The MycUpscaling project has made pioneering advancements in plant–microbe synthetic biology, pushing well beyond the current state of the art in several key areas:
It is the first project to engineer the host plant specifically to biofortify its microbial symbiont (AMF) by enhancing triacylglycerol (TAG) production and transfer.
It applied, for the first time in AMF systems, a combinatorial “Push–Pull–Package” (PPP) lipid metabolic engineering strategy, which had previously only been used in seed oil enhancement.
The project developed a library of multigene transgenic Medicago truncatula lines with optimized root expression of lipid biosynthesis and transport genes.
It demonstrated through radioisotopic flux tracing and lipidomic profiling that engineered lines redirect acyl flux away from membrane lipids toward storage lipids beneficial for AMF spore formation—evidence never before shown in this symbiotic system.
These scientific advancements bridge plant lipid metabolism, fungal physiology, and synthetic biology, setting a new benchmark for future research on microbial bio-inoculants.
As the project enters its return phase (at UCLouvain), the following milestones are expected:
Scale-up validation of selected engineered lines in Petri dish and bioreactor systems, measuring spore production efficiency, root colonization, and hyphal development.
Cost-efficiency analysis of producing biofortified AMF spores compared to conventional inocula.
Optimization of bioreactor culture conditions (e.g. aeration, nutrient flow) for large-scale, sterile AMF production.
Completion of microscopy imaging and targeted lipidomics to spatially resolve lipid flux in the symbiotic interface.
Submission of a peer-reviewed publication and final dissemination actions including public events and industrial outreach.
Socio-Economic and Societal Impact
The project directly addresses two major societal needs:
Sustainable Agriculture and Fertilizer Reduction
By enabling cost-effective, clean AMF inoculum production, MycUpscaling supports the shift away from synthetic phosphorus fertilizers—mitigating environmental pollution and reducing dependence on non-renewable resources.
Industrial Competitiveness and Bioeconomy
The project lays the groundwork for commercial-scale AMF production technologies with potential applications in crop biostimulants, horticulture, and ecological restoration. The biofortified spores can improve plant nutrition, stress resilience, and yield—factors highly relevant to Europe’s agrotech industry.
Scientific Capacity and Innovation
The fellow has gained unique training in mycorrhiza in vitro culture, synthetic biology, metabolic flux analysis, fostering EU leadership in the emerging field of microbiome-based agricultural inputs.
Wider Societal Benefits
By contributing to agroecological transitions, improved soil health, and climate-resilient agriculture, MycUpscaling is aligned with the EU Green Deal, Farm to Fork strategy, and the UN Sustainable Development Goals (SDGs 2, 12, 13, and 15).