Temperature Dependence of Nonelectrolyte Permeation across Red Cell Membranes

Galey, William R.; Owen, Jeffrey D.; Solomon, A. K.

doi:10.1085/jgp.61.6.727

Cited by 66 publications

(38 citation statements)

References 25 publications

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“…Furthermore, the addition of the ethyl moiety to the urea molecule had less effect on absolute permeation resistance as the temperature increased. Similar temperature effects were found for the permeation of propionamide, butyramide, and valeramide across red blood cell membranes at 20, 25, and 30°C (8). Al decreased lipid partiality at all temperatures above 9°C but increased lipid partiality for the gel state (6°C in Fig.…”

Section: Resultssupporting

confidence: 74%

Aluminum and Temperature Alteration of Cell Membrane Permeability of Quercus rubra

Chen¹,

Sucoff²,

Stadelmann³

1991

Plant Physiol.

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This report extends research on Al-induced changes in membrane behavior of intact root cortex cells of Northern red oak (Quercus rubra). Membrane permeability was determined by the plasmometric method for individual intact cells at temperatures from 2 or 4 to 35°C. Al (0.37 millimolar) significantly increased membrane permeability to urea and monoethyl urea and decreased permeability to water. Al significantly altered the activation energy required to transport water (+32%), urea (+9%), and monoethyl urea (-7%) across cell membranes. Above 90C, Al increased the lipid partiality of the cell membranes; below 70C, Al decreased it. Al narrowed by 60C the temperature range over which plasmolysis occurred without membrane damage. These changes in membrane behavior are explainable if Al reduces membrane lipid fluidity and kink frequency and increases packing density and the occurrence of straight lipid chains.

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Section: Resultssupporting

confidence: 74%

Aluminum and Temperature Alteration of Cell Membrane Permeability of Quercus rubra

Chen¹,

Sucoff²,

Stadelmann³

1991

Plant Physiol.

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“…The activation energy of urea transport in erythrocytes with a low urea permeability (Fig. 2) is somewhat higher than that found in human red cells of 11 kcal/mole (Galey, Owen & Solomon, 1973). In bimolecular phospholipid membranes values of 12-14 kcal/mole have been found by Poznansky et al (1976).…”

Section: The Effect Of Thiourea On Urea Transportmentioning

confidence: 74%

Separative pathways for urea and water, and for chloride in chicken erythrocytes.

Brahm¹,

Wieth²

1977

The Journal of Physiology

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SUMMARY1. Urea and water permeabilities of chicken erythrocytes are considerably lower than those of mammalian red cells.2. The permeabilities to urea, thiourea and to N-methylurea (about 1o-6 cm/sec at 250 C) were independent of concentration within a very broad range, and we found no evidence of interaction between transport of analogue molecules. The activation energies were between 17 and 19 kcal/mole, and urea transport was not inhibited by phloretin, which inhibits urea transport in mammalian red cells.3. The water permeability of chicken red cells (as measured by the diffusion of tritiated water) was 1P35 x 10-3 cm/sec at 25°C. The activation energy was 10 kcal/mole, and the water permeability was not affected by phloretin or parachloromercuribenzoate.4. It is concluded that the urea and water permeabilities of the chicken erythrocyte membrane are similar to those of a non-porous bimolecular phospholipid membrane.5. Like the red cells ofother animal species the chicken red cell membrane contains an anion transport system, mediating a rapid exchange of chloride across' the cell membranes. The pH dependence, temperature dependence, and sensitivity to inhibitors were similar to the properties of the anion transport system found in mammalian red cells. Our study shows, therefore, that the transport system offers a highly specific pathway to the exchange of anions, without presenting an inspecific leak to the permeation of water and urea.

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“…Urea shows no saturation kinetics (Fig.3) and well-established inhibitors of water and urea transport in other RBC with UT-B and AQP1 (Table6) inhibit neither P urea nor P d . The E A of P urea is high, 71.2kJmol -1 , and of the same magnitude as other nonelectrolytes that permeate the lipid membrane phase (Wartiovaara, 1949;Macey et al, 1972;Galey et al, 1973;Brahm, 1983a). E A of P d is 41.9kJmol -1 .…”

Section: Do Urea and Water Share A Pathway In Common In Rbc?mentioning

confidence: 86%

The permeability of red blood cells to chloride, urea, and water

Brahm

2013

Journal of Experimental Biology

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SUMMARYThis study extends permeability (P) data on chloride, urea and water in red blood cells (RBC), and concludes that the urea transporter (UT-B) does not transport water. cms -1 (human). DIDS, DNDS and phloretin inhibit P Cl by >99% in all RBC species. PCMBS, PCMB and phloretin inhibit P urea by >99% in Amphiuma, dog and human RBC, but not in chick and duck RBC. PCMBS and PCMB inhibit P d in duck, dog and human RBC, but not in chick and Amphiuma RBC. Temperature dependence, as measured by apparent activation energy, E A , of P Cl is 117.8 (duck), 74.9 (Amphiuma) and 89.6kJmol −1 (dog). The E A of P urea is 69.6 (duck) and 53.3kJmol −1 (Amphiuma), and that of P d is 34.9 (duck) and 32.1kJmol −1 (Amphiuma). The present and previous RBC studies indicate that anion (AE1), urea (UT-B) and water (AQP1) transporters only transport chloride (all species), water (duck, dog, human) and urea (Amphiuma, dog, human), respectively. Water does not share UT-B with urea, and the solute transport is not coupled under physiological conditions.

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Temperature Dependence of Nonelectrolyte Permeation across Red Cell Membranes

Cited by 66 publications

References 25 publications

Aluminum and Temperature Alteration of Cell Membrane Permeability of Quercus rubra

Aluminum and Temperature Alteration of Cell Membrane Permeability of Quercus rubra

Separative pathways for urea and water, and for chloride in chicken erythrocytes.

The permeability of red blood cells to chloride, urea, and water

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