Abstract
Sucrose (Suc) is the predominant form of carbon transported through the phloem from source to sink organs and is also a prominent sugar for short-distance transport. In all streptophytes analyzed, Suc transporter genes (SUTs or SUCs) form small families, with different subgroups evolving distinct functions. To gain insight into their capacity for moving Suc in planta, representative members of each clade were first expressed specifically in companion cells of Arabidopsis (Arabidopsis thaliana) and tested for their ability to rescue the phloem-loading defect caused by the Suc transporter mutation, Atsuc2-4. Sequence similarity was a poor indicator of ability: Several genes with high homology to AtSUC2, some of which have phloem-loading functions in other eudicot species, did not rescue the Atsuc2-4 mutation, whereas a more distantly related gene, ZmSUT1 from the monocot Zea mays, did restore phloem loading. Transporter complementary DNAs were also expressed in the companion cells of wild-type Arabidopsis, with the aim of increasing productivity by enhancing Suc transport to growing sink organs and reducing Suc-mediated feedback inhibition on photosynthesis. Although enhanced Suc loading and long-distance transport was achieved, growth was diminished. This growth inhibition was accompanied by increased expression of phosphate (P) starvation-induced genes and was reversed by providing a higher supply of external P. These experiments suggest that efforts to increase productivity by enhancing sugar transport may disrupt the carbon-to-P homeostasis. A model for how the plant perceives and responds to changes in the carbon-to-P balance is presented.
Highlights
Sucrose (Suc) is the predominant form of carbon transported through the phloem from source to sink organs and is a prominent sugar for short-distance transport
Both AtSUC1 from Arabidopsis (Arabidopsis thaliana; type I; Wippel and Sauer, 2012) and HvSUT1 from barley (Hordeum vulgare; type IIB; Reinders et al, 2012) restored phloem loading in an Arabidopsis Atsuc2–/– mutant when expressed from the companion cell-specific AtSUC2 promoter (AtSUC2p), showing that their biochemical activity in planta can replace that of AtSUC2
A construct in which CoYMVp was fused to AtSUC2 complementary DNA was shown to rescue the Atsuc2-4–/– knockout mutation (Srivastava et al, 2009b)
Summary
Sucrose (Suc) is the predominant form of carbon transported through the phloem from source to sink organs and is a prominent sugar for short-distance transport. Enhanced Suc loading and long-distance transport was achieved, growth was diminished This growth inhibition was accompanied by increased expression of phosphate (P) starvation-induced genes and was reversed by providing a higher supply of external P. There are relatively few reports of overexpression (OE) in planta to characterize their contribution to growth and development or for possible gains in productivity Both AtSUC1 from Arabidopsis (Arabidopsis thaliana; type I; Wippel and Sauer, 2012) and HvSUT1 from barley (Hordeum vulgare; type IIB; Reinders et al, 2012) restored phloem loading in an Arabidopsis Atsuc2–/– mutant when expressed from the companion cell-specific AtSUC2 promoter (AtSUC2p), showing that their biochemical activity in planta can replace that of AtSUC2. Ectopic expression of potato StSUT1 in the storage parenchyma of pea (Pisum sativum) cotyledons during seed development enhanced Suc influx and enhanced cotyledon growth rates (Rosche et al, 2002), and ectopic SUT expression in wheat (Triticum aestivum) grains increased levels of storage protein, indicating that enhanced Suc transport has benefits beyond carbohydrate accumulation (Weichert et al, 2010)
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