Background: Amylases are used in various industrial processes and a key requirement for the efficiency of these
processes is the use of enzymes with high catalytic activity at ambient temperature. Unfortunately, most amylases isolated
from bacteria and filamentous fungi have optimal activity above 45 °C and low pH. For example, the most commonly
used industrial glucoamylases, a type of amylase that degrades starch to glucose, are produced by Aspergillus
strains displaying optimal activities at 45–60 °C. Thus, isolating new amylases with optimal activity at ambient temperature
is essential for improving industrial processes. In this report, a glucoamylase secreted by the cold-adapted
yeast Tetracladium sp. was isolated and biochemically characterized.
Results: The effects of physicochemical parameters on enzyme activity were analyzed, and pH and temperature
were found to be key factors modulating the glucoamylase activity. The optimal conditions for enzyme activity were
30 °C and pH 6.0, and the Km and kcat using soluble starch as substrate were 4.5 g/L and 45 min−1, respectively. Possible
amylase or glucoamylase encoding genes were identified, and their transcript levels using glucose or soluble
starch as the sole carbon source were analyzed. Transcription levels were highest in medium supplemented with
soluble starch for the potential glucoamylase encoding gene. Comparison of the structural model of the identified
Tetracladium sp. glucoamylase with the solved structure of the Hypocrea jecorina glucoamylase revealed unique structural
features that may explain the thermal lability of the glucoamylase from Tetracladium sp.