Expression of RSOsPR10 in rice roots is antagonistically regulated by jasmonate/ethylene and salicylic acid via the activator OsERF87 and the repressor OsWRKY76, respectively.

Plant roots play important roles in absorbing water and nutrients, and in tolerance against environmental stresses. Previously, we identified a rice root-specific pathogenesis-related protein (RSOsPR10) induced by drought, salt, and wounding. RSOsPR10 expression is strongly induced by jasmonate (JA)/ethylene (ET), but suppressed by salicylic acid (SA). Here, we analyzed the promoter activity of RSOsPR10. Analyses of transgenic rice lines harboring different-length promoter::ß-glucuronidase (GUS) constructs showed that the 3-kb promoter region is indispensable for JA/ET induction, SA repression, and root-specific expression. In the JA-treated 3K-promoter::GUS line, GUS activity was mainly observed at lateral root primordia. Transient expression in roots using a dual luciferase (LUC) assay with different-length promoter::LUC constructs demonstrated that the novel transcription factor OsERF87 induced 3K-promoter::LUC expression through binding to GCC-cis elements. In contrast, the SA-inducible OsWRKY76 transcription factor strongly repressed the JA-inducible and OsERF87-dependent expression of RSOsPR10. RSOsPR10 was expressed at lower levels in OsWRKY76-overexpressing rice, but at higher levels in OsWRKY76-knockout rice, compared with wild type. These results show that two transcription factors, OsERF87 and OsWRKY76, antagonistically regulate RSOsPR10 expression through binding to the same promoter. This mechanism represents a fine-tuning system to sense the balance between JA/ET and SA signaling in plants under environmental stress.

RSOsPR10 expression in response to environmental stresses is regulated antagonistically by jasmonate/ethylene and salicylic acid signaling pathways in rice roots.

Plant roots play important roles not only in the absorption of water and nutrients, but also in stress tolerance. Previously, we identified RSOsPR10 as a root-specific pathogenesis-related (PR) protein induced by drought and salt treatments in rice. Transcripts and proteins of RSOsPR10 were strongly induced by jasmonate (JA) and the ethylene (ET) precursor 1-aminocyclopropane-1-carboxylic acid (ACC), while salicylic acid (SA) almost completely suppressed these inductions. Immunohistochemical analyses showed that RSOsPR10 strongly accumulated in cortex cells surrounding the vascular system of roots, and this accumulation was also suppressed when SA was applied simultaneously with stress or hormone treatments. In the JA-deficient mutant hebiba, RSOsPR10 expression was up-regulated by NaCl, wounding, drought and exogenous application of JA. This suggested the involvement of a signal transduction pathway that integrates JA and ET signals in plant defense responses. Expression of OsERF1, a transcription factor in the JA/ET pathway, was induced earlier than that of RSOsPR10 after salt, JA and ACC treatments. Simultaneous SA treatment strongly inhibited the induction of RSOsPR10 expression and, to a lesser extent, induction of OsERF1 expression. These results suggest that JA/ET and SA pathways function in the stress-responsive induction of RSOsPR10, and that OsERF1 may be one of the transcriptional factors in the JA/ET pathway.

Structure and function of the shufflon in plasmid R64.

Conservative site-specific recombination plays key roles in creating biological diversity in prokaryotes. Most site-specific inversion systems consist of two recombination sites and a recombinase gene. In contrast, the shufflon multiple inversion system of plasmid R64 consists of seven sfx recombination sites, which separate four invertible DNA segments, and the rci gene encoding a site-specific recombinase of the integrase family. The rci product mediates recombination between any two inverted sfx sites, resulting in the inversion of four DNA segments independently or in groups. Random shufflon inversions construct seven pilV genes encoding constant N-terminal segment with different C-terminal segments. The pilV products are tip-located adhesins of the type IV pilus, called the thin pilus, of R64 and recognize lipopolysaccharides of recipient bacterial cells during R64 liquid matings. Thus, the shufflon determines the recipient specificity of liquid matings. Rci protein of R64 was overexpressed, purified, and used for in vitro recombination reactions. The cleavage and rejoining of DNA strands in shufflon recombinations were found to take place in the form of a 5' protruding 7-bp staggered cut within sfx sequences. Thus, the sfx sequence is asymmetric: only the 7-bp spacer sequence and the right arm sequence are conserved among various R64 sfxs, whereas the sfx left arm sequences are not conserved. Rci protein was shown to bind to entire sfx sequences, suggesting that it binds to the right arms of the sfx sequences in a sequence-specific manner and to their left arms in a non-sequence-specific manner. The sfx left arm sequences greatly affected the shufflon inversion frequency. The artificial symmetric sfx sequence, in which the sfx left arm was changed to the inverted repeat sequence of the right arm, exhibited the highest inversion frequency. Rci-dependent deletion of a DNA segment flanked by two symmetric sfx sequences in direct orientation was observed, suggesting that the asymmetry of sfx sequences may prevent recombination between sfx sequences in direct orientation in the R64 shufflon. The Rci C-terminal domain was not required for recombination using the symmetric sfx sequence. A model, where the C-terminal domain of Rci protein plays a key role in the sequence-specific and non-specific binding of Rci to asymmetric sfx sites, was proposed. Site-specific recombination in the temperate phage Mx8 of M. xanthus was also described. The Mx8 attP site is located within the coding sequence of the Mx8 intP gene. Therefore, the integration of Mx8 into the M. xanthus chromosome results in the conversion of the intP gene into a new gene, intR. As a result of this conversion, the 112-amino-acid C-terminal sequence of the intP product is replaced with a 13-amino acid sequence of the intR product. The C-terminal domain of Mx8 IntP recombinase is only required for integration and not for excision.