Wang Hui, Niu Lifang, Fu Chunxiang, Meng Yingying, Sang Dajun, Yin Pengcheng, Wu Jinxia, Tang Yuhong, Lu Tiegang, Wang Zeng-Yu, Tadege Million, Lin Hao
Biotechnology Research Institute, Chinese Academy of Agricultural Sciences, Beijing, China.
Department of Plant and Soil Sciences, Institute for Agricultural Biosciences, Oklahoma State University, 3210 Sam Noble Parkway, Ardmore, OK, United States of America.
PLoS Genet. 2017 Mar 6;13(3):e1006649. doi: 10.1371/journal.pgen.1006649. eCollection 2017 Mar.
Lignocellulosic biomass can be a significant source of renewable clean energy with continued improvement in biomass yield and bioconversion strategies. In higher plants, the leaf blade is the central energy convertor where solar energy and CO2 are assimilated to make the building blocks for biomass production. Here we report that introducing the leaf blade development regulator STENOFOLIA (STF), a WOX family transcription factor, into the biofuel crop switchgrass, significantly improves both biomass yield and sugar release. We found that STF overexpressing switchgrass plants produced approximately 2-fold more dry biomass and release approximately 1.8-fold more solubilized sugars without pretreatment compared to controls. The biomass increase was attributed mainly to increased leaf width and stem thickness, which was also consistent in STF transgenic rice and Brachypodium, and appeared to be caused by enhanced cell proliferation. STF directly binds to multiple regions in the promoters of some cytokinin oxidase/dehydrogenase (CKX) genes and represses their expression in all three transgenic grasses. This repression was accompanied by a significant increase in active cytokinin content in transgenic rice leaves, suggesting that the increase in biomass productivity and sugar release could at least in part be associated with improved cytokinin levels caused by repression of cytokinin degrading enzymes. Our study provides a new tool for improving biomass feedstock yield in bioenergy crops, and uncovers a novel mechanistic insight in the function of STF, which may also apply to other repressive WOX genes that are master regulators of several key plant developmental programs.
随着生物质产量和生物转化策略的不断改进,木质纤维素生物质可以成为可再生清洁能源的重要来源。在高等植物中,叶片是核心能量转换器,太阳能和二氧化碳在此被同化,以制造生物质生产的基础物质。在此,我们报告称,将叶片发育调节因子窄叶(STENOFOLIA,STF)——一种WOX家族转录因子——导入生物燃料作物柳枝稷中,可显著提高生物质产量和糖释放量。我们发现,与对照相比,过表达STF的柳枝稷植株产生的干生物量增加了约2倍,未经预处理时释放的可溶性糖增加了约1.8倍。生物量的增加主要归因于叶片宽度和茎粗的增加,这在STF转基因水稻和短柄草中也一致,并且似乎是由细胞增殖增强引起的。STF直接结合到一些细胞分裂素氧化酶/脱氢酶(CKX)基因启动子的多个区域,并在所有三种转基因禾本科植物中抑制它们的表达。这种抑制伴随着转基因水稻叶片中活性细胞分裂素含量的显著增加,这表明生物质生产力和糖释放量的增加至少部分可能与细胞分裂素降解酶的抑制导致的细胞分裂素水平改善有关。我们的研究为提高生物能源作物的生物质原料产量提供了一种新工具,并揭示了STF功能的一种新的机制性见解,这也可能适用于其他作为几个关键植物发育程序主要调节因子的抑制性WOX基因。
