Effect of osmolality and anion channel inhibitors on myo-inositol efflux in cultured astrocytes.

Recent studies have shown that swelling-activated myo-inositol efflux from rat C6 glioma cells is mediated by a single transport mechanism and most likely by a volume-sensitive anion channel. In those studies, cells were acclimated in hypertonic medium and then swollen by returning the cells to isotonic medium. In the present study, myo-inositol efflux was determined in primary cultures of astrocytes by first incubating the cells in isotonic radiolabelled medium for 2 hr and then placing the cells in either unlabelled isotonic, hypertonic, or hypotonic medium and measuring release with time. Computer analyses of efflux data indicated a two-component system of myo-inositol efflux. The rate constants for the initial fast component for isotonic and hypotonic cells were 0.0398 +/- 0. 005 and 0.0631 +/- 0.0288 min(-1), respectively. The efflux rates of the slow component, while quite small, were severalfold greater with increasing hypotonic media as compared to the cells in isotonic medium. Several anion membrane transport inhibitors were tested to explore the swelling activated efflux mechanism of myo-inositol. Furosemide (0.5 mM), 1,9 dideoxyforskolin (0.1 mM), NPPB (0.1 mM), niflumic acid (0.5 mM), and SITS (0.5 mM) blocked the fast component of myo-inositol efflux by 17, 49, 55, 75, and 93%, respectively. Our results suggest that the fast component of myo-inositol efflux in primary cultures of astrocytes is mediated by anion transporters or channels and that myo-inositol flux contributes to cell volume regulation in cultures of primary astrocytes.

Effect of dibutyryl cyclic AMP on the kinetics of myo-inositol transport in cultured astrocytes.

Dibutyryl cyclic AMP (dBcAMP) is known to induce maturation and differentiation in astrocytes. As myo-inositol is an important osmoregulator in astrocytes, we examined the effects of maturation and biochemical differentiation on the kinetic properties of myo-inositol transport. Treatment of astrocytes with dBcAMP significantly decreased the Vmax of myo-inositol uptake, but the effect on Km was not significant. The myo-inositol content of astrocytes was significantly decreased in cells treated for 5 days with dBcAMP as compared with untreated controls. Maximum suppression of myo-inositol uptake occurred 7 days after exposure of astrocytes to dBcAMP; this was gradually reversible when dBcAMP was removed from the medium. After exposure to hypertonic medium for 6 h, mRNA expression of the myo-inositol co-transporter was diminished by approximately 36% in astrocytes treated with dBcAMP as compared with untreated cells. It appears that myo-inositol transporters in astrocytes treated with dBcAMP are either decreased in number or inactivated during maturation and differentiation, suggesting that the stage of differentiation and biochemical maturation of astrocytes is an important factor in osmoregulation.

Effect of ammonia and methionine sulfoximine on myo-inositol transport in cultured astrocytes.

Ammonia causes astrocyte swelling which is abrogated by methionine sulfoximine (MSO). Since myo-inositol is an important osmolyte, we investigated the effects of ammonia and MSO on myoinositol flux in cultured astrocytes for periods up to 72 hours. Uptake of myo-inositol was significantly decreased by 26.7 (P < 0.05) and 39.3 (P < 0.006) percent after 48 hours of exposure to 5 or 10 mM ammonia, respectively. The maximum rate of uptake was 14.0+/-0.5 nmol/hour/mg protein which was reduced to 7.45+/-0.27 and 7.02+/-0.57 nmoles/hour/mg protein by 5 or 10 mM ammonia, respectively. The Kms by Michaelis-Menten equation for the control, and in the presence of 5, or 10 mM ammonia were 32.5+/-4.52, 44.4+/-5.82, and 39.3+/-7.0 microM, respectively. Kms by Hanes-Woolf plot for the control, 5, or 10 mM ammonia were 25, 45, and 40 microM, respectively. Treatment of astrocytes with either 5 or 10 mM NH4Cl for 6 hours caused a decrease in myo-inositol content by 66% and 58%, respectively. MSO (3 mM) partially diminished the ammonia-induced inhibition of myo-inositol uptake and decreased myo-inositol content by 31% after 24 hours. Additionally, ammonia increased myo-inositol efflux briefly through the fast efflux component but had little effect on myo-inositol efflux through the slow efflux component of astrocytes exposed to ammonia for up to 72 hours. Predominantly decreased myo-inositol influx coupled with brief efflux through the fast component may represent an adaptive response to diminish the extent of ammonia-induced astrocyte swelling.

Effect of osmolality and myo-inositol deprivation on the transport properties of myo-inositol in primary astrocyte cultures.

myo-Inositol uptake measured in primary astrocyte cultures was saturable in the presence of Na+ with a Km of 13-18 microM and a Vmax of 9.4 nmoles/mg protein/hour in myo-inositol-fed cells, indicating a high affinity transport system. In myo-inositol-deprived cells, Km was about 53 microM with a Vmax of 13.2 nmoles/mg protein/hour. Decreasing osmolality decreased the Vmax to about 1.9 nmoles/mg protein/hour whereas increasing osmolality increased Vmax about 5-fold, while Kms were essentially unchanged in myo-inositol fed cells. In cells deprived of myo-inositol, Vmax decreased in hypotonic medium and increased in hypertonic medium almost 10-fold, but with more than a doubling of the Km regardless of the osmolality. Glucose (25 mM) inhibited myo-inositol uptake 51% whereas the other hexoses used inhibited uptake much less. Our findings indicate that myo-inositol uptake in astrocytes occurs through an efficient carrier-mediated Na(+)-dependent co-transport system that is different from that of glucose and its kinetic properties are affected by myo-inositol availability and osmotic stress.

Examination of reptilian erythrocytes as models of the progenitor of mammalian red blood cells.

Among the reptile species examined, only loggerhead turtle RBC with their high capacity of anaerobic metabolism and low oxygen uptake possess all the suitable metabolic characteristics as a model for transition from aerobic to anaerobic metabolism of mammalian erythrocytes (RBC). Neither the alligator RBC, which lack a significant level of anaerobic metabolism, nor the savannah monitor lizard RBC with their higher level of temperature-dependent aerobic metabolism, possess all the characteristics suitable as a model for the metabolic evolution of mammalian RBC. In the formation of this metabolic model, no phylogenetic relationships are implied or inferred. The metabolic similarity of loggerhead turtle RBC to mammalian RBC is further indicated by the high activity of the pentose phosphate (PPO4) pathway, as evidenced by the low thermal sensitivity of their oxygen uptake and by their low 14C6O2/14C1O2 ratios. By comparison, although the 14C6O2/14C1O2 ratios of both alligator and monitor lizard RBC are low as compared to loggerhead turtle RBC, only alligator RBC share with loggerhead turtle RBC a low thermal sensitivity of their oxygen uptake. A comparison of hemoglobin concentrations relative to hematocrit for loggerhead turtle, alligator and monitor lizard RBC indicates that RBC hemoglobin concentrations are approximately the same for each of these species. Apart from this similarity, RBC from these three species of reptiles were differentiated in this study with respect to their density and osmotic fragility.

Osmotic regulation of myo-inositol uptake in primary astrocyte cultures.

Uptake of myo-inositol by astrocytes in hypertonic medium (440 mosm/kg H2O) was increased near 3-fold after incubation for 24 hours, which continued for 72 hours, as compared with the uptake by cells cultured in isotonic medium (38 nmoles/mg protein). myo-Inositol uptake by astrocytes cultured in hypotonic medium (180 mosm/kg H2O) for periods up to 72 hours was reduced by 74% to 8 to 10 nmoles/mg protein. Astrocytes incubated in either hypotonic or hypertonic medium for 24 hours and then placed in isotonic medium reversed the initial down- or up-regulation of uptake. Activation of chronic RVD and RVI correlates with regulation of myo-inositol uptake. A 30 to 40 mosm/kg H2O deviation from physiological osmolality can influence myo-inositol homeostasis. The intracellular content of myo-inositol in astrocytes in isotonic medium was 25.6 +/- 1.3 micrograms/mg protein (28 mM). This level of myo-inositol is sufficient for this compound to function as an osmoregulator in primary astrocytes and it is likely to contribute to the maintenance of brain volume.

Studies on avian erythrocyte metabolism. XVII. Kinetics and transport properties of myo-inositol in chicken reticulocytes.

The uptake of myo-inositol was determined in a reticulocyte-enriched fraction prepared from chicken blood and compared with uptake in mature erythrocytes. While reticulocytes accumulated inositol at levels more than threefold that of the plasma concentration, erythrocyte levels were only slightly higher than that of the plasma concentration. The rate of uptake in reticulocytes was approximately 66 mumol/ml rbc/h compared to 5 mumol/ml rbc/h in mature erythrocytes when measured at an inositol medium concentration of 250 microM. The kinetic analysis of inositol influx by reticulocytes reveals a two component system: saturable and nonsaturable. The saturable component, which has a Km for inositol of approximately 222 microM, is Na-dependent. This Na-dependent saturable component, which presumably reflects active transport of inositol, accounts for 30-35% of the transport process. The saturable component is completely inhibited by amiloride but to a lesser extent by ouabain and bumetanide. Moreover, in the course of reticulocyte maturation, the saturable component is lost concomitantly with the completion of the synthesis of myo-inositol pentakisphosphate and the drastic decrease in the membrane permeability to inositol. In addition, phloretin and cytochalasin B, which bind to hexose carriers and inhibit hexose sugar transport, also inhibited inositol transport. The uptake of inositol was not affected by excesses of 3-O-methylglucose (100 mM) or by physiological concentrations of D-glucose. Thus, the transport mechanism of myo-inositol appears distinct from that of D-glucose.

Relative oxidation of glutamate and glucose by vertebrate erythrocytes.

1. Lungfish erythrocytes (RBC), unlike those in other species of fishes, oxidize endogenous glutamate at a higher rate than they oxidize glucose. This pattern closely resembles that found in invertebrates. 2. The exogenous glutamate oxidation rate of RBC from most species of fish as well as other groups of vertebrates is approximately equal to or less than that observed for glucose. 3. These findings suggest that the nucleated RBC of most vertebrates appear to rely less on the TCA cycle for energy production and more on the glycolytic metabolism of carbohydrates. 4. The RBC of lungfish are also distinguished from RBC of other vertebrates by their relatively higher permeability to exogenous substrates. For example, chicken RBC have a glucose accumulation rate which is approximately one third that observed for lungfish RBC at twice the medium glucose concentration. 5. The unique characteristics of lungfish RBC may be related to their adaptation to the high concentrations of urea produced during estivation.

Studies on avian erythrocyte metabolism. XVI. Accumulation of 2,3-bisphosphoglycerate with shifts in oxygen affinity of chicken erythrocytes.

The ability of the chicken erythrocyte to accumulate 2,3-bisphosphoglycerate (2,3-P2-glycerate) and its effect upon the oxygen affinity (P50) of the cell suspensions have been determined. Erythrocytes from chick embryos, which contain 4-6 mM 2,3-P2-glycerate, and from chickens at various ages, which contain 3-4 mM inositol pentakisphosphate but no 2,3-P2-glycerate, were incubated with inosine, pyruvate, and inorganic phosphate. Red blood cells from 20-day chick embryos incubated in Krebs-Ringer, pH 7.45, containing 20 mM inosine and 20 mM pyruvate had an increase in 2,3-P2-glycerate from 4.3 to 11.9 mM after 4 h. Importantly, as 2,3-P2-glycerate concentration increased there was a corresponding increase in P50 of the cell suspension. Further, erythrocytes from 9- and 11-week, and 7-, 14-, 24-, and 28-month-old chickens when incubated similarly with inosine and pyruvate accumulated 2,3-P2-glycerate with corresponding increases in P50 of the cell suspensions. The ability of the red cell to accumulate this compound under the incubation conditions used apparently decreases with age of the bird (e.g., 11.9 mM in the 20-day embryo to 1.1 mM in the 28-month-old chicken after 4 h incubation). Despite the presence of significant amounts of inositol-P5, the accumulation of 2,3-P2-glycerate markedly decreases oxygen affinity of the cell suspensions. The delta P50/mumol increase in 2,3-P2-glycerate in the red cells of the 20-day chick embryo after 4 h incubation is 1.5 Torr; conversely, the delta P50/mumol decrease in 2,3-P2-glycerate in the red cells of the 17-day embryo after 6 h incubation in the presence of sodium bisulfite is 2.8 Torr. The demonstrated ability of the chicken erythrocyte to accumulate 2,3-P2-glycerate in response to certain substrates suggests that regulation of concentration of this compound could contribute significantly to regulation of blood oxygen affinity in birds.

Perturbation of the human T-cell antigen receptor-T3 complex leads to the production of inositol tetrakisphosphate: evidence for conversion from inositol trisphosphate.

Antibodies directed against the T-cell antigen receptor-T3 complex mimic antigen and lead to cellular changes consistent with activation. When cells of the human T-cell line Jurkat were stimulated with a monoclonal antibody directed against T3, inositol phosphates were produced. In addition to inositol trisphosphate, which is the product of phosphatidylinositol bisphosphate cleavage, a second inositol polyphosphate was formed. This compound was more polar than inositol trisphosphate but less polar than inositol pentakisphosphate. It cochromatographed with inositol tetrakisphosphate from ostrich erythrocytes. In permeabilized Jurkat cells, this compound was shown to be formed from inositol 1,4,5-trisphosphate, but only in the presence of ATP, and 32P was incorporated into it from [gamma-32P]ATP. There also was coincident formation of inositol 1,3,4-trisphosphate. We conclude that the more polar compound is inositol tetrakisphosphate, which is formed by phosphorylation of inositol 1,4,5-trisphosphate and may be the precursor of inositol 1,3,4-trisphosphate.

Active cation transport and Na+K+Mg ATPase of the monotreme erythrocytes.

The erythrocytes of the echidna (Tachyglossus aculeatus) and platypus (Ornithorhynchus anatinus), which are practically devoid of intracellular ATP content (1), were examined for active Rb86 influx and for the presence of Na+K+Mg ATPase. We found that intact erythrocytes of both species possess the ability to actively transport cations. Ouabain sensitive Rb86 influx in the echidna was approximately 0.17 mumoles/ml cells x hr, whereas the platypus exhibited a higher value of 0.43 mumoles/ml cells x hr. Surprisingly, ouabain sensitive Na+K+Mg ATPase activity of isolated membranes was high amounting to some 15 to 25 fold higher than the human erythrocyte counterpart determined under identical conditions. These findings suggest that a trace amount of ATP is sufficient to maintain active cation transport across the monotreme cell membranes.

Metabolic properties of low ATP erythrocytes of the monotremes.

The erythrocytes of the monotremes, having a trace amount of ATP, can metabolize glucose to lactate at a rate comparable to human and other mammalian erythrocytes. The echidna energy metabolism is unique in that adenosine can stimulate glycolytic carbon flow, resulting in a nearly 20-fold net synthesis of ATP.

Erythrocyte phosphate composition and osmotic fragility in the Australian lungfish, Neoceratodus fosteri, and osteoglossid, Scleropages schneichardti.

The packed cell volume (PCV), hemoglobin concentration (g/dl) and mean corpuscular volume (MCV) in the Australian lungfish, Neoceratodus fosteri, and in one of three Australian osteoglossids, Scleropages schneichardti, were 32.3 and 29.9; 10.5 and 10.0; and 407 and 176 micron 3 respectively. Total acid-soluble phosphates (TPi) from the red blood cells (RBC) of the lungfish and osteoglossid were 35.3 and 18.1 mumol/cm3 RBC respectively. Inorganic phosphate (Pi), adenosine triphosphate (ATP) and guanosine triphosphate (GTP) represented 16.4, 39.7 and 17.8% of the cell phosphates in the lungfish respectively. Inositol bisphosphate was not present in extracts of the red cells of N. fosteri, in contrast to the red cells of Lepidosiren paradoxa and Protopterus aethiopicus, in which it was first observed. In the osteoglossid, Pi and ATP represented 37.6 and 46.4% of the erythrocyte phosphate, respectively, with only traces of GTP present. ATP is the predominant organic phosphate in the red cells of both species. The osmotic fragility of erythrocytes of N. fosteri are quite resistant to hemolysis, with hemolysis beginning at 35-30 mM and a complete hemolysis occurring at 20 mM NaCl. The red cells of S. schneichardti begin to hemolyze at 95-90 mM with hemolysis continuing to completion at 60 mM NaCl.

Studies on avian erythrocyte metabolism. XII. The synthesis and degradation of inositol pentakis (dihydrogen phosphate).

The pathway(s) of synthesis and degradation of inositol 1, 3, 4, 5, 6 pentakis (dihydrogen phosphate) (inositol-P5), found predominantly in the avian erythrocyte, are unknown. Myo-inositol (inositol), D-glucose, inosine, and phosphate have been studied as potential precursors of inositol-P5 synthesis in chicken erythrocytes. Whole blood from chickens at several ages has been incubated for prolonged periods and the concentration of inositol-P5 measured to determine the ability of the avian erythrocyte to catabolize inositol-P5. Incubation of erythrocyte suspensions from 5-day chicks with [U-14 C]myo-inositol (inositol) for 17 hr lead to the appearance of 19.8% of the radioactivity in the aqueous acid-soluble extract of the erythrocytes (RBC). Fractionation of this extract on an anion exchange column yielded five major radioactive peaks, three of which represent 1) free myo-inositol, accounting for 63.5% of the radioactivity; 2) myo-inositol monokis (dihydrogen phosphate) (inositol-P), representing 1.6% of the radioactivity; and 3) inositol 1, 3, 4, 5, 6 pentakis (dihydrogen phosphate) (inositol-P5), representing 27.0% of the label in the erythrocyte. Sodium fluoride did not inhibit the incorporation of [U-14 C]myo-inositol into inositol-P5. Similar incubations with D-[U-14 C]-glucose and [U-14 C]-inosine yielded no incorporation of radioactivity into inositol-P5. These data are consistent with the interpretation that inositol is the major precursor for synthesis of inositol-P5 in chick red cells. Incubation of whole blood from 1-, 5-, and 42-day chicks and mature birds at 40 C for as long as 72 hr resulted in increases in RBC inorganic phosphate (Pi) thought due primarily to depletion of adenosine triphosphate (ATP). Inositol-P5 content of RBC of 5- and 42-day birds decreased 28 and 20%, respectively, after 72 hr, but no change was noted in inositol-P5 levels of RBC from mature birds. The red cells of the mature bird appear to be unable to catabolize inositol-P5 at significant rates. The apparent inability of the chicken erythrocyte to alter readily its concentration of inositol-P5 suggests that the hemoglobin oxygen delivery system of birds may be less adaptable to changing oxygen requirements by regulating the concentration of hemoglobin modulator than is that of the mammals.

Regulation of hemoglobin function and whole blood oxygen affinity by carbon dioxide and pH in the loggerhead (Caretta caretta) and green sea turtle (Chelonia mydas mydas).

The oxygen affinity of suspensions of erythrocytes from juvenile and adult loggerhead (Caretta caretta) and green sea (Chelonia mydas mydas) turtles decreased markedly with increasing concentrations of carbon dioxide (0 to near 15%) or hydrogen ion (pH 7.6 to pH 7.2). The P50's were higher with increases in pCO2, particularly at pH near 7.4, than were the P50's with increases in hydrogen ion concentration at any given CO2 concentration. Solutions of hemoglobins from the juvenile loggerhead (8-9 mos.) and green sea (10 mos.) turtles responded to 2, 3-DPG, ATP, or inositol-P5 when added at molar ratios of phosphate to hemoglobin of 4:1 and 20:1 in 0% and 6.29% CO2 but showed no decrease in oxygen affinity at these two CO2 levels in the green turtle when the molar ratio of phosphate to hemoglobin was 0.4. These compounds had little effect on the P50 of these hemoglobins in 14.6% CO2. The P50 of the adult loggerhead turtle hemoglobin did not increase in the presence of organic phosphates beyond the effect induced by CO2 alone. The P50 of hemoglobin from the adult green sea turtle increased only slightly when the molar ratio of phosphate to hemoglobin was 20:1 and at 0 and 6% CO2 concentration; little effect was observed at 14.6% CO2. These data demonstrate that blood oxygen affinities and hemoglobin function in these two species of marine turtles are altered significantly by CO2 and to a lesser degree by pH. It is suggested that such alterations may be of significance in vivo during prolonged diving when there are dramatic rises in blood pCO2 and [H+] and profound decreases in pO2.

Adenosine triphosphate-deficient erythrocytes of the egg-laying mammal, echidna (tachyglossus aculeatus).

The erythrocytes of the short-beaked echidna (Tachyglossus aculeatus), an egg-laying mammal, were examined for the presence of phosphorylated compounds. The erythrocytes contained only 0.03 +/- 0.01 micromoles of adenosine 5'-triphosphate per milliliter of cells. This amount is two orders of magnitude less than that in human cells. Although the echidna erythrocytes had an abundance of 2,3-diphosphoglycerate and other glycolytic intermediates, no other energy-rich pyridine and purine compounds were detected.

Oxygen binding of fetal and adult bovine hemoglobin in the presence of organic phosphates and uric acid riboside.

The P50 values of "stripped" fetal and adult bovine hemoglobin were 18.4 and 28.9 respectively. Neither the oxygen-hemoglobin dissociation curve nor the Hill coefficient, n, of fetal or adult bovine hemoglobin was affected by uric acid riboside (UAR), 2,3-diphosphoglyceric acid (2,3-DPG), adenosine triphosphate (ATP), or inositol pentaphosphate (IPP). Combinations of UAR and ATP with adult bovine hemoglobin or 2,3-DPG and ATP with fetal hemoglobin also had no effect. It was concluded that neither adult nor fetal bovine red cells contained an identifiable compound which affects the binding of oxygen to hemoglobin.