Laurent Beney

Influence of the fluidity of the membrane on the response of microorganisms to environmental stresses.

Abstract. The aim of this mini-review is to relate membrane physical properties to the adaptation and resistance of microorganisms to environmental stresses. In the first part, the effects of various stresses on the structure and dynamic properties of phospholipid and biological membranes are presented. The compensation of these effects, i.e., change in membrane fluidity, phase transitions, by the active cellular control of the membrane chemical composition, is then described. In this natural process, the change in membrane fluidity is viewed as the detecting input signal that initiates the regulation, activating proteic effectors that in turn may influence the chemical composition of the membrane (feedback). This adaptation system allows the maintenance of the physical characteristics of membranes and, thereby, of their functionality. When environmental stresses are extreme and occur abruptly, the regulation process may not compensate for the changes in the membrane physical characteristics. In such cases, important variations in the membrane fluidity and structure may induce cellular damages and cell death. However, the lethal consequences are not systematically observed because protective effects of changes in the membrane physical state on the resistance to stresses are also reported.

Lipid-Induced ER Stress: Synergistic Effects of Sterols and Saturated Fatty Acids

Stress within the endoplasmic reticulum (ER) induces a coordinated response, namely the unfolded protein response (UPR), devoted to helping the ER cope with the accumulation of misfolded proteins. Failure of the UPR plays an important role in several human diseases. Recent studies report that intracellular accumulation of saturated fatty acids (SFAs) and cholesterol, seen in diseases of high incidence, such as obesity or atherosclerosis, results in ER stress. In the present study, we evaluated the effects of perturbations to lipid homeostasis on ER stress/UPR induction in the model eukaryote Saccharomyces cerevisiae. We show that SFA originating from either endogenous (preclusion of fatty acid desaturation) or exogenous (feeding with extracellular SFA) sources trigger ER stress and that ergosterol, the major sterol in yeast, acts synergistically with SFA in this process. This latter effect is connected to ergosterol accumulation within microsomal fractions from SFA‐accumulating cells, which display highly saturated phospholipid content. Moreover, treating the cells with the molecular chaperone 4‐phenyl butyrate abolishes UPR induction, suggesting that lipid‐induced ER stress leads to an overload of misfolded protein that acts, in turn, as the molecular signal for induction of the UPR. The present data are discussed in the context of human diseases that involve lipid deregulation.

The effect of osmotic pressure on the membrane fluidity of Saccharomyces cerevisiae at different physiological temperatures

Abstract. Membrane fluidity in whole cells of Saccharomyces cerevisiaeW303-1A was estimated from fluorescence polarization measurements using the membrane probe, 1,6-diphenyl-1,3,5-hexatriene, over a wide range of temperatures (6–35xa0°C) and at seven levels of osmotic pressure between 1.38xa0MPa and 133.1xa0MPa. An increase in phase transition temperatures was observed with increasing osmotic pressure. At 1.38xa0MPa, a phase transition temperature of 12±2xa0°C was observed, which increased to 17±4xa0°C at 43.7xa0MPa, 21±7xa0°C at 61.8xa0MPa, and 24±9xa0°C at an osmotic pressure of 133.1xa0MPa. From these results we infer that, with increases in osmotic pressure, the change in phospholipid conformation occurs over a larger temperature range. These results allow the representation of membrane fluidity as a function of temperature and osmotic pressure. Osmotic shocks were applied at two levels of osmotic pressure and at nine temperatures, in order to relate membrane conformation to cell viability.

Viability of Escherichia coli after combined osmotic and thermal treatment: a plasma membrane implication

This study investigates the influence of temperature (T) and osmotic pressure (Pi) on the viability of Escherichia coli K12 during an osmotic treatment. Osmotic shock (dehydration and rehydration within 1 s) in liquid media at different temperatures (4, 10, 30 and 37 degrees C) and different levels of osmotic pressure (26, 30, 35, 40, 82 and 133 MPa) were realized. Results show that a sudden dehydration, below 40 MPa, destroyed up to 80% of the bacterial population for each tested temperature, whereas viability was greater than 90% for an osmotic pressure less than 26 MPa. The influence of T and Pi on the membranes physical structure is finally considered to explain the results in light of FTIR and electron microscopy study of the influence of temperature and osmotic pressure on E. coli membrane phospholipids conformation.

Death of Escherichia coli during rapid and severe dehydration is related to lipid phase transition

AbstractThis study reports the effects of exposure to increasing osmotic pressure on the viability and membrane structure of Escherichia coli. Changes in membrane structure after osmotic stress were investigated by electron transmission microscopy, measurement of the anisotropy of the membrane fluorescent probe DPH (1,6-diphenyl-1,3,5-hexatriene) inserted innE. coli, and Fourier infrared spectroscopy (FTIR). The results show that, above a critical osmotic pressure of 35xa0MPa, the viability of the bacterium is drastically reduced (2 log decrease in survivors). Electron micrographs revealed a severe contraction of the cytoplasm and the formation of membrane vesicles at 40xa0MPa. Changes in DPH anisotropy showed that osmotic dehydration to 40xa0MPa promoted a decrease in the membrane fluidity of integral cells ofnE. coli. FTIR measurements showed that at 10–40xa0MPa a transition from lamellar liquid crystal to lamellar gel among the phospholipids extracted fromnE. coli occurred. Bacterial death resulting from dehydration can be attributed to the conjunction between membrane deformation, caused by the volumetric contraction, and structural changes of the membrane lipids. The influence of the latter on the formation of membrane vesicles and on membrane permeabilization at lethal osmotic pressure is discussed, since vesiculation is hypothetically responsible for cell death.

Influence of thermal and osmotic stresses on the viability of the yeast Saccharomyces cerevisiae.

This work studies the effect of thermal and dehydration kinetics on the viability of Saccharomyces cerevisiae. The influence of the rate of temperature (T) and osmotic pressure (pi) increases are first investigated. Results showed that yeast viability is preserved by slow variations of temperature or osmotic pressure in a precise range of T or pi. The influence of a previous thermal stress on the resistance to a hyperosmotic stress is also studied. Temperatures equal to or lower than 10 degrees C allowed the preservation of viability after an osmotic stress whereas temperatures above 10 degrees C did not preserve yeast survival.

SHAPE MODIFICATION OF PHOSPHOLIPID VESICLES INDUCED BY HIGH PRESSURE : INFLUENCE OF BILAYER COMPRESSIBILITY

Giant vesicles composed of pure egg yolk phosphatidylcholine (EYPC) or containing cholesterol (28 mol%) have been studied during a high hydrostatic pressure treatment to 285 MPa by microscopic observation. During pressure loading the vesicles remain spherical. A shape transition consisting of budding only occurs on the cholesterol-free vesicles during pressure release. The decrease in the volume delimited by the pure EYPC bilayer between 0.1 and 285 MPa was found to be 16% of its initial volume, whereas the bulk compression of water in this pressure range is only 10%. So the compression at 285 MPa induced a water exit from the pure EYPC vesicle. The shape transition of the EYPC vesicle during pressure release is attributed to an increase in its area-to-volume ratio caused by the loss of its water content during compression. Because bulk compression of the cholesterol-containing vesicle is close to that of water, no water transfer would be induced across the bilayer and the vesicle remains spherical during the pressure release.

Air drying optimization of Saccharomyces cerevisiae through its water–glycerol dehydration properties

Aims:u2002 This study describes the different stages of optimization in an original drying process for yeasts, which allows the retrieval of dried samples of Saccharomyces cerevisiae CBS 1171 with maximum viability.

Control of Relative Air Humidity as a Potential Means to Improve Hygiene on Surfaces: A Preliminary Approach with Listeria monocytogenes

Relative air humidity fluctuations could potentially affect the development and persistence of pathogenic microorganisms in their environments. This study aimed to characterize the impact of relative air humidity (RH) variations on the survival of Listeria monocytogenes, a bacterium persisting on food processing plant surfaces. To assess conditions leading to the lowest survival rate, four strains of L. monocytogenes (EGDe, CCL500, CCL128, and LO28) were exposed to different RH conditions (75%, 68%, 43% and 11%) with different drying kinetics and then rehydrated either progressively or instantaneously. The main factors that affected the survival of L. monocytogenes were RH level and rehydration kinetics. Lowest survival rates between 1% and 0.001% were obtained after 3 hours of treatment under optimal conditions (68% RH and instantaneous rehydration). The survival rate was decreased under 0.001% after prolonged exposure (16h) of cells under optimal conditions. Application of two successive dehydration and rehydration cycles led to an additional decrease in survival rate. This preliminary study, performed in model conditions with L. monocytogenes, showed that controlled ambient RH fluctuations could offer new possibilities to control foodborne pathogens in food processing environments and improve food safety.

Cell Death Induced by Mild Physical Perturbations Could Be Related to Transient Plasma Membrane Modifications

An understanding of membrane destabilization induced by osmotic treatments is important to better control cell survival during biotechnological processes. The effects on the membranes of the yeast Saccharomyces cerevisiae of perturbations similar in intensity (same amount of energy) but differing in the source type (heat, compression and osmotic gradient) were investigated. The anisotropy of the fluorescent probe 1,6-diphenyl-1,3,5-hexatriene was measured before and after each treatment to assess the reversibility of the membrane changes related to each treatment. Except for heat shock at 75°C, changes in membrane fluidity were reversible after the return to initial conditions, showing that two kinds of physical stress can be distinguished regarding the reversibility of membrane changes: high and mild energy stresses. With the application of osmotic gradients, anisotropy was assessed during treatment with five osmotic pressure levels from 30.7 to 95.4 MPa with two different yeast strains and related to the rate of cell death caused by each stress. The exposure of cells to increasing osmotic pressures involved a progressive lowering of membrane anisotropy during lethal perturbations. Osmotic stresses associated with reversible fluidity changes of increasing intensity in the membrane led to proportional death rates and time-dependant cell death of increasing rapidity during the application of the stress. Finally, a hypothesis relating the extent of membrane structural changes to the kinetic of cell death is proposed.