Uptake of Methylammonium Ions by Hydrodictyon africanum

Methylamine influx into Hydrodictyon has been measured with[^l4C]methylamine. The influx increases with rising externalpH up to about pH 8. Between pH 8 and 9 influx remains quiteconstant, with a further increase above pH 9. Influx is light-dependent,temperature-sensitive, and is decreased by . During short-term influx (less than 4 h) metabolism of methylamineappears negligible. Prolonged influx results in CH₃ accumulation, and efflux of K⁺, Na⁺, and H⁺. There is no effecton Cl^– influx. Methylamine decreases the membrane electricp.d. by 60–120 mV at external concentrations of 0?2–1?0mM. The results indicate that, below pH 9, methylamine enters thecell almost entirely as CH₃. It is suggested that a passive electrogenic uniporter is involved, and thatby analogy uniport of may also be expected in Hydrodictyon. The results are discussed in relation to theevidence for uptake of CH₃ and by other plant cells.     

Ion Transport in Hydrodictyon africanum

The concentrations of K, Na, and Cl in the cytoplasm and vacuole, the tracer fluxes of these ions into and out of the cenocyte, and the electrical potential difference between bathing solution and vacuole and cytoplasm, have been measured in Hydrodictyon africanum. If the ions were acted on solely by passive electrochemical forces, a net efflux of K and Cl and a net influx of Na would be expected. Tracer fluxes indicate a net influx of K and Cl and efflux of Na in the light; these net fluxes are consequently active, with an obligate link to metabolism. The effects of darkness and low temperature indicate that most of the tracer K and Cl influx and Na efflux are linked to metabolism, while the corresponding tracer fluxes in the direction of the free energy gradient are not. Ouabain specifically inhibits the metabolically linked portions of tracer K influx and Na efflux. Alterations in the external K concentration have similar effects on metabolically mediated K influx and Na efflux. It would appear that K influx and Na efflux are linked, at least in the light.     

The Role of Cyclic and Pseudocyclic Photophosphorylation in Photosynthetic 14CO2 Fixation in Hydrodictyon africanum

Experiments are reported in which the effects on photosynthesisof various inhibitors of cyclic photophosphorylation were investigated.These inhibitors, generally had only a small inhibitory effecton photosynthesis, and the inhibition was not increased by conditionswhich inhibit pseudocyclic photophosphorylation. These inhibitorsdo not inhibit the Emerson enhancement effect. From these resultsit was concluded that photosynthesis does not need any ATP otherthan that produced in non-cyclic photophosphorylation. The effectsof these inhibitors on active K influx in light-anaerobic conditionsin the presence or absence of CO₂ suggest that some of the ATPproduced by non-cyclic photophosphorylation can be used to supportactive K influx. The results are discussed in relation to themechanism of the Emerson effect, the stoichiometry of non-cyclicphotophosphorylation, and the ATP requirements for autotrophicgrowth.     

Ouabain-insensitive K influx in Hydrodictyon africanum

Summary The occurrence is reported of cells of Hydrodictyon africanum which have, contrary to previous reports by the author, a K influx which is almost insensitive to ouabain. The conditions which govern the ouabain-sensitivity of the K influx have not yet been defined. The low ouabain sensitivity of the total K influx seems to be related to a smaller than usual activity of the component of K influx which is linked to Na efflux, and also to a smaller sensitivity of this component to inhibition by ouabain. The major components of K influx in ouabain-insensitive cells correspond to those components previously described as the passive and Cl-linked components.The occurrence is also reported of an increased sensitivity of active Cl influx (and the coupled cation influxes) in the light to uncouplers when the medium is aerated or otherwise stirred.     

Acid-base regulation during nitrate assimilation in Hydrodictyon africanum

Abstract The acid-base balance during NO₃^? assimilation in Hydrodictyon africanum has been investigated during growth from (1) an analysis of the elemental composition of the cells, (2) the alkalinity of the ash and (3) the net H⁺ changes in the medium during growth. These investigations agree in showing that some 0.25 excess organic negative charges are generated per N assimilation from No₃^? as N-source and C02 as C-source; the excess OH^? (0.75 OH^? per NO₃^? assimilated) appears in the medium. Approximately half of the excess organic negative charge is attributable to cell wall uronates; the remainder is intracellular. All of the excess OH^? appearing in the medium must have crossed the plasmalemma (as net downhill H⁺ influx or OH^? efflux). Previous work has shown that the value of ψco is more negative than ψ_K⁺ during NO₃^? assimilation, suggesting that the active electrogenic H⁺ extrusion pump is still operative despite the net downhill H⁺ influx. The interpretation of this in terms of H⁺?NO₃^? symport which causes the entry of more H⁺ than is consumed in NO₃^? metabolism, with extrusion of the excess H⁺via the active, electrogenic H⁺ pump, was tested by measuring short-term H⁺ influx upon addition of NO^?₃. A net H⁺ influx occurs before NOa assimilation (as indicated by additional O₂ evolution in the light) has commenced, suggesting a mechanistic relation of H⁺ and NO₃^? influxes. This is consistent with the interpretation suggested above. Determinations of cytoplasmic pH showed no significant effect of NO₃^? assimilation, suggesting that cytoplasmic pH changes sufficient to change the ‘pH-regulating’ H⁺ fluxes are smaller than the errors in the determination of cytoplasmic pH.     

Energetics of Active Phosphate Influx in Hydrodictyon africanum

The energy source for active phosphate influx in Hydrodictyonafricanum has been investigated using gas mixtures with andwithout O₂ and CO₂, light of various wavelengths, and metabolicinhibitors selective for respiratory or photosynthetic electrontransport and phosphorylation. It is concluded that, as in theother green algae studied, active phosphate transport requiresATP. In the dark this is supplied by oxidative phosphorylation;in the light the influx is much less sensitive to inhibitionof oxidative phosphorylation, and photophosphorylation (includingcyclic photophosphorylation) can act as energy source. Thissituation is more like that for active K influx (coupled toactive Na efflux) than to active Cl influx in H. africanum,except that the active dark influx is relatively greater forphosphate influx. The significance of these results for themechanism of regulation of light-stimulated ATP-requiring processes,and for the role of photosynthetic and oxidative phosphorylationin the energy metabolism of green cells, is discussed.     

Measurement of Cytoplasmic pH by the DMO Technique in Hydrodictyon africanum

The 5, 5-dimethyl-[2-¹⁴C]oxazolidine-2, 4-dione (DMO) distributiontechnique for the measurement of intracellular pH has been appliedto giant cells of Hydrodictyon africanum. Significant metabolism of DMO was found in this alga; the free[DMO + DMO–] in subcellular samples is thus derived fromthe total label in cells equilibrated in [¹⁴C]DMO solutionsby measuring and subtracting the label in metabolic productsof DMO. A further problem arises from the observation that theDMO concentration in the vacuolar sap is always lower than thatpredicted by the transmembrane equilibration of undissociatedDMO from the bathing medium. This is interpreted in terms ofa finite permeability to the anion DMO–. Since the effectof P_DMO– on the DMO distribution is much smaller at thetonoplast (where the transmembrane electrical potential differenceis small) than at the plasmalemma, the values of cytoplasmicpH are computed assuming equilibration of undissociated DMOacross the tonoplast. At an external pH of 7.0 the cytoplasmic pH is about 7.4; decreaseor increase of external pH by 1 unit causes a decrease and anincrease in cytoplasmic p11 respectively of about 0.2 pH units.Determinations of _vo at pH 6, 7, and 8, together with an assumedconstant value of _cv, permit calculations of µ_H+ at theplasmalemma and tonoplast. The values are relatively independentof external pH in the range pH 6–8 at 21–25 and12–14 kJ mol^–1 respectively. The significance ofthese results for the regulation of intracellular pH, and forthe regulation and energising of the fluxes of ions, is discussed.     

Light Stimulation of Active Transport in Hydrodictyon africanum

The mechanism of light stimulation of active K and Cl influx and active Na efflux, in Hydrodictyon africanum has been investigated using different wavelengths of red light and different gas mixtures, and the inhibitors DCMU and CCCP. The active Cl influx requires photosystem 2, since its relative quantal efficiency falls with increasing wavelength of red light, and it is as sensitive to the inhibitor DCMU as is photosynthesis; it is relatively insensitive to the uncoupler CCCP. The active K influx and active Na efflux are inhibited by CCCP, but the relative quantal efficiency of these processes increases with increasing wavelength of red light, and they are relatively insensitive to DCMU. These cation fluxes can be supported by cyclic photophosphorylation, whereas Cl influx needs photosystem 2 but probably not ATP.     

Acid-base regulation during ammonium assimilation in Hydrodictyon africanum

Abstract The acid-base balance during ammonium (used to mean NH ₄⁺ and/or NH₃) assimilation in Hydrodictyon africanum has been measured on cells growing with about 1 mol m^?3 ammonium at an external pH of about 6.5. Measurements made included (1) ash alkalinity (corrected for intracellular ammonium) which yields net organic negative charge, (2) the accumulation of organic N in the cells and (3) the change in extracellular H⁺ (from the pH change and the buffer capacity). These measurements showed that some 0.25 excess organic negative charge (half in the cell wall, half inside the plasmalemma) accumulates per organic N synthesized, while some 1.25H⁺ accumulate in the medium per organic N synthesized. Granted a permeability (PNH₃) of some 10^?3 cm s^?1, and a finite [NH₃] in the cytoplasm of these N-assimilating cells it is likely that most of the ammonium entering these growing cells is as NH ₄⁺. This means that most of the H ⁺ appearing in the medium must have originated from inside the cell and have been subjected to active efflux at the plasmalemma: H⁺ accumulates in the medium equivalent to any NH₃ entry by requilibration from exogenous NH ₄⁺. The cell composition (net organic negative charge, organic N content) is very similar in these ammonium-grown cells to that of NO₃⁺grown cells, suggesting that there is no action of a ‘biochemical pH stat’ during longterm assimilation of NO₃⁺in H. africanum. Short-term experiments were carried out at an external pH of 7.2 in which ammonium at various concentrations were supplied to NO₃⁺-grown cells. There was in all cases a rapid influx followed by a slower uptake; at least at the lower concentrations (less than 100 μmol dm^?3) the net influx was all attributable to NH₄⁺influx via a uniporter, probably partly short-circuited by a passive NH₃ efflux due to intrinsic membrane permeability to NH₃. The net ammonium influx was in all cases associated with H⁺ accumulation in the medium. (1.3-1.7 H ⁺ per ammonium taken up); as in the growth experiments, most of the ammonium taken up was assimilated. Determinations of cytoplasmic pH showed either no effect on, or a slight decrease in, pH during ammonium assimilation; the changes that occurred were in the direction expected for actuating a ‘pH-regulating’ change in H⁺ fluxes.     

The Action of Phlorizin on Photosynthesis and Light-stimulated Ion Transport in Hydrodictyon africanum

Phlorizin at 1 mM inhibits the coupled active influx of K andefflux of Na in Hydrodictyon africanum in the light. It doesnot inhibit the coupled influx of Cl and monovalent cations,nor the passive ion fluxes. Photosynthesis can be stimulatedup to 30 per cent under light-saturated conditions. It is concludedthat the effects of phlorizin cannot be solely due to an inhibitionof the membrane ATPase, and that photophosphorylation must insome way be affected. The nature of this effect is discussedin the light of the effects of phlorizin on photophosphorylationin isolated chloroplasts.     

Measurement of Simultaneous Oxygen Evolution and Uptake in Hydrodictyon africanum

Oxygen uptake and evolution in illuminated and darkened cellsof Hydrodictyon africanum have been measured using ¹⁸O₂ massspeetrometry. Under conditions of light and CO₂ saturation forphotosynthesis, light stimulates oxygen uptake more than two-fold.This stimulation is prevented by DCMU but is not affected bycyanide or the uncoupler CCCP. The data are consistent withthe occurrence of a pseudocyclic electron flow and photophosphorylationin vivo in H. africanum; this agrees with data on light-dependentactive phosphate influx in this alga. Part of the light-stimulatedoxygen uptake might be involved in glycolate synthesis by thepathway proposed by Coombs and Whittingham.     

The Linkage of Light-stimulated Cl Influx to K and Na Influxes in Hydrodictyon africanum

There are reciprocal stimulations of Cl influx by K and Na,and of K and Na influx by Cl, in the light in Hydrodictyon africanum.The component of the K influx which stimulates, and is stimulatedby, Cl, is independent of the ouabainsensitive mechanism forK influx also found in H. africanum. The concentration dependenceof the cation effects on Cl influx and on the Cl-stimulatedportion of their own influxes are similar. The stimulation withK saturates at about 0.3 mM K; that with Na saturates at about2 mM Na. The Cl-dependent portions of the K and Na influxeshave similar responses to changes in photo-synthetic metabolism(far-red illumination, CDMU, and CCCP) as does the light-stimulatedCl influx. This suggests that Cl influx, and the Cl-stimulatedportions of K and Na influxes are both dependent on photosystem2 of photosynthesis, and are less sensitive to the uncouplerCCCP than is ¹⁴CO₂ fixation or the K-Na pump. It would thusappear that the Cl-dependent portions of the K and Na influxesin the light are linked to the cation-stimulated portion ofthe Cl influx. There is no very great change in the electricalcomponent of the inwardly directed passive driving force oncations under conditions in which Cl is being pumped comparedwith those under which it is not. It is not clear whether suchincrease in this driving force as do occur could account quantitativelyfor the increase in the cation influxes associated with Cl transport,or whether chemical coupling must be invoked. In addition tothe Cl-stimulated portions of the cation influxes, there arealso light-stimulated portions of K and Na influx which areindependent of Cl, not associated with the cation regulatingmechanism, and which seem to have a similar linkage to photosynthesisas does the Cl-K-Na pump. Since the light-stimulated portionof the K efflux appears to be similar to this portion of theK influx, these Cl-independent light-stimulated portions ofK and Na influxes are tentatively related to light-induced changesin cation permeability.     

ATP Synthesis Coupled to Nitrate Photoreduction in the Alga Hydrodictyon africanum

The presence of exogenous stimulates O₂evolution in illuminated H. africanum cells at the CO₂ compensationpoint, and it is likely that reduction in the light uses reductant produced in non-cyclic electron flow.When sources of ATP other than fermentation are absent, thepresence of , light, and a functional non-cyclic electron transport pathway stimulates active, ATP-dependentH₂ influx. This is consistent with non-cyclic electron flow associated with reduction being coupled to ATP synthesis. This -dependent ATP synthesis may be quantitatively important as a source ofATP during photolithotrophic growth with as N source in H. africanum and other algal unicells.     

Cyclic and Non-cyclic Photophosphorylation as Energy Sources for Active K Influx in Hydrodictyon africanum

Under anaerobic conditions in the light, active K influx inHydrodictyon africanum is supported by cyclic photophosphorylation.The use of selective inhibitors shows that, in the presenceof CO₂, a considerable portion of the ATP used by the K pumpis supplied by noncyclic photophosphorylation. The rest of theATP in these conditions comes from cyclic photophosphorylation.This is true under light-limiting as well as light-saturatedconditions. If non-cyclic photophosphorylation is inhibited (by removalof carbon dioxide, by the addition of cyanide which interfereswith the carboxylation reaction, or by inhibition of photosystemtwo with DCMU or supplying only far-red light), the K influxat low light intensities is stimulated, and its characteristicsbecome those of a process powered by cyclic photophosphorylationalone. These results are interpreted in terms of a competitionfor ATP between K influx and CO₂ fixation. Implicit in thisexplanation is a requirement for a switch of excitation energyabsorbed by photosystem one from cyclic photophosphorylationto non-cyclic photophosphorylation whenever conditions (presenceof CO₂and photosystem two activity) allow CO₂ fixation to occur. Further evidence for such a switch of excitation energy absorbedby photosystem one was obtained in experiments in which redand far-red light were applied separately and together. It wasfound that CO₂ fixation showed the Emerson enhancement effect,while K influx (in the presence of CO₂) shows a ‘de-enhancement’.This suggests that far-red light alone powers cyclic photophosphorylation;if red light is also present, some of the far-red quanta arediverted to non-cyclic photophosphorylation. The nature of the interaction between cyclic and non-cyclicphotophosphorylation is discussed in relation to these and otherpublished results.     

The Mechanism of Photosynthetic Product Secretion by Carrot-Tissue 2

Green carrot-callus cultures exposed for 3 h in liquid mediato light and ¹⁴CO₂ secreted a constant 6–8 per cent oftheir total ¹⁴C-photosynthate into the medium over a wide rangeof ¹⁴CO₂-fixation rates, obtained by varying ¹⁴CO₂ levels. Themajor secreted products (sucrose and glutamine) or analoguesof these compounds did not affect secretion when included inthe bathing medium. Dual-labelling studies with [6-T] glucoseand ¹⁴CO₂ demonstrated that secretion occurred from a metabolicrather than a storage compartment. The effects of long preincubationperiods in liquid media and of osmotic shock showed that secretiontook place from specific sites on the boundary of the metaboliccompartment.     

Na_2SO_3和NaHCO_3对叶绿体CF_1－ATPase活力作用的机制

Ｎａ２ＳＯ３对热－ＤＴＴ活化的游离ＣＦ１及类囊体膜上ＣＦ１－ＡＴＰａｓｅ活力均有显著的促进作用,ＮａＨＣＯ３亦有明显的促进作用。Ｎａ２ＳＯ３和ＮａＨＣＯ３的促进作用与它们解除Ｍｇ２＋的抑制作用有关。从ＮａＨＣＯ３和Ｎａ２ＳＯ３及它们与Ｍｇ２＋之间的竞争性关系,表明三者是结合在酶的同一部位上。Ｎａ２ＳＯ３可明显降低热－ＤＴＴ活化的游禹ＣＦ１－ＡＴＰａｓｅ催化反应的活化能,这可能与促进产物ＡＤＰ的释放有关。     

Further Characteristics of Salt-Dependent Bicarbonate Use by the Seagrass Zostera muelleri

Millhouse, J. and Strother, S. 1987. Further characteristicsof salt-dependent bicarbonate use by the seagrass Zostera muelleri.—J.exp. Bot. 38: 1055–1068. The contribution of HCO^–₃to photosynthetic O₂ evolutionin the seagrass Zostera muelleri Irmisch ex Aschers. increasedwith increasing salinity of the bathing seawater when the inorganiccarbon concentration was kept constant. K_1/2 (seawater salts)for HCO^–₃ -dependent photosynthesis was 66% of seawatersalinity. Both short- and long-term pretreatment at low salinitiesstimulated photosynthesis in full strength seawater. Twentyfour hours pre-incubation of seagrass plants in 3·0 molm^–3 NaHCO₃ resulted in increased photosynthesis at allsalinities, apparently due to stimulation of HCO^–₃ use(K_1/2 (seawater salts) = 26%). V_max (HCO^–₃) was not affectedby low salinity pretreatment. The kinetics of HCO^–₃ stimulationby the major seawater cations was investigated. Ca²⁺ was themost effective cation with the highest V_max (HCO^–₃) andwith K_1/2(Ca²⁺) = 14 mol m^–3. Mg²⁺ was also very effectiveat less than 50 mol m^–3 but higher concentrations wereinhibitory. This inhibition cannot be accounted for solely byprecipitation of MgCO₃. Na⁺ and K⁺ were both capable of stimulatingHCO^–₃ use. Stimulation was in two distinct parts. Up to500 mol m^–3, both citrate and chloride salts gave similarresults (K_1/2(Na⁺) 81 mol m^–3, V_max(HCO^–₃) 0·26µmol O₂ mg^–1 chl min^–1), but use of citratesalts above 500 mol m^–2 caused a second stimulation ofHCO^–₃ use (K_1/2(Na⁺) 830 mol m^–3, V_max(HCO^–₃)0·68 µmol O₂ mg^–1 chl min^–1). V_max(HCO^–₃)for the second-phase Na⁺ or K⁺ stimulation was of the same orderas for Ca²⁺-stimulated HCO^–₃ use. To further characterizesalt-dependent HCO^–₃ use, the sensitivity of photosynthesisto Tris and TES buffers was investigated. The effects of Trisappear to be due to the action of Tris⁺ causing stimulationof HCO^–₃ -dependent photosynthesis in the absence of salt,but inhibition of HCO^–₃ use in saline media. TES has noeffect on photosynthesis. External carbonic anhydrase, althoughimplicated in salt-dependent HCO^–₃ use in Z. muelleri,could not be detected in whole leaves. Key words: Zostera muelleri, HCO^–₃ use, salinity     

C4 characteristics of photosynthesis in the C3 alga Hydrodictyon africanum

Abstract Results obtained with Hydrodictyon africanum, and data from the literature, show that most green algae of the chlorophyte type (e.g. Chlorella, Chlamydomonas, Hydrodictyon) differ in their photosynthetic C fixation characteristics from most green algae of the charophyte type (e.g. Spirogyra, Chara) and from C₃ higher plants. The chlorophyte algae fix inorganic carbon by the photosynthetic carbon reduction cycle pathway, but have a low CO₂ compensation point in 250 μM O₂, a low inhibition of CO₂ fixation from 10 μM CO₂/250 μM O₂ when compared with 10 μM CO₂/zero O₂, and a low half-saturation constant for CO₂. These three characteristics are different from those of charophytes and C₃ higher plants, and resemble those of C₄ higher plants. It is suggested that these characteristics of chlorophyte algae are the result of a ‘CO₂ concentrating mechanism’ which increases the CO₂/O₂ ratio at the site of ribulose bisphosphate carboxylase-oxygenase action in a similar way to that achieved by the C₄?C₃ acid cycle in C₄ plants. In the chlorophyte algae, however, CO₂ concentration probably involves active HCO₃^? transport at the inner membrane of the chloroplast envelope. Active HCO₃^? transport can occur at the plasmalemma of charophyte algae and submerged aquatic higher plants as well as chlorophyte algae, so it is unlikely to explain the differences between the two groups of aquatic green plants. Differences in the properties of ribulose bisphosphate carboxylase-oxygenase, and differences in CO₂ production in the light, also seem inadequate to account for the different photosynthetic characteristics. The chlorophyte type of ‘C0₂ concentrating mechanism’ appears to be common in other classes of eukaryotic algae, and in cyanophytes. Some of the ‘advanced’ members of these eukaryotic algal classes (including the chlorophytes) may lack the mechanism, while some ‘primitive’ charophytes may retain the mechanism which their ancestors presumably possessed.