Assimilation of [<sup>15</sup>N]Nitrate and [<sup>15</sup>N]Nitrite in Leaves of Five Plant Species under Light and Dark Conditions

Reed, Andrew J.; Canvin, David T.; Sherrard, Joseph H.; Hageman, R. H.

doi:10.1104/pp.71.2.291

Cited by 62 publications

(37 citation statements)

References 17 publications

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“…shown for various lines of wild-type tobacco that nitrate as well as nitrite reduction can take place in the dark in leaves, although at a reduced rate (Reed et al, 1983;Lejay et al, 1997). The values obtained in this work are very similar to those obtained previously for the wild-type and Del lines using detached leaves (Lejay et al, 1997).…”

supporting

confidence: 79%

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

et al. 2006

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Diurnal variations in nitrate reductase (NR) activity and nitrogen metabolites were examined in wild-type Nicotiana plumbaginifolia and transformants with various degrees of NR deregulation. In the C1 line, NR was only deregulated at the transcriptional level by placing the NR gene under the control of the cauliflower mosaic virus 35S RNA promoter. In the Del8 and S521D lines, NR was additionally deregulated at the posttranslational level either by a deletion mutation in the N-terminal domain or by a mutation of the regulatory phosphorylation site (serine-521). Posttranslational regulation was essential for pronounced diurnal variations in NR activity. Low nitrate content was related to deregulation of NR, whereas the level of total free amino acids was much higher in plants with fully deregulated NR. Abolishing transcriptional and posttranslational regulation (S521D plants) resulted in an increase of glutamine and asparagine by a factor of 9 and 14, respectively, compared with wild type, whereas abolishing transcriptional regulation (C1 plants) only resulted in increases of glutamine and asparagine by factors ,2. Among the minor amino acids, isoleucine and threonine, in particular, showed enhanced levels in S521D. Nitrate uptake rates were the same in S521D and wild type as determined with 15 N feeding. Deregulation of NR appears to set the level of certain amino acids, whereas diurnal variations were still determined by light/dark. Generally, deregulation of NR at the transcriptional level did not have much influence on metabolite levels, but additional deregulation at the posttranslational level resulted in profound changes of nitrogen metabolite levels.

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confidence: 79%

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

et al. 2006

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“…Nitrogen assimilation is also suppressed by a reduction in carbohydrate status (Fritz et al 2006), and therefore by the duration of the dark period. Nevertheless, nitrate reduction often continues in the dark, albeit often at reduced rates (9-76% of diurnal rates in a range of species [Reed et al 1983];~50% [Aslam et al 1979] or 88% [Bloom et al 1989] in Hordeum vulgare L.). In species that perform little or no nitrate reduction in leaves, amino acid synthesis in leaves does not, in principle, require light.…”

Section: The Role Of Variation In Anabolic Demandsmentioning

confidence: 99%

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance

Buckley

Adams

2010

Plant Cell & Environment

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Leaf respiration continues in the light but at a reduced rate. This inhibition is highly variable, and the mechanisms are poorly known, partly due to the lack of a formal model that can generate testable hypotheses. We derived an analytical model for non-photorespiratory CO2 release by solving steady-state supply/demand equations for ATP, NADH and NADPH, coupled to a widely used photosynthesis model. We used this model to evaluate causes for suppression of respiration by light. The model agrees with many observations, including highly variable suppression at saturating light, greater suppression in mature leaves, reduced assimilatory quotient (ratio of net CO2 and O2 exchange) concurrent with nitrate reduction and a Kok effect (discrete change in quantum yield at low light). The model predicts engagement of non-phosphorylating pathways at moderate to high light, or concurrent with processes that yield ATP and NADH, such as fatty acid or terpenoid synthesis. Suppression of respiration is governed largely by photosynthetic adenylate balance, although photorespiratory NADH may contribute at sub-saturating light. Key questions include the precise diel variation of anabolism and the ATP : 2e -ratio for photophosphorylation. Our model can focus experimental research and is a step towards a fully process-based model of CO2 exchange.Key-words: alternative oxidase; carbon metabolism; Kok effect; photorespiration; photosynthesis; respiration.Abbreviations: A, net CO2 assimilation rate; Ao, net O2 evolution rate; AOX, alternative oxidase; Bn, net anabolic NADH supply; Bp, net anabolic NADPH demand; Bt, net anabolic ATP demand; ci, intercellular CO2 partial pressure; COX, cytochrome oxidase; fm, fraction of photorespiratory NADH that remains in mitochondria; fx, fraction of excess thylakoid reducing potential dissipated as NADPH export; G6PDH, glucose-6-phosphate dehydrogenase; I, incident PPFD; J, potential thylakoid e -transport rate; J′, Vc in RuBP-limiting conditions; Ja, actual thylakoid e -transport rate; Jm, max potential thylakoid e -transport rate; M, maintenance ATP demand; mETC, mitochondrial e -transport chain; O, ambient O2 partial pressure; OPPP, oxidative pentose phosphate pathway; pe, ATP : 2e -ratio, ADP phosphorylated per 2 e -transported to ferredoxin; po, P : O ratio, ratio of ADP phosphorylation to O2 reduction in mitochondria; pom, overall max P : O ratio; pom,ana, max P : O ratio for NADH generated in anabolic C flow; pom,cat, max P : O ratio for NADH derived from catabolic substrate oxidation; pom,cyt, max P : O ratio for cytosol derived NADH; pom,mtx, max P : O ratio for matrix derived NADH; PPFD, photosynthetic photon flux density; QY, quantum yield of CO2 from incident PPFD; Rc, rate of non-photorespiratory CO2 release; Ro, rate of O2 reduction by mitochondria; RuBP, ribulose-1,5-bisphosphate; S, net conversion of TP to sucrose and/or starch; t, net ATP demand resulting from S; TP, triose phosphate; Vana, rate of C flow into C skeletons for biosynthesis; Vby, rate of CO2 release due to ana...

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“…Plants can assimilate NO3-during both the light and dark portions of the photoperiod, although rates of assimilation may differ. In experiments using '"NO3-and excised leaves or leaf disks, it has been amply demonstrated that N03 reduction can occur in darkness (8,11,24,32), and the rate of reduction is associated with availability ofcarbohydrate (2, 15). Nevertheless, it was found consistently that reduction rates were lower in darkness.…”

Section: Introductionmentioning

confidence: 99%

Assimilation of ¹⁵NO₃⁻ Taken Up by Plants in the Light and in the Dark

Rufty¹,

Israel²,

Volk³

1984

Plant Physiol.

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An experiment was conducted to determine the extent that NO3-taken up in the dark was assimilated and utilized differently by plants than NO3-taken up in the light. Vegetative, nonnodulated soybean plants (Glycine max L. Merrill, 'Ransom') were exposed to '5NO3-throughout light (9 hours) or dark (15 hours) phases of the photoperiod and then returned to solutions containing '4NO3-, with plants sampled subsequently at each light/dark transition over 3 days. The rates of '5N03-absorption were nearly equal in the light and dark (8A2 and 7.93 micromoles per hour, respectively) however, the whole-plant rate of '5N03-reduction during the dark uptake period (2.58 micromoles per hour) was 46% of that in the light (5.63 micromoles per hour). The lower rate of reduction in the dark was associated with both substantial retention of absorbed '5NO3-in roots and decreased efficiency of reduction of '5NO3-in the shoot. The rate of incorporation of '5N into the insoluble reduced-N fraction of roots in darkness (1.10 micromoles per hour) was somewhat greater than that in the light (0.92 micromoles per hour), despite the lower rate of whole-plant '5NO3-reduction in darkness.A hrge portion of the '5NO3-retained in the root in darkness was translocated and incorporated into insoluble reduced-N in the shoot in the following light period, at a rate which was similar to the rate of whole-plant reduction of 'I5NO3-acquired during the light period. Taking into account reduction of NO3-from all endogenous pools, it was apparent that plant reduction in a given light period (A13.21 micromoles per hour) exceeded considerably the rate of acquisition of exogenous NO3-(8.42 micromoles per hour) during that period. The primary source of substrate for NO3-reduction in the dark was exogenous NO3-being concurrently absorbed. In general, these data support the view that a relatively small portion (<20%) ofthe whole-plant reduction ofNO3-in the light occurred in the root system. Plants can assimilate NO3-during both the light and dark portions of the photoperiod, although rates of assimilation may differ. In experiments using '"NO3-and excised leaves or leaf disks, it has been amply demonstrated that N03 reduction can occur in darkness (8,11,24,32), and the rate of reduction is associated with availability ofcarbohydrate (2, 15). Nevertheless, it was found consistently that reduction rates were lower in darkness. Furthermore, activities of nitrate reductase in leaves ' The extent to which the rate of NO3-assimilation in intact plants is diminished during the dark phase of a 'normal' photoperiod has not been examined. The present experiment was conducted with that intent. Nonnodulated vegetative soybean plants were exposed to '5NO3 throughout light or dark periods to determine whole-plant NO3-assimilation during the period in which it was absorbed. In addition, following exposure to '5N03, sets of plants were returned to nutrient solutions containing '4NO3-. The subsequent partitioning of '5N among plant parts and the reduction ofendogenous ...

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Assimilation of [¹⁵N]Nitrate and [¹⁵N]Nitrite in Leaves of Five Plant Species under Light and Dark Conditions

Cited by 62 publications

References 17 publications

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance

Assimilation of ¹⁵NO₃⁻ Taken Up by Plants in the Light and in the Dark

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Assimilation of [15N]Nitrate and [15N]Nitrite in Leaves of Five Plant Species under Light and Dark Conditions

Cited by 62 publications

References 17 publications

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

Posttranslational Regulation of Nitrate Reductase Strongly Affects the Levels of Free Amino Acids and Nitrate, whereas Transcriptional Regulation Has Only Minor Influence

An analytical model of non‐photorespiratory CO2 release in the light and dark in leaves of C3 species based on stoichiometric flux balance

Assimilation of 15NO3− Taken Up by Plants in the Light and in the Dark

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Assimilation of [¹⁵N]Nitrate and [¹⁵N]Nitrite in Leaves of Five Plant Species under Light and Dark Conditions

An analytical model of non‐photorespiratory CO₂ release in the light and dark in leaves of C₃ species based on stoichiometric flux balance

Assimilation of ¹⁵NO₃⁻ Taken Up by Plants in the Light and in the Dark