Variable Effects of Nitrate on ATP-Dependent Proton Transport by Barley Root Membranes

DuPont, Frances M.

doi:10.1104/pp.84.2.526

Cited by 31 publications

(49 citation statements)

References 30 publications

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“…A tonoplast-enriched membrane fraction was isolated as described previously (6,9). Roots (10 gm) were excised into ice water, rinsed, and then ground in homogenization buffer (67 mL) containing 250 mm sucrose, 50 mm Tris, 8 mM EDTA, and 4 mm DTT (pH 8.0).…”

Section: Membrane Preparationsmentioning

confidence: 99%

“…The generation and dissipation of pH gradients across the membrane vesicles were followed by measuring quenching and recovery of acridine orange fluorescence as described previously (6,9). The assay buffer contained 250 mM sorbitol, 50 mm choline-Cl, 1 mM MgCl2, 1 mm EGTA, 2.5 1M acridine orange, and 5 mM Mes adjusted to pH 7.8 with Tris.…”

Section: Enzyme Assaysmentioning

confidence: 99%

“…The generation and dissipation of pH gradients across the membrane vesicles were followed by measuring quenching and recovery of acridine orange fluorescence as described previously (6,9 …”

Section: Enzyme Assaysmentioning

confidence: 99%

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Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Garbarino¹,

DuPont²

1989

Plant Physiol.

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101

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Na+/H exchange activity in barley (Hordeum vulgare cv CM-72) root tonoplast was induced by Na+ even in the presence of inhibitors of protein synthesis. Induction occurred with a half-time of only 15 minutes. When salt-treated roots were transferred to a nutrient solution containing no Nat, the activity disappeared with a similar time course. The data suggest that Na+/H+ exchange was due to activation of an existing protein rather than to de novo protein synthesis.Buildup of salts in the soil is a major problem on irrigated farmland and in semiarid regions where winter rainfall is not sufficient to flush accumulated salts from the top soil (18). To grow in saline soils, plants must maintain a much lower ratio of Na+/K+ in their cytoplasm than is present in their surroundings (10,13,14). Multiple mechanisms, including morphological and biochemical adaptations, are probably involved in maintaining this low cytoplasmic Na+/K+ ratio. In barley (Hordeum vulgare), two such mechanisms are extrusion of Na+ into the vacuole across the tonoplast membrane and extrusion of Na+ into the external medium across the plasma membrane (13, 16). The energy for Na+ extrusion could be provided by the proton gradients generated by the plasma membrane or tonoplast H+-ATPases. Recently, using the tonoplast ATPase to generate the H+ gradient, we discovered a Na+/H+ exchange in vesicles from a tonoplast-enriched fraction isolated from barley roots (9). Na+/H+ antiports have also been reported in tonoplast fractions from red beet (Beta vulgaris) (2) and sugar beet (3). The Na+/H+ exchange activity in cell suspension cultures of sugar beet, a halophyte, was partly constitutive (3). In contrast, that of barley, a relatively salt-tolerant glycophyte, was undetectable unless the plants were grown in the presence of Na+. In this paper, induction of the tonoplast Na+/H+ exchange activity in barley is characterized in more detail. MATERIALS AND METHODS Plant MaterialA salt-tolerant cultivar of barley, Hordeum vulgare L. cv CM-72 (1), was grown as described previously (7) Membrane PreparationsA tonoplast-enriched membrane fraction was isolated as described previously (6, 9). Roots (10 gm) were excised into ice water, rinsed, and then ground in homogenization buffer (67 mL) containing 250 mm sucrose, 50 mm Tris, 8 mM EDTA, and 4 mm DTT (pH 8.0). The fraction collected from the 22/30% interface of a sucrose step gradient was washed and resuspended in buffer containing 250 mM sorbitol, 1 mM DTT, and 5 mm Mes adjusted to pH 7.0 with Tris. Aliquots containing 0.5 to 1.5 mg protein/mL were stored at -70C. Enzyme AssaysThe generation and dissipation of pH gradients across the membrane vesicles were followed by measuring quenching and recovery of acridine orange fluorescence as described previously (6,9

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Section: Membrane Preparationsmentioning

confidence: 99%

Section: Enzyme Assaysmentioning

confidence: 99%

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Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Garbarino¹,

DuPont²

1989

Plant Physiol.

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101

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“…The fact that the permeant NEM (and CCCP) displayed a greater inhibition than the relatively non-permeant PCMBS allows the speculation that two different mannitol carriers might be operative in celery petiole parenchyma, one at the plasmalemma and one at the tonoplast. The observed inhibition by KNO3 (50 mM) on mannitol uptake (31 %) could be indirect support of such an additional (active) tonoplastlocated carrier as KNO3 is known to inhibit mainly tonoplast H+-ATPase (Sze, 1985;DuPont, 1987). Alternatively, the strong inhibition of NEM (and CCCP) as compared to PCMBS could also be interpreted as indicates the presence of SH-groups of a plasmalemma mannitol-carrier on both sides of the membrane.…”

Section: Concentration-dependencementioning

confidence: 99%

Carbohydrate transport in discs of storage parenchyma of celery petioles

Keller

1991

New Phytologist

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SUMMARYThe sugar alcohol mannitol is, together with glucose and fructose, the main soluble carbohydrate of celery petioles. It is accumulated in the storage parenchyma of mature petioles and remobilized during senescence. The mechanisms of mannitol uptake into discs isolated from petiole parenchyma was studied. Uptake kinetics showed a biphasic response to increasing external concentrations of ["ClD-mannitol with a predominant saturable component at low concentrations (below about 2 mM) and a linear component at higher concentrations (at least up to 16 mM). The saturable component showed an apparent K^^^ of about 1 mM and a fairly sharp pH optimum around pH 6-5. It was stimulated by the plasmalemma H+-ATPase stimulator FC and inhibited by the SHreagents PCMBS and NEM and the uncoupler DNP. CCCP was also inhibitory, but its effect could be reversed by DTT, suggesting a dual role of CCCP as SH-reagent and uncoupler in this tissue. Competition studies with 14-different polyols and sugars showed that uptake was very specific. The saturable uptake component was clearly turgor-dependent. Lowering of cell turgor by treatment of increasing concentrations of the relatively nonpermeant glycinebetaine (0 to 0-8 M) resulted in a linear increase of V^^,^ and an unaltered K^.It is concluded that celery petiole parenchyma contains at least a mannitol carrier at the plasmalemma which operates in an active proton-cotransport manner. It is speculated that a superimposed mannitol carrier is present at the tonoplast and might operate by facilitated diffusion.

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“…No sensitivity to vanadate was observed. The antiporter activity observed in these fractions was thus likely to be associated with the tonoplast (9,17).…”

Section: Origin Of Membrane Vesiclesmentioning

confidence: 99%

Evidence for a Highly Specific K⁺/H⁺ Antiporter in Membrane Vesicles from Oil-Seed Rape Hypocotyls

Cooper¹,

Lerner²,

Reinhold³

1991

Plant Physiol.

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We present evidence strongly suggesting that a proton gradient (acid inside) is used to drive an electroneutral, substratespecific, K+/H antiport in both tonoplast and plasma membraneenriched vesicles obtained from oilseed rape (Brassica napus) hypocotyls. Proton fluxes into and out of the vesicles were monitored both by following the quenching and restoration of quinacrine fluorescence (indicating a transmembrane pH gradient) and of oxonol V fluorescence (indicating membrane potential.) Supply of K+ (with Cl-or SCN-) after a pH gradient had been established across the vesicle membrane by provision of ATP to the H+-ATPase dissipated the transmembrane pH gradient but did not depolarize the positive membrane potential. Evidence that the K+/H+ exchange thus indicated could not be accounted for by mere electric coupling included the findings that, first, no positive potential was generated when KSCN or KCI was supplied, even in the absence of 100 millimolar Cl-and, second, efflux of K+ from K+-loaded vesicles drives intravesicular accumulation of H+ against the electrochemical potential gradient. Neither was the exchange due to competition between K+ and quinacrine for membrane sites, nor to inhibition of the H+-ATPase. Thus, it is likely that it was effected by a membrane component. The exchanger utilized primarily K+ (at micromolar concentrations); Na+/ H+ antiport was detected only at concentrations two orders of magnitude higher. Rb+, Li+, or Cs+ were ineffective. Dependence of tonoplast K+/H+ antiport on K+ concentration was complex, showing saturation at 10 millimolar K+ and inhibition by concentrations higher than 25 millimolar. Antiport activity was associated both with tonoplast-enriched membrane vesicles (where the proton pump was inhibited by more than 80% by 50 millimolar N03-and showed no sensitivity to vanadate or oligomycin) and with plasma membrane-enriched fractions prepared by phase separation followed by separation on a sucrose gradient (where the proton pump was vanadate and diethylstilbestrol-sensitive but showed no sensitivity to N03-or oligomycin). The possible physiological role of such a K+/H exchange mechanism is discussed.According to the chemiosmotic hypothesis, currently widely accepted, a primary membrane-sited H+-translocating ATPase generates a transmembrane electrochemical potential gradient for protons; the return flux of the protons drives the transmembrane flux of other solutes via secondary symport or antiport mechanisms. Although good evidance at isolated membrane level has been obtained for the presence and function of H+-ATPases in higher plant cell membranes (25), evidence at this level for secondary systems transporting ions has been more difficult to attain, with the exception of the tonoplast-associated Ca2+/H' antiporter (4, 20, 23). With regard to monovalent cation flux, there are good indications for the existence of Na+/H+ antiporters in the case of several halophytes or salt-tolerant species (3,6,11,12,13). The presence of these mechanisms has been related ...

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Variable Effects of Nitrate on ATP-Dependent Proton Transport by Barley Root Membranes

Cited by 31 publications

References 30 publications

Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Carbohydrate transport in discs of storage parenchyma of celery petioles

Evidence for a Highly Specific K⁺/H⁺ Antiporter in Membrane Vesicles from Oil-Seed Rape Hypocotyls

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Variable Effects of Nitrate on ATP-Dependent Proton Transport by Barley Root Membranes

Cited by 31 publications

References 30 publications

Rapid Induction of Na+/H+ Exchange Activity in Barley Root Tonoplast

Rapid Induction of Na+/H+ Exchange Activity in Barley Root Tonoplast

Carbohydrate transport in discs of storage parenchyma of celery petioles

Evidence for a Highly Specific K+/H+ Antiporter in Membrane Vesicles from Oil-Seed Rape Hypocotyls

Contact Info

Product

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Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Rapid Induction of Na⁺/H⁺ Exchange Activity in Barley Root Tonoplast

Evidence for a Highly Specific K⁺/H⁺ Antiporter in Membrane Vesicles from Oil-Seed Rape Hypocotyls