Mussatto Solange I, Aguilar Cristóbal N, Rodrigues Lígia R, Teixeira José A
IBB-Institute for Biotechnology and Bioengineering, Centre of Biological Engineering, University of Minho, Braga, Portugal.
Carbohydr Res. 2009 Apr 21;344(6):795-800. doi: 10.1016/j.carres.2009.01.025. Epub 2009 Feb 4.
The ability of Aspergillus japonicus ATCC 20236 to colonize different synthetic materials (polyurethane foam, stainless steel sponge, vegetal fiber, pumice stones, zeolites, and foam glass) and to produce fructooligosaccharides (FOS) from sucrose (165 g/L) is described. Cells were immobilized in situ by absorption, through direct contact with the carrier particles at the beginning of fermentation. Vegetal fiber was the best immobilization carrier as A. japonicus grew well on it (1.25 g/g carrier), producing 116.3g/L FOS (56.3g/L 1-kestose, 46.9 g/L 1-nystose, and 13.1g/L 1-beta-fructofuranosyl nystose) with 69% yield (78% based only in the consumed sucrose amount), giving also elevated activity of the beta-fructofuranosidase enzyme (42.9 U/mL). In addition, no loss of material integrity, over a 2 day-period, was found. The fungus also immobilized well on stainless steel sponge (1.13 g/g carrier), but in lesser extents on polyurethane foam, zeolites, and pumice stones (0.48, 0.19, and 0.13 g/g carrier, respectively), while on foam glass no cell adhesion was observed. When compared with the FOS and beta-fructofuranosidase production by free A. japonicus, the results achieved using cells immobilized on vegetal fiber were closely similar. It was thus concluded that A. japonicus immobilized on vegetal fiber is a potential alternative for high production of FOS at industrial scale.
描述了日本曲霉ATCC 20236在不同合成材料(聚氨酯泡沫、不锈钢海绵、植物纤维、浮石、沸石和泡沫玻璃)上定殖以及从蔗糖(165 g/L)生产低聚果糖(FOS)的能力。在发酵开始时,通过与载体颗粒直接接触,细胞通过吸附原位固定。植物纤维是最佳的固定化载体,因为日本曲霉在其上生长良好(1.25 g/g载体),产生116.3 g/L FOS(56.3 g/L 1-蔗果三糖、46.9 g/L 1-蔗果四糖和13.1 g/L 1-β-呋喃果糖基蔗果四糖),产率为69%(仅基于消耗的蔗糖量计算为78%),同时β-呋喃果糖苷酶的活性也较高(42.9 U/mL)。此外,在两天的时间内未发现材料完整性损失。该真菌在不锈钢海绵上也固定良好(1.13 g/g载体),但在聚氨酯泡沫、沸石和浮石上的固定程度较低(分别为0.48、0.19和0.13 g/g载体),而在泡沫玻璃上未观察到细胞粘附。与游离日本曲霉生产FOS和β-呋喃果糖苷酶的情况相比,使用固定在植物纤维上的细胞所获得的结果非常相似。因此得出结论,固定在植物纤维上的日本曲霉是工业规模高产FOS的潜在替代方案。
