Your search keyword '"Kikuchi, Yusuke"' showing total 2 results

1. Aquaporin-mediated long-distance polyphosphate translocation directed towards the host in arbuscular mycorrhizal symbiosis: application of virus-induced gene silencing.

Author

Kikuchi Y, Hijikata N, Ohtomo R, Handa Y, Kawaguchi M, Saito K, Masuta C, and Ezawa T

Subjects

Aquaporins genetics, Biological Transport, Gene Knockdown Techniques, Genes, Fungal, Glomeromycota genetics, Glomeromycota physiology, Models, Biological, Mycelium metabolism, Phylogeny, Plant Transpiration physiology, Aquaporins metabolism, Gene Silencing, Lotus microbiology, Mycorrhizae physiology, Plant Viruses metabolism, Polyphosphates metabolism, Symbiosis, Nicotiana microbiology

Abstract

Arbuscular mycorrhizal fungi translocate polyphosphate through hyphae over a long distance to deliver to the host. More than three decades ago, suppression of host transpiration was found to decelerate phosphate delivery of the fungal symbiont, leading us to hypothesize that transpiration provides a primary driving force for polyphosphate translocation, probably via creating hyphal water flow in which fungal aquaporin(s) may be involved. The impact of transpiration suppression on polyphosphate translocation through hyphae of Rhizophagus clarus was evaluated. An aquaporin gene expressed in intraradical mycelia was characterized and knocked down by virus-induced gene silencing to investigate the involvement of the gene in polyphosphate translocation. Rhizophagus clarus aquaporin 3 (RcAQP3) that was most highly expressed in intraradical mycelia encodes an aquaglyceroporin responsible for water transport across the plasma membrane. Knockdown of RcAQP3 as well as the suppression of host transpiration decelerated polyphosphate translocation in proportion to the levels of knockdown and suppression, respectively. These results provide the first insight into the mechanism underlying long-distance polyphosphate translocation in mycorrhizal associations at the molecular level, in which host transpiration and the fungal aquaporin play key roles. A hypothetical model of the translocation is proposed for further elucidation of the mechanism., (© 2016 The Authors. New Phytologist © 2016 New Phytologist Trust.)

Published

2016

2. Polyphosphate accumulation is driven by transcriptome alterations that lead to near-synchronous and near-equivalent uptake of inorganic cations in an arbuscular mycorrhizal fungus

Author

Kikuchi, Yusuke, Hijikata, Nowaki, Yokoyama, Kaede, Ohtomo, Ryo, Handa, Yoshihiro, Kawaguchi, Masayoshi, Saito, Katsuharu, and Ezawa, Tatsuhiro

Subjects

arbuscular mycorrhizal (AM) fungi, polyphosphate, inorganic cation, transcriptome, symbiosis

Abstract

・Arbuscular mycorrhizal (AM) fungi accumulate a massive amount of phosphate as polyphosphate to deliver to the host, but the physiological and molecular mechanisms underlying have yet to be elucidated. In the present study, the dynamics of cationic components during polyphosphate accumulation were investigated in conjunction with transcriptome analysis. ・Rhizophagus sp. HR1 was grown with Lotus japonicus under phosphorus-deficient conditions, and extraradical mycelia were harvested after phosphate application at prescribed intervals. Levels of polyphosphate, inorganic cations, and amino acids were measured, and RNA-Seq was performed on the Illumina platform. ・Phosphate application triggered not only polyphosphate accumulation but also near-synchronous and -equivalent uptake of Na+, K+, Ca2+, and Mg2+, whereas no distinct changes in the levels of amino acids were observed. During polyphosphate accumulation, genes responsible for mineral uptake, phosphate and nitrogen metabolisms, and maintenance of cellular homeostasis were up-regulated. ・The results suggest that the inorganic cations play a major role in neutralizing negative charge of polyphosphate, and these processes are achieved by the orchestrated regulation of gene expression. Our findings for the first time provide a global picture of the cellular responses to increased phosphate availability, which is the initial process of nutrient delivery in the associations.

Published

2014