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1

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Light-dependent pH changes in leaves of C3 plants (1990)

Yin, Zu-Hua ; Neimanis, Spidola ; Wagner, Ute ; [et al.]

Springer

Planta 182 (1990), S. 244-252

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ISSN: 1432-2048

Keywords: Chloroplast ; Cytosol ; Photosynthesis ; pH ; Vacuole

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Chloroplasts, mesophyll protoplasts, cytoplasts, vacuoplasts, vacuoles and leaves were stained with pH-indicating fluorescent dyes of differing pK values. Fluorescence microscopy was used to obtain information on the intracellular and intercellular distribution of the probes. The kinetics of blue or green fluorescence emitted from chloroplasts, protoplasts, cytoplasts and leaves was measured during illumination with red light. The intensity of light used for fluorescence excitation was so low that it had little effect on photosynthesis. In leaves, fluorescence signals emitted from chloroplasts were small and usually insignificant compared to signals originating from the cytosol. Both indicated light-dependent alkalization and reversal of alkalization on darkening. Vacuolar signals were opposite in sign to cytosolic signals. They indicated acidification of the vacuole in the light-dark transient and reversal of this effect on darkening.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00197118

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2

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Light-dependent pH changes in leaves of C3 plants (1990)

Yin, Zu-Hua ; Dietz, Karl-Josef ; Heber, Ulrich

Springer

Planta 182 (1990), S. 262-269

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ISSN: 1432-2048

Keywords: Chloroplast development ; Cytosol ; pH ; Photosynthesis ; Vacuole

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Etiolated leaves and the inhibitors of photosynthesis 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU) and dl-glyceraldehyde were used to study the relationship between thylakoid energization, photosynthesis, the light-dependent alkalization of the cytosol of mesophyll cells and the acidification of mesophyll vacuoles. No light-dependent pH changes were observed in etiolated leaves. As chloroplasts developed in the light and became photosynthetically competent, mesophyll vacuoles became more acidic when the leaves were illuminated in CO2-free air. Acidification was suppressed and even replaced by a small light-dependent alkaline shift during photoassimilation of CO2. In green leaves, DCMU and dl-glyceraldehyde inhibited the cytosolic and vacuolar pH responses to illumination. Inhibition was also observed under anaerobiosis. In the absence of DCMU and glyceraldehyde, the extent of the light-dependent vacuolar acidification corresponded closely to the extent of thylakoid energization by light. Because, in contrast to DCMU, glyceraldehyde did not inhibit thylakoid energization while inhibiting the extrachloroplast pH responses, it is concluded that the signal transfer from the chloroplasts to the cytosol which results in increased vacuolar acidification in the light involves metabolites of the Calvin cycle. The observations do not support the view that the cytosolic energy state is increased in the light by the mitochondrial oxidation of the NADH generated during the oxidation of photorespiratory glycine in the mitochondria.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00197120

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3

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Acquisition and assimilation of gaseous ammonia as revealed by intracellular pH changes in leaves of higher plants (1996)

Yin, Zu-Hua ; Kaiser, Werner M. ; Heber, Ulrich ; [et al.]

Springer

Planta 200 (1996), S. 380-387

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ISSN: 1432-2048

Keywords: Ammonia ; Cytosol (pH) ; C3 and C4 plants ; Dye (pH-indicating) ; Vacuole (pH)

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Atmospheric ammonia (NH3) from various anthropogenic sources has become a serious problem for natural vegetation. Ammonia not only causes changes in plant nitrogen metabolism, but also affects the acid-base balance of plants. Using the pH-sensitive fluorescent dyes pyranine and esculin, cytosolic and vacuolar pH changes were measured in leaves of C3 and C4 plants exposed for brief periods to concentrations of NH3 in air ranging from 1.33 to 8.29 μmol NH3 · mol-1 gas (0.94–5.86 mg · m-3). After a lag phase, uptake of NH3 from air at a rate of 200 nmol NH3 · m - 2 leaf area · s- 1 into leaves of Zea mays L. increased pyranine fluorescence indicating cytosolic alkalinisation. The increase was much larger in the dark than in the light. In illuminated leaves of the C3 plant Pelargonium zonale L. and the C4 plants Z. mays and Amaranthus caudatus L., NH3-dependent cytosolic alkalinisation was particularly pronounced when CO2 was supplied at very low levels (16 or 20 μmol CO2 · mol- 1 gas, containing 210 mmol O2 · mol- 1 gas). An increase in esculin fluorescence, which was smaller than that of pyranine, was indicative of trapping of some of the NH3 in the vacuoles of leaves of Spinacia oleracea L. and Z. mays. Photosynthesis and transpiration remained unchanged during exposure of illuminated leaves to NH3, yielding an influx of 200 nmol NH3 · m-2 leaf area · s-1 for up to 30 min, the longest exposure time used. Both CO2 and O2 influenced the extent of cytosolic alkalinisation. At 500 μmol CO2 · mol-1 gas the cytosolic alkalinisation was suppressed more than at 16 or 20 μmol CO2 · mol-1 gas. The suppressing effect of CO2 on the NH3induced alkalinisation was larger in illuminated leaves of the C4 plants Z. mays and A. caudatus than in leaves of the C3 plant P. zonale. A reduction of the O2 concentration from 210 to 10 mmol O2 · mol -1 gas, which inhibits photorespiration, increased the NH3induced cytosolic alkalinisation in C3 plants. Suppression by CO2 or O2 of the alkaline pH shift caused by the dissolution and protonation of NH3 in queous leaf compartments, and possibly by the production of organic compounds synthesised from atmospheric NH3, indicates that NH3 which enters leaves is rapidly assimilated if photosynthesis or photorespiration provide nitrogen acceptor molecules.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00231393

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4

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Light-dependent proton transport into mesophyll vacuoles of leaves of C3 plants as revealed by pH-indicating fluorescent dyes: a reappraisal (1996)

Yin, Zu-Hua ; Hüve, Katja ; Heber, Ulrich

Springer

Planta 199 (1996), S. 9-17

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ISSN: 1432-2048

Keywords: Fluorescent dyes ; Light scattering ; Photosynthesis ; Proton transport ; Vacuole

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Esculin, a pH-sensitive fluorescent dye, was used to indicate light-dependent pH changes in leaves of Spinacia oleracea L. and Pelargonium zonale L. Shortly after its introduction into the leaves via the transpiration stream, esculin was localized mainly in the symplasm. An increase in its blue fluorescence on illumination with red actinic light indicated that the cytosolic pH had increased. A similar light-dependent alkalinization was seen when the green fluorescence of pyranine was used to monitor changes in the cytosolic pH. After esculin had been transferred into the vacuoles, a light-dependent vacuolar acidification was indicated by a decrease in its blue fluorescence. Since the pK of esculin is close to neutrality, it is suitable as an indicator of proton transport into vacuoles provided the vacuolar sap is only moderately acidic. In leaf cells with very acidic vacuoles, esculin therefore responds only to cytosolic pH changes as long as it remains in the cytosol. The observations made with esculin after it had entered the vacuoles confirmed earlier conclusions on light-dependent proton transport into the vacuoles of mesophyll cells. Previous measurements had been made with 5-carboxy-2′,7′-dichlorofluoresceine (CDCF), which has a pK of 4.8. In contrast to esculin, CDCF can, in principle, record pH changes in very acidic vacuoles. However, earlier conclusions made on the basis of observed CDCF fluorescence are now recognized to have no unambiguous basis because new measurements, reported here, show that CDCF fluorescence is influenced not only by pH changes but also by changes in light scattering. The latter are, like pH changes, light-dependent and originate from the thylakoid system of chloroplasts. They indicate both the formation of a large transthylakoid proton gradient and the dissipation of excess light energy as heat. Decreased green fluorescence of leaves which had been fed CDCF may therefore, depending on conditions, indicate vacuolar acidification or the dissipation of excess light energy absorbed by the pigment system of chloroplasts, or both. Pyranine fluorescence was found to be much less influenced by light scattering than CDCF fluorescence.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00196875

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5

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Light-dependent pH changes in leaves of C4 plants Comparison of the pH response to carbon dioxide and oxygen with that of C3 plants (1993)

Raghavendra, A. S. ; Yin, Zu-Hua ; Heber, Ulrich

Springer

Planta 189 (1993), S. 278-287

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ISSN: 1432-2048

Keywords: Chloroplast energisation ; Cytosol (pH) ; Dye (fluorescent, pH-indicating) ; pH (cytosol, vacuole) ; Phosphoenolpyruvate carboxylase ; Photosynthesis (C3 and C4 plants) ; Vacuole (pH)

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Cytosolic and vacuolar pH changes caused by illumination or a changed composition of the gas phase were monitored in leaves of the NAD malic-enzyme-type C4 plant Amaranthus caudatus L. and the C3 plant Vicia faba L. by recording changes in the fluorescence of pH-indicating dyes which had been fed to the leaves. Light-dependent cytosolic alkalization and vacuolar acidification were maximal in the mesophyll cells under high-fluence-rate illumination and in the absence of CO2. Under the same conditions, measurements of light scattering and electrochromic absorption changes at 518 nm revealed maximum thylakoid energization. The results show an intimate relationship between the energization of the photosynthetic apparatus by light, an increase in cytosolic pH and a decrease in vacuolar pH. This was true for both the C4 and the C3 plant, although kinetics, extent and even direction of cytosolic pH changes differed considerably in these plants, reflecting the differences in photosynthetic carbon metabolism. Darkening produced rapid acidification in Vicia, but not in Amaranthus. Continued alkalization in Amaranthus is interpreted to be the result of the decarboxylation of a C4 intermediate and the release of liberated CO2. In the presence of CO2, energy consumption by carbon reduction decreased thylakoid energization, cytosolic alkalization and vacuolar acidification. Under low-fluence-rate illumination, thylakoid energization and light-dependent cytosolic and vacuolar pH changes were decreased in CO2-free air compared with thylakoid energization and pH changes in 1% oxygen/99% nitrogen not only in the C3 plant, but also in Amaranthus. Since oxygenation of ribulose bisphosphate initiates energy-consuming photorespiratory reactions in 21% oxygen, but not in 1% oxygen, this shows that photorespiratory reactions are active not only in the C3 but also in the C4 plant in the absence of external CO2. Photorespiratory conditions appeared to decrease energization not only in the chloroplasts, but also in the cytosol. This is indicated by decreased transfer of protons from the cytosol into the vacuole, a process which is energy-dependent.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00195087

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6

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Light-induced pH changes in leaves of C4 plants (1993)

Yin, Zu-Hua ; Heber, Ulrich ; Raghavendra, A. S.

Springer

Planta 189 (1993), S. 267-277

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ISSN: 1432-2048

Keywords: Cytosol (pH) ; Dye (fluorescent, pH-indicating) ; pH (cytosol, vacuole) ; Photosynthesis (C3 and C4 plants) ; Vacuole (pH)

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Light-induced changes in the fluorescence of the pH-indicating dyes pyranine or 5-(and 6-)carboxy-2′, 7′-dichlorofluorescein (CDCF) which had been fed to leaves were examined to monitor cellular pH changes. After short-term feeding of pyranine (pK 7.3) to leaves of Amaranthus caudatus L., a NAD-malic-enzyme-type C4 plant, vascular bundles and surrounding cells became fluorescent. Fluorescence emission from mesophyll cells required longer feeding times. In CO2-free air, pyranine fluorescence increased much more on illumination after mesophyll cells had become fluorescent than when only the vascular bundles and the bundle sheath of Amaranthus leaves had been stained. After short feeding times and in the absence of actinic illumination, CO2 decreased pyranine fluorescence very slowly in Amaranthus and rapidly in C3 leaves. After prolonged feeding times, the extent of the light-dependent increase in pyranine fluorescence was several times greater in different C4 plants than in C3 species. The kinetics of the fluorescence changes were also remarkably different in C3 and C4 plants. Carbon dioxide (500 μl · l−1) suppressed the light-induced increase in pyranine fluorescence more in C4 than in C3 leaves. Light-dependent changes in light scattering, which are indicative of chloroplast energization, and in 410-nm transmission, which indicate chloroplast movement, differed kinetically from those of the changes in pyranine fluorescence. Available evidence indicated that light-dependent changes in pyranine fluorescence did not originate from the apoplast of leaf cells. Microscopic observation led to the conclusion that, after prolonged feeding times or prolonged incubation, changes in pyranine fluorescence emitted from C4 leaves reflect pH changes mainly in the cytosol of mesophyll cells. A transient acidification reaction indicated by quenching of pyranine fluorescence in the dark-light transient and not observed in C3 species is attributed to the carboxylation of phosphoenolpyruvate. After short feeding times and in the absence of actinic illumination, CO2 (250 μl μ l−1) decreased pyranine fluorescence very slowly in Amaranthus and more rapidly in C3 leaves. After prolonged feeding times, both the rate and the extent of CO2-dependent quenching of pyranine fluorescence increased, but the increase was insufficient to indicate the presence of highly active carbonic anhydrase in the compartment from which pyranine fluorescence was emitted. In contrast to pyranine, CDCF (pK 4.8) did not increase but rather decreased its fluorescence on illumination of an Amaranthus leaf, indicating acidification of an acidic compartment, most probably the vacuole of green leaf cells. The pattern of the acidification reaction was similar in C4 and C3 leaves. The remarkably large extent of the light-dependent increase in pyranine fluorescence from leaves of C4 species and its slow kinetics are proposed to be caused by an alkalization of the cytosol which in the absence of CO2 is larger in the mesophyll than in the bundle sheath. It gives rise to deprotonation of dye originally located in the mesophyll and, in addition, of dye which diffuses from the bundle sheath into the mesophyll following a pH gradient. Implications of slow diffusional transport of pyranine and CO2 between mesophyll and bundle-sheath cells and the fast metabolite transport required in C4 photosynthesis are discussed.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00195086

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7

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Light-dependent pH changes in leaves of C3 plants (1991)

Yin, Zu-Hua ; Siebke, Katharina ; Heber, Ulrich

Springer

Planta 184 (1991), S. 30-34

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ISSN: 1432-2048

Keywords: Action spectrum ; Cyclic photophosphorylation ; Intracellular energy transfer ; Light-dependent pH change ; Photorespiration ; Proton pumping

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Action spectra in the red region of the spectrum for light-dependent cytosolic alkalization in leaves of C3 plants which also received a low background of blue light differed from the action spectra for light-dependent vacuolar acidification. Light above 680 nm was less effective in supporting the cytosolic alkalization reaction than light below 680 nm. In contrast, in leaves illuminated in CO2-free air the light-dependent vacuolar acidification exhibited a maximum at or even above 700 nm. When photorespiratory carbohydrate oxidation was suppressed in low oxygen, a substantially changed action spectrum of the acidification reaction resembled in shape that of the cytosolic alkalization with the exception that it was extended towards the far-red. From the presented data and from previously published data (Yin et al., 1990b, Planta 182, 253–261; Yin et al., 1990c, Planta 182, 262–269) it is concluded that in the presence of a weak background of blue light, and in the absence of CO2 which drains electrons from the electron transport chain, cyclic photophosphorylation induced by far-red light permits increased export of dihydroxyacetone phosphate from the chloroplasts into the cytosol where its oxidation increases the cytosolic energy state giving rise to increased proton transport across the tonoplast. The data do not lend support to the view that export of malate from the chloroplasts and its oxidation in the mitochondria contribute significantly to cytosolic energization in the light.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00208232

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8

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Influences of different nitrogen sources on nitrogen- and water-use efficiency, and carbon isotope discrimination, in C3 Triticum aestivum L. and C4 Zea mays L. plants (1998)

Yin, Zu-Hua ; Raven, John A.

Springer

Planta 205 (1998), S. 574-580

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ISSN: 1432-2048

Keywords: Key words: C3 and C4 plants (Triticum ; Zea) ; Carbon isotope discrimination ; Carboxylation (non-Rubisco) ; Nitrogen source (NO ; 3 ; NH4+ ; NH4NO3 ; NH3) ; Nitrogen-use efficiency ; Water-use efficiency

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract. The impacts of various nitrogen sources, i.e. NO− 3, NH4 + or NH4NO3 in combination with gaseous NH3, on nitrogen-, carbon- and water-use efficiency and 13C discrimination (δ13C) by plants of the C3 species Triticum aestivum L. (wheat) and the C4 species Zea mays L. (maize) were studied. Triticum aestivum and Z. mays were hydroponically grown with 2 mol · m−3 of N supplied as NO− 3, NH4 + or NH4NO3 for 21 and 18 d, respectively, and thereafter exposed to gaseous NH3 at 320 μg · m−3 or to ambient air for 7 d. In T. aestivum and Z. mays over a 7-d growth period, nitrogen-use efficiency (NUE) values were influenced by N-sources in the decreasing order NH4NO3-N 〉 NO− 3-N 〉 NH4 +-N and NO− 3-N 〉 NH4NO3-N 〉 NH4 +-N, respectively. Fumigation with NH3 decreased the NUE values of plants grown with any of the N-forms. During 28- and 7-d growth periods, N-sources affected water-use efficiency (WUE) values in the decreasing order of NH4 +-N 〉 NO− 3-N≈NH4NO3-N in non-fumigated T. aestivum, while fumigation with NH3 increased the WUE of NO− 3-grown plants. There were insignificant effects of N-sources on WUE values of Z. mays over 25- and 7-d growth periods. Furthermore, δ13C values in plant tissues (leaves, stubble and roots) were higher (less negative) in NH4 +-grown plants of T. aestivum and Z. mays than in those supplied with NH4NO3 or NO− 3. Regardless of the N-form supplied to the roots of the plant species, exposure to NH3 caused more-positive δ13C values in the plant tissues. These results indicate that the variations in N-source were associated with small but significant variations in δ13C values in plants of T. aestivum and Z. mays. These differences in δ13C values are in the direction expected from differences in WUE values over long or short growth periods and with differences in the extent of non-Rubisco (ribulose-1,5-bisphosphate carboxylase-oxygenase, EC 4.1.1.39) carboxylate contribution to net C acquisition, as a function of N-source.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/s004250050358

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9

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Vacuolar pH oscillations in mesophyll cells accompany oscillations of photosynthesis in leaves: Interdependence of cellular compartments, and regulation of electron flow in photosynthesis (1992)

Siebke, Katharina ; Yin, Zu-Hua ; Raghavendra, Agepati S. ; [et al.]

Springer

Planta 186 (1992), S. 526-531

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ISSN: 1432-2048

Keywords: Electron transport ; Metabolite transport ; Oscillation (pH, photosynthesis) ; Photosynthesis (oscillations) ; Proton pumping ; Vacuole ; Vicia (pH oscillations)

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Oscillations of photosynthesis induced in leaves of Vicia faba L. were accompanied by oscillations not only in the pH of the chloroplast stroma, but also by pH oscillations in the cytosol and in the vacuole of leaf mesophyll cells. Cytosolic pH oscillations were in phase with stromal oscillations, but antiparallel to vacuolar pH oscillations. During maxima of photosynthesis, the cytosolic pH exhibited maxima and the vacuolar pH minima. Vacuolar acidification is interpreted to be the result of energized proton transport from the cytosol into the vacuole. Since the ratio of dihydroxyacetone phosphate to phosphoglycerate is maximal during the peaks of photosynthesis (Stitt et al., 1988, J. Plant Physiol. 133, 133–143; Laisk et al., 1991, Planta 185, 554–562), while the activity of NADP-malic dehydrogenase is highest during minima of photosynthesis (Scheibe and Stitt, 1988, Plant Physiol. Biochem. 26, 473–481), the present data indicate in agreement with earlier observations (Yin et al., 1991, Planta 184, 30–34) that light-dependent cytosolic energization is brought about by the oxidation of dihydroxyacetone phosphate rather than of malate. They also indicate that the over-reduction of the electrontransport chain observed during minima of photosynthesis is relieved not predominantly by oxaloacetate reduction and export of the resulting malate from the chloroplasts but by another reaction, presumably oxygen reduction.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00198032

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10

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Light-dependent pH changes in leaves of C3 plants (1990)

Yin, Zu-Hua ; Neimanis, Spidola ; Heber, Ulrich

Springer

Planta 182 (1990), S. 253-261

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ISSN: 1432-2048

Keywords: Cytosol ; Metabolite ; Photosynthesis ; pH regulation ; Transport ; Vacuoles

Source: Springer Online Journal Archives 1860-2000

Topics: Biology

Notes: Abstract Illumination of leaves of C3 plants caused cytosolic alkalization and vacuolar acidification in the mesophyll cells. Both phenomena were particularly pronounced when CO2 was absent, were suppressed by CO2, and were related to the activation state of the photosynthetic apparatus. The cytosolic alkalization reaction has at least two major components. Trivalent cytosolic phosphoglycerate must be protonated before it can be transferred into the chloroplasts for reduction. Pumping of protons from the cytosol into the vacuole also contributes to cytosolic alkalization. The dependence of light scattering by chloroplast thylakoids on the energy fluence rate was closely related to that of vacuolar acidification under different conditions for chloroplast energization. This indicates (i) transport of energy from the chloroplasts to the cytosol in the light and (ii) use of this energy for the transport of protons into the vacuoles. The light-dependent vacuolar acidification is interpreted to be caused by the increase in the activity of a proton-translocating enzyme of the tonoplast. The decrease of vacuolar acidification during photosynthetic carbon reduction or photorespiration is indicative of decreased cytosolic energization. In low light, the light-dependent vacuolar acidification was stimulated in the absence of CO2 when photorespiration was inhibited. The data do not support the view that photorespiration is capable of increasing the cytosolic energy state in the light.

Type of Medium: Electronic Resource

URL: http://dx.doi.org/10.1007/BF00197119

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