The Medicago truncatula Vacuolar iron Transporter-Like proteins VTL4 and VTL8 deliver iron to symbiotic bacteria at different stages of the infection process.

Jennifer H Walton,Gyöngyi Kontra-Kováts,Ágota Domonkos,Beatrix Horváth,Péter Kaló,Marina Franceschetti,Janneke Balk,Ella M Brear,Robert T Green

doi:10.1111/nph.16735

Abstract

Summary The symbiotic relationship between legumes and rhizobium bacteria in root nodules has a high demand for iron, and questions remain regarding which transporters are involved. Here, we characterize two nodule‐specific Vacuolar iron Transporter‐Like (VTL) proteins in Medicago truncatula.Localization of fluorescent fusion proteins and mutant studies were carried out to correlate with existing RNA‐seq data showing differential expression of VTL4 and VTL8 during early and late infection, respectively.The vtl4 insertion lines showed decreased nitrogen fixation capacity associated with more immature nodules and less elongated bacteroids. A mutant line lacking the tandemly‐arranged VTL4–VTL8 genes, named 13U, was unable to develop functional nodules and failed to fix nitrogen, which was almost fully restored by expression of VTL8 alone. Using a newly developed lux reporter to monitor iron status of the bacteroids, a moderate decrease in luminescence signal was observed in vtl4 mutant nodules and a strong decrease in 13U nodules. Iron transport capability of VTL4 and VTL8 was shown by yeast complementation.These data indicate that VTL8, the closest homologue of SEN1 in Lotus japonicus, is the main route for delivering iron to symbiotic rhizobia. We propose that a failure in iron protein maturation leads to early senescence of the bacteroids.

Highlights

Legumes and a small number of other plant species (Parasponia sp.) are able to form a symbiosis with rhizobium bacteria which enables the host plant to access N2 as a source of nitrogen
Localization of fluorescent fusion proteins and mutant studies were carried out to correlate with existing RNA-seq data showing differential expression of VTL4 and VTL8 during early and late infection, respectively
Vtl4 insertion lines showed decreased nitrogen fixation capacity associated with more immature nodules and less elongated bacteroids

Summary

Introduction

Legumes and a small number of other plant species (Parasponia sp.) are able to form a symbiosis with rhizobium bacteria which enables the host plant to access N2 as a source of nitrogen. The host plant provides carbohydrates derived from photosynthesis for the energydemanding reduction of N2 to ammonium, carried out by the bacterial nitrogenase enzyme. Root nodules have a high requirement for iron owing to abundant proteins that use iron as a cofactor. The bacterial nitrogenase enzyme (NifH + nifDK) binds 12 iron in the form of iron-sulphur clusters and another 7 in the Fe-Mo cofactor (Dean et al, 1993; Howard & Rees, 2006). The nitrogen-fixing bacteria contain numerous cytochromes and other iron proteins. When the plant is starved of iron, nodule initiation and further development is strongly impaired (O’Hara et al, 1988; Tang et al, 1990; Brear et al, 2013)

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