UPLC-MS-Based Metabolomics Profiling and Chemometric Analysis for Hypericum sinaicum Boiss and the Endophytic Aspergillus foetidus in Comparison to Hypericum perforatum L.

One of the endangered plant species in Saint Catherine protectorate is Hypericum sinaicum Boiss which is endemic to Egypt, Jordan, and Saudi Arabia. The fungus-host relationship can assist in the investigation of bioactive compounds produced by H. sinaicum paving the way for economic and medicinal implications. Therefore, a comprehensive metabolic approach via MS and chemical analysis was used to track and compare metabolites from H. sinaicum and Aspergillus foetidus var. pallidus, the endophytic fungus, with Hypericum perforatum. Metabolomics analysis revealed the presence of 25 metabolites distributed among samples and the discovery of new chemotaxonomic compounds, i. e., phloroglucinols and xanthones, allowing the discrimination between species. A. foetidus extract is considered a reliable source of furohyperforin and naphthodianthrone derivatives. In conclusion, using A. foetidus as an in vitro technique for producing potential phytoconstituents was cost effective, having easier optimization conditions and faster growth with fewer contamination rates than other in vitro methods.

Naphto-Γ-pyrones from the marine-derived fungus Aspergillus foetidus.

Nine naphto-γ-pyrones rubrofusarine B (1), TMC 256 A1 (2), fansecinones A (3) and B (4), aurasperones A (5), B (6) and F (7), dianhydro-aurasperone C (8) and asperpyrone B (9) were isolated from the marine-derived fungus Aspergillus foetidus KMM 4694. Their structures were established based on spectroscopic methods. The effect of the substances on viability and colony formation of human drug-resistant prostate cancer 22Rv1 cell was evaluated.

Partial purification and characterization of phytase from Aspergillus foetidus MTCC 11682.

Phytase is a phosphatase enzyme widely used as feed additive to release inorganic phosphorus from plant phytate and enhance its uptake in monogastric animals. Although engineered fungal phytases are used most, a natural enzyme gives opportunity to understand novel properties, if any. In the current study, a novel fungal strain, Aspergillus foetidus MTCC 11682 was immobilized on poly urethane cubes and used for phytase production, purification and molecular characterization. Phytase produced by this method was partially purified by ammonium sulphate precipitation and Sephacryl S-200HR gel filtration to 23.4-fold (compared to crude extract) with recovery of 13% protein. Electrophoresis analysis revealed that phytase has molecular weight of 90.5 kDa on non-reducing and 129.6 kDa on reducing SDS-PAGE. The purified phytase exhibited a wider pH and temperature stability. Analysis of the cloned sequence showed that the gene has 1176 bp that encodes for a peptide of 391 amino acids of the core catalytic region. It was also found that phytase from A. foetidus has a sequence identity of 99% with the phytase gene of other Aspergillus species at nucleotide level and 100% at protein level in A. niger, A. awamori, A. oryzae. In silico analysis of sequence identified the presence of two consecutive and one non-consecutive intra chain disulfide bonds in the phytase. This probably contributed to the differential migration of phytase on reducing and non-reducing SDS-PAGE. There are predicted 11 O-glycosylation sites and 8 N-glycosylation sites, possibly contributed to an enhanced stability of enzyme produced by this organism. This study opened up a new horizon for exploring the novel properties of phytase for other applications.

Bioremediation potential of arsenic by non-enzymatically biofabricated silver nanoparticles adhered to the mesoporous carbonized fungal cell surface of Aspergillus foetidus MTCC8876.

Our study aiming for the diminution of arsenic concentration in arsenic contaminated aqua environment by using novel adsorbents based on bio-fabricated silver nanoparticles on a fungal cell surface. Bioreduction of silver ion was done in a non-enzymatic manner in presence of the biomass of fungus Aspergillus foetidus MTCC8876. Aspergillus spp. cells were harvested following the bioreduction and made into carbon by carbonization that led to pore formation (pore width of 2.35 nm) on the cell surface. The average size of silver nanoparticles in the sample of SACF (silver nanoparticles adhered to mesoporous carbonized fungal cell) was 35 nm. Whereas mesoporous carbonized control fungal (CCF) cell was devoid of any particles on its surface. For structural characterizations of this adsorbent as well as to emerge its changes as a validation of arsenic adsorption, different biophysical methods such as FTIR, XRD, SEM, FESEM, TEM, BET surface area analysis and SERS analysis were followed. Batch mode experiments were performed to investigate the influence of As (V) concentrations, reaction time, pH of the solution and also the temperature of experiments on the efficiency of As (V) removal by adsorbents SACF & CCF. This arsenic-adsorbent interaction was proved to be endothermic in nature as well as the negative ΔG value indicated the spontaneity. SACF showed exceptional efficiency for the removal (>93%) of arsenic rather than CCF from an aqueous environment within a very short time of 3.5 h due to its porosity and the presence of the silver nanocrystals.

Production, purification and characterization of an aspartic protease from Aspergillus foetidus.

An acidic thermostable protease was extracellularly produced either in shake flask or in stirred tank bioreactor by an Aspergillus foetidus strain isolated from the Brazilian savanna soil using different nitrogen sources. Its maximum activity (63.7 U mL-1) was obtained in a medium containing 2% (w/v) peptone. A cultivation carried out in a 5.0 L stirred-tank bioreactor provided a maximum protease activity 9% lower than that observed in Erlenmeyer flasks, which was obtained after a significantly shorter (by 16-29%) time. Protease purification by a combination of gel-filtration chromatography resulted in a 16.9-fold increase in specific activity (248.1 U g-1). The estimated molecular weight of the purified enzyme was 50.6 kDa, and the optimal pH and temperature were 5.0 and 55 °C, respectively. The enzyme was completely inhibited by pepstatin A, and its activity enhanced by some metals. According to the inhibition profiles, it was confirmed that the purified acid protease belongs to the aspartic protease type. These results are quite promising for future development of large-scale production of such protease, which can be useful in biotechnological applications requiring high enzyme activity and stability under acidic conditions.

Kinetic and thermodynamic studies of a novel acid protease from Aspergillus foetidus.

The kinetics of a thermostable extracellular acid protease produced by an Aspergillus foetidus strain was investigated at different pH, temperatures and substrate concentrations. The enzyme exhibited maximal activity at pH 5.0 and 55°C, and its irreversible deactivation was well described by first-order kinetics. When temperature was raised from 55 to 70°C, the deactivation rate constant increased from 0.018 to 5.06h(-1), while the half-life decreased from 37.6 to 0.13h. The results of activity collected at different temperatures were then used to estimate, the activation energy of the hydrolysis reaction (E*=19.03kJ/mol) and the standard enthalpy variation of reversible enzyme unfolding (ΔH°U=19.03kJ/mol). The results of residual activity tests carried out in the temperature range 55-70°C allowed estimating the activation energy (E(*)d=314.12kJ/mol), enthalpy (311.27≤(ΔH°d≤311.39kJ/mol), entropy (599.59≤ΔS(*)d≤610.49kJ/mol K) and Gibbs free energy (103.18≤ΔG(*)d≤113.87kJ/mol) of the enzyme irreversible denaturation. These thermodynamic parameters suggest that this new protease is highly thermostable and could be important for industrial applications. To the best of our knowledge, this is the first report on thermodynamic parameters of an acid protease produced by A. foetidus.

Produção de proteases por fungos filamentosos isolados do cerrado do centro-oeste brasileiro / Protease production by filamentous fungi isolated from the midwestern Brazilian Cerrado

Proteases ácidas pertencem a um importante grupo de enzimas industriais produzidas por fungos filamentosos, com aplicações na indústria de alimentos, de couro, farmacêutica e de cosméticos. O objetivo principal deste trabalho foi avaliar a produção de proteases ácidas extracelulares de fungos filamentosos isolados do solo do cerrado do centro-oeste brasileiro. Inicialmente, foi realizada uma triagem para avaliar a capacidade de 17 linhagens de fungos quanto à produção de protease em meio de cultura contendo Agar-leite. O fungo Aspergillus foetidus foi selecionado como melhor produtor de protease ácida extracelular. Visando à otimização da produção de proteases pelo fungo selecionado, avaliou-se a influência de diversos fatores no cultivo (pH, temperatura, agitação e diferentes fontes de nitrogênio e carbono). Após essa etapa, um planejamento experimental estatístico foi realizado com as variáveis independentes temperatura, pH inicial do meio e fonte de carbono e nitrogênio. A produção máxima de protease foi encontrada (63,7 U/mL) nas condições: pH inicial do meio igual a 7,0 a 28 ºC, 150 rpm em peptona 2% (p/v). Os estudos em biorreator demonstraram produção de protease nas condições de agitação e aeração iguais à 300 rpm e 1,0 vvm, após 120 h de cultivo. Os ensaios com diferentes temperaturas para a estimativa dos parâmetros termodinâmicos demonstraram que a protease ácida produzida pelo fungo é altamente estável apresentando máxima atividade em pH 5,0 e temperatura ótima igual a 55ºC. E, finalmente, para a purificação da enzima foi realizada cromatografia de gel-filtração. A enzima apresentou massa molecular de 50,6 kDa, e a análise do zimograma confirmou a atividade proteolítica. Além disso, a protease purificada foi inibida pelo composto pepstatina, indicando uma característica de protease ácida. Esses resultados obtidos demonstram um fungo filamentoso produtor de uma nova protease ácida com potencial aplicação para indústria farmacêutica e de cosméticos

The acid proteases belong to the most important group of industrial enzymes produced by filamentous fungi, with applications in the food, leather, pharmaceutical and cosmetics industries. This study aimed the evaluation of extracellular acid proteases production from filamentous fungi isolated from different samples of the midwestern Brazil cerrado. Initially, a screening was performed to assess the ability of the 17 strains of yeast for production of protease-agar medium containing milk culture. The Aspergillus foetidus was selected as the best producer. Aimed at optimizing the production of proteases by the selected fungus, first evaluated the influence of various factors on the cultivation (pH, temperatura, agitation and different sources of nitrogen and carbon). After this step, a statistical experimental design was carried out with the independent variables temperatura, initial pH of the medium and source of carbon and nitrogen. The best conditions for protease production were (63.7 U / mL): initial pH values greater than 7.0, at 28 °C, 150 rpm peptone 2% (w/v). Aiming future production of this protease in industrial scale, studies have shown better in bioreactor protease production under the conditions of agitation and aeration equal to 300 rpm and 1.0 vvm, after 120 h of cultive. The tests at different temperaturas to estimate the thermodynamic parameters showed that the acid protease produced by the fungus is highly stable with maximum activity at pH 5.0 and optimum temperatura of 55 °C. And finally, for the purification of the enzyme were performed gel-filtration chromatography. The enzyme had a molecular mass of 50.6 kDa, and the analysis of the zymogram showed a proteolytic band. Furthermore, the purified protease was inhibited by pepstatin compound, indicating a feature of acid protease. These results demonstrate a new filamentous fungus producing acid protease with potential application to pharmaceuticals and cosmetics

Cadmium-induced oxidative stress tolerance in cadmium resistant Aspergillus foetidus: its possible role in cadmium bioremediation.

Toxic effects of cadmium (Cd) were examined on a cadmium-resistant strain of Aspergillus foetidus isolated from wastewater. The Cd removal potential was analyzed. The results indicated that the strain could tolerate up to 25 mM and 63 mM Cd in liquid and solid Czapek-Dox media, respectively. It efficiently removed Cd from liquid growth media and industrial wastewater by mycelial biosorption. The strain produced oxalic acid for the purpose of Cd bioleaching as confirmed by the presence of cadmium oxalate crystals on the mycelial surface. Intracellular proline contents and the antioxidative enzyme activities increased up to a certain level to detoxify the overproduced free radicals. These data indicate that the strain has inherent mechanisms to grow in Cd contaminated environment, tolerate high Cd doses and high Cd uptake potential which are pre-requisite for acting as a suitable candidate for Cd bioremediation.