Caratterizzazione della microflora spontanea di un alimento fermentato vegano

Tra i prodotti vegani più richiesti vi sono i “formaggi” vegani, alimenti fermentati a base di frutta secca o ottenuti attraverso trattamenti su latte di mandorla e latte di soia, e successivamente fermentati. Nella mia attività ho caratterizzato un alimento fermentato vegano e studiato la successione microbica durante la fermentazione di un “formaggio” ottenuto partendo da anacardi e preparato in maniera artigianale. Oltre agli aspetti microbiologici, ho analizzato anche alcune caratteristiche fisico chimiche. Durante il processo di produzione gli anacardi vengono messi in ammollo per 8 ore a temperatura ambiente e, successivamente, i semi vengono scolati e risciacquati sotto acqua corrente. Gli anacardi vengono poi addizionati di acqua e microrganismi probiotici e tritati in un mixer fino al raggiungimento di una crema omogenea. A questo punto il prodotto viene lasciato riposare a temperatura ambiente per 48 ore durante le quali ha luogo la fermentazione e poi addizionato di ingredienti. Le indagini chimico fisiche effettuate hanno evidenziato che il pH si mostra già basso prima dell’inizio della fermentazione vera e propria e scende a 4.5 dopo 48 ore di riposo a causa dell’accumulo di acidi organici, ed in particolare di acido lattico e acetico che indicando un’attività fermentativa condotta dai batteri lattici. Le analisi microbiologiche hanno confermato che l’effettivo agente di fermentazione era costituito da questi batteri che sono stati identificati a livello molecolare. Le specie identificate due eterofermentanti (Weissella e Leuconostoc), presenti soprattutto nelle prime fasi della fermentazione, ed una omofermentante (Pediococcus), prende il sopravvento mano a mano che la fermentazione procede. Il lavoro svolto ha permesso di ottenere alcune importanti informazioni per la produzione industriale di un “formaggio” vegano fermentato. Il processo studiato presenta numerosi punti di rischio che devono essere presi in considerazione prima di poter giungere alla messa a punto di un prodotto definitivo.

Conjugal Transfer of the Tn916-like Transposon TnFO1 from Enterococcus faecalis Isolated from Cheese to Other Gram-positive Bacteria

A Tn916-like transposon (TnFO1) was found in the multiple antibiotic resistant Enterococcus faecalis strain FO1 isolated from a raw milk cheese. In this strain, the tetracycline determinant was localized by DNA-DNA hybridization with a tetM nucleotide probe on the chromosome and on a 30-kb plasmid. The transposon TnFO1 was identified and characterized by DNA-DNA hybridization experiments with the five internal HincII fragments of Tn916. The tetracycline resistance determinant was identified by its complete nucleotide sequence as TetM. Transposon TnFO1 was also detected in its circular form by DNA-DNA hybridization and PCR amplification. Both ends including the joining region of the closed circular transposon TnFO1 were sequenced. TnFO1 could be transferred by conjugation from Enterococcus faecalis into Enterococcus faecalis, Lactococcus lactis subsp. lactis biovar. diacetylactis, Listeria innocua, Leuconostoc mesenteroides and Staphylococcus aureus, and from Lactococcus lactis subsp. lactis biovar. diacetylactis into Listeria innocua. Pulsed-field electrophoresis of genomic DNA from E. faecalis FO1 transconjugants showed that transposon TnFO1 integrated at different sites.

Isolation and characterization of microorganisms with probiotic potential

Tese de mestrado em Microbiologia Aplicada, apresentada à Universidade de Lisboa, através da Faculdade de Ciências, 2016

The production of the enzyme dextransucrase by batch and continuous fermentation techniques

A review of the literature of work carried out on dextransucrase production, purification, immobilization and reactions has been carried out. A brief review has also been made of the literature concerning general enzyme biotechnology and fermentation technology. Fed-batch fermentation of the bacteria Leuconostoc mesenteroides NRRL B512 (F) to produce dextransucrase has formed the major part of this research. Aerobic and anaerobic fermentations have been studied using a 16 litre New Brunswick fermenter which has a 3-12 litre working volume. The initial volume of broth used in the studies was 6 litres. The results of the fed-batch fermentations showed for the first time that yields of dextransucrase are much higher under the anaerobic conditions than during the aerobic fermentations. Dextransucrase containing 300-350 DSU/cm3 of enzyme activity has been obtained during the aerobic fermentations, while in the anaerobic fermentations, enzyme yields containing 450-500 DSU/cm3 have been obtained routinely. The type of yeast extract used in the fermentation medium has been found to have significant effects on enzyme yield. Of the different types studied, the Gistex Standard was found to be the type that favoured the highest enzyme production. Studies have also been carried out on the effect of agitation rate and antifoam on the enzyme production during the anaerobic experiments. Agitation rates of up to 600 rpm were found not to affect the enzyme yield, however, the presence of antifoam in the medium led to a significant reduction in enzyme activity (less than 300 DSU/cm3). Scale-up of the anaerobic fermentations has been performed at up to the 1000 litre level with enzyme yields containing more than 400 DSU/cm3 of activity being produced. Some of the enzyme produced at this scale was used for the first time to produce dextran on an industrial scale via the enzyme route, with up to 99% conversion of sucrose to dextran being obtained. An attempt has been made at continuous dextransucrase production. Cell washout was observed to occur at dilution rates of greater than 0.4 h-1. Dextransucrase containing up to 25 DSU/cm3/h has been produced continuously.

Batch and continuous fermentation methods for the production of dextransucrase

The available literature concerning dextransucrase and dextran production and purification has been reviewed along with the reaction mechanisms of the enzyme. A discussion of basic fermentation theory is included, together with a brief description of bioreactor hydrodynamics and general biotechnology. The various fermenters used in this research work are described in detail, along with the various experimental techniques employed. The micro-organism Leuconostoc mesenteroides NRRL B512 (F) secretes dextransucrase in the presence of an inducer, sucrose, this being the only known inducer of the enzyme. Dextransucrase is a growth related product and a series of fed-batch fermentations have been carried out to extend the exponential growth phase of the organism. These experiments were carried out in a number of different sized vessels, ranging in size from 2.5 to 1,000 litres. Using a 16 litre vessel, dextransucrase activities in excess of 450 DSU/cm3 (21.67 U/cm3) have been obtained under non-aerated conditions. It has also been possible to achieve 442 DSU/cm3 (21.28 U/cm3) using the 1,000 litre vessel, although this has not been done consistently. A 1 litre and a 2.5 litre vessel were used for the continuous fermentations of dextransucrase. The 2.5 litre vessel was a very sophisticated MBR MiniBioreactor and was used for the majority of continuous fermentations carried out. An enzyme activity of approximately 108 DSU/cm3 (5.20 U/cm3) was achieved at a dilution rate of 0.50 h-1, which corresponds to the maximum growth rate of the cells under the process conditions. A number of continuous fermentations were operated for prolonged periods of time, with experimental run-times of up to 389 h being recorded without any incidence of contamination. The phenomenon of enzyme enhancement on hold-up of up to 100% was also noted during these fermentations, with dextransucrase of activity 89.7 DSU/cm3 (4.32 U/cm3) being boosted to 155.7 DSU/cm3 (7.50 U/cm3) following 24 hours of hold-up. These findings support the recommendation of a second reactor being placed in series with the existing vessel.

Biodeterioration of harvested sugar cane in Jamaica

The microbiological, physical and chemical changes which occur instored, harvested sugarcane were studied in Jamaica and the United Kingdom.The degree of deterioration was proportional to time of storage, and wasrevealed by a statistically significant reduction in sucrose content.Other symptoms included a fall in pH, and increases in reducing sugars,dextran, viscosity, and microbial count. Cut cane was universally infectedwith Leuconostoc mesenteroides, which reached a maximum count of 107 to 108organisms per ml. juice within. 3 to 4 days of harvest. Counts of othermicroorganisms were generally insignificant, except for occasional lactobacilli.A new dextran-forming species was named Lactobacillus confusus.Microorganisms isolated from deteriorated cane were screened for theirability to cause deterioration of a sterile, synthetic cane juice. L. mesenteroides strains were the most deteriogenic, but attempts toreproduce the symptoms of "sour" cane by inoculation of this organism intocut cane were only partially successful. L. mesenteroides was present in the soil and the epiphytic flora of the stalk. The principal vector of infection appeared to be the cutters' machete, especially in wet weather. Cane harvested by a chopper machine deteriorated more rapidly than hand-cut whole-stalks. Economic losses due to deterioration of harvested cane were estimated to be 9.2% of the initial recoverable sugar for the 1969 crop at Frome Estate, Jamaica. Dextran content was a useful indicator of cane biodeterioration. The dextran content of mill juices was correlated with rainfall, and significant correlations were obtained between dextran content and viscosity of mill syrups and the amount of sugar lost in final molasses; it also caused the formation of elongated crystals. Attempts to control sour cane by chemical and physical methods were unsuccessful, and it was concluded that the only solution is to mill cane within 24 hours of harvest. A novel method for removal of dextran from mill juices by enzymic treatment with dextranase was developed and patented.

Dextranas e seus derivados fosforilados: obtenção e avaliação do potencial antioxidante, imunomodulatório e anticoagulante

Glucans are polysaccharides with different pharmacological and biological activities described. However, there are some reports about the activities of the glucan type α (alpha). In this context, a group of α-D-glucans called dextrans extracted from Leuconostoc mesenteroides bacteria, with molecular weights of 10 (D10), 40 (D40) and 147 (D147) kDa and their phosphorylated derivatives P10, P40 and P147, were evaluated as for their antioxidant, anticoagulant and immunomodulatory potential for the first time, in order to elucidate compounds with potent activities and low toxicity. Infrared spectroscopy analysis, monosaccharide composition and chemical dosages showed that these dextrans are the same polysaccharide, but with different molecular weights, besides confirming the success of phosphorylation. None presented with anticoagulant features. The reducing power test showed that D147 was twice as potent as other dextrans. On the other hand, all six samples showed similar activity (50%) when it came to scavenging the OH radical. To the superoxide ion scavenging, only D10 had a pronounced activity (50%). D40 was the single native dextran that presented with immunomodulatory features since it double stimulated the proliferation of murine macrophages (RAW 264.7) and double the release of nitric oxide by the cells, both in the absence and presence of lipopolysaccharides (LPS). In addition, D40 showed a greater scavenging activity (50%) for the hydrogen peroxide, which caused it to also be the more potent dextran when it came to inhibiting lipid peroxidation (70%). On other hand, P147 showed the highest iron and copper ion chelation activity (~85%). P10 proved be the most effective compound to macrophage proliferation. The results point toward dextrans with a 40 kDa weight as being ideal for antioxidant and immunomodulatory use, could be supplemented with phosphorylated derivatives. However, future studies with the D40 and other similarly dextrans are to confirm this hypothesis.

Impiego di fermentati vegetali per migliorare il profilo aromatico del pane

ABSTRACT Il lavoro svolto in questa tesi è stato quello di produrre dei pani andando a sostituire nella formulazione l’acqua con delle puree vegetali di mirtilli o peperoni, utilizzate fresche o fermentate. La fermentazione è stata condotta tramite due ceppi di batteri lattici (Leuconostoc mesenteroides L223 e Lactiplantibacillus plantarum L88) e due di lieviti (Saccharomyces cerevisiae Y267 e Hanseniaspora uvarum Y309), che erano stati precedentemente isolati dalle puree di mirtilli e peperoni fermentate spontaneamente, e che presentavano le migliori performances. Gli obiettivi di questa tesi erano di arricchire il profilo sensoriale e il contenuto in sostanze funzionali (ad esempio polifenoli e vitamine, di cui le matrici utilizzate sono particolarmente ricche) del pane. I prodotti ottenuti sono stati analizzati per monitorare gli aspetti chimico-fisici (pH, lievitazione dell’impasto) e il profilo aromatico. Sui diversi pani ottenuti è stato infine eseguito un test di assaggio per valutare l’accettabilità del prodotto ed una sua possibile introduzione nel mercato. I risultati delle analisi hanno mostrato un rilevante sviluppo di sostanze volatili nelle puree vegetali fermentate e queste molecole, in parte, sono state trasferite nel pane andando a modificare il suo profilo aromatico. L’aggiunta di puree fermentate ha quindi fortemente caratterizzato gli impasti e i pani ottenuti, che presentavano un profilo aromatico più complesso rispetto ai pani ottenuti con le sole puree vegetali non fermentate. Questo aspetto positivo è stato confermato dal test di assaggio, poiché i pani addizionati di puree fermentate (soprattutto mirtillo) hanno ottenuti punteggi positivi in termini di dolcezza, acidità e fruttato. Questo conferma le grandi potenzialità di questi pani, che oltre a differenziare i prodotti presenti sul mercato, possono andare a valorizzare matrici vegetali sovra-mature, e destinate ad essere scartate, o parti di vegetali non utilizzate nelle produzioni.