Abstract
Several aspects of the legume–rhizobia symbiosis are far from being completely understood, such as the transport of compounds through the symbiosome membrane and the molecular actors (receptors, transcription factors and hormones) involved in the systemic regulation of nodulation. In this work, the transcriptomes of L. japonicus plants growing under symbiotic or non-symbiotic conditions were studied in roots and shoots, in order to look for new genes involved in nodule function and regulation both at the local and systemic levels. Several of the genes differentially expressed in roots were well-known nodulins; however, other genes with unknown function were also discovered that showed univocal nodule-specific expression profiles. Transporters of the Nitrate Transporter1/Peptide Transporter Family family, putative oligopeptide transporters, as well as other uncharacterized transporters were upregulated in nodulated roots. Five transcription factors, as well as receptors/kinases and an f-box domain containing protein, all of unknown function, were also more upregulated in nodulated roots. In the shoots of nodulated plants, genes involved in jasmonic acid and indole-3-acetic acid metabolism were differentially expressed. Moreover, three genes encoding for different glutaredoxins, proteins that were recently involved in the systemic signaling of the Arabidopsis nitrogen status, were highly downregulated in the leaves of nodulated plants. Protein–protein interaction network analysis identified nitrate reductase as a central hub in nitrogen metabolism, and a putative protein of the NADH-ubiquinone complex was highly connected to several SWEET transporters. Clustering analysis of the differentially expressed genes also suggested a possible role for a previously uncharacterized ethylene-responsive transcription factor and for LBD38 homologs in L. japonicus nodule function. The new genes identified in this study represent a promising target for the understating and manipulation of symbiotic nitrogen fixation, with the aim of improving crop legumes’ productivity.
Highlights
Characterizing all the genes and proteins involved in legume–rhizobia symbiosis is of great importance in order to find targets for crop yield improvement through enhancing symbiotic nitrogen fixation (SNF) [1,2]
Lots of efforts have been made in order to identify the genes that compose the transcriptional network involved in nodule organogenesis [7], and it was found that this network shares several common symbiosis genes with the network responsible for the symbiosis with arbuscular mycorrhiza (AM) [8,9]
Different uncharacterized transporters, transcription factors and receptors/kinases were identified; while, in the shoot, genes involved in hormone metabolism and redox metabolism were differentially expressed
Summary
Characterizing all the genes and proteins involved in legume–rhizobia symbiosis is of great importance in order to find targets for crop yield improvement through enhancing symbiotic nitrogen fixation (SNF) [1,2]. Substantial advances in this field have been obtained thanks to the use of two model legumes: Lotus japonicus and Medicago truncatula [1,3,4]. The transporters present in this membrane control the flux of nutrients from the plant to the bacteria and vice versa, representing interesting targets for the enhancement of SNF in crop and pasture legumes. Work using biochemical assays and proteomic approaches have demonstrated the existence of several SM transporters; the genes that encode for several of them are still unidentified, including several key transporters for carbon and nitrogen metabolites [1,10]
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