Membrane Potentials of <i>Vallisneria</i> Leaf Cells and Their Relation to Photosynthesis

Prins, H. B. A.; Harper, James R.; Higinbotham, Noe

doi:10.1104/pp.65.1.1

Cited by 37 publications

(31 citation statements)

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“…2 and 3 of reference 3). In Vallisneria spiralis, an aquatic angiosperm, the PD of the epidermal transfer cells is similar to that of the leaf parenchyma cells (27). In various species, and more particularly in Capsicum annuum, Fe deficiency leads to a stimulation of H+ excretion by the roots and to a concomittant increase of malate and citrate synthesis.…”

Section: Effect Of Addition Of A-aib and Of Other Amino Acids On The mentioning

confidence: 88%

“…Indeed, we were interested in determining whether this cell type not only increases the surface of exchange between the apoplast and the symplast but also generates electrochemical potential gradients different from those of the parenchyma cells or from those of the cells from which its originates. As emphasized in the discussion, the data presently available (3,16,21,27) do not provide a clear answer to this question. The other aim of this paper is to examine whether the electrochemical potential gradients generated by the transfer cells of the haustorium are used indeed to achieve active uptake of the organic solutes present in the apoplast of the gametophytes, as it was suggested by our previous results (6,7), and then to bring information on the properties of exchanges between the two generations.…”

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confidence: 80%

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The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

Renault

Despeghel-Caussin²,

Bonnemain³

et al. 1989

Plant Physiol.

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The epidermal cells of the sporophyte haustorium of Polytrichum formosum are modified into transfer cells. These cells are located in a strategic place allowing them to control the exchanges between the two generations. Their plasmalemma creates proton gradients (A# and ApH) which increase during the development of the sporophyte. As the sporophyte grows from 2 to 4 cm long, the pH of the incubation medium of the haustoria decreases from 5.2 to 4.3, and the transmembrane potential difference (PD) hyperpolarizes form -140 to -210 millivolts. These gradients become rapidly larger than that generated by the plasmalemma of the basal cells of the sporophyte. They are used to energize the uptake of the solutes present in the apoplast of the gametophyte, particularly the amino acids. Below 20 micromolar a-aminoisobutyric acid uptake in the transfer cells is mediated by a saturable system and is optimal at acidic pH (4.0 and 4.5). It is strongly inhibited by compounds dissipating both A/4 and ApH (10 micromolar carbonylcyanide-m-chlorophenyl hydrazone) or only A# (0.1 molar KCI). The absorption of a-aminoisobutyric acid and of the other neutral amino acids tested induces an alkalinization of the medium and a depolarization of membrane potential difference which is concentration dependent. These data show that the uptake of amino acids by the transfer cells of the haustorium is a secondary translocation (proton-amino acid symport) energized by a primary translocation (proton efflux). More particularly, they show that transfer cells possess a membrane enzymic equipment particularly efficient to achieve the uptake of the solutes leaked in the apoplast from other cell types.For 20 years, transfer cells, which are widely distributed in the plant kingdom, have held the attention of many researchers (12-14, 24, 26 and references therein). These cells, which result from the transformation of different cellular types, are characterized in particular by internal wall ingrowths that increase 5-to 10-fold the surface area of the plasmalemma and by numerous mitochondria. They are often found in contact with conducting cells (sieve-tubes or vessels), at the interface of the two generations (gametophyte-sporophyte), or at the plant-environment interface. Due to their structural particularities and their distribution, it has been suggested that they are involved in apoplast-symplast exchanges (13,26 (6,7,14), and in the latter case, they originate from the leaf apoplast (9). Consequently, the study of their functioning should yield important information on the properties of exchanges between the gametophyte and the sporophyte. Another interest of the transfer cells of the haustorium of bryophytes lies in the absence of symplastic connections with the gametophyte (8, 14): only the apoplastic pathway is operating. Consequently, the properties of exchanges between the two generations are highly dependent on the properties of the plasmalemma of this cell type. The transfer cells which mediate the loading of the sieve tubes in highe...

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Section: Effect Of Addition Of A-aib and Of Other Amino Acids On The mentioning

confidence: 88%

mentioning

confidence: 80%

The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

Renault

Despeghel-Caussin²,

Bonnemain³

et al. 1989

Plant Physiol.

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“…Photosynthesis regulates ion transport across the plasma membrane (Spanswick, 1981;Marten et al, 2010). Light-induced hyperpolarization of the plasma membrane has been particularly well studied in a diversity of plants, including Chara corallina and Vallisneria spiralis (Prins et al, 1980;Mimura and Tazawa, 1986). Photosynthesis-dependent membrane hyperpolarization is believed to result from activation of the plasma membrane H + -ATPase.…”

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confidence: 99%

Photosynthesis Activates Plasma Membrane H⁺-ATPase via Sugar Accumulation

et al. 2016

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“…Although the effect of DMO supports the hypothesis that the polarity was influenced by acidification of the cytoplasm, acetic acid, which normally invokes the same reaction as DMO, did not suppress, but rather stimulated, the pH polarity. In Vallisneria spiralis, also a submerged aquatic member ofthe Hydrocharitaceae, acetate stimulated the lightdependent proton pump as judged from the hyperpolarization of the membrane potential (18). From these considerations, we conclude that the stimulating effect of light and the inhibiting effect of CO2 (DIC) are not caused by a change in cytoplasmic pH.…”

Section: Influence Of Light Intensitymentioning

confidence: 63%

“…These polar reactions are thought to be associated with the ability of these species to use bicarbonate as a carbon source for photosynthesis. The acidification of the medium on the lower side of the leaf is due to an active proton efflux while the release of hydroxyl ions on the upper side of the leaf is a passive process (18). The polar reaction facilitates the use of bicarbonate in photosynthesis by shifting the bicarbonate-CO2 equilibrium in the unstirred layer on the lower side of the leaf, thereby increasing the CO2 concentration of the unstirred layer and increasing diffusion ofCO2 into the leaf (19)(20)(21)(22).…”

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confidence: 99%

Light-Induced Polar pH Changes in Leaves of Elodea canadensis

Elzenga¹,

Prins²

1989

Plant Physiol.

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Leaves of the submerged aquatic Elodea canadensis Michx. exhibit a light induced polar pH reaction. In this study, the effects of light intensity and dissolved inorganic carbon concentration on this polar reaction were examined. At a light intensity of 100 watts per square meter the leaf showed a polar pH response when the dissolved inorganic carbon concentration was less than about 1 millimolar. The polar reaction was suppressed at a higher dissolved inorganic carbon concentration. This suppression was not due to the buffering capacity of bicarbonate. Because another weak acid, acetate, did not inhibit the polarity, but even had a small stimulatory effect, the effect of bicarbonate is also not due to acidification of the cytoplasm. The suppression of the polar reaction by C02/HCO3 was relieved when the light intensity was increased. Apparently there is competition for product(s) of the photosynthetic light reactions between processes generating the polar reaction and the carbon fixation reactions. The possibility that the redox state of the cell regulates the generation of the polar reaction is discussed.

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Membrane Potentials of Vallisneria Leaf Cells and Their Relation to Photosynthesis

Cited by 37 publications

References 18 publications

The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

Photosynthesis Activates Plasma Membrane H⁺-ATPase via Sugar Accumulation

Light-Induced Polar pH Changes in Leaves of Elodea canadensis

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Membrane Potentials of Vallisneria Leaf Cells and Their Relation to Photosynthesis

Cited by 37 publications

References 18 publications

The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

The Proton Electrochemical Transmembrane Gradients Generated by the Transfer Cells of the Haustorium of Polytrichum formosum and Their Use in the Uptake of Amino Acids

Photosynthesis Activates Plasma Membrane H+-ATPase via Sugar Accumulation

Light-Induced Polar pH Changes in Leaves of Elodea canadensis

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Product

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Photosynthesis Activates Plasma Membrane H⁺-ATPase via Sugar Accumulation