ABSTRACT
Production of carotenoids by yeast fermentation is an advantaged technology due to its easy scaling and safety. Nevertheless, carotenoid production needs an economic culture medium and other efficient yeast stains. The study aims to isolate and identify a yeast strain capable of producing carotenoids using a cost-effective substrate. A new strain was identified as Rhodotorula toruloides L/24-26-1, which can produce carotenoids at different pretreated and unpretreated sugarcane molasses concentrations (40 and 80 g/L). The highest biomass concentration (18.6 ± 0.6 g/L) was reached in the culture using 80 g/L of hydrolyzed molasses. On the other hand, the carotenoid accumulation reached the maximum value using pretreated molasses at 40 g/L (715.4 ± 15.1 µg/g d.w). In this case, the ß-carotene was 1.5 times higher than that on the control medium. The yeast growth in molasses was not correlated with carotenoid production. The most outstanding production of The DPPH, ABTS, and FRAP tests demonstrated the antioxidant activity of the obtained carotenogenic extracts. This research demonstrated the R. toruloides L/24-26-1 strain biotechnological potential for carotenoid compounds. The yeast produces carotenoids with antioxidant activity in an inexpensive medium, such as sulfuric acid pretreated and unpretreated molasses.
Subject(s)
Fermentation , Molasses , Rhodotorula , Saccharum , beta Carotene , Rhodotorula/metabolism , Rhodotorula/genetics , Rhodotorula/growth & development , Rhodotorula/isolation & purification , Rhodotorula/classification , Saccharum/metabolism , beta Carotene/metabolism , beta Carotene/biosynthesis , Carotenoids/metabolism , Antioxidants/metabolism , Biomass , Culture Media/chemistry , PhylogenyABSTRACT
In this study, an extracellular phytase produced by Aspergillus niger 7A-1, was biochemically characterized for possible industrial application. The enzyme was purified from a crude extract obtained by solid-state fermentation (SSF) of triticale waste. The extract was obtained by microfiltration, ultrafiltration (300, 100 and 30â¯kDa) and DEAE-Sepharose column chromatography. The molecular weight of the purified enzyme was estimated to be 89â¯kDa by SDS-PAGE. The purified enzyme was most active at pH 5.3 and 56⯰C, and retained 50% activity over a wide pH range of 4 to 7. The enzymatic thermostability assay showed that the enzyme retained more than 70% activity at 80⯰C for 60â¯s, 40% activity for 120â¯s and 9% after 300â¯s. The phytase showed broad substrate specificity, a Km value of 220⯵M and Vmax of 25⯵M/min. The purified phytase retained 50% of its activity with phosphorylated compounds such as phenyl phosphate, 1-Naphthyl phosphate, 2-Naphthyl phosphate, p-Nitrophenyl phosphate and Glycerol-2-phosphate. The inhibition of phytase activity by metal ions was observed to be drastically inhibited (50%) by Ca++ and was slightly inhibited (10%) by Ni++, K+, and Na+, at 10 and 20â¯mM concentrations. A positive effect was obtained with Mg++, Mn++, Cu++, Cd++ and Ba++ at 25 and 35% with stimulatory effect on the phytase activity.