Li Mi, Pu Yunqiao, Yoo Chang Geun, Gjersing Erica, Decker Stephen R, Doeppke Crissa, Shollenberger Todd, Tschaplinski Timothy J, Engle Nancy L, Sykes Robert W, Davis Mark F, Baxter Holly L, Mazarei Mitra, Fu Chunxiang, Dixon Richard A, Wang Zeng-Yu, Neal Stewart C, Ragauskas Arthur J
BioEnergy Science Center (BESC), Oak Ridge National Laboratory (ORNL), Oak Ridge, TN USA ; BioSciences Division, ORNL, Oak Ridge, TN USA ; UT-ORNL Joint Institute for Biological Sciences, Oak Ridge, TN USA.
Biosciences Center, National Renewable Energy Laboratory (NREL), Golden, CO USA.
Biotechnol Biofuels. 2017 Jan 3;10:12. doi: 10.1186/s13068-016-0695-7. eCollection 2017.
The native recalcitrance of plants hinders the biomass conversion process using current biorefinery techniques. Down-regulation of the caffeic acid -methyltransferase () gene in the lignin biosynthesis pathway of switchgrass reduced the thermochemical and biochemical conversion recalcitrance of biomass. Due to potential environmental influences on lignin biosynthesis and deposition, studying the consequences of physicochemical changes in field-grown plants without pretreatment is essential to evaluate the performance of lignin-altered plants. We determined the chemical composition, cellulose crystallinity and the degree of its polymerization, molecular weight of hemicellulose, and cellulose accessibility of cell walls in order to better understand the fundamental features of why biomass is recalcitrant to conversion without pretreatment. The most important is to investigate whether traits and features are stable in the dynamics of field environmental effects over multiple years.
Field-grown down-regulated plants maintained both reduced cell wall recalcitrance and lignin content compared with the non-transgenic controls for at least 3 seasons. The transgenic switchgrass yielded 35-84% higher total sugar release (enzymatic digestibility or saccharification) from a 72-h enzymatic hydrolysis without pretreatment and also had a 25-32% increase in enzymatic sugar release after hydrothermal pretreatment. The -silenced switchgrass lines had consistently lower lignin content, e.g., 12 and 14% reduction for year 2 and year 3 growing season, respectively, than the control plants. By contrast, the transgenic lines had 7-8% more xylan and galactan contents than the wild-type controls. Gel permeation chromatographic results revealed that the weight-average molecular weights of hemicellulose were 7-11% lower in the transgenic than in the control lines. In addition, we found that silencing of in switchgrass led to 20-22% increased cellulose accessibility as measured by the Simons' stain protocol. No significant changes were observed on the arabinan and glucan contents, cellulose crystallinity, and cellulose degree of polymerization between the transgenic and control plants. With the 2-year comparative analysis, both the control and transgenic lines had significant increases in lignin and glucan contents and hemicellulose molecular weight across the growing seasons.
The down-regulation of in switchgrass resulting in a reduced lignin content and biomass recalcitrance is stable in a field-grown trial for at least three seasons. Among the determined affecting factors, the reduced biomass recalcitrance of the -silenced switchgrass, grown in the field conditions for two and three seasons, was likely related to the decreased lignin content and increased biomass accessibility, whereas the cellulose crystallinity and degree of its polymerization and hemicellulose molecular weights did not contribute to the reduction of recalcitrance significantly. This finding suggests that lignin down-regulation in lignocellulosic feedstock confers improved saccharification that translates from greenhouse to field trial and that lignin content and biomass accessibility are two significant factors for developing a reduced recalcitrance feedstock by genetic modification.
植物本身的难降解性阻碍了利用当前生物炼制技术进行生物质转化的过程。下调柳枝稷木质素生物合成途径中的咖啡酸 - 甲基转移酶()基因可降低生物质的热化学和生物化学转化难降解性。由于潜在环境对木质素生物合成和沉积的影响,研究未经预处理的田间种植植物中物理化学变化的后果对于评估木质素改变植物的性能至关重要。我们测定了化学成分、纤维素结晶度及其聚合度、半纤维素分子量和细胞壁的纤维素可及性,以便更好地理解生物质未经预处理就难以转化的基本特征。最重要的是研究在多年的田间环境影响动态中,这些特性和特征是否稳定。
与非转基因对照相比,田间种植的下调植物在至少3个生长季中均保持了细胞壁难降解性降低和木质素含量降低的特性。未经预处理进行72小时酶水解后,转基因柳枝稷的总糖释放量(酶解消化率或糖化率)提高了35 - 84%,水热预处理后酶促糖释放量也增加了25 - 32%。沉默的柳枝稷品系的木质素含量始终低于对照植物,例如在第2年和第3年生长季分别降低了12%和14%。相比之下,转基因品系的木聚糖和半乳聚糖含量比野生型对照高7 - 8%。凝胶渗透色谱结果显示,转基因品系中半纤维素的重均分子量比对照品系低7 - 11%。此外,我们发现,通过西蒙斯染色法测定,柳枝稷中基因的沉默导致纤维素可及性提高了20 - 22%。转基因植物和对照植物之间的阿拉伯聚糖和葡聚糖含量、纤维素结晶度以及纤维素聚合度均未观察到显著变化。通过两年的比较分析,对照品系和转基因品系在整个生长季中木质素和葡聚糖含量以及半纤维素分子量均有显著增加。
柳枝稷中基因的下调导致木质素含量降低和生物质难降解性降低这一现象在田间种植试验中至少三个生长季内是稳定的。在已确定的影响因素中,在田间条件下生长两季和三季的沉默柳枝稷生物质难降解性降低可能与木质素含量降低和生物质可及性增加有关,而纤维素结晶度及其聚合度以及半纤维素分子量对难降解性降低的贡献不显著。这一发现表明,木质纤维素原料中木质素的下调可提高糖化率,这一结果从温室试验转化到了田间试验,并且木质素含量和生物质可及性是通过基因改造开发低难降解性原料的两个重要因素。
