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Single-cell, real-time measurements of extracellular oxygen and proton fluxes fromSpirogyra grevilleana

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Summary

We have adapted the self-referencing microelectrode technique to allow sensitive and noninvasive measurement of oxygen fluxes around single cells. The self-referencing technique is based on the translational movement of a selective microelectrode through the gradient next to the cell wall or membrane. The electrode is moved at a known frequency and between known points. The differential electrode output values are converted into a directional measurement of flux by the Fick equation. By coupling the newly developed oxygen-selective self-referencing electrochemical microelectrode (SREM-O2) system with self-referencing ionselective proton measurements (SRIS-H+) we have characterized oxygen and proton fluxes from a single cell of the filamentous green algaSpirogyra gre illeana (Hass.). Oxygen showed a net efflux and protons showed a net influx when the cell was illuminated. These photosynthesis-dependent fluxes were found to be spatially associated with the chloroplasts and were sensitive to treatment with dichlorophenyldimethylurea. In the dark the directions of oxygen and proton fluxes were reversed. This oxygen influx was associated with mitochondrial respiration and was reduced by 78% when the cells was treated with 0.5 mM KCN. The residual cyanide-resistant respiration was inhibited by the application of 5 mM salicylhydroxamic acid, an inhibitor of the alternative oxidase. Similarly the cytochrome pathway was also inhibited by the presence of 20 μM NO, while the cyanide-resistant alternative oxidase was not. These results demonstrate the use of the newly developed SREM-O2 system to measure and characterize metabolic fluxes at a level of sensitivity that allows for subcellular resolution. These measurements, in conjunction with SERIS-H+ measurements, have led to new insights in our understanding of basic cellular physiology in plant cells.

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Abbreviations

SRIS:

self-referencing ion selective

SREM:

self-referencing electrochemical microelectrode

ICP:

inductive coupled plasma spectroscopy

References

  • Armstrong W (1994) Polarographic oxygen electrodes and their use in plant aeration studies. Proc R Soc Edinburg 102: 511–527

    Google Scholar 

  • Atkins CA, Graham D (1971) Light-induced pH changes by cells ofChlamydomonas reinhardtii: dependence on CO2 uptake. Biochim Biophys Acta 226: 481–485

    Google Scholar 

  • Badger MR, Price GD (1994) The role of carbonic anhydrase in photosynthesis. Annu Rev Plant Physiol 45: 369–392.

    Google Scholar 

  • Bates TE, Loesch A, Burnstock G, Clark JB (1996) Mitochondrial nitric oxide synthase: a ubiquitous regulator of oxidative phosphorylation? Biochem Biophys Res Commum 218: 40–44

    Google Scholar 

  • Davies PW, Brink F (1942) Microelectrodes for measuring local oxygen tension in animal tissues. Rev Sci Instr 13: 524–533

    Google Scholar 

  • Degenhardt J, Larsen PB, Howell SH, Kochian LV (1998) Aluminum resistance in theArabidopsis mutant alr-104 is caused by an aluminum-induced increase in rhizosphere pH. Plant Physiol 117: 19–27

    Google Scholar 

  • Dennis DT, Turpin DH (1990) Plant physiology, biochemistry and molecular biology. Wiley, New York

    Google Scholar 

  • Denny P, Weeks DC (1970) Effects of light and bicarbonate on membrane potential inPotamogeton schweinfurthii (Benn.). Ann Bot 34: 483–496

    Google Scholar 

  • de Visser R, Blacquiere T (1984) Inhibition and Stimulation of root respiration in Pisum and Plumbago by hydroxamate. Plant Phyiol 75: 813–817

    Google Scholar 

  • Dutta A, Popel AS (1995) A theoretical analysis of intracellular oxygen diffusion. J Theor Biol 175: 433–445

    Google Scholar 

  • Felle H, Bertl A (1986) The fabrication of H+-selective liquid membrane micro-electrodes for use in plant cells. J Exp Bot 37: 1416–1428

    Google Scholar 

  • Freidman MN, Robinson SW, Gerhadt GA (1996) O-phenylenediamine-modified carbon fiber electrodes for the detection of nitric oxide. Anal Chem 68: 2621–2628

    Google Scholar 

  • Garcia JL (1976) Nitric oxide production in rice soils. Ann Microbiol 127: 401–414

    Google Scholar 

  • Gnaiger E, Forstner H (1983) Polarographic oxygen sensors. Springer, Berlin Heidelberg New York Tokyo

    Google Scholar 

  • Hodges TK (1973) Ion absorption by plant roots. Adv Agron 25: 163–207

    Google Scholar 

  • Huppe HC, Turpin DH (1994) Integration of carbon and nitrogen metabolism in plants and algal cells. Annu Rev Plant Physiol 45: 577–607

    Google Scholar 

  • Jaffe LF, Nuccitelli R (1974) An ultrasensitive vibrating probe for measuring steady extracellular currents. J Gell Biol 63: 614–628

    Google Scholar 

  • James DE (1978) Culturing algae. Carolina Biological Company, Burlington, NC

    Google Scholar 

  • Kochian LV, Shaffe JE, Kühtreiber WM, Jaffe LF, Lucas WJ (1992) Use of an extracellular, ion-selective vibrating microelectrode system for the quantification of K+, H+, and Ca2+ fluxes in maize roots and suspension cells. Planta 188: 601–610

    Google Scholar 

  • Kühtreiber WM, Jaffe LF (1990) Detection of extracellular calcium gradients with a calcium-specific vibrating electrode. J Cell Biol 110: 1565–1573

    Google Scholar 

  • Lüttge U, Higinbotham N (1979) Transport in plants. Springer, New York Heidelberg Berlin

    Google Scholar 

  • McClure PR, Kochian LV, Spanswick RM, Shaff JE (1990) Evidence of cotransport of nitrate and protons in maize roots. Plant Physiol 93: 281–289

    Google Scholar 

  • Millar AH, Day DA (1996) Nitric oxide inhibits the cytochrome oxidase but not the alternative oxidase of plant mitochondria. FEBS Lett 398: 155–158

    Google Scholar 

  • Neuman J, Levine RP (1971) Reversible pH changes in cells ofChlamydomonas reinhardtii resulting from CO2 fixation in the light and its evolution in the dark. Plant Physiol 47: 700–704

    Google Scholar 

  • Novacky A, Fischer E, Ullrich-Eberius CI, Lüttge U, Ullrich WR (1978) Membrane potential changes during transport of glycine as a neutral amino acid and nitrate inLemna gibba. FEBS Lett 88: 264–267

    Google Scholar 

  • Okazaki Y, Tazawa M, Iwasaki N (1994) Light-induced changes in cytosolic pH in leaf cells ofEgeria densa: measurements with pH-sensitive microelectrodes. Plant Cell Physiol 35: 943–950

    Google Scholar 

  • Raghavendra AS, Yin ZH, Heber U (1993) Light dependent pH changes in leaves of C4 plants: comparison of the light response to carbon dioxide and oxygen with that of C3 plants. Planta 189: 278–287

    Google Scholar 

  • Ross E (1938) The effects of sodium cyanide and methylene blue on oxygen consumption byNitella da ata. Am J Bot 25: 458–463

    Google Scholar 

  • Sargent DF, Taylor CPS (1972) Terminal oxidases ofChlorella pyrenoidosa. Plant Physiol 49: 775–778

    Google Scholar 

  • Schneiderman G, Goldstick TK (1978) Oxygen electrode design criteria and performance characteristics: recessed cathode. J Appl Physiol 45: 145–154

    Google Scholar 

  • Silver IA (1967) Problems in the investigation of tissue oxygen microenvironment. In: Reneau D (ed) Chemical engineering in medicine. American Chemical Society, Washington, DC, pp 343–351

    Google Scholar 

  • Smith PJS, Sanger RH, Jaffe LF (1994) The vibrating Ca2+ electrode: a new technique for detecting plasma membrane regions of Ca2+ influx and efflux. Methods Cell Biol 40: 115–134

    Google Scholar 

  • Syrett PJ (1951) The effect of cyanide on the respiration and the oxidative assimilation of glucose byChlorella ulgaris. Ann Bot 15: 473–492

    Google Scholar 

  • Thaler M, Simonis W, Schönknecht G (1992) Light-dependent changes of the cytoplasmic H+ and Cl activity in the green algaeEremosphaera irdis. Plant Physiol 99: 103–110

    Google Scholar 

  • Torkelson JD, Lynnes JA, Weger HG (1995) Extracellular peroxidase mediated oxygen consumption inChlamydomonas reinhardtii (Chlorophyta). J Phycol 31: 562–567

    Google Scholar 

  • Trebst AV, Tsujimoto HY, Arnon DI (1958) Separation of light and dark phases in the photosynthesis of isolated chloroplasts. Nature 182: 351–355

    Google Scholar 

  • Ullrich WR (1987) Nitrate and ammonium uptake in green algae and higher plants: mechanism and relationship with nitrate metabolism. In: Ullrich WR, Aparicio PJ, Syrett PJ, Castillo F (eds) Inorganic nitrogen metabolism. Springer, Berlin Heidelberg New York Tokyo, pp 32–38

    Google Scholar 

  • —, Novacky A (1981) Nitrate-dependent membrane potential changes and their induction inLemna gibba. Plant Sci Lett 22: 211–217

    Google Scholar 

  • Webster DA, Hackett DP (1965) Respiratory chain of colorless algae I: Chlorophyta and Euglenophyta. Plant Physiol 41: 1091–1100

    Google Scholar 

  • Weger HG, Dasgupta R (1993) Regulation of alternative pathway respiration inChlamydomonas reinhardtii (Chlorophyceae). J Phycol 29: 300–308

    Google Scholar 

  • —, Guy RD, Turpin DH (1990) Cytochrome and alternative pathway respiration in green algae. Plant Physiol 93: 356–360

    Google Scholar 

  • —, Lynnes JA, Torkelson JD (1996) Characterization of extracellular oxygen consumption by the green algaeSelenastrum minutum. Physiol Plant 96: 268–274

    Google Scholar 

  • Whalen WJ (1974) Some problems with an intracellular pO2 electrode. Adv Exp Med Biol 50: 39–41

    Google Scholar 

  • —, Riley J, Nair P (1967) A microelectrode for measuring intracellular PO2. J Appl Physiol 23: 798–801

    Google Scholar 

  • Yin ZH, Neimanis S, Heber U (1990) Light-dependent pH changes in the leaves of C3 plants II: effects of CO2 and O2 on the cytosolic and vacuolar pH. Planta 182: 253–261

    Google Scholar 

  • —, Heber U, Raghavendra AS (1993) Light induced pH changes in leaves of C4 plants: comparison of cytosolic alkalization and vacuolar acidification with that of C3 plants. Planta 189: 267–277

    Google Scholar 

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Authors and Affiliations

  1. Department of Biological Sciences, 105 Schrenk Hall, University of Missouri-Rolla, 1870 Miner Circle, 65409, Rolla, MO, USA

    D. M. Porterfield

  2. Marine Biological Laboratory, BioCurrents Research Center, Woods Hole, Massachusetts

    P. J. S. Smith

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  1. D. M. Porterfield
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  2. P. J. S. Smith
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Porterfield, D.M., Smith, P.J.S. Single-cell, real-time measurements of extracellular oxygen and proton fluxes fromSpirogyra grevilleana . Protoplasma 212, 80–88 (2000). https://doi.org/10.1007/BF01279349

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  • DOI: https://doi.org/10.1007/BF01279349

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