Application of anhydrobiosis and dehydration of yeasts for non-conventional biotechnological goals

Rapoport, Alexander; Turchetti, Benedetta; Buzzini, Pietro

doi:10.1007/s11274-016-2058-8

Cited by 24 publications

(11 citation statements)

References 92 publications

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“…Yeasts can overcome desiccation through the phenomenon of anhydrobiosis, which determines a temporary and reversible suspension of their metabolism (Rapoport, Turchetti, & Buzzini, ). Like plants and animals, yeasts respond to high osmotic pressure increasing their intracellular solute concentration by pumping inorganic ions from external medium or synthesizing compatible solutes (i.e.…”

Section: Major Factors In Extreme Habitats: Hard But Not Impossiblementioning

confidence: 99%

Extremophilic yeasts: the toughest yeasts around?

Buzzini

Turchetti

Yurkov

2018

Yeast

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Microorganisms are widely distributed in a multitude of environments including ecosystems that show challenging features to most life forms. The combination of extreme physical and chemical factors contributes to the definition of extreme habitats although the definition of extreme environments changes depending on one's point of view: anthropocentric, microbial-centric or zymo-centric. Microorganisms that live under conditions that cause hard survival are called extremophiles. In particular organisms that require extreme conditions are called true extremophiles while organisms that tolerate them to some extent are termed extremotolerant. Deviation of temperature, pH, osmotic stress, pressure and radiation from the common range delineates extreme environments. Yeasts are versatile eukaryotic organisms that are not frequently considered the toughest microorganisms in comparison with prokaryotes. Nevertheless extremophilic or extremotolerant species are present also within this group. Here a brief description is provided of the main extreme habitats and the metabolic and physiological modifications adopted by yeasts depending on their adverse conditions. Additionally the main extremophilic and extremotolerant yeast species associated with a few extreme habitats are listed.

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Section: Major Factors In Extreme Habitats: Hard But Not Impossiblementioning

confidence: 99%

Extremophilic yeasts: the toughest yeasts around?

Buzzini

Turchetti

Yurkov

2018

Yeast

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“…However, one of the most important stresses occurs during dehydration. Removal of water by dry-air and elevated temperatures generate modifications in the water potential of the medium and in the cells themselves, leading to a decrease in their volume and an increase of their contact surface with air (Beker and Rapoport, 1987;Gervais and Beney, 2001;Lemetais et al, 2012;Rapoport et al, 2016). All these modifications can induce the accumulation of reactive oxygen species (ROS), consequently, oxidative stress and cause the cells death (Eleutherio et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Biophysical Stress Responses of the Yeast Lachancea thermotolerans During Dehydration Using Synchrotron-FTIR Microspectroscopy

et al. 2020

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During industrial yeast production, cells are often subjected to deleterious hydric variations during dehydration, which reduces their viability and cellular activity. This study is focused on the yeast Lachancea thermotolerans, particularly sensitive to dehydration. The aim was to understand the modifications of single-cells biophysical profiles during different dehydration conditions. Infrared spectra of individual cells were acquired before and after dehydration kinetics using synchrotron radiation-based Fourier-transform infrared (S-FTIR) microspectroscopy. The cells were previously stained with fluorescent probes in order to measure only viable and active cells prior to dehydration. In parallel, cell viability was determined using flow cytometry under identical conditions. The S-FTIR analysis indicated that cells with the lowest viability showed signs of membrane rigidification and modifications in the amide I (α-helix and β-sheet) and amide II, which are indicators of secondary protein structure conformation and degradation or disorder. Shift of symmetric C-H stretching vibration of the CH 2 group upon a higher wavenumber correlated with better cell viability, suggesting a role of plasma membrane fluidity. This was the first time that the biophysical responses of L. thermotolerans single-cells to dehydration were explored with S-FTIR. These findings are important for clarifying the mechanisms of microbial resistance to stress in order to improve the viability of sensitive yeasts during dehydration.

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“…They provide a better understanding of the role of water in the maintenance of various cell structures and biological macromolecules and reveal the potential opportunities for living organisms to survive under extreme conditions. Application of this knowledge is important for the traditional production of active (or instant) dry yeast preparations for the food industry, as well as for the nonconventional use of viable dry yeasts (Rapoport, ; Rapoport, Turchetti, & Buzzini, ; Rapoport, Golovina, Gervais, Dupont, & Beney, ). In addition, as yeast cells are an efficient eukaryotic cell model, information on intracellular protective reactions that promote the survival of living organisms under extreme conditions could also be extrapolated for higher organisms, such as in medical applications.…”

Section: Introductionmentioning

confidence: 99%

Anhydrobiosis in yeasts: Psychrotolerant yeasts are highly resistant to dehydration

Khroustalyova

Giovannitti

Severini

et al. 2019

Yeast

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Yeast cells are able to transition into a state of anhydrobiosis (temporary reversible suspension of metabolism) under conditions of desiccation. One of the most efficient approaches for understanding the mechanisms underlying resistance to dehydrationrehydration is to identify yeasts, which are stable under such treatments, and compare them with moderately resistant species and strains. In the current study, we investigated the resistance to dehydration-rehydration of six psychrotolerant yeast strains belonging to two species. All studied strains of Solicoccozyma terricola and Naganishia albida were found to be highly resistant to dehydration-rehydration. The viability of S. terricola strains was close to 100%. Such results have not been previously reported in studies of anhydrobiosis in yeasts. The plasma membrane changes, revealed by determining its permeability under various rehydration conditions, were also surprisingly minimal. Thus, the high level of resistance of psychrotolerant yeast strains might be related to the chemical composition and molecular organisation of their plasma membranes. Aside from plasma membrane characteristics, other important factors may also influence the maintenance of yeast cell viability under conditions of dehydration-rehydration.

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Application of anhydrobiosis and dehydration of yeasts for non-conventional biotechnological goals

Cited by 24 publications

References 92 publications

Extremophilic yeasts: the toughest yeasts around?

Extremophilic yeasts: the toughest yeasts around?

Biophysical Stress Responses of the Yeast Lachancea thermotolerans During Dehydration Using Synchrotron-FTIR Microspectroscopy

Anhydrobiosis in yeasts: Psychrotolerant yeasts are highly resistant to dehydration

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