Cell Size and Water Permeability as Determining Factors for Cell Viability after Freezing at Different Cooling Rates

Dumont, Frédéric; Marechal, Pierre-André; Gervais, Patrick

doi:10.1128/aem.70.1.268-272.2004

Cited by 109 publications

(108 citation statements)

References 18 publications

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“…Our results for the effect of different freezing rates on yeast survival in the range of cooling rates that we studied are consistent with the results of other workers (7,8,23,24). The levels of survival (expressed as RGC) generally remained high at cooling rates of 10 to 15°C per min but decreased dramatically at cooling rates of 30 to 35°C per min or higher (Table 1 and Fig.…”

Section: Discussionsupporting

confidence: 81%

Aquaporin-Mediated Improvement of Freeze Tolerance of Saccharomyces cerevisiae Is Restricted to Rapid Freezing Conditions

Tanghe

Dijck

Colavizza

et al. 2004

Appl Environ Microbiol

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Previous observations that aquaporin overexpression increases the freeze tolerance of baker's yeast (Saccharomyces cerevisiae) without negatively affecting the growth or fermentation characteristics held promise for the development of commercial baker's yeast strains used in frozen dough applications. In this study we found that overexpression of the aquaporin-encoding genes AQY1-1 and AQY2-1 improves the freeze tolerance of industrial strain AT25, but only in small doughs under laboratory conditions and not in large doughs under industrial conditions. We found that the difference in the freezing rate is apparently responsible for the difference in the results. We tested six different cooling rates and found that at high cooling rates aquaporin overexpression significantly improved the survival of yeast cells, while at low cooling rates there was no significant effect. Differences in the cultivation conditions and in the thawing rate did not influence the freeze tolerance under the conditions tested. Survival after freezing is determined mainly by two factors, cellular dehydration and intracellular ice crystal formation, which depend in an inverse manner on the cooling velocity. In accordance with this so-called two-factor hypothesis of freezing injury, we suggest that water permeability is limiting, and therefore that aquaporin function is advantageous, only under rapid freezing conditions. If this hypothesis is correct, then aquaporin overexpression is not expected to affect the leavening capacity of yeast cells in large, industrial frozen doughs, which do not freeze rapidly. Our results imply that aquaporinoverexpressing strains have less potential for use in frozen doughs than originally thought.Although much correlative evidence is available, the determinants of freeze resistance in Saccharomyces cerevisiae are largely unknown (for a review see reference 34). The injury sustained during freezing and thawing is caused by a combination of multiple types of stress imposed on the cells, such as changes in temperature, water content, water state, pH, and free radical, ion, and solute concentrations. The concomitant loss of survival is not attributable to any one form of injury and depends on the cooling and warming rates, the final temperature, the duration of freezing, and the suspending medium (23,24).When a cell suspension is cooled to a temperature of 0°C or less, both the suspending medium and the cells initially supercool. Extracellular ice crystal formation precedes intracellular freezing and is determined by the freezing point of the suspending medium and the presence of ice-nucleating agents. Based only on osmolarity, the freezing point of the cytoplasm is predicted to be approximately Ϫ1°C. Nevertheless, the cell interior typically remains unfrozen until the temperature is Ϫ10 to Ϫ15°C. This intracellular supercooling may be due to prevention of growth of ice into the cell interior by the cell membrane and due to the lack of nucleators of supercooled water within the cell (23, 24).Following external fr...

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Section: Discussionsupporting

confidence: 81%

Aquaporin-Mediated Improvement of Freeze Tolerance of Saccharomyces cerevisiae Is Restricted to Rapid Freezing Conditions

Tanghe

Dijck

Colavizza

et al. 2004

Appl Environ Microbiol

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“…Esta maior eficiência na conservação a ultrabaixas temperaturas pode estar relacionada com a maior velocidade de congelamento, que causa menores danos à célula, por menor desidratação e menos rompimento de membranas (Dumont et al, 2004;Fellows, 2006). Segundo Almeida et al (2002), a técnica da crioconservação, isto é, o armazenamento a -196 ºC, proporciona potencial para uma preservação sem limites de tempo, com a redução do metabolismo a níveis tão baixos que todos os processos bioquímicos são significativamente reduzidos e a deterioração biológica é virtualmente paralisada.…”

Section: Resultsunclassified

Conservação de grãos de pólen de mamoneira a baixas temperaturas

2012

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Conservation of castor bean pollen at low temperaturesThe objective of storing pollen is to preserve material for future use, providing optimal conditions to maintain their original germination, vigor and genetic integrity. The aim of this study was to investigate the germination of castor bean (Ricinus communis L.) pollen after storage at low temperatures. For this purpose, pollen of the cultivars IAC 80 and AL Guarany 2002 were used and stored at four different temperatures, -196; -72; -18; and 4°C, for a period of 60 days. The pollen viability was assessed weekly for five weeks, with a last evaluation performed after eight weeks of storage using the in vitro germination test. Culture medium containing 10 gL -1 agar, 100 gL -1 sucrose, 0.004 g L -1 boric acid, pH 6.0 was prepared and poored into cavity slides, where the pollen was evenly distributed over the surface of the medium. The plates were incubated at 20°C in BOD. The experiment was arranged in a 2x4 factorial completely randomized design (2 cultivars x 4 temperatures) for each storage time, with 100 pollen grains analyzed per repetition, totaling six of each treatment. There was significant difference between treatments for the cultivar x temperature interaction in the fifth week of observation (p<0.05). Other cultivar x temperature interactions were highly significant at all times of observation (p<0.01). It is therefore concluded that the use of ultra low temperatures allows the maintenance of castor bean pollen viability until the fifth week of storage.

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“…Both penetrate the cell wall and plasmatic membrane, avoiding the intracellular ice formation and altering the plasmatic membrane elasticity, allowing a better accommodation of the cellular volume expansion during water freezing [15]. However, DMSO and GO can also affect the cellular metabolism due to their toxicity [6].…”

Section: Discussionmentioning

confidence: 99%

“…Besides the loss of cellular structure, slow freezing of external water causes cell dehydration and increase of cytoplasmic ion concentration. This process reduces the freezing temperature of the cytoplasm turning it in a highly viscous concentration mixture with low metabolic activity but with irreversible damages to cell and/or cell proteins [15].…”

Section: Discussionmentioning

confidence: 99%

“…Cryoprotective agents: 1 % dimethyl sulfoxide (DMSO); 5 % glycerol (GO); 10 % saccharose (SA); 4 % glucose (GU); 6 % polyethylene glycol-6000 (PEG) and 5 % malt extract (ME) GO 56 100 100 100 100 100 0 93 100 87 100 95 DMSO 93 100 100 100 93 98 54 87 100 75 80 86 GU 18 100 100 100 100 100 0 100 93 93 100 96 SA 83 100 100 100 100 100 40 100 100 100 100 100 ME 23 100 100 100 100 100 0 100 87 93 93 93 PEG 0 100 100 100 100 100 0 100 80 80 73 83 Cryoprotectant average 46 100 100 100 99 -16 97 93 88 91 -Cultivation medium and substrates with mycelium: potato dextrose agar disks (PDA); whole oat grains (OG); whole wheat grains (WG), whole rice grains without hulls, known as brown rice (RG) and whole millet grains (MG). Cryoprotective agents: 1 % dimethyl sulfoxide (DMSO); 5 % glycerol (GO); 10 % saccharose (SA); 4 % glucose (GU); 6 % polyethylene glycol-6000 (PEG) and 5 % malt extract (ME) linked intracellular water reduces the differences between intra and intercellular freezing temperatures [15] and controls the cellular dehydration at slow freezing temperatures. Another possibility is that the wheat grain structure is composed of a capillary net [16], which provides physical protection to mycelium.…”

Section: Discussionmentioning

confidence: 99%

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Cryopreservation at −20 and −70 °C of Pleurotus ostreatus on Grains

et al. 2012

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Alternative substrates for cryopreservation at -20°C have been little explored for basidiomycetes and could bring new possibilities of lower cost cryopreservation. Nevertheless, freezing temperatures between -15 and -60°C are very challenging because they frequently result in cryoinjuries. The objective of this study was to evaluate substrates associated to cryoprotective agents for Pleurotus ostreatus cryopreservation at -20 or -70°C in order to develop alternative techniques for basidiomycete cryopreservation. P. ostreatus was grown on potato dextrose agar or whole grains of oat, wheat, rice or millet and transferred to cryovials with cryoprotective solution with 1 % dimethyl sulfoxide, 5 % glycerol, 10 % saccharose, 4 % glucose, 6 % polyethylene glycol-6000 or 5 % malt extract. The mycelium in the cryovials were cryopreserved at -20 or -70°C and recovered for evaluation of the mycelial growth viability after 1 and 3 years. Both substrates and cryoprotectants affect the viability of the mycelial growth cryopreserved at -20 or -70°C; wheat grains combined with cryoprotectants such as saccharose or glucose are effective for keeping mycelium viable after cryopreservation at -20°C for 1 or 3 years; for cryopreservation at -70°C after 1 or 3 years, any substrate combined with any cryoprotectant is effective for preserving the mycelium viable, except for millet grains with polyethylene glycol after 3 years; semi-permeable cryoprotective agents such as saccharose and glucose are the most effective for cryopreservation at -20 or -70°C for at least 3 years.

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Cell Size and Water Permeability as Determining Factors for Cell Viability after Freezing at Different Cooling Rates

Cited by 109 publications

References 18 publications

Aquaporin-Mediated Improvement of Freeze Tolerance of Saccharomyces cerevisiae Is Restricted to Rapid Freezing Conditions

Aquaporin-Mediated Improvement of Freeze Tolerance of Saccharomyces cerevisiae Is Restricted to Rapid Freezing Conditions

Conservação de grãos de pólen de mamoneira a baixas temperaturas

Cryopreservation at −20 and −70 °C of Pleurotus ostreatus on Grains

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