Nitrate assimilation in the forage legume Lotus japonicus L.

Nitrate assimilation in the model legume, Lotus japonicus, has been investigated using a variety of approaches. A gene encoding a nitrate-inducible nitrate reductase (NR) has been cloned and appears to be the only NR gene present in the genome. Most of the nitrate reductase activity (NRA) is found in the roots and the plant assimilates the bulk of its nitrogen in that tissue. We calculate that the observed rates of nitrate reduction are compatible with the growth requirement for reduced nitrogen. The NR mRNA, NRA and the nitrate content do not show a strong diurnal rhythm in the roots and assimilation continues during the dark period although export of assimilated N to the shoot is lower during this time. In shoots, the previous low NR activity may be further inactivated during the dark either by a phosphorylation mechanism or due to reduced nitrate flux coincident with a decreased delivery through the transpiration stream. From nitrate-sufficient conditions, the removal of nitrate from the external medium causes a rapid drop in hydraulic conductivity and a decline in nitrate and reduced-N export. Root nitrate content, NR and nitrate transporter (NRT2) mRNA decline over a period of 2 days to barely detectable levels. On resupply, a coordinated increase of NR and NRT2 mRNA, and NRA is seen within hours.

Dimerization properties of TraM, the antiactivator that modulates TraR-mediated quorum-dependent expression of the Ti plasmid tra genes.

TraM, an 11.2 kDa antiactivator, modulates the acyl-homoserine lactone-mediated autoinduction of Ti plasmid conjugative transfer by interacting directly with TraR, the quorum-sensing transcriptional activator. Most antiactivators and antisigma factors examined to date act in dimer form. However, whether, and if so, how TraM dimerizes is unknown. Analyses based on a genetic assay using fusions of TraM to the lambda cI DNA binding domain, and biochemical assays using chemical crosslinking and gel filtration chromatography showed that TraM forms homodimers. Although SDS-PAGE studies suggested that the lone cysteine residue at position 71 was involved in interprotomer disulfide-bridging in TraM, altering Cys-71 to a serine did not significantly affect dimerization or the antiactivator activity of this mutant protein when expressed at wild-type levels in vivo. Analysis of N-terminal, C-terminal, and internal deletion mutants of TraM identified two regions of the protein involved in dimerization; one located within a segment between residues 20 and 50, and the other located to a segment between residues 67 and 96. Both regions are required for formation of fully stable dimers. Analysis of the activity of these deletion mutants in vivo, and their ability to bind TraR and to disrupt TraR-DNA complexes in vitro, suggests that while the internal segment of the protein is required for dimerization, determinants located at the far C-terminus and beginning at between residues 10 and 20 at the N-terminus play a role in TraR binding and antiactivator function. When co-expressed with lambda cI'::TraR fusions, wild-type TraM mediated quormone-independent dimerization of the transcriptional activator, suggesting that dimers of TraM can multimerize TraR.

Mutational analysis of TraR. Correlating function with molecular structure of a quorum-sensing transcriptional activator.

TraR, the quorum-sensing activator of the Agrobacterium tumefaciens Ti plasmid conjugation system, induces gene expression in response to its quormone, N-(3-oxooctanoyl)-L-homoserine lactone. Ligand binding results in dimerization of TraR and is required for its activity. Analysis of N- and C-terminal deletion mutants of TraR localized the quormone-binding domain to a region between residues 39 and 140 and the primary dimerization domain to a region between residues 119 and 156. The dominant-negative properties of these mutants predicted a second dimerization domain at the C terminus of the protein. Analysis of fusions of N-terminal fragments of TraR to lambda cI' confirmed the dimerization activity of these two domains. Fifteen single amino acid substitution mutants of TraR defective in dimerization were isolated. According to the analysis of these mutants, Asp-70 and Gly-113 are essential for quormone binding, whereas Ala-38 and Ala-105 are important, but not essential. Additional residues located within the N-terminal half of TraR, including three located in alpha-helix 9, contribute to dimerization, but are not required for ligand binding. These results and the recently reported crystal structure of TraR are consistent with and complement each other and together define some of the structural and functional relationships of this quorum-sensing activator.