Screening strategy targeting the presence of food enzyme-producing fungi in food enzyme preparations

Safety assessment of β-fructofuranosidase from Aspergillus brunneoviolaceus

β-Fructofuranosidase (β-D-fructofuranoside fructohydrolase; EC 3.2.1.26) is used in the production of fructo-oligosaccharides that are commonly used by the food industry as prebiotics for their purported health benefits. The β-fructofuranosidase discussed herein is obtained from a novel source organism that is a non-genetically modified strain of Aspergillus brunneoviolaceus, which phylogenetically belongs to the Aspergillus section Nigri. The safety of β-fructofuranosidase was evaluated in a series of toxicology studies as prescribed by Tier 1 toxicity testing by the European Food Safety Authority, including an evaluation of the mutagenicity and genotoxicity potential using the in vitro bacterial reverse mutation and mammalian chromosomal aberration assays, as well as systemic toxicity in a 90-day oral subchronic toxicity study in Sprague-Dawley rats. β-Fructofuranosidase was demonstrated to lack mutagenic or genotoxic potential based on the results of the in vitro assays due to absence of increased revertant colonies in the bacterial reverse mutation test and incidence of chromosome aberrations in the chromosomal aberration assay. Administration of β-fructofuranosidase by gavage at doses up to 1200 mg total organic solids (TOS)/kg body weight/day for 90 days did not elicit any systemic toxic effects in rats based on a lack of adverse effect in any study parameter, and therefore the no-observed-adverse-effect level of β-fructofuranosidase was concluded to be 1200 mg TOS/kg body weight/day, the highest dose tested. The results of the toxicology studies on β-fructofuranosidase from A. brunneoviolaceus demonstrate this species to be a safe and suitable source of enzymes for use by the food industry.

Food Enzyme Database (FEDA): a web application gathering information about food enzyme preparations available on the European market

Following the European Commission No. 1332/2008 regulation and the consequent necessity of a scientific evaluation of food enzymes (FEs) for their approval for sale on the European Union market, many FE dossiers have been submitted to the European Commission and various documents currently co-exist. In order to centralize all relevant information in one structured location that is easily accessible to support enforcement laboratories and the competent authorities, we developed a web application, called Food Enzyme Database (FEDA). FEDA allows searching and collection of information originating from many different sources in one centralized portal. Queries can be performed using key information types, which include information on the producing company, production source (strain type, genetically modified microorganism status), type of enzyme protein and evaluation status with employed evaluation criteria. The database contains all current publicly available information. Centralizing all information coupled with intuitive searching functionality also allows the generation of general statistics regarding the current market situation. FEDA is open access and is freely available at the following location: https://feda.sciensano.be.

Database URL:https://feda.sciensano.be

Co-culture of fungi-microalgae consortium for wastewater treatment: A review

The treatment of wastewater by microalgae has been studied and proved to be effective through previous studies. Due to the small size of microalgae, how to efficiently harvest microalgae from wastewater is a crucial factor restricting the development of algal technologies. Fungi-assisted microalgae bio-flocculation for microalgae harvesting and wastewater treatment simultaneously, which was overlooked previously, has attracted increasing attention in the recent decade due to its low cost and high efficiency. This review found that fungal hyphae and microalgae can stick together due to electrostatic neutralization, surface protein interaction, and exopolysaccharide adhesion in the co-culture process, realizing co-pelletization of microalgae and fungi, which is conducive to microalgae harvesting. Besides, the combination of fungi and microalgae has a complementary effect on pollutant removal from wastewaters. The co-culture of fungi-microalgae has excellent development prospects with both environmental and economic benefits, and it is expected to be applied on an industrial scale.

Development of a Real-time PCR Method Targeting an Unauthorized Genetically Modified Microorganism Producing Alpha-Amylase

Using a recently developed genetically modified microorganisms (GMM) detection strategy, unexpected contaminations of unauthorized GMM in commercialized microbial fermentation products have been reported. A first-line real-time PCR screening analysis was initially performed to determine the presence of key targets frequently found in genetically modified (GM) bacteria. A second-line real-time PCR analysis was subsequently applied to identify specific GMM, including to date a GM Bacillus velezensis producing protease and a GM B. subtilis producing vitamin B2. In this study, an additional real-time PCR method specific to a newly identified GMM producing alpha-amylase was developed to be integrated in such second-line real-time PCR analysis, allowing to strengthen the GMM detection strategy. This method was successfully validated based on the assessment of its specificity and sensitivity performance. In addition, its applicability was confirmed using several food enzyme products commercialized on the market. Finally, via its transfer to an external laboratory, the transferability of the in-house validated method was positively evaluated, allowing its easy implementation in enforcement laboratories.