Pascale Mentré scite author profile

Nowadays, biologists can explore the cell at the nanometre level. They discover an unsuspected world, amazingly overcrowded, complex and heterogeneous, in which water, also, is complex and heterogeneous. In the cell, statistical phenomena, such as diffusion, long considered as the main transport for water soluble substances, must be henceforth considered as inoperative to orchestrate cell activity. Results at this level are not yet numerous enough to give an exact representation of the cell machinery; however, they are sufficient to cease reasoning in terms of statistics (diffusion, law of mass action, pH, etc.) and encourage cytologists and biochemists to prospect thoroughly the huge panoply of the biophysical properties of macromolecule-water associations at the nanometre level. Our main purpose, here, is to discuss some of the more common misinterpretations due to the ignorance of these properties, and expose briefly the bases for a better approach to the cell machinery. Giorgio Careri, who demonstrated the correlation between proton currents at the surface of lysozyme and activity of this enzyme was one of the pioneers of this approach. Keywords Interfacial water · Intracellular diffusion · Signal transduction · Proton currents · Giorgio CareriUp to the 1980s, most biologists had never even suspected that the physical properties of water could play a key role in the orchestration of the cell machinery. In fact, the only topic in which these properties were taken into consideration was protein folding.Until nowadays, water, which composes 70-80% of the cell mass, was generally considered as abundant enough to allow efficient diffusion of the water-soluble substances down their concentration gradients without expense of energy. Very few people P. Mentré (B)

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Localization of cations by pyroantimonate. II. Electron probe microanalysis of calcium and sodium in skeletal muscle of mouse.

Mentré¹,

Halpern²

1988

J Histochem Cytochem.

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A new formulation of the pyroantimonate (PA) method for localization of calcium and sodium is proposed and evaluated in mouse skeletal muscle. This study, performed at the ultrastructural level by means of transmission electron microscopy (TEM) and electron probe microanalysis (EPMA), completes a previous work done at the optical level with analytical ion microscopy (AIM), which enabled us to define the appropriate composition of fixatives. In our present experiments, calcium and sodium were shown localized in various cell structures, e.g., T-tubules, glycogen, granules, nuclei. For AIM, the best fixatives were characterized by PA supersaturation, which resulted in smaller crystals and a high rate of penetration in the presence of paraformaldehyde and either phenol or collidine. Contrary to the findings at the optical level, collidine did not give satisfactory results at the ultrastructural level. The method of floating sections on the microtome trough was an important cause of cation displacement. We found that alkalinization of the floating medium significantly decreased ion loss. The technique also provided an indication of the form of these elements: free or easily liberated cations were precipitated into coarse PA deposits; electron-positive chelates were "stained" by PA; neutral chelates were not stained, but some of them could be detected by EPMA. This PA method should make possible more precise localization of cellular calcium, such as in glycogen metabolism, and perhaps detection of movements of cytoplasmic calcium and sodium.

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Localization of cations by pyroantimonate. I. Influence of fixation on distribution of calcium and sodium. An approach by analytical ion microscopy.

Mentré¹,

Escaig²

1988

J Histochem Cytochem.

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A modification of the potassium pyroantimonate (PA) method for localization of calcium and sodium was tested using skeletal muscle of mouse. Massive diffusion of these cations, depending on the method of fixation, was demonstrated by analytical ion microscopy (AIM) images on the optical microscopy level. Rapid penetration of the fixative appeared to be the principal condition that reduced diffusion of Ca2+ and Na+. Paraformaldehyde (2%) appeared more efficient than glutaraldehyde (1%) for preserving metal composition. Addition of 1% phenol strikingly improved the quality of the AIM images. Supersaturated PA (4%) appeared to retain about 10 times more sodium in the tissue than insaturated PA (2%). The role of different buffers is also discussed, particularly collidine, which permitted better preservation of sodium. Fixation with this buffer should be very useful for study by AIM of large-scale distribution of sodium. These results are analyzed at the ultrastructural level in the accompanying report.

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Pascale Mentré

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Effects of high hydrostatic pressures on living cells: A consequence of the properties of macromolecules and macromolecule-associated water

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Localization of cations by pyroantimonate. II. Electron probe microanalysis of calcium and sodium in skeletal muscle of mouse.

Localization of cations by pyroantimonate. I. Influence of fixation on distribution of calcium and sodium. An approach by analytical ion microscopy.

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