Ora Son

Induction of thioredoxin is required for nodule development to reduce reactive oxygen species levels in soybean roots.

Nodules are formed on legume roots as a result of signaling between symbiotic partners and in response to the activities of numerous genes. We cloned fragments of differentially expressed genes in spot-inoculated soybean (Glycine max) roots. Many of the induced clones were similar to known genes related to oxidative stress, such as thioredoxin and β-carotene hydroxylase. The deduced amino acid sequences of full-length soybean cDNAs for thioredoxin and β-carotene hydroxylase were similar to those in other species. In situ RNA hybridization revealed that the thioredoxin gene is expressed on the pericycle of 2-d-old nodules and in the infected cells of mature nodules, suggesting that thioredoxin is involved in nodule development. The thioredoxin promoter was found to contain a sequence resembling an antioxidant responsive element. When a thioredoxin mutant of yeast was transformed with the soybean thioredoxin gene it became hydrogen peroxide tolerant. These observations prompted us to measure reactive oxygen species levels. These were decreased by 3- to 5-fold in 7-d-old and 27-d-old nodules, coincident with increases in the expression of thioredoxin and β-carotene hydroxylase genes. Hydrogen peroxide-producing regions identified with cerium chloride were found in uninoculated roots and 2-d-old nodules, but not in 7-d-old and 27-d-old nodules. RNA interference-mediated repression of the thioredoxin gene severely impaired nodule development. These data indicate that antioxidants such as thioredoxin are essential to lower reactive oxygen species levels during nodule development.

ATHB12, an ABA-Inducible Homeodomain-Leucine Zipper (HD-Zip) Protein of Arabidopsis, Negatively Regulates the Growth of the Inflorescence Stem by Decreasing the Expression of a Gibberellin 20-Oxidase Gene

Arabidopsis thaliana homeobox 12 (ATHB12) is rapidly induced by ABA and water stress. A T-DNA insertion mutant of ATHB12 with a reduced level of ATHB12 expression in stems had longer inflorescence stems and reduced sensitivity to ABA during germination. A high level of transcripts of gibberellin 20-oxidase 1 (GA20ox1), a key enzyme in the synthesis of gibberellins, was detected in athb12 stems, while transgenic lines overexpressing ATHB12 (A12OX) had a reduced level of GA20ox1 in stems. Consistent with these data, ABA treatment of wild-type plants resulted in decreased GA20ox1 expression whereas ABA treatment of the athb12 mutant gave rise to slightly decreased GA20ox1 expression. Retarded stem growth in 3-week-old A12OX plants was rescued by exogenous GA(9), but not by GA(12), and less GA(9) was detected in A12OX stems than in wild-type stems. These data imply that ATHB12 decreases GA20ox1 expression in stems. On the other hand, the stems of A12OX plants grew rapidly after the first 3 weeks, so that they were almost as high as wild-type plants at about 5 weeks after germination. We also found changes in the stems of transgenic plants overexpressing ATHB12, such as alterations of expression GA20ox and GA3ox genes, and of GA(4) levels, which appear to result from feedback regulation. Repression of GA20ox1 by ATHB12 was confirmed by transfection of leaf protoplasts. ABA-treated protoplasts also showed increased ATHB12 expression and reduced GA20ox1 expression. These findings all suggest that ATHB12 negatively regulates the expression of a GA 20-oxidase gene in inflorescence stems.

Expression of srab7 and SCaM genes required for endocytosis of Rhizobium in root nodules

Symbiotic nitrogen fixation requires the internalization of rhizobia into root cells of legumes and subsequent formation of symbiosomes, rhizobia-containing organelles inside the plant cells. A small GTP-binding protein from soybean, sRab7, was shown to be essential for nodule development. When yeast ypt7 (Rab7) null mutant was transformed with the srab7 gene, highly fragmented vacuoles seen in the mutant were replaced with a prominent central vacuole, as in the wild-type cells. These results confirm that sRab7 is an authentic homolog of Ypt7p. When nodules obtained at different stages of development were hybridized with srab7 cDNA, 7-day-old nodules showed the most intense hybridization signal. Hybridization was only detected in the infection zone of forming nodules, implying that sRab7 may be involved in endocytosis of rhizobia. SCaM-1 and SCaM-4, soybean calmodulin genes, were also expressed in the same region at this stage of nodulation as shown by in situ hybridization. RT-PCR analysis confirmed the expression of these genes. These results indicate that both the srab7 and SCaM genes were expressed at an early stage of nodulation. Since membrane fusion of vesicles has been shown to be dependent on calmodulin and Ypt7p, the similarity of the expression patterns between the two genes in soybean nodules may indicate that sRab7 and SCaM are essential for vesicular fusion during rhizobial endocytosis and symbiosome formation.

Identification of nucleosome assembly protein 1 (NAP1) as an interacting partner of plant ribosomal protein S6 (RPS6) and a positive regulator of rDNA transcription

The ribosomal protein S6 (RPS6) is a downstream component of the signaling mediated by the target of rapamycin (TOR) kinase that acts as a central regulator of the key metabolic processes, such as protein translation and ribosome biogenesis, in response to various environmental cues. In our previous study, we identified a novel role of plant RPS6, which negatively regulates rDNA transcription, forming a complex with a plant-specific histone deacetylase, AtHD2B. Here we report that the Arabidopsis RPS6 interacts additionally with a histone chaperone, nucleosome assembly protein 1(AtNAP1;1). The interaction does not appear to preclude the association of RPS6 with AtHD2B, as the AtNAP1 was also able to interact with AtHD2B as well as with an RPS6-AtHD2B fusion protein in the BiFC assay and pulldown experiment. Similar to a positive effect of the ribosomal S6 kinase 1 (AtS6K1) on rDNA transcription observed in this study, overexpression or down regulation of the AtNAP1;1 resulted in concomitant increase and decrease, respectively, in rDNA transcription suggesting a positive regulatory role played by AtNAP1 in plant rDNA transcription, possibly through derepression of the negative effect of the RPS6-AtHD2B complex.

Identification of uricase as a potential target of plant thioredoxin: Implication in the regulation of nodule development

During symbiotic nodule development in legume roots, early signaling events between host and rhizobia serve critical determinants for the proper onset of nodule morphogenesis, nitrogen fixation, and assimilation. Previously we isolated thioredoxin from soybean nodules as one of differentially expressed genes during nodulation and noted its positive role in nitrogen fixation. To identify the target proteins of thioredoxin in nodules, we used thioredoxin affinity chromatography followed by mass spectrometry. Nodulin-35, a subunit of uricase, was found to be a target of thioredoxin. Their interaction was confirmed by pull-down assay and by bimolecular fluorescent complementation. With an increased uricase activity observed also in the presence of thioredoxin, these results appear to implicate a novel role of thioredoxin in the regulation of enzyme activities involved in nodule development and nitrogen fixation.

Identification of the Raptor-binding motif on Arabidopsis S6 kinase and its use as a TOR signaling suppressor

TOR (target of rapamycin) kinase signaling plays central role as a regulator of growth and proliferation in all eukaryotic cells and its key signaling components and effectors are also conserved in plants. Unlike the mammalian and yeast counterparts, however, we found through yeast two-hybrid analysis that multiple regions of the Arabidopsis Raptor (regulatory associated protein of TOR) are required for binding to its substrate. We also identified that a 44-amino acid region at the N-terminal end of Arabidopsis ribosomal S6 kinase 1 (AtS6K1) specifically interacted with AtRaptor1, indicating that this region may contain a functional equivalent of the TOS (TOR-Signaling) motif present in the mammalian TOR substrates. Transient over-expression of this 44-amino acid fragment in Arabidopsis protoplasts resulted in significant decrease in rDNA transcription, demonstrating a feasibility of developing a new plant-specific TOR signaling inhibitor based upon perturbation of the Raptor-substrate interaction.

Molecular details of the Raptor-binding motif on Arabidopsis S6 kinase

A putative raptor-binding fragment was identified from Arabidopsis S6 kinase 1 (AtS6K1) N-terminal domain in our previous study. Here, we report a further characterization of this fragment, which identified a 12-amino acid core element absolutely required for the interaction. Although the amino acid sequence of the element per se had no significant homology with the canonical consensus of the TOS (TOR-signaling) motif found in the mammalian TOR (target of rapamycin) kinase substrates, its overall sequence composition is similar to that of the TOS motif in that the acidic and non-polar amino acids residues are arranged in alternating fashion and having one or two of the bulky hydrophobic amino acid (F) buried in the interior. Substitution of this bulky residue completely abolished the binding of the fragment to AtRaptor1, as in the case of the mammalian TOS motif. Taken together with its position relative to the catalytic domain of the kinase, which also shows a resemblance with the TOS motif, these results appear to suggest that this core binding element in the N-terminus of AtS6K1 represents a plant version of the TOS motif.

Involvement of TOR signaling motif in the regulation of plant autophagy

In our previous studies, we have demonstrated that a stretch of amino-acid sequences identified from Arabidopsis ribosomal S6 kinase 1 (AtS6K1) provided a plant version of the TOS (TOR-signaling) motif, mediating the interaction with the Raptor protein in the TOR (Target of Rapamycin) kinase complex. Here we report the presence of same element in Arabidopsis Autophagy related-13 (AtATG13) protein, which is a key component of the plant autophagy response. Its composition is nearly identical to that found in the AtS6K1 in the five-amino-acid core sequence, and the presence of this five-amino-acid sequence was found to be essential for its interaction with the Raptor protein. A mutant AtATG13 protein lacking this five-amino-acid element conferred an elevated autophagy response and could not effectively phosphorylated by TOR kinase activity, demonstrating its role in mediating the TOR signaling to the components that carry it as a possible TOS motif. A ligand-binding simulation model using the MM-PBSA method indicates that both of the five-amino-acid sequence elements of AtS6K1 and AtATG13 have strong probability of making stable interface with the Raptor binding pocket, corroborating our proposition for this element as the plant TOS motif.