The effects of slow chilling (2 degrees C min(-1)) and rapid chilling (2,000 degrees C min(-1)) were investigated on the survival and membrane fluidity of Escherichia coli, of Bacillus subtilis, and of Saccharomyces cerevisiae. Cell death was found to be dependent on the physiological state of cell cultures and on the rate of temperature downshift. Slow temperature decrease allowed cell stabilization, whereas the rapid chilling induced an immediate loss of viability of up to more than 90 and 70% for the exponentially growing cells of E. coli and B. subtilis, respectively. To relate the results of viability with changes in membrane physical state, membrane anisotropy variation was monitored during thermal stress using the fluorescence probe 1,6-diphenyl-1,3,5-hexatriene. No variation in the membrane fluidity of all the three microorganisms was found after the slow chilling. It is interesting to note that fluorescence measurements showed an irreversible rigidification of the membrane of exponentially growing cells of E. coli and B. subtilis after the instantaneous cold shock, which was not observed with S. cerevisiae. This irreversible effect of the rapid cold shock on the membrane correlated well with high rates of cell inactivation. Thus, membrane alteration seems to be the principal cause of the cold shock injury.
International audienceThe effect of rapid and slow chilling on survival and nisin sensitivity was investigated in Escherichia coli. Membrane permeabilization induced by cold shock was assessed by uptake of the fluorescent dye 1-N-phenylnapthylamine. Slow chilling (2 degrees C min(-1)) did not induce transient susceptibility to nisin. Combining rapid chilling (2,000 degrees C min(-1)) and nisin causes a dose-dependent reduction in the population of cells in both exponential and stationary growth phases. A reduction of 6 log of exponentially growing cells was achieved with rapid chilling in the presence of 100 IU ml(-1) nisin. Cells were more sensitive if nisin was present during stress. Nevertheless, addition of nisin to cell suspension after the rapid chilling produced up to 5 log of cell inactivation for exponentially growing cells and 1 log for stationary growing cells. This suggests that the rapid chilling strongly damaged the cell membrane by disrupting the outer membrane barrier, allowing the sensitization of E. coli to nisin post-rapid chilling. Measurements of membrane permeabilization showed a good correlation between the membrane alteration and nisin sensitivity. Application involving the simultaneous treatment with nisin and rapid cold shock could thus be of value in controlling Gram negatives, enhancing microbiological safety and stability
Many fluorescent techniques are employed to evaluate the viability and activity of microbial cells used in biotechnology. These techniques are sometimes complex and the interpretation of results opened to misunderstanding. Moreover, new developments are constantly proposed especially concerning a more accurate evaluation of the state of the cells including eukaryotic microorganisms. This paper aims at presenting to biotechnologists unfamiliar with fluorescence the principles of these methods and the related possible pitfalls. It focuses on probes of the physical (integrity and fluidity) and energetical (intracellular pH and membrane potential) state of the cell membrane (bacterial and yeast cells) and presents also other probes (nucleic acids, respiration...) and new technical trends. The specificities of Gram-negative bacterial cells are also discussed.
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