| Literature DB >> 26790563 |
Aleksandr Gavrin1, David Chiasson2, Evgenia Ovchinnikova2, Brent N Kaiser2, Ton Bisseling1, Elena E Fedorova1.
Abstract
In root nodules rhizobia enter host cells via infection threads. The release of bacteria to a host cell is possible from cell wall-free regions of the infection thread. We hypothesized that the VAMP721d and VAMP721e exocytotic pathway, identified before in Medicago truncatula, has a role in the local modification of cell wall during the release of rhizobia. To clarify the role of VAMP721d and VAMP721e we used Glycine max, a plant with a determinate type of nodule. The localization of the main polysaccharide compounds of primary cell walls was analysed in control vs nodules with partially silenced GmVAMP721d. The silencing of GmVAMP721d blocked the release of rhizobia. Instead of rhizobia-containing membrane compartments - symbiosomes - the infected cells contained big clusters of bacteria embedded in a matrix of methyl-esterified and de-methyl-esterified pectin. These clusters were surrounded by a membrane. We found that GmVAMP721d-positive vesicles were not transporting methyl-esterified pectin. We hypothesized that they may deliver the enzymes involved in pectin turnover. Subsequently, we found that GmVAMP721d is partly co-localized with pectate lyase. Therefore, the biological role of VAMP721d may be explained by its action in delivering pectin-modifying enzymes to the site of release.Entities:
Keywords: endosymbiosis; exocytosis; intracellular infection; legume-rhizobia symbiosis; plant cell wall; soybean
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Year: 2016 PMID: 26790563 DOI: 10.1111/nph.13837
Source DB: PubMed Journal: New Phytol ISSN: 0028-646X Impact factor: 10.151