Kihira Miho, Taniguchi Kazushi, Kaneko Chihiro, Ishii Yohei, Aoki Hiromi, Koyanagi Atsushi, Kusano Hiroaki, Suzui Nobuo, Yin Yong-Gen, Kawachi Naoki, Fujimaki Shu, Shimada Hiroaki
Department of Biological Science and Technology, Tokyo University of Science, Niijuku 6-3-1, Katsushika, Tokyo, 125-8585 Japan.
Laboratory of Plant Gene Expression, Research Institute for Sustainable Humanosphere, Kyoto University, Gokasho, Ugi, 6110011, Japan.
Plant Cell Physiol. 2017 Mar 1;58(3):440-450. doi: 10.1093/pcp/pcw217.
FLO2, FLOURY ENDOSPERM 2, is highly conserved in higher plants, and rice FLO2 has been predicted to be involved in regulation of accumulation of storage compounds. We analyzed the function of Arabidopsis thaliana FLO2 (AtFLO2) because A. thaliana set structurally different seeds from those of rice. Although the flo2 mutant of A. thaliana showed normal germination, inflorescence and morphogenesis of flowers, peculiar phenotypes on leaves and siliques were observed, suggesting that this gene played important roles during both the vegetative and reproductive stages. The mutant leaves showed a decrease in chloroplast numbers, and increased total biomass with faster growth. When grown in high light intensity conditions, it was observed that aging events were induced. The flo2 mutant showed depressed transportation of photoassimilates into the sink organs. In the reproductive stage, the flo2 mutant had significantly smaller size siliques, causing a reduced yield of seeds. These seeds were structurally weak, and the quality of seeds was significantly lowered, with reduction of accumulation of storage compounds by seeds. A positron-emitting tracer imaging system (PETIS) analysis detected a decreased amount of photoassimilate transport in the flo2 mutant. Therefore, it was presumed that the phenotypes of the flo2 mutant were caused by reduced performance of translocation or transportation of the photoassimilates. Our observation suggests that AtFLO2 is strongly involved in regulation of translocation and transport of assimilates, and contributes greatly to quality control of the various processes involving substance supply or transfer, such as photoassimilation, leaf enlargement, yield of seeds in a silique and accumulation of seed storage compounds.
FLO2,即粉质胚乳2,在高等植物中高度保守,据预测水稻FLO2参与储存化合物积累的调控。我们分析了拟南芥FLO2(AtFLO2)的功能,因为拟南芥种子的结构与水稻种子不同。虽然拟南芥flo2突变体表现出正常的萌发、花序和花的形态发生,但在叶片和角果上观察到了特殊表型,这表明该基因在营养生长和生殖生长阶段均发挥重要作用。突变体叶片的叶绿体数量减少,总生物量增加且生长更快。在高光强条件下生长时,观察到衰老事件被诱导。flo2突变体显示光合产物向库器官的转运受到抑制。在生殖阶段,flo2突变体的角果明显较小,导致种子产量降低。这些种子结构脆弱,种子质量显著下降,种子储存化合物的积累减少。正电子发射示踪成像系统(PETIS)分析检测到flo2突变体中光合产物运输量减少。因此,推测flo2突变体的表型是由光合产物转运或运输性能降低所致。我们的观察表明,AtFLO2强烈参与同化物的转运调控,并对涉及物质供应或转移的各种过程的质量控制有很大贡献,如光同化、叶片扩大、角果种子产量和种子储存化合物的积累。
