The Transport and Metabolism of Urea in Chara australis: I. PASSIVE DIFFUSION, SPECIFIC TRANSPORT AND METABOLISM OF UREA, THIOUREA AND METHYLUREA

Most of the urea entering Chara australis cells is rapidly metabolizedto produce CO₂, which diffuses out of the cells into the surroundingmedium. A simple and convenient apparatus to measure both the¹⁴C-urea retained by cells and the ¹⁴CO₂ released into the mediumwas developed and used in a study of urea transport in Chara.The permeability coefficient for urea in the Chara plasmalemmawas estimated from the slope of an uptake versus concentrationfunction as 85 nm s^-1. Computer modelling of urea uptake andmetabolism suggests that this could be a 20% underestimate ofthe true value.The corresponding permeability coefficients forthiourea and N-methyl-urea were estimated in the same way as34 and 35 nm s^-1, respectively. These permeabilities are muchgreater than expected on the basis of either/water partitioncoefficients for the solutes and are consistent with the diffusionof urea and its similarly-sized analogues through aqueous poresin the plasmalemma.At external concentrations of urea less than20 mmol m^-3, the bulk of the uptake is effected by a specifictransport mechanism with an apparent K_m for urea of less than1.0 mmol m^-3. This transport system operates most rapidly withexternal pH in the range 6.5–7.5 and is influenced bythe nitrogen status of the cell.Evidence is produced here suggestingthat the specific transport of urea may be an active process. Key words: Chara, urea uptake, metabolism, diffusion, specific transport     

The Transport and Metabolism of Urea in Chara australis: III. TWO SPECIFIC TRANSPORT SYSTEMS

Reciprocal competitive inhibition studies were used to showthat N-methyl-urea (NMU), acetamide and urea all compete forbinding to a common transport system, designated system I andthat this system is one of two specific mechanisms transportingurea in Chara. System I binds urea with a Km of about 0–3mmol m-3 and is strongly influenced by metabolic controls. SystemI is active and electrogenic and may be energized by the couplingof urea uptake to an influx of protons. This is the first reportof an electrogenic urea transport system in an alga. The secondspecific mechanism for urea transport, designated system II,binds urea with a relatively low affinity (K_m c. 7–0 mmolm-3) and does not transport NMU to a significant extent. SystemII is less subject to metabolic control than system I and, thoughit may be active, is not electrogenic. Key words: Urea, methylurea, proton cotransport, metabolic control     

Physiological Control of Chloride Transport in Chara corallina: II. THE ROLE OF CHLORIDE AS A VACUOLAR OSMOTICUM

The extent to which Cl⁻ is replaceable as the major anionic constituent of the vacuole of Chara corallina was investigated. It was found that external Cl⁻ is not essential in order for nongrowing cells to increase internal osmotic pressure. After growth of cells in low (9 micromolar) Cl⁻, the vacuolar Cl⁻ concentration is one-half that of cells grown at normal external Cl⁻ concentration (850 micromolar). In contrast, both internal osmotic pressure and total concentration of the major cations, K⁺ and Na⁺, in the same cells were found to be only slightly sensitive to the external Cl⁻ concentration. Thus, it is proposed that, at limiting external Cl⁻ concentration, the cell is able to transport or synthesize another anion for vacuolar use rather than utilize a neutral solute.     

Partial Purification and Characterization of Aminopeptidase II from Chara australis

Aminopeptidase II, one of the two major aminopeptidases in the giant alga Chara australis, was partially purified. Its molecular weight was estimated to be about 80,000 by gel permeation chromatography. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis showed that it is composed of a single polypeptide with a molecular weight of about 85,000. Aminopeptidase II hydrolyzed alanine-2-naphthylamide more efficiently than the naphthylamides of lysine and proline, and only weakly hydrolyzed the naphthylamides of arginine, phenylalanine, valine, and leucine. The optimal pH for the hydrolysis of alanine-2-naphthylamide was near 7.0. The activity of aminopeptidase II was inhibited by the SH-reagents p-chloromercuribenzoic acid and N-ethylmaleimide and by the metal chelator 1,10-phenanthroline.     

Potassium Transport Across the Membranes of Chara: II.42K FLUXES AND THE ELECTRICAL CURRENT AS A FUNCTION OF MEMBRANE VOLTAGE

Smith, J. R. 1987. Potassium transport across the membranesof Chara. II. ⁴²K fluxes and the electrical current as a functionof membrane voltage.—J. exp. Bot. 38: 752–777. The current required to clamp the trans-membrane voltage ofinternodal cells of Chara australis at different levels wasmeasured simultaneously with either the ⁴²K influx or efflux.Examination of the voltage-dependence of the ratio of the electricalcurrent to the unidirectional tracer fluxes yielded no evidenceof any amplification of the electrical driving force on theK⁺ ions. There was thus no evidence for the interaction of K⁺ions with themselves or any other species during their passageacross the membrane. These measurements allow the determinationof , the fraction of the electrical current carried by K⁺ ions.When the external [K⁺] = 10 mol m^–3, the average valueof was 0?85 for V_m > –125 mV and 07?5 for V_m <–150 mV. When the external [K⁺] = 0?1 mol m^–3, was 0?6 for V_m < –80 mV and 0?1 for V_m > –250mV. It was also found that the conductance associated with K⁺transport was inhibited by hyperpolarization. Key words: Potassium, conductance, flux-ratio     

Plasmalemma Transport of OH- in Chara corallina: II. FURTHER ANALYSIS OF THE DIFFUSION SYSTEM ASSOCIATED WITH- OH EFFLUX

The dynamic and steady state aspects of the pH and electricpotential () profiles, that develop in the experimental mediumin association with the photosynthetic assimilation of exogenousHCO^–₃ by internodal cells of Chara corallina, were investigated.A theoretical treatment is presented which explains the originof the phenomenon. This theory was tested by comparing thepH and values generated by a numerical analysis model (whichsimulated the experimental system) against experimental data.Verification of our model indicates that the steady state ionicfluxes, associated with HCO^–3 assimilation (HCO^–₃,OH^–, and CO^23–, are not significantly influencedby the electric potential gradients. The main driving forcecausing the observed fluxes is the diffusion gradient associatedwith the respective ion. By simultaneous measurement of and pH, at the centre of analkaline band, a direct correlation was established betweenlight-activation and dark-deactivation of the OH^– transportsystem and the light-mediated changes in at the cell surface.In addition, under steady state conditions, an almost perfectcorrelation was observed between alkaline band pH centres andthe negative electric potential maxima. These data offer strongsupport for the hypothesis that OH^–efflux, in this system,is an electrogenic process. Based on our present analysis, the profile along the cell indicatesthat, in terms of the spatial aspect of HCO3^– transport,the rate of HCO^–₃ influx varies quite dramatically alongthe length of an internodal cell. This aspect is discussed interms of the cellular integration of OH^– and HCO^–₃transport in this species.     

The regulation of ammonia uptake in Chara australis

The regulation of ammonia uptake was investigated in internodalcells of the freshwater alga Chara australis. Ammonia uptakewas estimated by monitoring (i) its depletion from the bathingsolution, (ii) the uptake of radiolabelled methylamine, an analogueof ammonia, and (iii) depletion of ammonia in the unstirredlayer with the microelectrode ion-flux estimation technique(MIFE). Distribution of methylamine (¹⁴CH₃NH₃⁺) between thevacuole and cytoplasm was estimated with efflux analysis. Whencells were bathed continuously in solutions containing ammoniaor methylamine, the uptake rates of both amines decreased over12 to 48 h despite the continuing existence of a large electrochemicalgradient favouring influx of the NH⁺₄ and CH₃NH⁺₄ cations. Treatmentwith 1.0 to 10.0 mM MSX, an inhibitor of glutamine synthetase,caused the internal ammonia concentration to rise and reducedthe subsequent uptake of ammonia and methylamine by up to 70%within 2 h. These results suggest that the permease facilitatingNH⁺₄/CH₃NH⁺₄ influx is under feedback or kinetic regulationfrom either internal ammonia or an intermediate of nitrogenassimilation. Treatment with metabolic inhibitors (CCCP, azide and DCMU) andsome weak acids (DMO and butyric acid) for 30 to 60 min inhibitedmethylamine uptake, but the changes in the electrical potentialdifference across the plasma membrane could not account forthe magnitude of inhibition. The rate of cytopiasmic streaming,which is an indicator of the cellular ATP concentration in Chara,was inhibited by many of these treatments. However, under certainconditions of external pH and concentration, butyric acid couldreversibly inhibit ammonia and methylamine uptake without affectingcytoplasmic streaming, demonstrating that a decrease in cytoplasmicATP concentration was not responsible for the inhibition. Theeffect of butyric acid was rapid, causing a 60% inhibition ofuptake in 15 min. We conclude that weak acids can inhibit theNH⁺₄/CH₃NH⁺₄ permease by acidifying the cytoplasm and suggestthat this may also explain the effects of the metabolic inhibitorson ammonia and methylamine uptake. Key words: Ammonia, methylamine, uptake, regulation, Chara     

高等植物尿素代谢及转运的分子机理

尿素广泛存在于自然界中,是易于被许多生物（如植物）利用的生长氮源。该文通过概述尿素在不同生命系统中存在的基础生理意义及各类型尿素转运蛋白,讨论了植物细胞中尿素合成与分解的各种途径及尿素在植物氮营养、代谢和运输中的生理作用。迄今为止,在植物中已发现了2类转运尿素的膜蛋白,即MIPs和DUR3,它们分别在低亲和力、高亲和力尿素运输中发挥潜在作用。异源表达结果表明MIPs介导了尿素的被动迁移：而AtDUR3则参与拟南芥根系对尿素的吸收。对MIPs和DUR3转运尿素的酶学特征、亚细胞作用位点和表达调控状况等的研究表明：它们的分子生物学功能与植物的氮营养及氮素再分配和利用相关。     

Potassium Transport Across the Membranes of Chara: III. EFFECTS OF pH, INHIBITORS AND ILLUMINATION

Smith, J. R., Walker, N. A. and Smith, F. A. 1987. Potassiumtransport across the membranes of Chara. III. Effects of pH,inhibitors and illumination.—J. exp. Bot. 38: 778–787. The effects of several treatments, normally used to inhibitelectrogenic proton transport, upon the potassium permeability(P_k) of the membranes of Chara were examined by means of simultaneousmeasurements of the ⁴²K influx (ⁱⁿ_K) and the membrane electricalconductance (G_m). ⁱⁿ_K, P_K and G_mwere found to be substantiallyunaffected when the external pH (pH?) was varied over the range5?0 to 85. However, when pH? was increased to 11 it was foundthat, although G_m increased considerably, both P_k and ⁱⁿ_K decreasedtypically by an order of magnitude. When cells were placed intotal darkness, P_K decreased substantially only after one dayhad elapsed. For the particular experimental conditions used,the inhibitors DES, NaN₃, and La₃₊ were found to alter P_K, whereasDCCD left P_K substantially unaffected. These results suggestthat care must be taken with some common procedures used toexamine the electrical properties of the electrogenic protonpump. Key words: Potassium, pH, illumination, inhibitors     

Intercellular Transport in Plants: II. CYCLOSIS AND THE RATE OF INTERCELLULAR TRANSPORT OF CHLORIDE IN CHARA

The effect of streaming speed on intercellular transport ofchloride has been studied using pairs of internodal cells ofChara. The rate of transport was measured by that fraction ofthe chloride that entered one internode which was transportedout of it into the cells of the node and the next internode.The speed of cytoplasmic streaming was altered by treating thefirst cell with cytochalasin B. The relative rate of intercellular transport depended markedlyon the streaming speed at all speeds up to those found in untreatedcells. The chloride influx into the treated cell did not dependon the streaming speed. It is concluded that the rate of intercellular transport oflow molecular weight solutes in Chara will be normally limitedby the rate at which cytoplasmic streaming brings solute tothe plasmodesmata, rather than by the diffusion permeabilityof the plasmodesmata. This conclusion may well apply to othercharophyte plants, and could in principle apply to higher plants.     

STUDIES ON THE METABOLISM OF UREA AND OTHER NITROGENOUS COMPOUNDS IN CHLORELLA ELLIPSOIDEA: III ASSIMILATION OF UREA

Assimilation of urea by Chlorella ellipsoidea was investigatedby using ¹⁴C-urea. It was revealed that urea carbon metabolizedby the N-starved cell was almost quantitatively recovered incarbon dioxide under dark-aerobic conditions. The rate of ureaconsumption was considerably influenced by the N-content ofalgal cells, practically no metabolism of urea being observedwith the cells containing more than 7 per cent N on a dry weightbasis. Similar results were also obtained when urea was replacedwith ammonia as nitrogen source. Based on the results obtained,a tentative scheme for the assimilation process of urea in Chlorellawas proposed. (Received February 7, 1960; )     

Transport of potassium inChara australis: II. Kinetics of a symport with sodium

Summary An electrogenic K⁺–Na⁺ symport with a high affinity for K⁺ has been found inChara (Smith & Walker, 1989). Under voltage-clamp conditions, the symport shows up as a change in membrane current upon adding either K⁺ or Na⁺ to the bathing medium in the presence of the other. Estimation of kinetic parameters for this transport has been difficult when using intact cells, since K⁺–Na⁺ current changes show a rapid falling off with time at K⁺ concentrations above 50 m. Cytoplasm-enriched cell fragments are used to overcome this difficulty since they do not show the rapid falling off of current change seen with intact cells. Current-voltage curves for the membrane in the absence or presence of either K⁺ or Na⁺ are obtained, yielding difference current-voltage curves which isolate the symport currents from other transport processes. The kinetic parameters describing this transport are found to be voltage dependent, withK _m for K⁺ ranging from 30 down to 2 m as membrane potential varies from –140 to –400 mV, andK _m for Na⁺ ranging between 470 and 700 m over a membrane potential range of –140 to –310 mV.Two different models for this transport system have been investigated. One of these involves the simultaneous transport of both the driver and substrate ions across the membrane, while the other allows for the possibility of the two ions being transported consecutively in two distinct reaction steps. The experimental results are shown to be consistent with either of these cotransport models, but they do suggest that binding of K⁺ occurs before that of Na⁺, and that movement of charge across the membrane (the voltage-dependent step) occurs when the transport protein has neither K⁺ nor Na⁺ bound to it.     

Investigations of Carbon Transport in Plants: II. THE EFFECTS OF LIGHT AND DARKNESS AND SINK ACTIVITY ON TRANSLOCATION

The use of ¹¹C as a tracer has allowed repetitive measurementsof the speed of assimilate translocation to be made on singlemaize plants throughout prolonged periods of light and darkness.The speed appeared to double when the light was switched on.The time required to achieve a maximum speed, usually about3·5 cm min^–1, depended on the duration of the previousdark period. When the plant was transferred to darkness thespeed immediately decreased by about 20 per cent and continuedto decrease over the next 20 h to values of 0·5 to 0·9cm min^–1. The mean speed of translocation in tomato in the light, andother C3 plants, was usually about 1 cm min^–1. It wasreduced by 15–30 per cent when the fruit was removed orcooled from 26 to 10°C.     

Potassium Transport Across the Membranes of Chara: I. THE RELATIONSHIP BETWEEN RADIOACTIVE TRACER INFLUX AND ELECTRICAL CONDUCTANCE

Smith, J. R., Smith, F. A. and Walker, N. A. 1987. Potassiumtransport across the membrane of Chara. I. The relationshipbetween radioactive tracer influx and electrical conductance.—J.exp. Bot. 38:731–751. The ⁴²K influx () and the electrical conductance (G_m) were measured simultaneously for the ‘membrane’of internodal cells of Chara australis as a function of theexternal [KCl] (K?. In bathing solutions of pH = 5?0, progressively increased from 20?5to 430?60 nmol m^–2 s^–1 and G_m increased from 0?36?0?02to 3?8?0?8 S m^–2 when K? was increased from 0?1 to 10mol m^–3. The resting membrane potential difference (p.d.)was approximately -135 mV for low K? and approached the expectedNernst equilibrium p.d. for K⁺ ions when K? > 1?0 mol m^–3.Measurements of ³⁶Cl influx suggested that the ⁴²K influx waspredominantly electrogenic. The equivalent Goldman permeabilityto K⁺ ions (P_k) was approximately 20–30 nm s^–1 anddid not vary significantly with increasing K?. The equivalentconductance attributable to the electrogenic transport of K⁺ ions was calculated from assuming passive, independent diffusionof K⁺ ions and the ratio was found to be typically close to one. It was also found that themagnitudes of and G_m measuredsimultaneously for each individual cell were also well correlatedfor K? 1?0 mol m^–3, and that the slope of the line ofbest fit was close to one. For each K? it was found that theconductance not attributable to K⁺ translocation and presumablyassociated primarily with the transport of protons or theirequivalents was typically 0?2–0?5 Sm^–2. For K? >1?0 mol m^–3 the results indicated that the transport ofK⁺ ions was essentially independent, i.e. there was no evidencefor flux interactions. The results also indicated that the equivalentconductance derived from the measured ⁴²K influx could usefullyindicate the fraction of the electrical conductance attributableto the translocation of K⁺ ions. Key words: Potassium, conductance, influx     

Chloride Transport in Chara: I. KINETICS AND CURRENT-VOLTAGE CURVES FOR A PROBABLE PROTON SYMPORT

Chara cells show an inward positive electric current acrossthe plasmalemma when exposed to Cl^– under voltage-clampconditions. The rapid rise of this current suggests that itis directly associated with the inward transport of Cl^–.The dependence of the current on Cl^– concentration showssaturation, the data fitting the Michaelis-Menten equation withV_m up to 100 nmol m^–2 s^–1 (for Cl^–starvedcells) with K_M 10–20 µM, and with some allowancefor an unstirred layer of water adjacent to the membrane. Theeffects on the current of clamp potential, illumination, withdrawalof alkali metal cations, and addition of amine were also investigated.These results suggest that the mechanism is the symport of 2H⁺ with each Cl^–, and that the actions of light, externalK⁺, and amine in stimulating Cl^–, influx are indirect.