Lignocellulosic biomass can be converted into biofuels and other valuable bioproducts, but it must first undergo physicochemical and enzymatic degradation. Among the various enzymes involved in lignocellulose degradation, thermophilic glycoside hydrolase family 5 (GH5) cellulases have gained significant attention given their ability to sustain enzymatic activity at temperatures exceeding 60 °C. These high temperatures not only accelerate enzymatic reactions, improving reaction rates and process efficiency, but also enhance substrate solubility and reduce the risk of microbial contamination, making them highly valuable for the paper, food, feed, pharmaceutical, and biofuel industries. In this work, we identified five GH5 cellulases with predicted thermophilic properties from termite gut metagenomes and evaluated their structural features using machine-learning classification, comparative structural modeling, interatomic contact analysis, and temperature-dependent flexibility simulations. The candidates, spanning GH5 subfamilies 2, 25, 37, 39, and 40, displayed high structural confidence (pLDDT > 90) and aliphatic indices comparable to those of thermophilic references. Analysis of amino acid composition analysis revealed enrichment in aromatic and charged residues. Hydrophobic contact densities were consistently higher than in mesophilic controls and aligned with thermophilic benchmarks. Temperature-dependent flexibility simulations showed restrained RMSF profiles, more closely resembling the thermophilic reference enzyme than to the mesophilic control. These findings are consistent with a thermophilic profile, pending experimental confirmation, and provide useful insights for the selection and engineering of GH5 cellulases for high-temperature biotechnological applications.
Farace et al. (Sun,) studied this question.