Nitrogen nutrition effects on δ13C of plant respired CO2 are mostly caused by concurrent changes in organic acid utilisation and remobilisation

Plant Cell Environ. 2024 Dec;47(12):5511-5526. doi: 10.1111/pce.15062. Epub 2024 Sep 2.

Abstract

Nitrogen (N) nutrition impacts on primary carbon metabolism and can lead to changes in δ13C of respired CO2. However, uncertainty remains as to whether (1) the effect of N nutrition is observed in all species, (2) N source also impacts on respired CO2 in roots and (3) a metabolic model can be constructed to predict δ13C of respired CO2 under different N sources. Here, we carried out isotopic measurements of respired CO2 and various metabolites using two species (spinach, French bean) grown under different NH4 +:NO3 - ratios. Both species showed a similar pattern, with a progressive 13C-depletion in leaf-respired CO2 as the ammonium proportion increased, while δ13C in root-respired CO2 showed little change. Supervised multivariate analysis showed that δ13C of respired CO2 was mostly determined by organic acid (malate, citrate) metabolism, in both leaves and roots. We then took advantage of nonstationary, two-pool modelling that explained 73% of variance in δ13C in respired CO2. It demonstrates the critical role of the balance between the utilisation of respiratory intermediates and the remobilisation of stored organic acids, regardless of anaplerotic bicarbonate fixation by phosphoenolpyruvate carboxylase and the organ considered.

Keywords: ammonium:nitrate ratio; anaplerosis; carbon isotope fractionation; respiration.

MeSH terms

  • Ammonium Compounds / metabolism
  • Carbon Dioxide* / metabolism
  • Carbon Isotopes* / analysis
  • Malates / metabolism
  • Nitrogen* / metabolism
  • Phaseolus / metabolism
  • Phaseolus / physiology
  • Plant Leaves* / metabolism
  • Plant Roots* / metabolism

Substances

  • Carbon Dioxide
  • Carbon Isotopes
  • Nitrogen
  • Malates
  • malic acid
  • Ammonium Compounds