Comparative nuclear magnetic resonance studies of diffusional water permeability of red blood cells from different species. VIII. Adult and fetal guinea pig (Cavia procellus)

Light and Scanning Electron Microscopy of Red Blood Cells From Humans and Animal Species Providing Insights into Molecular Cell Biology

We reviewed the many discoveries in cell biology, made since the 17^th century, which have been based on red blood cells (RBCs). The advances in molecular and structural biology in the past 40 years have enabled the discovery with these cells, most notably, of the first water channel protein (WCP) called today aquaporin1 (AQP1). The main aim of our work reviewed was to examine by light and electron microscopy a very wide range of RBCs from reptiles, birds, monotremes, marsupials and placentals, in order to estimate from these images the RBC cell volume and surface area. The diffusional water permeability of the RBC membrane from these species has further been measured with a nuclear magnetic resonance (NMR) spectroscopy technique. The significance of the observed permeability of RBCs to water and possible influences on the whole body are discussed.

Morphology and water permeability of red blood cells from green sea turtle (Chelonia mydas)

The morphology and diffusional water permeability (P d) of red blood cells (RBCs) from green sea turtle (GST) (Chelonia mydas) are presented for the first time. The RBCs had an ellipsoidal shape with full-axis lengths (diameters): D = 14.4 μm; d = 10.2 μm; h = 2.8 μm. The values of P d (cm s(-1)) were 5.1 × 10(-3) at 15 °C, 5.7 × 10(-3) at 20 °C, 6.3 × 10(-3) at 25 °C, 6.8 × 10(-3) at 30 °C, and 7.9 × 10(-3) at 37 °C (i.e., significantly higher than in human RBCs in which it was measured to be 4.2 × 10(-3) at 25 °C, 5.0 × 10(-3) at 30 °C, and 6.2 × 10(-3) at 37 °C). There was a lack of inhibition of P d of GST RBCs by p-chloromercuribenzoate (PCMB), a well-known inhibitor of the RBC water channel proteins (WCPs). The activation energy of water diffusion (E a,d) in GST RBCs was 15.0 ± 1.6 kJ mol(-1) which is lower than the E a,d for human RBCs (~25 kJ mol(-1)). These results indicate that in the membrane of GST RBCs, there were no WCPs that were inhibited by the mercurial reagent, while the lipid bilayer of this membrane is unusually permeable to water. This is likely to be a phylogenetically old trait, like that found in amphibians and even the later birds, all of which have nucleated erythrocytes; and it is also likely to be a result of the animal's adaptation to a herbivorous diet (algae and seagrasses).

Comparative studies of water permeability of red blood cells from humans and over 30 animal species: an overview of 20 years of collaboration with Philip Kuchel

NMR measurements of the diffusional permeability of the human adult red blood cell (RBC) membrane to water (P(d)) and of the activation energy (E(a,d)) of the process furnished values of P(d) ~ 4 × 10(-3) cm/s at 25 °C and ~6.1 × 10(-3) cm/s at 37 °C, and E(a,d) ~ 26 kJ/mol. Comparative NMR measurements for other species showed: (1) monotremes (echidna and platypus), chicken, little penguin, and saltwater crocodile have the lowest P(d) values; (2) sheep, cow, and elephant have P(d) values lower than human P(d) values; (3) cat, horse, alpaca, and camel have P(d) values close to those of humans; (4) guinea pig, dog, dingo, agile wallaby, red-necked wallaby, Eastern grey kangaroo, and red kangaroo have P(d) values higher than those of humans; (5) mouse, rat, rabbit, and "small and medium size" marsupials have the highest values of P(d) (>8.0 × 10(-3) cm/s at 25 °C and >10.0 × 10(-3) cm/s at 37 °C). There are peculiarities of E(a,d) values for the RBCs from different species. The maximum inhibition of diffusional permeability of RBCs induced by incubation with p-chloromercuribenzene sulfonate varied between 0% (for the chicken and little penguin) to ~50% (for human, mouse, cat, sheep, horse, camel, and Indian elephant), and ~60-75% (for rat, guinea pig, rabbit, dog, alpaca, and all marsupials). These results indicate that no water channel proteins (WCPs) or aquaporins are present in the membrane of RBCs from monotremes (echidna, platypus), chicken, little penguin and saltwater crocodile whereas WCPs from the membranes of RBCs from marsupials have peculiarities.

Water channel proteins (later called aquaporins) and relatives: past, present, and future

Water channels or water channel proteins (WCPs) are transmembrane proteins that have a specific three-dimensional structure with a pore that can be permeated by water molecules. WCPs are large families (over 450 members) that are present in all kingdoms of life. The first WCP was discovered in the human red blood cell (RBC) membrane in 1980s. In 1990s other WCPs were discovered in plants, microorganisms, various animals, and humans; and it became obvious that the WCPs belong to the superfamily of major intrinsic proteins (MIPs, over 800 members). WCPs include three subfamilies: (a) aquaporins (AQPs), which are water specific (or selective water channels); (b) aquaglyceroporins (and glycerol facilitators), which are permeable to water and/or other small molecules; and (c) "superaquaporins" or subcellular AQPs. WCPs (and MIPs) have several structural characteristics which were better understood after the atomic structure of some MIPs was deciphered. The structure-function relationships of MIPs expressed in microorganisms (bacteria, archaea, yeast, and protozoa), plants, and some multicellular animal species [nematodes, insects, fishes, amphibians, mammals (and humans)] are described. A synthetic overview on the WCPs from RBCs from various species is provided. The physiological roles of WCPs in kidney, gastrointestinal system, respiratory apparatus, central nervous system, eye, adipose tissue, skin are described, and some implications of WCPs in various diseases are briefly presented. References of detailed reviews on each topic are given. This is the first review providing in a condensed form an overview of the whole WCP field that became in the last 20 years a very hot area of research in biochemistry and molecular cell biology, with wide and increasing implications.

Study of diffusion in erythrocyte suspension using internal magnetic field inhomogeneity

Transport of water and ions through cell membranes plays an important role in cell metabolism. We demonstrate a novel technique to measure water transport dynamics using erythrocyte suspensions as an example. This technique takes advantage of inhomogeneous internal magnetic field created by the magnetic susceptibility contrast between the erythrocytes and plasma. The decay of longitudinal magnetization due to diffusion in this internal field reveals multi-exponential behavior, with one component corresponding to the diffusive exchange of water across erythrocyte membrane. The membrane permeability is obtained from the exchange time constant and is in good agreement with the literature values. As compared to the other methods, this technique does not require strong gradients of magnetic field or contrast agents and, potentially, can be applied in vivo.

Why does the mammalian red blood cell have aquaporins?

Aquaporins are now known to mediate the rapid exchange of water across the plasma membranes of diverse cell types. This exchange has been studied and kinetically characterized in red blood cells (erythrocytes; RBC) from many animal species. In recent years, a favoured method has been one based on NMR spectroscopy. Despite knowledge of their molecular structure the physiological raison d' etre of aquaporins in RBCs is still only speculated upon. Here, we present two hypotheses that account for the fact that the exchange of water is so fast in RBCs. The first is denoted the "oscillating sieve" hypothesis and it posits that known membrane undulations at frequencies up to 30 Hz with displacements up to 0.3 microm are energetically favoured by the high water permeability of the membrane. The second denoted the "water displacement" hypothesis is based on the known rapid exchange across the RBC membrane of ions such as Cl- and HCO3- and solutes such as glucose, all of whose molecular volumes are significantly greater than that of water. The ideas are generalizable to other cell types and organelles.

Comparative nuclear magnetic resonance studies of water permeability of red blood cells from maternal venous blood and newborn umbilical cord blood

Comparative morphological and nuclear magnetic resonance (NMR) measurements of the diffusional permeability (Pd) were performed on red blood cells (RBCs) from maternal venous blood and fetal RBCs, isolated from cord blood taken at delivery. Fetal RBC had a diameter of 8.79+/-0.03 microm (mean+/-standard deviation, SD), a volume of 103 microm3 and a surface area of 157 microm2. We report here the first comparative measurements of Pd of maternal and fetal RBCs by using a Mn2+-doping NMR technique. The values of Pd were, in the case of maternal RBC, 3.7 x 10(-3) cm/s at 15 degrees C, 4.1 x 10(-3) cm/s at 10 degrees C, 4.9 x 10(-3) cm/s at 25 degrees C, 5.2 x 10(-3) cm/s at 30 degrees C and 7.2 x 10(-3) cm/s at 37 degrees C. For fetal RBC all corresponding Pd values were almost half, namely 2.0 x 10(-3) cm/s at 15 degrees C, 2.3 x 10(-3) cm/s at 20 degrees C, 2.8 x 10(-3) cm/s at 25 degrees C, 3.4 x 10(-3) cm/s at 30 degrees C and 4.4 x 10(-3) cm/s at 37 degrees C. The decreased Pd values of fetal RBCs were probably due to lower channel-mediated water permeability compared with adult RBCs. The values of the activation energy for water permeability (E(a,d)) were significantly higher for fetal RBCs (27.6+/-5.0 kJ/mol) than for adult RBCs (22.8+/-2.7 kJ/mol). A positive correlation between the Pd values of the two kinds of RBCs was found. This points to the genetic basis for the determination of RBC water permeability.

Comparative studies of the protein composition of red blood cell membranes from eight mammalian species

The polypeptide pattern of red blood cell (RBC) membranes from cow, sheep, horse, rabbit, guinea pig, rat, mouse, analyzed by polyacrylamide gel electrophoresis, was compared to human RBC counterpart. Some qualitative and quantitative differences were noted. Among the high molecular weight components the bands 2.1-2.3 appeared slightly decreased in rabbit and rat and increased in sheep RBC membranes. Band 3 appeared to have a higher molecular weight in the cow, guinea pig and mouse RBCs, and a lower molecular weight in the sheep RBCs. Band 4.1 from the RBC membranes of cow, sheep, rabbit and guinea pig was splitted into two sub-bands, while band 4.2 overlapped with band 4.1 in horse and guinea pig RBC membranes. There are marked differences in the number and position of bands in the 4.5 region, while band 4.9 is present in higher amounts in horse, rabbit and guinea pig RBC membranes. Band 6 (glyceraldehyde 3-phosphate dehydrogenase) was undetectable in horse, rat and mouse RBC membranes and was decreased in sheep, rabbit and guinea pig. There are also major differences in the region of band 7 and below ("post-7"). Band 8 was undetectable in horse, cow and guinea pig, and was in higher amounts in rat. A band corresponding to a molecular weight of about 22 kD in the "post-8" region was present only in guinea pig RBC membranes.