Liu Yanrong, Yan Jianping, Wang Kexin, Li Dayong, Han Yejun, Zhang Wanjun
1College of Biological Science, China Agricultural University, Beijing, 100193 People's Republic of China.
2College of Grassland Science and Technology, China Agricultural University, Beijing, 100193 People's Republic of China.
Biotechnol Biofuels. 2020 Mar 19;13:56. doi: 10.1186/s13068-020-01693-0. eCollection 2020.
Switchgrass ( L.), a C perennial grass, has been recognized as one of the most potentially important lignocellulose biofuel crops. MicroRNA319 (miR319) plays a key role in plant development, abiotic resistance, and cell wall biosynthesis by repressing expression of its target genes. We hypothesized miR319- pathway could play important roles in switchgrass feedstock characteristics for biofuel production, and produced switchgrass transgenic plants overexpressing miR319 (by ectopic expressing - gene), blocking miR319 (by overexpressing a target mimicry of miR319/) and repression of miR319 target gene . Plant phenotype, biomass yield, and feedstock quality of transgenic plants were analyzed.
Overexpression of miR319 in switchgrass promoted leaf elongation and expansion of transgenic plants, increased plant height, stem diameter, and resulted in a significant increase in plant biomass yield. Transgenic plants overexpressing of miR319 reduced lignin content, showed significantly higher enzymatic hydrolysis efficiency compared to the wild type plant. However, opposite results were observed in the plants. Furthermore, suppression of miR319 target gene activity also reduced lignin content, increased lignin monomer S/G ratio and the proportion of β--4 linkages, while significantly improving the sugar production per plant. Quantitative real-time (qRT-PCR) analysis indicated that expression of and with predicted TCP binding sites in their promoter regions was negatively regulated by miR319- module.
MiR319- module plays positive roles in regulating biomass yield and quality of switchgrass. It can be utilized as a candidate molecular tool in regulating biomass yield and feedstock quality. The finding could also be transferred to other grasses for forage quality improvement through genetic manipulation.
柳枝稷(Panicum virgatum L.)是一种C4多年生草本植物,被认为是最具潜在重要性的木质纤维素生物燃料作物之一。微小RNA319(miR319)通过抑制其靶基因的表达,在植物发育、非生物抗性和细胞壁生物合成中发挥关键作用。我们推测miR319通路可能在柳枝稷用于生物燃料生产的原料特性方面发挥重要作用,并培育了过表达miR319(通过异位表达MIM164基因)、阻断miR319(通过过表达miR319的靶标模拟物MIM319)和抑制miR319靶基因TCP2的柳枝稷转基因植株。对转基因植株的植物表型、生物量产量和原料质量进行了分析。
柳枝稷中miR319的过表达促进了转基因植株叶片的伸长和扩展,增加了株高、茎直径,并导致植物生物量产量显著增加。过表达miR319的转基因植株木质素含量降低,与野生型植株相比,酶解效率显著更高。然而,在MIM319植株中观察到相反的结果。此外,抑制miR319靶基因TCP2的活性也降低了木质素含量,增加了木质素单体S/G比和β-O-4连接的比例,同时显著提高了单株糖产量。定量实时(qRT-PCR)分析表明,在其启动子区域具有预测TCP结合位点的TCP2和TCP4的表达受miR319-MIM164模块负调控。
MiR319-MIM164模块在调节柳枝稷生物量产量和质量方面发挥积极作用。它可作为调节生物量产量和原料质量的候选分子工具。这一发现也可通过基因操作转移到其他禾本科植物以改善饲料质量。
