Production of short-chain fructooligosaccharides (scFOS) using extracellular β-D-fructofuranosidase produced by Aspergillus thermomutatus

Aspergillus thermomutatus produces an extracellular β-D-fructofuranosidase when cultured in Khanna medium with sucrose as additional carbon source at 30°C under agitation for 72 hr. Addition of glucose and fructose in the culture medium affected the production of the enzyme negatively. The optimum hydrolytic activity was achieved at 60°C and pH 5.0, with half-life (T50) of 30 hr at 50°C and 62% of its activity maintained at pH 5.0 for 48 hr. The extracellular extract containing β-D-fructofuranosidase was effective in producing fructooligosaccharides (FOS), mainly 1-kestose. The highest concentration of FOS was obtained at 30°C and 60°C, indicating the existence of at least two enzymes with transfructosylating activity. At 30°C, the maximal FOS concentration was obtained from 48 to 72 hr, while at 60°C, it was achieved only at 72 hr. The best production of FOS (86.7 g/L) was obtained using 500 g/L sucrose as substrate. PRACTICAL APPLICATION: Fructooligosaccharides (FOS) are linear oligomers of fructose units with important applications in the food industry as sweetening agents and biopreservatives. Due to the presence of β-glycosidic bonds, they cannot be hydrolyzed by human enzymes, allowing the use of FOS-containing products by diabetics. FOS used in the preparation of dairy products imparts humectancy to soft baked products, lowers the freezing point of frozen desserts, provides crispness to low-fat cookies, and provides many other advantages. Diets containing FOS can reduce the levels of triglycerides and cholesterol and improve the absorption of ions, such as Ca²⁺ and Mg²⁺ . FOS also exhibit bifidogenic effect on Bifidobacterium and Lactobacillus strains in the colon. Industrially, FOS is produced during the transfructosylation reaction of sucrose catalyzed by β-D-fructofuranosidase. Identifying new sources of β-D-fructofuranosidase is an important challenge to meet its industrial demand.

β-Fructofuranosidase and β -D-Fructosyltransferase from New Aspergillus carbonarius PC-4 Strain Isolated from Canned Peach Syrup: Effect of Carbon and Nitrogen Sources on Enzyme Production

β-fructofuranosidase (invertase) and β-D-fructosyltransferase (FTase) are enzymes used in industrial processes to hydrolyze sucrose aiming to produce inverted sugar syrup or fructooligosaccharides. In this work, a black Aspergillus sp. PC-4 was selected among six filamentous fungi isolated from canned peach syrup which were initially screened for invertase production. Cultivations with pure carbon sources showed that invertase and FTase were produced from glucose and sucrose, but high levels were also obtained from raffinose and inulin. Pineapple crown was the best complex carbon source for invertase (6.71 U/mL after 3 days of cultivation) and FTase production (14.60 U/mL after 5 days of cultivation). Yeast extract and ammonium chloride nitrogen sources provided higher production of invertase (6.80 U/mL and 6.30 U/mL, respectively), whereas ammonium nitrate and soybean protein were the best nitrogen sources for FTase production (24.00 U/mL and 24.90 U/mL, respectively). Fermentation parameters for invertase using yeast extract were Y_P/S = 536.85 U/g and P_P = 1.49 U/g/h. FTase production showed values of Y_P/S = 2,627.93 U/g and P_P = 4.4 U/h using soybean protein. The screening for best culture conditions showed an increase of invertase production values by 5.10-fold after 96 h cultivation compared to initial experiments (fungi bioprospection), while FTase production increased by 14.60-fold (44.40 U/mL) after 168 h cultivation. A. carbonarius PC-4 is a new promising strain for invertase and FTase production from low cost carbon sources, whose synthesized enzymes are suitable for the production of inverted sugar, fructose syrups, and fructooligosaccharides.

Comparative evaluation of extracellular β-d-fructofuranosidase in submerged and solid-state fermentation produced by newly identified Bacillus subtilis strain

AIMS

To screen and identify a potential extracellular β-d-fructofuranosidase or invertase-producing bacterium from soil, and comparatively evaluate the enzyme biosynthesis under submerged and solid-state fermentation (SSF).

METHODS AND RESULTS

Extracellular invertase-producing bacteria were screened from soil. Identification of the potent bacterium was performed based on microscopic examinations and 16S rDNA molecular sequencing. Bacillus subtilis LYN12 invertase secretion was surplus with wheat bran humidified with molasses medium (70%), with elevated activity at 48 h and 37°C under SSF, whereas under submerged conditions, increased activity was observed at 24 h and 45°C in the molasses medium. The study revealed a simple fermentative medium for elevated production of extracellular invertase from a fast growing Bacillus strain.

CONCLUSIONS

Bacterial invertases are scarce and limited reports are available. By far, this is the first report on the comparative analysis of optimization of extracellular invertase synthesis from B. subtilis strain by submerged and SSF. The use of agricultural residues increased yields resulting in the development of a cost-effective and stable approach.

SIGNIFICANCE AND IMPACT OF THE STUDY

Bacillus subtilis LYN12 invertase possesses excellent fermenting capability to utilize agro-industrial residues under submerged and solid-state conditions. This could be a beneficial candidate in food and beverage processing industries.

Purification and biochemical characterization of an extracellular β-d-fructofuranosidase from Aspergillus sp

This study focused on the purification and characterization of an extracellular β-d-fructofuranosidase or invertase from Aspergillus sojae JU12. The protein was purified by size exclusion chromatography with 5.41 fold and 10.87% recovery. The apparent molecular mass of the enzyme was estimated to be ~ 35 kDa using SDS-PAGE and confirmed by deconvoluted mass spectrometry. The fungal β-d-fructofuranosidase was suggested to be a monomer by native PAGE and zymography, and was found to be a glycoprotein possessing 68.92% carbohydrate content. The products of enzyme hydrolysis were detected by thin layer chromatography and revealed the monosaccharide units, d-glucose and d-fructose. β-d-fructofuranosidase showed enhanced activity at broad pH 4.0-9.0 and activity at a temperature range from 30 to 70 °C, while the enzyme was stable at pH 8.0 and 40 °C, respectively. The β-d-fructofuranosidase activity was lowered by metal ion inhibitors Ag2+ and Hg2+ whereas elevated by SDS and β-ME. The fungal β-d-fructofuranosidase was capable of hydrolyzing d-sucrose and the kinetics were determined by Lineweaver-Burk plot with Km of 10.17 mM and Vmax of 0.7801 µmol min-1. Additionally, the extracellular β-d-fructofuranosidase demonstrated tolerance to high ethanol concentrations indicating its applicability in the production of alcoholic fermentation processes.

Biochemical characterization and functional analysis of invertase Bmsuc1 from silkworm, Bombyx mori

Invertase or β-fructofuranosidase (EC 3.2.1.26) belongs to the glycoside hydrolase family 32, which catalyzes the hydrolysis of sucrose into fructose and glucose. Here, we report the biochemical and functional characterization of invertase Bmsuc1 from Bombyx mori. Bmsuc1 showed optimal hydrolysis at pH 7.0-8.0 and its optimum temperature is 50°C using sucrose as substrate. Circular dichroism spectra indicated Bmsuc1 had a primarily β-strand structure. The thermal denaturations transition of Bmsuc1 was a cooperative process with a Tm, ΔH, and ΔS of 53.81±0.12°C, 185.51±0.14KJ/mol and 0.56±0.01KJ/(molK), respectively. Moreover, homology modeling and multi-sequence alignment suggested that Bmsuc1 has a canonical β-propeller fold and one conserved catalytic triad, Asp⁶³-Asp¹⁸¹-Glu²³⁴, which is located in the bottom of the substrate-binding pocket. Bmsuc1 was expressed at high levels in the silk gland at both the transcriptional and translational levels. These expression profiles combined with invertase activity analyses of Bmsuc1 suggested that it might function as a digestive enzyme to hydrolyze sugar in the silk gland lumen. Collectively, these findings expand towards a better understanding of the structure of Bmsuc1 and its function in the silk gland.