Sustainable use of giant reed to produce industrialized enzymes
A. Ascacio-Valdés,
J.C. De León-Medina,
M.A. De León-Zapata,
E.I. Laredo-Alcalá,
A.C. Flores-Gallegos,
N.P. Meléndez-Rentería
Affiliations
A. Ascacio-Valdés
Food Research Department, Faculty of Chemical Sciences, Autonomous University of Coahuila, Boulevard Venustiano Carranza without number, 25280, Saltillo, Mexico; Research Center for the Conservation of Biodiversity and Ecology of Coahuila, Autonomous University of Coahuila, Hidalgo 212 central zone, 27540, Cuatrociénegas, Mexico
J.C. De León-Medina
Food Research Department, Faculty of Chemical Sciences, Autonomous University of Coahuila, Boulevard Venustiano Carranza without number, 25280, Saltillo, Mexico
M.A. De León-Zapata
Research Center for the Conservation of Biodiversity and Ecology of Coahuila, Autonomous University of Coahuila, Hidalgo 212 central zone, 27540, Cuatrociénegas, Mexico
E.I. Laredo-Alcalá
Research Center for the Conservation of Biodiversity and Ecology of Coahuila, Autonomous University of Coahuila, Hidalgo 212 central zone, 27540, Cuatrociénegas, Mexico
A.C. Flores-Gallegos
Food Research Department, Faculty of Chemical Sciences, Autonomous University of Coahuila, Boulevard Venustiano Carranza without number, 25280, Saltillo, Mexico
N.P. Meléndez-Rentería
Research Center for the Conservation of Biodiversity and Ecology of Coahuila, Autonomous University of Coahuila, Hidalgo 212 central zone, 27540, Cuatrociénegas, Mexico; Corresponding author.
The giant reed (Arundo donax) is a fast-growing plant adapted to different climatic and soil conditions; although its origin is Asian, the species has spread throughout the world. During its development, it consumes three times more water than typical native vegetation and is responsible for changing the landscape of riparian areas; the high biomass productivity and the annual harvest period make this crop an alternative to produce and/or extract industrial bioproducts. The main objective of this research was to evaluate the feasibility of using giant reed in a bioprocess that produces enzymes by a solid-state fermentation experiment, four fungal species were tested (Aspergillus niger GH1, Aspergillus niger PSH, Trichoderma harzianum, and Rhizopus oryzae); enzyme activities were performed using reported methodologies varying only reaction volumes. The A. niger GH1 and PSH strains were the best adapted to the plant material, A. niger GH1 was capable to produce 4 of the 5 evaluated enzymes (cellulase-endoglucanase (174.39 ± 19.62 U/L), xylanase (1313.31 ± 39.25 U/L), invertase (642.22 ± 23.55 U/L), and polyphenol oxidase (6094.01 ± 306.54) while A. niger PSH was able to produce 3 of the 5 evaluated enzymes (cellulase-endoglucanase (147.09 ± 13.88 U/L), xylanase (1307.76 ± 31.40 U/L), and invertase (603.92 ± 3.14 U/L).