Phosphate uptake by phosphate-starved Euglena

Phosphate-deprived Euglena acquire the ability to rapidly in-corporate added phosphate and, also, synthesize an induced acid phosphatase localized in the pellicle. The phosphate uptake system is saturated at low concentrations of phosphate and is inhibited by dinitrophenol, by low temperature, by K⁺, Li⁺, and Na⁺ ions, and competitively by arsenate. The orthophosphate incorporated into the cell is rapidly converted into organic forms but enough remains unesterified to suggest that the uptake is an active transport process. The data do not rule out the possibility that the induced phosphatase is involved in the transport process.     

Models of prebiological phosphorylation

The hypothesis that contemporary metabolic pathways evolved from analogous chemical reaction sequences on the primitive Earth leads to a reexamination of models of prebiological phosphorylation. Present-day phosphate uptake by algae and bacteria seems to involve two transport systems: (a) An active transport process occurring at low external phosphate concentrations (as in unpollusive) process at higher phosphate concentrations (>10⁻⁶ M) (as in the interstitial water of reducing sediments). Laboratory model experiments are described for the reaction of reducing sugars with orthophosphate in the presence of cyanogen, producing glycosyl phosphates. These reactions proceed with appreciable yields only at high phosphate concentrations (>10⁻³ M), and may thus possibly serve as simulations of prebiological phosphorylation with diffusive transport, as it may have occurred in the interstitial water of reducing sediments.     

Kinetic studies of streptomycin uptake implicated in self-resistance in a streptomycin producer

Summary Streptomycin (SM)-producingStreptomyces griseus was permeable to extracellular SM during exponential growth, and less permeable during the stationary phase when antibiotic production was maximal. Uptake of [³H] dihydrostreptomycin ([³H]DSM) by the producer organism was abolished by inhibitors of electron transport, sulfhydryl reagents and an uncoupler of oxidative phosphorylation, and it was competitively inhibited by spermidine. These results indicate that SM was taken up by an active transport process via a polyamine transport system. A mutant with lower SM-resistance showed the same level of SM 6-phosphotransferase as the parent strain. It is suggested that selfresistance in the SM-producers is at least partly determined by transport and permeability mechanisms.     

Experimental demonstration of the effect of the unstirred water layer on the kinetic constants of the membrane transport ofd-glucose in rabbit jejunum

Summary The rate of active transport of a probe molecule into the intestinal mucosal cells is determined by the rate of movement of the solute molecule across two barriers, the unstirred water layer and the microvillus membrane of the epithelial cell. Previously a theoretical equation has been derived which describedJ _d, the velocity of unidirectional flux, as a function of the characteristics of the transport carrier in the membrane and of the resistance of the overlying unstirred water layer (UWL). The predictions of these equations have been tested experimentally by studying the effect of the rate of stirring of the bulk phase on thein vitro uptake ofd-glucose by rabbit jejunum. These studies demonstrated that, first, alterations in the UWL have a profound effect on the magnitude of the apparent affinity constant, xK _m ^* , of the active transport process. Second, at bulk phase concentrations in excess of theK _m the passive component of the experimentally determined flux rate becomes of such magnitude as to introduce significant error into the estimate of both the maximal transport rate,J _d ^m , and the trueK _m. Third, as a result of the UWL, the use of double-reciprocal plots to determineJ _d ^m andK _m leads to the overestimation of these constants. Finally, failure to account for the UWL leads to important quantitative errors describing a number of the characteristics of the transport process: these include an underestimation of the Q₁₀ and the effect of sodium ion on the active transport of glucose in the jejunum. The results confirm that the kinetic characteristics of the uptake of an actively transported molecule are a complex function of the resistance of both the UWL and the mucosal cell membrane, and this transport process can be adequately described by a newly-derived equation. It is apparent that there are serious limitations in the interpretation of much of the previously published data dealing with active transport processes in the intestine, since these studies failed to account for the effect of the UWL.     

Sodium transport and oxygen consumption in toad bladder: A thermodynamic approach

The relationship between active sodium transport and oxygen consumption was investigated in toad urinary bladder exposed to identical sodium-Ringer's solution at each surface, while controlling the transepithelial electrical potential difference Δψ. Rates of sodium transport and oxygen consumption were measured simultaneously, both in the short-circuited state (Δψ = 0) and when Δψ was varied. Under short-circuit conditions, when the rates of active sodium transport changed spontaneously or were depressed with amiloride, the ratio of active sodium transport to the estimated suprabasal oxygen consumption Na⁺/O₂ was constant for each tissue, but varied among different tissues. Only when Δψ was varied did the ratio Na⁺/dO₂ change with the rate of active sodium transport; under these circumstances dNa⁺/dO₂ was constant but exceeded the ratio measured at short-circuit [(Na⁺/O₂)_Δψ=0]. This suggests that coupling between transport and metabolism is incomplete. The results are analyzed according to the principles of nonequilibrium thermodynamics, and interpreted in terms of a simple model of the transepithelial sodium transport system.     

Nucleoside transport in choroid plexus: Mechanism and specificity

In vitro the transport into and release of [³H]thymidine, [³H]deoxyuridine, and [³H]nitrobenzylthioinosine (NBTI) from the isolated choroid plexus, the anatomical locus of the blood-cerebrospinal fluid barrier, were studied separately. Using the ability of NBTI to inhibit nucleoside efflux from the choroid plexus, the transport of [³H]thymidine and [³H]deoxyuridine into the choroid plexus at 37 °C was measured. Like thymidine, deoxyuridine was transported into the choroid plexus against a concentration gradient by a saturable process that depended on intracellular energy production but not intracellular binding or metabolism. The Michaelis-Menten constants (K_T) for the active transport of thymidine and deoxyuridine into the choroid plexus were 13.6 and 7.2 μM, respectively. Deoxyuridine and adenosine were competitive inhibitors of thymidine transport into the choroid plexus with inhibitor constants (K_I) of 6.8 and 14.5 μM, respectively. [³H]NBTI was also transported into the choroid plexus at 37 °C; unlike [³H]thymidine and [³H]deoxyuridine, the release of [³H]NBTI was not inhibited by NBTI itself. These studies provide evidence that the choroid plexus contains an active nucleoside transport system of low specificity for nucleosides, and a separate, saturable efflux system for nucleosides that is very sensitive to inhibition by NBTI. In vivo these systems transport nucleosides from blood into cerebrospinal fluid.     

Solute transport at the plasmalemma and the early evolution of cells

The evolution of the plasmalemma and its porter systems is considered in relation to selective pressures on primitive cells. Initially the polar lipid bilayer acted to separate the genetic apparatus of the protocell from the rest of the world. The requirement for the supply of nutrients and removal of waste products resulted in the evolution of passive uniporters for a number of organic and inorganic solutes. There was also a requirement for primary active transport, whereby one or more solutes is transported across the membrane contrary to the direction predicted from passive driving forces, with an energy input from light, redox reactions, “high-energy phosphate” or some other metabolic process. Active transport is discussed in terms of cytoplasmic pH regulation, cytoplasmic volume regulation, Ca²⁺ exclusion/phosphate accumulation, and the accumulation of organic (heterotrophic) substrates.It is suggested that volume regulation in wall-less cells was initially achieved by Na⁺ exclusion with active Na⁺ extrusion as a later refinement; the same applies to the maintenance of the characteristically low free Ca²⁺ level in the cytoplasm. A requirement for active phosphate influx is also likely in view of the high concentrations of orthophosphate required for phosphorylation reactions relative to the likely external concentration of phosphate and the inside-negative potential difference. This p.d., which results inter alia from Na⁺ extrusion, makes the maintenance of intracellular pH via passive H⁺ fluxes very difficult in the face of continued intracellular production of H⁺ during fermentation. Hence an early role for primary active extrusion (uniport) of H⁺ is very likely. Such uniport is of universal occurrence in present-day cells. Besides its role in pH regulation and in energy-coupling, H⁺ transport energises secondary (H⁺-linked) transport of many other solutes. We suggest that transport of HCO₃^? might also have a pH-regulating role, but apparently HCO₃^? cannot substitute for H⁺ with respect to energy-coupling and secondary active transport.     

The Secretion of Oxygen into the Swim-bladder of Fish : I. The transport of molecular oxygen

Fish were maintained in sea water equilibrated with a gas mixture containing a non-equilibrium mixture of the three molecular species of oxygen, O¹⁸-O¹⁸ (mass 36), O¹⁸-O¹⁶ (mass 34), and O¹⁶-O¹⁶ (mass 32). Analyses in the mass spectrometer, of the gases secreted into the swim-bladder showed that no change in the relative abundance of these three molecular species had occurred during the secretory process and that therefore no exchange of atoms between oxygen molecules had occurred. Scission of the oxygen-oxygen bond probably does not occur during the transport process. It is concluded that the active transport of oxygen into the swim-bladder by the gas gland is a transport of molecular oxygen.     

Tissue specificity of assimilation and transport of nitrogen in the root ofZea mays L. seedlings. II. Radial transport of14C-amino acids

The radial transport of organic nitrogen compounds was studied in maize seedling roots in relation to the metabolism of uniformly labelled¹⁴C-amino acids (alanine, arginine, dicarboxylic amino acids and their amides) in the cortex zone. Most active metabolism accompanying transport to the stele was observed for¹⁴C-glutamic acid of “primary” amino acids and for¹⁴C-glutamine of “reserve” nitrogen sources. The transport of¹⁴C-asparagine and¹⁴C-arginine to the conducting bundles is accompanied by weak metabolism. A distinguishing feature of nitrogen metabolism in the stele is intensive decarboxylation of glutamic acid, formed in the course of radial transport and metabolism, to gamma-amino butyric acid. This process is assisted by a highly active glutamate decarboxylase present in the conducting bundles.     

Solute Transport Process in Intestinal Epithelial Cells

In rat small intestine, the active transport of organic solutes results in significant depolarization of the membrane potential measured in an epithelial cell with respect to a grounded mucosal solution and in an increase in the transepithelial potential difference. According to the analysis with an equivalent circuit model for the epithelium, the changes in emf's of mucosal and serosal membranes induced by active solute transport were calculated using the measured conductive parameters. The result indicates that the mucosal cell membrane depolarizes while the serosal cell membrane remarkably hyperpolarizes on the active solute transport. Corresponding results are derived from the calculations of emf's in a variety of intestines, using the data that have hitherto been reported. The hyperpolarization of serosal membrane induced by the active solute transport might be ascribed to activation of the serosal electrogenic sodium pump. In an attempt to determine the causative factors in mucosal membrane depolarization during active solute transport, cell water contents and ion concentrations were measured. The cell water content remarkably increased and, at the same time, intracellular monovalent ion concentrations significantly decreased with glucose transport. Net gain of glucose within the cell was estimated from the restraint of osmotic balance between intracellular and extracellular fluids. In contrast to the apparent decreases in intracellular Na⁺ and K⁺ concentrations, significant gains of Na⁺ and K⁺ occurred with glucose transport. The quantitative relationships among net gains of Na⁺, K⁺ and glucose during active glucose transport suggest that the coupling ratio between glucose and Na⁺ entry by the carrier mechanism on the mucosal membrane is approximately 1:1 and the coupling ratio between Na⁺-efflux and K⁺-influx of the serosal electrogenic sodium pump is approximately 4:3 in rat small intestine. In addition to the electrogenic ternary complex inflow across the mucosal cell membrane, the decreases in intracellular monovalent ion concentrations, the temporary formation of an osmotic pressure gradient across the cell membrane and the streaming potential induced by water inflow through negatively charged pores of the cell membrane in the course of an active solute transport in intestinal epithelial cells are apparently all possible causes of mucosal membrane depolarization.     

Electrically silent cotransport of Na+, K+ and Cl− in ehrlich cells

A cotransport system for Na⁺, K⁺ and Cl^? in Ehrlich cells is described. It is insensitive towards ouabain but specifically inhibited by furosemide and other ‘high ceiling’ diuretics at concentrations which do not affect other pathways of the ions concerned. As the furosemide-sensitive fluxes of these ions are not affected by changes in membrane potential, and as their complete inhibition by furosemide does not appreciably alter the membrane potential, they appear to be electrically silent. Application of the pulse-response methods in terms of irreversible thermodynamics reveals tight coupling between the furosemide-sensitive flows of Na⁺, K⁺ and Cl^? ($\text{q}$ close to unity for all three combinations) at a stoichiometry of 1 : 1 : 2. The site for each of the ions appears to be rather specific: K⁺ can be replaced by Rb⁺ but not by other cations tested whereas Cl^? can be poorly replaced by Br^? but not by NO₃^?, in contradistinction to the Cl^?-OH^? exchange system. The cotransport system appears to function in cell volume regulation as it tends to make the cell swell, thus counteracting the shrinking effect of the ouabain-sensitive (Na⁺, K⁺) pump.The experiments presented could not clarify whether the cotransport process is a primary or secondary active one; while incongruence between transport and conjugated driving force seems to indicate primary active transport, it is very unlikely that hydrolysis of ATP supplies energy for the transport process, since there is no stimulation of ATP turnover observable under operation of the cotransport system.     

Structure and active transport in the plasma membrane of the tubules of frog kidney

The active transport of organic anions through the plasma membrane of the proximal tubules of frog kidney was studied. For this purpose a marker anion, fluorescein, was used, its flow into the tubules registered by the increase of fluorescense. The kinetics of transport was measured as function of time, concentration of substrate, concentration of a competing acid (p-aminohippuric acid) and temperature. The process is inhibited by strophantin, a specific poison for (Na⁺ + K⁺)-dependent ATPase. These data show that fluorescein transport is effected with the participation of a charged carrier, probably by the downfield mechanism postulated by Mitchell. To confirm this mechanism, a passive flow of K⁺ was created inwards across the membrane of the proximal tubules by means of valinomycin. It led to the discharge of the membrane and to the inhibition of fluorescein transport. Anions are transported downfield across the membrane, probably in a state of complexes with two Na⁺ ions.A magnetic field of 10 000–28 000 oersted inhibits the fluorescein transport strongly. This can be regarded as a proof of the liquid-crystalline structure of biological membranes and demonstrates the importance of this structure for active transport.     

Coupled transepithelial sodium and potassium transport across isolated frog skin: Effect of ouabain,amiloride and the polyene antibiotic filipin

Summary Addition of the polyene antibiotic filipin (50 m) to the outside bathing solution (OBS) of the isolated frog skin resulted in a highly significant active outward transport of K⁺ because filipinper se increases the nonspecific Na⁺ and K⁺ permeability of the outward facing membrane. The K⁺ transport was calculated from the chemically determined changes in K⁺ concentrations in the solution bathing the two sides of the skin. The active transepithelial K⁺ transport required the presence of Na⁺ in the OBS, but not in the inside bathing solution (IBS), and it was inhibited by the Na⁺, K⁺-ATPase inhibitor ouabain. The addition of Ba⁺⁺ to the IBS in the presence of filipin in the OBS resulted in an activation of the transepithelial K⁺ transport and in an inhibition of the active Na⁺ transport. This is in agreement with the notion that Ba⁺⁺ decreases the passive K⁺ permeability of the inward facing membrane. In the presence of amiloride (which blocks the specific Na permeability of the outward facing membrane) and Ba⁺⁺ there was a good correlation between the active Na⁺ and K⁺ transport. It is concluded that the active transepithelial K⁺ transport is carried out by a coupled electrogenic Na–K pump, and it is suggested that the pump ratio (Na/K) is 1.5.     

Fluid transport in isolated rabbit eye lens

Fluid transport in the isolated rabbit eye lens was assayed gravimetrically, and was found to be, at least partly, an active process involving Na,K-ATPase. Thereby the pressure inside the lens proved to be elevated by 6 mm Hg. The energy required for this process was estimated at (1.5–6)·10^?2 J. The movement of fluid in vivo (monitored with fluorescein) proceeds from the anterior to the posterior surface and out into the vitreous body.     

Activation of a Na+-dependent amino acid transport system in preimplantation mouse embryos

The uptake of l-methionine-methyl-³H and l-leucine-³H from completely defined medium into acid-soluble fractions of preimplantation mouse embryos has been studied. Late four-cell embryos and early blastocysts raised in vitro can concentrate both amino acids by processes which exhibit saturable, Michaelis-Menten type kinetics, characteristic of carrier-mediated active transport systems. This uptake is temperature-sensitive and inhibited by certain amino acids which compete for the same uptake sites. Methionine uptake seems to be mediated by a single transport system (K_m = 6.25 × 10^?5M) at the four-cell stage. Complex kinetics suggest that two distinct transport systems exist at the early blastocyst stage (K_m = 6.25 × 10^?5M; 8.9 × 10^?4M). V_max values (mg/embryo/15 min) for methionine and leucine transport increase significantly from the late four-cell stage to the blastocyst stage, suggesting that additional carriers are produced or activated during development.Most importantly, leucine and methionine transport is Na⁺-independent at the four-cell stage, methionine transport is partially dependent at the morula stage, and both amino acids are completely Na⁺-dependent at the blastocyst stage. The cumulative results suggest that preimplantation embryos accumulate leucine and methionine by specific, chemically mediated, active transport systems. The qualitative and quantitative developmental changes in cell membrane function may represent preparatory steps for subsequent growth of embryonic and/or trophoblastic cells.     

Mechanism of monocarpic senescence in rice

During grain formation stage (90 to 110 days), the youngest flag leaf of rice (Oryza sativa L. cv. Jaya) remained metabolically most active (as indicated by cellular constituents and enzyme activities) and the third leaf the least active. At the grain development stage (110 to 120 days) the above pattern of age-related senescence of the flag leaf completely changed and it senesced at a faster rate than the second leaf which remained metabolically active even up to grain maturation time (120 to 130 days), when both the flag and the third leaf partially senesced. Removal of any leaf temporarily arrested senescence of the remaining attached leaves, that of flag leaf did not hasten senescence of the second leaf, while that of either the second or the third accelerated senescence of the flag. Removal of the inflorescence after emergence or foliar treatment of intact plant with kinetin equally delayed senescence and produced an age-related, sequential mode of senescence or leaves. Both translocation and retention of ³²P by the flag leaf were maximum at the time of grain formation and that by the second leaf was maintained even up to grain maturation time. The induction of senescence of the flag leaf was preceded by a plentiful transport of ³²P to the grains. Kinetin treatment decreased the transport of ³²P, prolonged its duration, and almost equally involved all of the leaves in this process. The pattern of senescence of isolated leaf tips was similar to that of attached leaves. The level of endogenous abscisic acid-like substance(s) maintained a close linearity with the senescence behavior of the leaves of intact and defruited plants during aging, and the rise in abscisic acid in the flag leaf was also preceded by higher ³²P transport to the grains.     

Functional membrane vesicles from the nervous system of insects: I. Sodium- and chloride-dependent γ-aminobutyric acid transport

(1) A synaptosomal fraction obtained from locust nervous tissue has been shown to possess an active γ-aminobutyric acid transport mechanism. This activity is preserved and even enriched by the membrane vesicles derived from osmotically shocked synaptosomes. (2) Electron-microscopy examination indicates that the above membrane vesicles are derived predominantly from the neuronal plasma membrane and are devoid of any internal cellular organelles and components. Active transport of γ-aminobutyric acid into these vesicles has been demonstrated with artificially imposed ion gradients as the sole energy source. (3) γ-Aminobutyric acid transport can be driven by an Na⁺ gradient (out>in) and /or by a gradient of Cl^? (out>in). This process is absolutely dependent on the simultaneous presence of both types of ion in the external medium. The stimulation of the process by valinomycin indicates that γ-aminobutyric acid transport is an electrogenic process which is stimulated by a membrane potential (interior negative).     

Plasma membrane Ca2+ transport: Antagonism by several potential inhibitors

Summary Inside-out vesicles prepared from human red blood cells took up Ca²⁺ by an active transport process. Membranes from the same red blood cells displayed Ca²⁺-activated, Mg²⁺-dependent adenosine triphosphatase activity. Both the initial rate of Ca²⁺ transport and the (Ca²⁺+Mg²⁺)-adenosine triphosphatase activity were increased approximately twofold by the calcium binding protein, calmodulin. Activities in the absence of added calmodulin were termed basal activities. Calmodulin-activated Ca²⁺ transport and adenosine triphosphatase activities could be antagonized in a relatively selective fashion by the phenothiazine tranquilizer drug, trifluoperazine. High concentrations of trifluoperazine also inhibited basal Ca²⁺ transport and adenosine triphosphatase activity. By contrast, calmodulin binding protein from beef brain selectively antagonized the effect of calmodulin on Ca²⁺ transport with no inhibition of basal activity. Ruthenium red antagonized calmodulin-activated and basal activity with equal potency. The results demonstrate that although phenothiazines can act as relatively selective antagonists of calmodulin-induced effects, other effects are possible and cannot be ignored. Calmodulin-binding protein may be a useful tool in the analysis of calmodulin functions. Ruthenium red probably interacts with Ca²⁺ pump adenosine triphosphatase at a site not related to calmodulin.     

In vitro studies on intestinal calcium and phosphate transport in horses

Transepithelial transport mechanisms play a key role in regulating the absorption and secretion of calcium (Ca^2 +) and inorganic phosphate (P_i) in the gastrointestinal tract. Although intestinal disorders with imbalances in macromineral homeostasis are frequently observed in horses, available data on intestinal Ca^2 + and P_i transport are limited. The aim of the present study was to characterize the intestinal Ca^2 + and P_i transport functionally by using the in vitro radioisotope tracer technique with Ussing chambers and to identify components involved in Ca^2 + transport at both mRNA and protein level. Among the different intestinal segments, the duodenum showed significant and highest active Ca^2 + absorption. The findings from RT-PCR and Western blot analysis suggest that the epithelial Ca^2 + channel TRPV6, the cytosolic calcium binding protein calbindin-D_9K and the plasma membrane calcium ATPase PMCA may be involved in active transcellular Ca^2 + transport. Regarding the P_i transport, the results indicate significant active P_i secretion in the jejunum, but the contributing mechanisms remain unclear. A significant inhibiting effect of ouabain as an antagonist of the basolateral Na⁺/K⁺-ATPase on the serosal-to-mucosal P_i transport suggests a pivotal role of Na⁺ in jejunal P_i transport in the horse.     

Role of Oxidative Metabolism in the Energy Suppply of Active Potassium Transport in Erythrocytes of the Lamprey Lampetra fluviatilis

To study role of glycolysis and oxidative metabolism in providing active transport of monovalent cations, isolated erythrocytes of the lamprey Lampetra fluviatlis were incubated at 20°C in the presence of various metabolic inhibitors. The active (ouabain-sensitive) K⁺ (⁸⁶Rb) influx into erythrocytes did not change after cell incubation for 1–2 h in the absence of glucose or in the presence of 10 mM deoxy-D-glucose or 1 mM monoiodoacetate. Inhibitors of oxidative phosphorylation (antimycin A, rotenone, sodium azide, cyanide) produced a significant decrease (on average, by 74% ) in the active K⁺ transport in the lamprey erythrocytes. All blockers of oxidative phosphorylation produced the same degree of inhibition of the K⁺ transport after the cell pre-incubation with them for 30 and 60 min. In experiments with rotenone, the K⁺ influx was reduced statistically significantly as early as in 5 min of cell incubation and reached a maximal effect after 10–20 min. The intracellular ATP content in erythrocytes decreased by 17, 37, and 45% after 5, 10, and 20 min of cell incubation with rotenone, respectively. The active K⁺ transport in the lamprey erythrocytes is most likely to be closely associated with the intracellular ATP concentration. The data obtained indicate that the energy supply of the Na,K-pump in the lamprey erythrocytes is due exclusively to oxidative phosphorylation processes.