Priming of seeds with INA and its transgenerational effect in common bean (Phaseolus vulgaris L.) plants.

Priming is a mechanism of defense that prepares the plant's immune system for a faster and/or stronger activation of cellular defenses against future exposure to different types of stress. This enhanced resistance can be achieved by using inorganic and organic compounds which imitate the biological induction of systemic acquired resistance. INA (2,6 dichloro-isonicotinic acid) was the first synthetic compound created as a resistance inducer for plant-pathogen interactions. However, the use of INA to activate primed resistance in common bean, at the seed stage and during germination, remains experimentally unexplored. Here, we test the hypothesis that INA-seed treatment would induce resistance in common bean plants to Pseudomonas syringae pv. phaseolicola, and that the increased resistance is not accompanied by a tradeoff between plant defense and growth. Additionally, it was hypothesized that treating seeds with INA has a transgenerational priming effect. We provide evidence that seed treatment activates a primed state for disease resistance, in which low nucleosome enrichment and reduced histone activation marks during the priming phase, are associated with a defense-resistant phenotype, characterized by symptom appearance, pathogen accumulation, yield, and changes in gene expression. In addition, the priming status for induced resistance can be inherited to its offspring.

Down-regulation of PvTRX1h increases nodule number and affects auxin, starch, and metabolic fingerprints in the common bean (Phaseolus vulgaris L.).

The legume-rhizobium symbiotic relationship has been widely studied and characterized. However, little information is available about the role of histone lysine methyltransferases in the legume-rhizobium interaction and in the formation of nitrogen-fixing nodules in the common bean. Thus, this study aimed to gain a better understanding of the epigenetic control of nodulation in the common bean. Specifically, we studied the role of PvTRX1h, a histone lysine methyltransferase coding gene, in nodule development and auxin biosynthesis. Through a reverse genetics approach, we generated common bean composite plants to knock-down PvTRX1h expression. Here we found that the down-regulation of PvTRX1h increased the number of nodules per plant, but reduced the number of colony-forming units recovered from nodules. Genes coding for enzymes involved in the synthesis of the indole-3-acetic acid were up-regulated, as was the concentration of this hormone. In addition, PvTRX1h down-regulation altered starch accumulation as determined by the number of amyloplasts per nodule. Metabolic fingerprinting by direct liquid introduction-electrospray ionization-mass spectrometry (DLI-ESI-MS) revealed that the root nodules were globally affected by PvTRX1h down-regulation. Therefore, PvTRX1h likely acts through chromatin histone modifications that alter the auxin signaling network to determine bacterial colonization, nodule number, starch accumulation, hormone levels, and cell proliferation.

Use of BABA and INA As Activators of a Primed State in the Common Bean (Phaseolus vulgaris L.).

To survive in adverse conditions, plants have evolved complex mechanisms that "prime" their defense system to respond and adapt to stresses. Their competence to respond to such stresses fundamentally depends on its capacity to modulate the transcriptome rapidly and specifically. Thus, chromatin dynamics is a mechanism linked to transcriptional regulation and enhanced defense in plants. For example, in Arabidopsis, priming of the SA-dependent defense pathway is linked to histone lysine methylation. Such modifications could create a memory of the primary infection that is associated with an amplified gene response upon exposure to a second stress-stimulus. In addition, the priming status of a plant for induced resistance can be inherited to its offspring. However, analyses on the molecular mechanisms of generational and transgenerational priming in the common bean (Phaseolus vulagris L.), an economically important crop, are absent. Here, we provide evidence that resistance to P. syringae pv. phaseolicola infection was induced in the common bean with the synthetic priming activators BABA and INA. Resistance was assessed by evaluating symptom appearance, pathogen accumulation, changes in gene expression of defense genes, as well as changes in the H3K4me3 and H3K36me3 marks at the promoter-exon regions of defense-associated genes. We conclude that defense priming in the common bean occurred in response to BABA and INA and that these synthetic activators primed distinct genes for enhanced disease resistance. We hope that an understanding of the molecular changes leading to defense priming and pathogen resistance will provide valuable knowledge for producing disease-resistant crop varieties by exposing parental plants to priming activators, as well as to the development of novel plant protection chemicals that stimulate the plant's inherent disease resistance mechanisms.