Evolving a terminal deoxynucleotidyl transferase for commercial enzymatic DNA synthesis

Abstract

Enzymatic DNA synthesis, using stepwise nucleotide addition catalyzed by template-independent polymerases, promises higher efficiency, quality, and sustainability than today’s industry-standard phosphoramidite-based processes. We report the directed evolution of a terminal deoxynucleotidyl transferase that uses 3-phosphate-blocked 2-deoxynucleoside triphosphates (dNTPs) to control the polymerization reaction. Over 32 iterative rounds of laboratory evolution, 80 amino acid substitutions—constituting ∼20% of the coding protein sequence—were introduced. The engineered polymerase exhibits uniformly high catalytic activity, raising incorporation efficiency by 200-fold to >99% for dNTPs with a 3-reversible terminator while reducing extension times by >600-fold to 90 s. The same enzyme variant displays improved enzyme robustness, as reflected in the 20◦C increase in thermostability. Based on these performance characteristics, the engineered polymerase represents an operational prototype for biocatalytic DNA synthesis at a commercial scale.