Leonardo Costa Pereira scite author profile

The yeast Dekkera bruxellensis plays an important role in industrial fermentation processes, either as a contaminant or as a fermenting yeast. In this study, an analysis has been conducted of the fermentation characteristics of several industrial D. bruxellensis strains collected from distilleries from the Southeast and Northeast of Brazil, compared with Saccharomyces cerevisiae. It was found that all the strains of D. bruxellensis showed a lower fermentative capacity as a result of inefficient sugar assimilation, especially sucrose, under anaerobiosis, which is called the Custer effect. In addition, most of the sugar consumed by D. bruxellensis seemed to be used for biomass production, as was observed by the increase of its cell population during the fermentation recycles. In mixed populations, the surplus of D. bruxellensis over S. cerevisiae population could not be attributed to organic acid production by the first yeast, as previously suggested. Moreover, both yeast species showed similar sensitivity to lactic and acetic acids and were equally resistant to ethanol, when added exogenously to the fermentation medium. Thus, the effects that lead to the employment of D. bruxellensis in an industrial process and its effects on the production of ethanol are multivariate. The difficulty of using this yeast for ethanol production is that it requires the elimination of the Custer effect to allow an increase in the assimilation of sugar under anaerobic conditions.

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Improving the digital skills of older adults in a COVID-19 pandemic environment

Garcia

Rodrigues

Pereira

et al. 2021

Educational Gerontology

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Atividade antifúngica do extrato de Psidium guajava Linn. (goiabeira) sobre leveduras do gênero Candida da cavidade oral: uma avaliação in vitro

Alves¹,

Leite²,

Pereira³

et al. 2006

Rev. bras. farmacogn.

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Natural predator and a human stimulus differently affect the behavior, cortisol and cerebral hemisphere activity of marmoset monkeys

Pereira

Duarte

Maior

et al. 2018

Physiology & Behavior

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The behavior, cortisol concentration and cerebral hemisphere activity of twelve marmoset monkeys were determined during standardized predatory stress-related events. Each subject was submitted to three 5-min trials, randomly held at 2-week intervals: a human intruder, a taxidermized oncilla cat and a no-stimulus control trial. Stimuli were positioned outside the home-cage and the ensuing reaction recorded. Baseline tympanic membrane temperature (TMT) was subtracted from the post-trial measure to determine changes in blood flow induced by ipsilateral brain activity. Cortisol was assayed immediately after the post-trial TMT assessments. Both genders reacted fearfully/anxiously towards the stimuli - each condition inducing a distinct pattern. Cortisol increased only when females were confronted with the wildcat, with higher levels of alarm calls predicting lower cortisol release. When either stimulus was present, changes in TMT were detected, albeit only in the right ear. The specific directional shift in temperature was gender- and stimulus-dependent, requiring further investigation. The control trial did not alter any of the parameters. Marmosets thus exhibit flexible multileveled coping strategies towards different aversive events, yet in general these seem to be asymmetrically processed by the right cerebral hemisphere.

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The fermentation of sugarcane molasses by Dekkera bruxellensis and the mobilization of reserve carbohydrates

Pereira

Lucatti

Basso

et al. 2013

Antonie van Leeuwenhoek

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The yeast Dekkera bruxellensis is considered to be very well adapted to industrial environments, in Brazil, USA, Canada and European Countries, when different substrates are used in alcoholic fermentations. Our previous study described its fermentative profile with a sugarcane juice substrate. In this study, we have extended its physiological evaluation to fermentation situations by using sugarcane molasses as a substrate to replicate industrial working conditions. The results have confirmed the previous reports of the low capacity of D. bruxellensis cells to assimilate sucrose, which seems to be the main factor that can cause a bottleneck in its use as fermentative yeast. Furthermore, the cells of D. bruxellensis showed a tendency to deviate most of sugar available for biomass and organic acids (lactic and acetic) compared with Saccharomyces cerevisiae, when calculated on the basis of their respective yields. As well as this, the acetate production from molasses medium by both yeasts was in marked contrast with the previous data on sugarcane juice. Glycerol and ethanol production by D. bruxellensis cells achieved levels of 33 and 53 % of the S. cerevisiae, respectively. However, the ethanol yield was similar for both yeasts. It is worth noting that this yeast did not accumulate trehalose when the intracellular glycogen content was 30 % lower than in S. cerevisiae. The lack of trehalose did not affect yeast viability under fermentation conditions. Thus, the adaptive success of D. bruxellensis under industrial fermentation conditions seems to be unrelated to the production of these reserve carbohydrates.

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