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Nitrogen use efficiency, growth and physiological parameters in different tomato genotypes under high and low N fertilisation conditions

Martín Flores-Saavedra, Gloria Villanueva, Pietro Gramazio, Santiago Vilanova, Antonio Mauceri, Maria Rosa Abenavoli, Francesco Sunseri, Jaime Prohens, Mariola Plazas

2024Plant Physiology and Biochemistry18 citationsDOIOpen Access PDF

Abstract

Identification of novel genotypes with enhanced nitrogen use efficiency (NUE) is a key challenge for a sustainable tomato production. In this respect, the performance of a panel of thirty tomato accessions were evaluated under high (HN; 5 mM N) and low (LN; 0.5 mM N) nitrogen irrigation solutions. For each treatment, when 50% of plants reached the first flower bud stage, plant growth and biomass traits, chlorophyll, flavonol and anthocyanin indexes, nitrogen balance index (NBI), C:N ratio in leaves, stems, and roots, and NUE were evaluated. Significant (p < 0.05) effects were observed for accession, N treatment, and their interaction across all the traits. Under LN, plants showed a delayed development (40 days for HN vs. 65 days for LN) and reduced growth and biomass. On average, LN condition led to 41.8% decrease in nitrogen uptake efficiency (NUpE) but also 189.0% increase in NUtE, resulting in 62.2% overall increase in NUE. A broad range of variation among accessions was observed under both HN and LN conditions. Under LN conditions, chlorophyll index and NBI decreased, while flavonol and anthocyanin indexes increased. Leaf C:N ratio was positively correlated with nitrogen utilisation efficiency (NUtE) in both N treatments. Multi-trait analyses identified top-performing accessions under each condition, allowing to identify one accession among top performers under both conditions. Correlation analysis revealed that high root biomass and leaf C:N ratio are useful markers for selecting high NUE accessions. These findings offer valuable insights for improving tomato NUE under varying nitrogen fertilization conditions and for breeding high-NUE cultivars. • N restriction delays growth and development in tomato. • High variation exists among tomato accessions in response to high and low N fertilisation. • Leaf C:N ratio was correlated with NUtE in high and low N treatments. • NUpE decreased under low N conditions, while NUtE and NUE increased. • Top-performing accessions were identified under high and low N conditions.

Topics & Concepts

NitrogenBiomass (ecology)ChlorophyllHorticultureBiologyAgronomyChemistryBotanyOrganic chemistryPlant nutrient uptake and metabolismIrrigation Practices and Water ManagementCrop Yield and Soil Fertility