Isolation and purification of an enzyme hydrolyzing ochratoxin A from aspergillus niger

Ochratoxin A is a mycotoxin produced by several Aspergillus and some Penicillium species which may be present in food and feed products. It can be enzymatically hydrolyzed into ochratoxin α and l-β-phenylalanine, thereby decreasing its toxicity. The ochratoxin A degradation capacity of Aspergillus niger is well known and here we report the isolation and purification of a novel enzyme from A. niger that hydrolyzes this mycotoxin. A wheat germ medium supplemented with ochratoxin A was used to produce the enzyme, which was purified from culture filtrate by acetone precipitation and anion exchange chromatography. An overall purification of 2.5-fold with a recovery of 68% and a final specific activity of 36 U/mg was obtained. The enzyme is a metalloenzyme as it was inhibited at 10 mM EDTA, whereas PMSF had no effect. The ochratoxin A hydrolytic enzyme presented a V max of 0.44 μM/min and a K m of 0.5 mM when the reaction was carried out at pH 7.5 and 37°C.Fundação para a Ciência e a Tecnologia (FCT

Biodistribution Investigations of Technetium-Labelllled Murine Bone Marrow-Derived Extracellllular Vesicles by Nanospect/Ct

The in vivo tracing of the biodistribution of extracellular vesicles (EVs) is a pre-requisite in identifying their target cells and understanding their function. Although luorescent labelling of EVs is already used, radiolabelling can provide more details in understanding biodistribution of EVs. In the present paper we report radiolabelling of bone marrow-derived EVs and in vivo tracing of their biodistribution. EVs isolated from the bone marrow supernatant of űő7ŰL/6 mice were labelled with the technetium-99m (99mTc) isotope. Labelling was eficient and labelled EVs were stable during the 2Ő hours follow-up. Detection of labelled EVs after intravenous injection in mice was performed using ex vivo measurements and in vivo imaging. Ex vivo examinations revealed that at Ő hours post-injection, the highest accumulation rate was in the liver, kidney, spleen and femur epiphysis. In vivo imaging using nanoSPEűT/űT conirmed the ex vivo examinations and demonstrated slow elimination of the radioactivity, 2Ő hours post- injection the bone marrow-containing epiphysis and lymph nodes showed the highest retention values; liver, spleen and kidney were also clearly detectable. In summary, labelling of bone marrow-derived EVs with 99mTc coupled with SPEűT/űT detection was a reliable method for quantitative distribution studies of EVs in vivo