Preparation of Aspergillus niger 426 naringinases for debittering citrus juice utilization of agro-industrial residues / Preparación de naringinasas de Aspergillus niger 426 para el desamargado de jugo de cítricos aprovechamiento de residuos agroindustriales

Naringin, considered as the main bitter component of grapefruit, requires the use of enzymes to reduce the level of this substance during juice processing. For this reason, it has been the focus of many studies. In this study, to increase the production of naringinase by Aspergillus niger cultivated in solid-state fermentation (SSF), a three-component simplex-centric mixing design along with a response surface methodology (RSM) was applied to generate statistical models and analyze the dataset. First, grapefruit peel, rice bran, and wheat bran were used for substrate selection for naringinase production and, finally, selected the best of the three inducers or their mixtures to remove the bitterness of grapefruit juice. Cultivation with 2.3 g of grapefruit peel, 2.5 g of rice bran, and 5.2 g of wheat bran and medium supplementation with a mixture of naringin, rutin, and hesperidin in the concentration of 2, 5, 4.5, and 3.0 g/L, respectively, resulted in a maximum activity of 28 U/mL. The results indicate that the sequencing procedure, which allowed the definition of an optimal mixture of components, is a new way for microorganisms to have a high naringinase yield, in particular by SSF, since our data showed a 96% increase in the production of naringinase. This dataset can help other researchers apply a mixing design to increase enzyme production.(AU)

Mixotrophic growth of Nostoc sp. on glucose, sucrose and sugarcane molasses for phycobiliprotein production / Crescimento mixotrófico de Nostoc sp. Glucose, sacarose e melaço de cana-de-açúcar foram testados como substratos para produção de biomassa e ficobiliproteinas - DOI: 10.4025/actascibiolsci.v29i1.121

Glucose, sacarose, and sugarcane molasses were tested as substrates for production of biomass and phycobiliproteins by Nostoc sp., varying their concentrations in relation to a mineral medium, BG11. All substrates increased the biomass and phycobiliproteins when compared with the control. Sugarcane molasses showed to be the best substrate for production of both biomass and phycobiliproteins. Greater biomass production occurred in sugarcane molasses 1.0 g L-1 and it was 5.7 times greater than the control. With glucose, it was in 2.5 g L-1 and sucrose, in 1.5 g L-1, reaching 2.5 and 4.8 times greater than the control, respectively. For phycobiliproteins, the major production was in sugarcane molasses 1.0 g L-1, 12.5 times greater than the control. With glucose, it was in 1.0 g L-1 and sucrose, in 0,5 g L-1, reaching 3.0 and 4.5 times greater than the control, respectively. The Nostoc sp. assayed can grow mixotrophically, using glucose, sucrose, and sugarcane molasses as organic substrates, and a greater production of biomass and phycobiliproteins can be reached when compared with the autotrophic growth.

Todos os substratos aumentaram a biomassa e ficobiliproteinas em relação ao controle, meio mineral BG11. Melaço de cana-de-açúcar foi o melhor substrato tanto para a produção de biomassa como de ficobiliproteinas. A maior produção de biomassa ocorreu usando melaço de cana-de-açúcar 1,0 g L-1 sendo 5,7 vezes maior que o controle. Com glucose foi em 2,5 g L-1 e sacarose 1,5 g L-1, sendo 2,5 e 4,8 vezes maior que o controle, respectivamente. A maior produção de ficobiliproteinas ocorreu usando melaço de cana-de-açúcar 1,0 g L-1 sendo 12,5 vezes maior que o controle. Com glucose foi em 1,0 g L-1 e sacarose 0,5 g L-1, 3,0 e 4,5 vezes maior que o controle, respectivamente. Nostoc sp. testado pode crescer mixotroficamente, usando glucose, sacarose e melaço de cana-deaçúcar como substratos orgânicos, uma maior produção de biomassa e ficobiliproteinas podendo ser alcançada nessas condições quando comparadas com o crescimento autotrófico.