Enzyme production and activities of lignocellulolytic fungi cultivated on agricultural residues

Abstract

A total of 30 fungal fruiting bodies were collected from decaying plant materials (barks and litter) from the wild based on morphological variations. Nine of these fungi purified to monoaxenic cultures were included in the present study and also a type strain Ganoderma lucidum ATCC- 32471. These fungi were screened for lignocellulolytic activities, five of these organisms produced ligninolytic enzymes when exposed to two different concentrations of guaiacol (0.02% and 0.2%) on two different media (MEA and PDA). All ten fungal isolates screened for cellulolytic activity were positive for the production of the cellulase enzyme. The fungal isolates were characterised using morphological and molecular methods. Molecular characterization using ITS1 and ITS4 primers was able to identify these fungal isolates to degrees of accuracy ranging from 98% to 100%. The phylogenetic and lineage analysis showed that the species varied amongst phylum Basidiomycota, Ascomycota and early diverging fungal lineages Mucormycotina. Both monocultures and dual cultures of these 10 fungal species were cultivated for the purpose of spectrophotometrically quantifying and evaluating enzyme production on agricultural waste residues; corn cob, sugar cane bagasse and wheat straw. A pattern of antagonistic invasion interaction was identified to demonstrate increased enzyme production on dual cultures. Four of these fungal species, Trichoderma sp. KN10, Rhizopus microsporus KN2, Fomitopsis sp. KN1 and Coriolopsis sp. KN6 demonstrated tendencies of invasion and replacement in co-cultures. The fungi and their dual cultures showed varying levels of enzyme production. Analysis of mean showed dual culture interactions involving KN10 with values for MnP production approximately at 1.46U/ml compared to monoculture of 0.06U/ml. Further, dual laccase values approximately at 0.09U/ml compared to monocultures of 0.05U/ml. Overall the highest enzyme activity was observed using wheat straw. This study demonstrated and proved that agricultural waste residues can be used for lignocellulytic enzyme production and that antagonistic invasion by some fungi (in particular Trichoderma sp. KN10) in co-cultures can increase production of one or more of the three enzyme laccase, lignin peroxidase and manganese peroxidase.