Characterization and engineering of a DNA polymerase reveals a single amino-acid substitution in the fingers subdomain to increase strand-displacement activity of A-family prokaryotic DNA polymerases

Background - The discovery of thermostable DNA polymerases such as Taq DNA polymerase revolutionized amplification of DNA by polymerase chain reaction methods that rely on thermal cycling for strand separation. These methods are widely used in the laboratory for medical research, clinical diagnostics, criminal forensics and general molecular biology research. Today there is a growing demand for on-site molecular diagnostics; so-called ‘Point-of-Care tests’. Isothermal nucleic acid amplification techniques do not require a thermal cycler making these techniques more suitable for performing Point-of-Care tests at ambient temperatures compared to traditional polymerase chain reaction methods. Strand-displacement activity is essential for such isothermal nucleic acid amplification; however, the selection of DNA polymerases with inherent strand-displacement activity that are capable of performing DNA synthesis at ambient temperatures is currently limited. Results - We have characterized the large fragment of a DNA polymerase I originating from the marine psychrophilic bacterium Psychrobacillus sp. The enzyme showed optimal polymerase activity at pH 8–9 and 25–110 mM NaCl/KCl. The polymerase was capable of performing polymerase as well as robust strand-displacement DNA synthesis at ambient temperatures (25–37 °C). Through molecular evolution and screening of thousand variants we have identified a single amino-acid exchange of Asp to Ala at position 422 which induced a 2.5-fold increase in strand-displacement activity of the enzyme. Transferring the mutation of the conserved Asp residue to corresponding thermophilic homologues from Ureibacillus thermosphaericus and Geobacillus stearothermophilus also resulted in a significant increase in the strand-displacement activity of the enzymes. Conclusions - Substituting Asp with Ala at positon 422 resulted in a significant increase in strand-displacement activity of three prokaryotic A-family DNA polymerases adapted to different environmental temperatures i.e. being psychrophilic and thermophilic of origin. This strongly indicates an important role for the 422 position and the O1-helix for strand-displacement activity of DNA polymerase I. The D422A variants generated here may be highly useful for isothermal nucleic acid amplification at a wide temperature scale

Features and structure of a cold active N-acetylneuraminic acid lyase

N-acetylneuraminate lyases (NALs) are enzymes that catalyze the reversible cleavage and synthesis of sialic acids. They are therefore commonly used for the production of these high-value sugars. This study presents the recombinant production, together with biochemical and structural data, of the NAL from the psychrophilic bacterium Aliivibrio salmonicida LFI1238 (AsNAL). Our characterization shows that AsNAL possesses high activity and stability at alkaline pH. We confirm that these properties allow for the use in a one-pot reaction at alkaline pH for the synthesis of N-acetylneuraminic acid (Neu5Ac, the most common sialic acid) from the inexpensive precursor N-acetylglucosamine. We also show that the enzyme has a cold active nature with an optimum temperature for Neu5Ac synthesis at 20°C. The equilibrium constant for the reaction was calculated at different temperatures, and the formation of Neu5Ac acid is favored at low temperatures, making the cold active enzyme a well-suited candidate for use in such exothermic reactions. The specific activity is high compared to the homologue from Escherichia coli at three tested temperatures, and the enzyme shows a higher catalytic efficiency and turnover number for cleavage at 37°C. Mutational studies reveal that amino acid residue Asn 168 is important for the high kcat. The crystal structure of AsNAL was solved to 1.65 Å resolution and reveals a compact, tetrameric protein similar to other NAL structures. The data presented provides a framework to guide further optimization of its application in sialic acid production and opens the possibility for further design of the enzyme