BIOCHEMICAL DISPOSAL OF EXCESS H<sup>+</sup>IN GROWING PLANTS?

Raven, John A.

doi:10.1111/j.1469-8137.1986.tb00644.x

Cited by 141 publications

(92 citation statements)

References 97 publications

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“…1986,19876,1988). Acid-base balance during growth demands an H+ efflux of 4/3 H+ per NH/ entering and assimilated (see Raven, 1985Raven, a, 1986Raven, , 19876, 1988. Consideration of SO42-and H2PO4" uptake and assimilation reduces the net H"^ efflux to 1-22 H^ per N assimilated, although the net negative charge on organic matter remains at 0-33 mol negative charge per mol N or 0-022 mol negative charge per mol C. Kirkby & Mengel (1967) report some 0-17 mol negative charge on uronate per mol N, or 0-011 mol negative charge on uronate per mol C. As mentioned in Section II, this negative charge arises by oxidation of reduced C derived from Rubisco-catalysed CO2 fixation, so does not involve non-Rubisco carboxylases.…”

Section: ^-(7)mentioning

confidence: 99%

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

1990

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SUMMARY This paper relates the 13C/12C ratio of C3 plant material relative to that of source CO2 to the N source for growth, the organic N content of the plant, and the extent of organic acid synthesis. The 13C/12C ratio is quantified as Δ, defined as (δ13C substrate –δ13C product)/(1+δ13C product), where δ13C values of substrate or product (i.e. the samples) are defined as [13C/12C]sample]/[(13C/12C)standard]−1. The computation is performed by relating differences in plant composition as a function of N nutrition and acid synthesis to the fraction of plant C which is acquired via Rubisco and via other carboxylases. The fractional contribution of the different carboxylases to C gain is then related, using the known isotopic fractionations exhibited by these carboxylases, in a model to predict the final Δ of the plant (relative to atmospheric CO2). Application of this approach to a ‘typical’ C3 land plant yields predictions of the decrease of Δ relative to a hypothetical case in which all C is fixed via Rubisco. The predicted decreases range from 0–24 %, for NH4+ assimilation (which always occurs in the roots) to 2–80%, for NO3− assimilation in shoots with the organic acid salt which results from acid‐base balance, plus any additional organic acid salts plus free acids for a plant with a basal C:N molar ratio in organic material of 15. Intermediate values are predicted for symbiotic growth with N2, or where NO3− assimilation in root or shoot is accompanied by some acid‐base regulation via OH‐ loss to the root medium. Comparison with published data on the difference in Δ of Ricinus communis cultured with NH4+ or NO3− shows that the measured influence of nitrogen source is in the right direction (NO3− grown plants with a smaller Δ, i.e. a larger deviation from the value predicted for the absence of non‐Rubisco carboxylations) to be explained by the observed difference in composition and hence fractional C contribution by the various carboxylases. However, the effect of N source on Δ is greater than that predicted by the model, i.e. a 2.1 % decrease as opposed to a 0.10 % decrease. It is likely that the major cause of the difference in δ13C of the plants grown on the two N sources is a change in the ratio of transport and biochemical conductances of leaf photosynthesis. Such a change is quantitatively consistent with the lower water use efficiency of NH4+ ‐grown plants. The predicted, and observed, changes in Δ as a function of N source are of the same magnitude as those found for C3 terrestrial species grown at different temperatures or photon flux densities, or in environments yielding different water use efficiencies by changing root water supply relative to shoot evaporation potential. Variations in N source should be added to the factors which might alter δ of plants growing in the field.

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Section: ^-(7)mentioning

confidence: 99%

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

1990

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“…(iii) Plants were darkened for 16-24 h to reduce the NIA transcript level and NIA activity to low levels, and leaves were then detached and supplied with malate or 2-oxoglutarate for 4 h in the light to investigate their impact on the light-induction of NIA. The increase of the NIA transcript and NIA activity was antagonized by malate, and synthesized and exported via the phloem to the roots where it is decarboxylated (Raven 1986(Raven , 1988Martinoia & Rentsch 1994). During the day, nitrate assimilation and the accompanying synthesis of malate proceed more rapidly than malate export, and malate accumulates to high levels that are equivalent to 25-30% of the amount of assimilated nitrate (Touraine, Grignon & Grignon 1988;Deng, Moureaux & Lamaze 1989;Kaiser & Förster 1989;Scheible et al 1997b).…”

Section: Introductionmentioning

confidence: 98%

“…Geiger et al 1998Geiger et al , 1999, which is affected by a range of extraneous factors including the temperature and water availability. A third aspect is the low pH-buffering capacity of plant leaves (Raven 1986(Raven , 1988, which makes it important to coordinate nitrate assimilation with processes involved in pH regulation, including the synthesis and export of malate. As we show elsewhere (Scheible et al, 2000), phosphoenolpyruvate carboxylase expression is tightly coordinated with expression of NIA and nitrite reductase, whereas enzymes for the synthesis of 2-oxoglutarate are expressed out of phase with a maximum later in the diurnal cycle facilitating remobilization of nitrogen that has temporarily accumulated in intermediates of the GOGAT pathway and photorespiration.…”

Section: Implications For Regulation Of the Interaction Between Nitramentioning

confidence: 99%

“…Changes in organic acid metabolism are also important for pH regulation. Protons are consumed during the conversion of nitrate to ammonium (Raven 1986(Raven , 1988. In single-celled organisms, the resulting alkalinization can be countered by regulating proton exchange with the surrounding medium.…”

Section: Introductionmentioning

confidence: 99%

“…In single-celled organisms, the resulting alkalinization can be countered by regulating proton exchange with the surrounding medium. In leaves the surrounding cell wall has only a small buffer capacity (Raven 1986(Raven , 1988) and a counter-anion, usually malate, is…”

Section: Introductionmentioning

confidence: 99%

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Influence of malate and 2-oxoglutarate on the NIA transcript level and nitrate reductase activity in tobacco leaves

Muller¹,

Scheible²,

Stitt³

et al. 2001

Plant Cell Environ

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slightly accelerated by 2-oxoglutarate. (iv) Plants were placed in the dark for 60 h to reduce NIA activity to the limit of detection, and leaf discs were then incubated in the dark on sucrose to achieve a photosynthesis-independent increase of NIA activity. This was strongly inhibited by malate. (v) It is concluded that malate inhibits NIA expression, affecting both the NIA transcript level and NIA activity. Although the results are consistent with a role for 2-oxoglutarate in the regulation of NIA expression, the impact is less marked and no endogenous changes of 2-oxoglutarate were found that are likely to have a significant effect on NIA expression.

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Interactions between Nitrogen and Phosphorus metabolism

Raven

2015

Annual Plant Reviews Volume 48

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BIOCHEMICAL DISPOSAL OF EXCESS H⁺IN GROWING PLANTS?

Cited by 141 publications

References 97 publications

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

Influence of malate and 2-oxoglutarate on the NIA transcript level and nitrate reductase activity in tobacco leaves

Interactions between Nitrogen and Phosphorus metabolism

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BIOCHEMICAL DISPOSAL OF EXCESS H+IN GROWING PLANTS?

Cited by 141 publications

References 97 publications

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

The influence of N metabolism and organic acid synthesis on the natural abundance of isotopes of carbon in plants

Influence of malate and 2-oxoglutarate on the NIA transcript level and nitrate reductase activity in tobacco leaves

Interactions between Nitrogen and Phosphorus metabolism

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BIOCHEMICAL DISPOSAL OF EXCESS H⁺IN GROWING PLANTS?