Involvement of programmed cell death in suppression of the number of root nodules formed in soybean induced by <i>Bradyrhizobium</i> infection

<p>Legumes establish symbiosis with nitrogen-fixing rhizobia through root nodules to acquire nitrogen. Legumes control nodule number through systemic (autoregulation of nodulation) as well as local regulation. Moreover, plants defend themselves against bacteria and other pathogens through the induction of localized (localized acquired resistance) and systemic (SAR, systemic acquired resistance; ISR, induced systemic resistance) responses. Herein, we show that the number of root nodules is suppressed by programmed cell death (PCD), and is simultaneously controlled by SAR and ISR in soybean (<i>Glycine max</i> [L.] Merr.). The wild-type soybean cultivar Williams 82 showed markedly fewer root nodule primordia and PCD symptoms, including accelerated DNA degradation, enhanced generation of reactive oxygen species (visualized by 3,3′-diaminobenzidine staining), and excessive cell death (detected on staining with trypan blue) compared to the hypernodulation mutant NOD1-3. These results suggest that PCD suppresses the formation of root nodules in wild-type soybean. In addition, microarray and gene ontology analyses showed that essential components of hypersensitive response (HR) or disease resistance, such as resistance (R) genes, mitogen-activated protein kinase cascade, SAR, salicylic acid, jasmonic acid, ethylene, etc., were activated in wild-type plants. These analyses corroborate the above findings, demonstrating that the suppression of root nodule formation by PCD is accompanied by HR, and is simultaneously controlled by SAR and ISR in soybean. These findings provide new insight into the control of nodulation to balance nutritional requirements and energy status in legumes.</p

Peribacteroid solution of soybean root nodules partly induces genomic loci for differentiation into bacteroids of free-living <i>Bradyrhizobium japonicum</i> cells

<div><p></p><p>In leguminous root nodules, rhizobia differentiate into morphology specific to symbiosis, called bacteroids. As bacteroids are surrounded with peribacteroid membranes filled with peribacteroid solution (PBS), it is considered that PBS contains substances inducing differentiation of rhizobia into bacteroids. In this study, genome-wide expression profiles of <i>Bradyrhizobium japonicum</i> cells cultured in PBS purified from root nodule of soybean (<i>Glycine max</i> L.) were compared with those of bacteroids using macroarray. PBS treatment preferentially induced regions in a large symbiosis island including various symbiosis relevant genes such as <i>nod, fix, nol</i> and <i>noe</i>, in which 75% of regions were commonly induced in bacteroids, while general repressions outside of the symbiosis island seen in bacteroids were not observed in PBS treated cells. The present results suggest that PBS contained some, but not all, substances inducing expression of the genes which are involved in differentiation into bacteroids.</p></div