to recognize a surprisingly wide range of 2’ modified nucleotides (dNTP, O‐Me, F, NH3, N3, OH) with varying efficiencies, providing insight into possible new enzyme‐substrate pairings. We describe initial kinetic characterization and further engineering efforts, which may lead to valuable new mutant enzyme‐modified substrate pairs capable of full length synthesis.
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