Abstract
The plasticity of plant development relies on its ability to balance growth and stress resistance. To do this, plants have established highly coordinated gene regulatory networks (GRNs) of the transcription factors and signaling components involved in developmental processes and stress responses. In root crops, yields of storage roots are mainly determined by secondary growth driven by the vascular cambium. In relation to this, a dynamic yet intricate GRN should operate in the vascular cambium, in coordination with environmental changes. Despite the significance of root crops as food sources, GRNs wired to mediate secondary growth in the storage root have just begun to emerge, specifically with the study of the radish. Gene expression data available with regard to other important root crops are not detailed enough for us directly to infer underlying molecular mechanisms. Thus, in this review, we provide a general overview of the regulatory programs governing the development and functions of the vascular cambium in model systems, and the role of the vascular cambium on the growth and yield potential of the storage roots in root crops. We then undertake a reanalysis of recent gene expression data generated for major root crops and discuss common GRNs involved in the vascular cambium-driven secondary growth in storage roots using the wealth of information available in Arabidopsis. Finally, we propose future engineering schemes for improving root crop yields by modifying potential key nodes in GRNs.
Highlights
In natural conditions, plants are exposed simultaneously to several sources of abiotic and biotic stresses, which could negatively influence their growth and vitality (Pandey et al, 2017; Schmidt and van Dongen, 2019)
Dong et al (2019) analyzed the transcriptome and proteome from the fibrous roots and four developmental stages of sweet potato storage roots, finding that genes related to meristem/cambium development, starch biosynthesis and hormones were differentially expressed during storage root formation
The results revealed that stress-responsive transcription factor (TF) in the gene regulatory networks (GRNs) closely control root secondary growth, with a highly connected hub in the identified GRN known as ETHYLENE RESPONSE FACTORs (ERFs)-1, a stress-responsive gene
Summary
Plants are exposed simultaneously to several sources of abiotic and biotic stresses, which could negatively influence their growth and vitality (Pandey et al, 2017; Schmidt and van Dongen, 2019). These include the profiling of genes involved in, for example, the regulation of storage root formation in the cassava (Yang et al, 2011; Wilson et al, 2017); understanding storage root formation, carbohydrate metabolism and carotenoid biosynthesis in the sweet potato (Tao et al, 2012; Firon et al, 2013; Wang et al, 2015c; Dong et al, 2019); root development, hormonal control and carotenoid biosynthesis in the carrot (Wang et al, 2015a; Ma et al, 2018; Machaj et al, 2018); taproot growth and sucrose accumulation in the sugar beet (Zhang et al, 2017); and root formation and glucosinolate biosynthesis, anthocyanin synthesis, stress response, and the relationship between storage root growth and stress responses in the radish (Wang et al, 2013; Mitsui et al, 2015; Xie et al, 2015; Xu et al, 2015; Gao et al, 2019; Hoang et al, 2020).
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