The effect of mutations near the T1 copper site on the biochemical characteristics of the small laccase from Streptomyces coelicolor A3(2).

Bacterial laccases show low activities but can be of biotechnological interest due to industrially suitable characteristics such as thermostability and tolerance to alkaline pH. In this study, three separate mutations (M298F, V290N and V290A) were introduced at or near the T1 copper site of the small laccase (SLAC) from Streptomyces coelicolor A3(2) and biochemical properties were assessed in comparison with the native enzyme. The mutation, V290N showed approximately double the activity of SLAC when ABTS was used as substrate while the specific activity of SLAC-M298F was 4-5 times higher than that of SLAC when the assays were performed at ≥70°C. There was no significant difference in activity with 2,6-dimethoxyphenol (2,6-DMP); however, there was a significant shift in the optimal pH from pH 9.5 (SLAC) to 7.5 (SLAC-V290N). Optimal temperature for activity was not significantly altered but thermostability was reduced in all three mutants. The substrate range of the mutant variants remained largely unchanged, with the exception of SLAC-M298F which was unable to oxidise veratryl alcohol. Interestingly, the "typical" laccase inhibitor, sodium azide, had no significant inhibitory effect on the activity of SLAC-M298F, which also exhibited increased resistance to inhibition by sulfhydryl compounds. SLAC-V290N showed higher catalytic efficiency for 2,6-DMP (kcat/Km=2.226mM(-1)s(-1)) and ABTS (kcat/Km=1.874mM(-1)s(-1)) compared to SLAC (kcat/Km=1.615mM(-1)s(-1) for 2,6-DMP and kcat/Km=1.611mM(-1)s(-1) for ABTS). This study has shown that three ligands that are closely associated with the T1 copper in SLAC play a key role in maintaining enzymatic activity. Whilst the introduction of mutations at these sites negated favourable characteristics such as thermostability, several favourable effects were observed. This study has also extended the knowledge base on the biochemical characteristics of SLAC, and its suitability as a template for engineering with the aim of widening its potential range of industrial applications.

Extracellular cellulase production by tropical isolates of Aureobasidium pullulans.

Cellulase production by Aureobasidium pullulans from the temperate regions has remained speculative, with most studies reporting no activity at all. In the current study, tropical isolates from diverse sources were screened for cellulase production. Isolates were grown on a synthetic medium containing cell walls of Msasa tree (Brachystegia sp.) as the sole carbon source, and their cellulolytic activities were measured using carboxymethyl cellulose and alpha-cellulose as substrates. All isolates studied produced carboxymethyl cellulase (endoglucanase) and alpha-cellulase (exoglucanase) activity. Endoglucanase-specific activities of ten selected isolates ranged from 2.375 to 12.884 micromol glucose.(mg protein)-1.h-1, while activities on alpha-cellulose (exoglucanase activity) ranged from 0.293 to 22.442 micromol glucose.(mg protein)-1.day-1. Carboxymethyl cellulose induced the highest cellulase activity in the selected isolates, while the isolates showed variable responses to nitrogen sources. The current study indicates that some isolates of A. pullulans of tropical origin produce significant extracellular cellulolytic activity and that crude cell walls may be good inducers of cellulolytic activity in A. pullulans.