Ana Luísa M. de Carvalho

Uracil-DNA glycosylases (UDGs) are widely used to prevent carryover contamination in nucleic acid amplification–based diagnostics; however, existing thermolabile UDGs exhibit limited thermal inactivation windows for emerging applications. Here, we combine evolutionary mining, structural analysis, and structure-guided saturation mutagenesis to define non-catalytic determinants that tune UDG thermolability without compromising catalytic function. From 8482 bacterial UDG sequences, we assembled a 24-member diversity panel and identified UDG_7 as a naturally thermolabile scaffold coupling robust low-temperature activity with sharp inactivation near 45 °C. The crystal structure of UDG_7 reveals a canonical family-I α/β fold with a fully conserved active site, closely resembling both mesophilic human and Escherichia coli UDGs and thermolabile cod UDG. These structural insights guided the design of a single-site variant library targeting 48 non-catalytic positions involved in packing and electrostatic networks. Pooled thermal shift assays distinguished a rigid structural core from 16 surface thermolability hotspots. A high-throughput functional screening of 480 single mutants yielded 114 clones with a desirable “on–off–off” profile and, after sequence consolidation, identified 54 unique variants that retained activity at 25 °C but lost activity at 30 to 37.5 °C. Biochemical characterization revealed nine single substitutions, Q51I, T112Y, V144M, D167F, R201F, R201Y, D219M, R221P, and R221D, that markedly lower the melting temperature while preserving near-native activity. Together, these results indicate that UDG_7 thermolability is encoded by a distributed, surface-biased electrostatic network that can be selectively disrupted without perturbing the conserved catalytic core, shifting the functional inactivation boundary downward and supporting robust carryover control under low-temperature amplification constraints.

Abstract The family 81 glycoside hydrolase (GH81) from Clostridium thermocellum is a β-1,3-glucanase belonging to cellulosomal complex. The gene encoding \{GH81\} from Clostridium thermocellum (CtLam81A) was cloned and expressed displaying a molecular mass of  82 kDa. CtLam81A showed maximum activity against laminarin (100 U/mg), followed by curdlan (65 U/mg), at pH 7.0 and 75 °C. CtLam81A displayed Km, 2.1 ± 0.12 mg/ml and Vmax, 109 ± 1.8 U/mg, against laminarin under optimized conditions. CtLam81A activity was significantly enhanced by Ca2+ or Mg2+ ions. Melting curve analysis of CtLam81A showed an increase in melting temperature from 91 °C to 96 °C by Ca2+ or Mg2+ ions and decreased to 82 °C by EDTA, indicating that Ca2+ and Mg2+ ions may be involved in catalysis and in maintaining structural integrity. \{TLC\} and MALDI-TOF analysis of β-1,3-glucan hydrolysed products released initially, showed β-1,3-glucan-oligosaccharides degree of polymerization (DP) from \{DP2\} to DP7, confirming an endo-mode of action. The catalytically inactive mutant CtLam81A-E515A generated by site-directed mutagenesis was co-crystallized and tetragonal crystals diffracting up to 1.4 Å resolution were obtained. CtLam81A-E515A contained 15 α-helices and 38 β-strands forming a four-domain structure viz. a β-sandwich domain I at N-terminal, an α/β-domain II, an (α/α)6 barrel domain III, and a small 5-stranded β-sandwich domain IV.