Exploring gene networks in two sunflower lines with contrasting leaf senescence phenotype using a system biology approach

Sebastián Moschen,Sebastián Moschen,Sebastián Moschen,Nicolas B Langlade,Nicolas B Langlade,Nicolas Blanchet,Nicolas Blanchet,Janet Higgins,Máximo Rivarola,Máximo Rivarola,Máximo Rivarola,Salvador Nicosia,Norma Paniego,Norma Paniego,Norma Paniego,Salvador Nicosia,Francisco Astigueta,Francisco Astigueta,Saleh Alseekh,Johanna Marino,Paula Fernández,Paula Fernández,Paula Fernández,Paula Fernández,Salvador Nicosia,Alisdair R Fernie,Ruth A Heinz,Ruth A Heinz,Ruth A Heinz,Sofia Bengoa Luoni,Francisco Astigueta

doi:10.1186/s12870-019-2021-6

Abstract

BackgroundLeaf senescence is a complex process, controlled by multiple genetic and environmental variables. In sunflower, leaf senescence is triggered abruptly following anthesis thereby limiting the capacity of plants to keep their green leaf area during grain filling, which subsequently has a strong impact on crop yield. Recently, we performed a selection of contrasting sunflower inbred lines for the progress of leaf senescence through a physiological, cytological and molecular approach. Here we present a large scale transcriptomic analysis using RNA-seq and its integration with metabolic profiles for two contrasting sunflower inbred lines, R453 and B481–6 (early and delayed senescence respectively), with the aim of identifying metabolic pathways associated to leaf senescence.ResultsGene expression profiles revealed a higher number of differentially expressed genes, as well as, higher expression levels in R453, providing evidence for early activation of the senescence program in this line. Metabolic pathways associated with sugars and nutrient recycling were differentially regulated between the lines. Additionally, we identified transcription factors acting as hubs in the co-expression networks; some previously reported as senescence-associated genes in model species but many are novel candidate genes.ConclusionsUnderstanding the onset and the progress of the senescence process in crops and the identification of these new candidate genes will likely prove highly useful for different management strategies to mitigate the impact of senescence on crop yield. Functional characterization of candidate genes will help to develop molecular tools for biotechnological applications in breeding crop yield.

Highlights

Leaf senescence is a complex process, controlled by multiple genetic and environmental variables
In the current study we identify both metabolic pathways associated with leaf senescence in sunflower as well as putative transcription factors that represent useful candidate genes for crop breeding
Despite not having a significant difference, B481–6 showed higher photosynthesis activity tendency respect to R453 which is coherent with a delay in senescence program

Summary

Introduction

Leaf senescence is a complex process, controlled by multiple genetic and environmental variables. Senescence is the final stage of leaf development preceding cell death and is a complex process controlled by multiple genetic and environmental variables. Senescence is an active phase of plant development involving regulated degradation and remobilization processes which could reduce crop yield when it is induced prematurely [5]. Annual plants, which include many of our grain and oil crops, undergo a visual process towards the end of the reproductive stage that is accompanied by nutrient remobilization from leaf to developing seeds [1]. A delay in leaf senescence has been directly correlated to grain yield, mainly due to photosynthesis maintenance during the reproductive stage [6,7,8,9]

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Conclusion