Kinetics and relative significance of remobilized and current C and N incorporation in leaf and root growth zones of Lolium perenne after defoliation: assessment by 13C and 15N steady-state labelling

1. Methods of determining the order of addition of substrates and dissociation of products by using flux ratios are investigated. Where an enzyme obeys hyperbolic steady-state velocity kinetics it is concluded that it may be particularly useful to compare the measured flux ratios with those calculated from the steady-state velocity parameters. 2. An expression is derived relating the relative contribution of the two pathways in a branched pathway to the flux ratios. 3. The relationship of equilibrium-reaction-rate measurements [Boyer & Silverstein (1963) Acta Chem. Scand. 17, Suppl. 1, S195] to the flux ratios is considered. Equilibrium-reaction rates are shown to be affected both by the addition of substrates and dissociation of products. Methods of analysing the data to distinguish between these events are discussed. 4. Methods of measurement of flux ratios are described, and it is concluded that the non-equilibrium steady-state method is preferable to measurements at chemical equilibrium. 5. The relative significance of flux ratio measurements and steady-state velocity inhibition data is discussed. It is concluded that flux ratios, when taken in conjunction with the inhibition data, provide the least ambiguous information about mechanism.

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Modeling rhizosphere carbon and nitrogen cycling in <i>Eucalyptus</i> plantation soil

Biogeosciences ◽

10.5194/bg-15-4943-2018 ◽

2018 ◽

Vol 15 (16) ◽

pp. 4943-4954 ◽

Cited By ~ 4

Author(s):

Rafael Vasconcelos Valadares ◽

Júlio César Lima Neves ◽

Maurício Dutra Costa ◽

Philip James Smethurst ◽

Luiz Alexandre Peternelli ◽

...

Keyword(s):

Organic Matter ◽

Soil Organic Matter ◽

Root Growth ◽

Priming Effect ◽

Model Performance ◽

N Cycling ◽

Eucalyptus Plantation ◽

Eucalyptus Plantations ◽

C And N ◽

C And N Cycling

Abstract. Vigorous Eucalyptus plantations produce 105 to 106 km ha−1 of fine roots that probably increase carbon (C) and nitrogen (N) cycling in rhizosphere soil. However, the quantitative importance of rhizosphere priming is still unknown for most ecosystems, including these plantations. Therefore, the objective of this work was to propose and evaluate a mechanistic model for the prediction of rhizosphere C and N cycling in Eucalyptus plantations. The potential importance of the priming effect was estimated for a typical Eucalyptus plantation in Brazil. The process-based model (ForPRAN – Forest Plantation Rhizosphere Available Nitrogen) predicts the change in rhizosphere C and N cycling resulting from root growth and consists of two modules: (1) fine-root growth and (2) C and N rhizosphere cycling. The model describes a series of soil biological processes: root growth, rhizodeposition, microbial uptake, enzymatic synthesis, depolymerization of soil organic matter, microbial respiration, N mineralization, N immobilization, microbial death, microbial emigration and immigration, and soil organic matter (SOM) formation. Model performance was quantitatively and qualitatively satisfactory when compared to observed data in the literature. Input variables with the most influence on rhizosphere N mineralization were (in order of decreasing importance) root diameter > rhizosphere thickness > soil temperature > clay concentration. The priming effect in a typical Eucalyptus plantation producing 42 m3 ha−1 yr−1 of shoot biomass, with assumed losses of 40 % of total N mineralized, was estimated to be 24.6 % of plantation N demand (shoot + roots + litter). The rhizosphere cycling model should be considered for adaptation to other forestry and agricultural production models where the inclusion of such processes offers the potential for improved model performance.

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Modelling Carbon Fluxes as an Aid to Understanding Perennial Ryegrass (Lolium perenne) Root Dynamics

Agronomy ◽

10.3390/agronomy8110236 ◽

2018 ◽

Vol 8 (11) ◽

pp. 236

Author(s):

Arif Robin ◽

Louis Irving ◽

Edith Khaembah ◽

Cory Matthew

Keyword(s):

Root Growth ◽

Lolium Perenne ◽

Perennial Ryegrass ◽

Growth Rates ◽

Plant Performance ◽

Seasonal Effects ◽

Cultivar Differences ◽

Root Turnover ◽

Root Dynamics ◽

Maintenance Respiration

Despite the importance of roots in determining plant performance, the factors controlling their development and longevity remain poorly understood. Grass morphology is based on repeating units called phytomers, with each capable of producing one leaf, one daughter tiller, and one or more roots. We developed a phytomer-based understanding of root birth, growth and senescence in Lolium perenne, using a modeling approach to explore seasonal effects on root turnover dynamics, and to explore cultivar differences in these processes. Similar to leaves, roots exhibit a clear progression from initiation, growing for approximately seven phyllochrons, with growth rates strongly influenced by environmental conditions. In spring, the phyllochron decreased over the experiment, while it increased in autumn. In spring, C availability exceeding maintenance respiratory requirements allowed root growth at each phytomer position, with a 70/30 split between maintenance and growth. Under C-deficient conditions in autumn, this split was approximately 80/20, with growth limited to younger phytomer positions, while older roots were more susceptible to starvation-induced senescence due to their high C requirements for maintenance respiration.

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