Abstract
Legumes associate with root colonizing rhizobia that provide fixed nitrogen to its plant host in exchange for recently fixed carbon. There is a lack of understanding of how individual plants modulate carbon allocation to a nodulated root system as a dynamic response to abiotic stimuli. One reason is that most approaches are based on destructive sampling, making quantification of localised carbon allocation dynamics in the root system difficult. We established an experimental workflow for routinely using non-invasive Positron Emission Tomography (PET) to follow the allocation of leaf-supplied 11C tracer towards individual nodules in a three-dimensional (3D) root system of pea (Pisum sativum). Nitrate was used for triggering a reduction of biological nitrogen fixation (BNF), which was expected to rapidly affect carbon allocation dynamics in the root-nodule system. The nitrate treatment led to a decrease in 11C tracer allocation to nodules by 40% to 47% in 5 treated plants while the variation in control plants was less than 11%. The established experimental pipeline enabled for the first time that several plants could consistently be labelled and measured using 11C tracers in a PET approach to quantify C-allocation to individual nodules following a BNF reduction. Our study demonstrates the strength of using 11C tracers in a PET approach for non-invasive quantification of dynamic carbon allocation in several growing plants over several days. A major advantage of the approach is the possibility to investigate carbon dynamics in small regions of interest in a 3D system such as nodules in comparison to whole plant development.
Highlights
Legumes establish a symbiosis with nitrogen (N)-fixing rhizobia
Details on the magnetic resonance imaging (MRI) and measurements as well as the analysis quantification given in the measurements as well as the datadata analysis andand quantification areare given section, where we describe its application to a concrete research question
Our study was designed to reveal the feasibility of using Positron Emission Tomography (PET) with 11 C tracer for establishing a routine in carbon allocation studies within a complex 3D structure of a root system
Summary
Legumes establish a symbiosis with nitrogen (N)-fixing rhizobia. Rhizobia are supplied with plant-derived carbon (C) and in return, rhizobia provide the plant with fixed, atmospheric N [1,2]. Legumes play a key role in natural ecosystems and agriculture, as they do not require additional application of synthetic N fertilizers and produce grains with high protein content for humans and cattle [3,4]. Nodules depend to a large part on recently fixed carbon from the leaves [5,6]. A plant host may invest a substantial amount of available photosynthates into his symbiont [7,8]. A timely and balanced carbon allocation in return for N is vital for plant performance. While much progress has been made associated with the regulation of biological N fixation (BNF)
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