木质纤维素生物质水解产物经真核菌转化为聚羟基丁酸生物聚合物

Nausheen Jaffur, P. Jeetah, Gopalakrishnan Kumar
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引用次数: 0

摘要

目前,由于环境可持续性意识的提高以及世界范围内严格法规的实施,现代世界正在发生一种猖獗的文化转变,逐步取代化石衍生塑料,转向对环境有益的新型生物材料。聚羟基烷酸酯(PHAs)是一种具有生物相容性、可生物降解性、无毒性和环保性的细胞内生物可降解聚合物,在制药、医疗、纺织、材料、燃料、农业等领域具有广泛的应用前景。然而,尽管PHA具有巨大的市场潜力,但其商业增长仅在很小程度上实现,因为该产品的成本效益非常值得商榷,因为加工碳基质的生产成本很高。这项研究的目的是探索从低价值的木质纤维素材料中开发低成本碳底物的可能性,否则这些材料将被作为废物丢弃,并给垃圾填埋场增加压力,以制造日常生活中使用的生物聚合物化合物,以及提高PHA底物的功能和葡萄糖的产量,从而可以进行工业升级。将木质纤维素生物质转化为可发酵糖的主要挑战之一是纤维的顽固性,这使得它非常抵抗糖的发酵释放。由于木质纤维素生物质具有特定的属性,例如极其协调的基质,这使得它由于生物降解而非常抵抗糖的发酵释放,因此在水解阶段转化可发酵糖之前,预处理阶段是必要的。本研究的重点是通过酶和微生物活动等可持续方法从木质纤维素生物质中合成生物聚合物,以检验其作为传统聚合物替代品的可行性。在30℃条件下培养具有8×108 CFU/ml活菌落的Cupriavidus Necator H16 (Ralstonia Eutropha),以Furcraea Foetida的1%还原糖为碳源,接种于M9低盐培养基中深层发酵。PHB在潜水培养中分批发酵,停留时间从0到48小时,使干细胞重量从0.32±0.05%增加到1.62±0.05%。48h后达到限氮期,从3ml发酵液中提取17.05±0.35%的PHB。PHB的产率明显低于文献报道的最优产率37.55% ~ 97.80%。尽管如此,傅里叶变换红外光谱(FTIR)揭示了生物聚合物中羰基、甲基和酯基以及分子间氢键的特征波段。苏丹黑B和FTIR光谱表明,PHB生物合成成功地以木质纤维素生物质(LCB)的纤维素为碳源在真核Ralstonia Eutropha细胞内进行了生物积累。因此,需要根据接种量、接种量、孵育时间和盐培养基条件等变量对该过程进行优化,以最大限度地提高Ralstonia Eutropha培养中Furcraea Foetida PHB的产量。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Biotransformation of Lignocellulosic Biomass Hydrolysate into Polyhydroxybutyrate Biopolymer via Ralstonia Eutropha
Currently, a rampant cultural shift is occurring in the modern world to progressively substitute fossil-derived plastics and shift to novel biomaterials that are benign to the environment owing to increased awareness of environmental sustainability along with the implementation of strict regulations worldwide. Polyhydroxyalkanoates (PHAs) are promising intracellular biodegradable polymers that have attracted considerable focus owing to their biocompatibility, biodegradability, non-toxicity and environment-friendly nature to function in diverse applications notably in the pharmaceutical, medical, textile, materials, fuel, agricultural industries. Nonetheless, despite its huge market potential, the commercial growth of PHA is achieved on a small extent only, since the cost-effectiveness of this product is highly debatable owing to the high production cost of processing the carbon substrate. The goal behind this research study is to explore the possibility of exploiting low-cost carbon substrates from low-value lignocellulosic materials that would have otherwise been discarded as waste and add stress to the landfill to manufacture biopolymer compounds that are used in everyday lives as well as to enhance the functionality and yields of glucose from PHA substrates that can undergo industrial upscaling. One of the major challenges of transforming lignocellulosic biomass into fermentable sugars is the recalcitrant nature of the fibre which renders it very resistant to the release of sugars for fermentation. Since lignocellulosic biomass has a specific attribute such as an extremely coordinated matrix which renders it very resistant to the release of sugars for fermentation owing to biological degradation, a pre-treatment phase is necessary prior to the hydrolysis stage for the transformation of the fermentable sugars. This study focuses on the biosynthesis of biopolymers from lignocellulosic biomass through sustainable approaches such as enzyme and microbial activities in order to examine its viability as a replacement for traditional polymers. Cupriavidus Necator H16 (Ralstonia Eutropha) having 8×108 CFU/ml viable colonies were cultured at 30 oC and was inoculated in submerged fermentation of M9 minimal salt medium using 1% reducing sugar from Furcraea Foetida as carbon source. Batch fermentation of PHB in submerged cultivation conducted for a residence time from 0 to 48h resulted in a dry cell weight from 0.32±0.05% to 1.62±0.05%. The nitrogen limiting phase was achieved after 48h and 17.05±0.35% of PHB was extracted from 3ml of the fermentation broth. The PHB yield was dramatically lower than reported optimal yields of 37.55 to 97.80% from works of literature. Nonetheless, Fourier-transform infrared spectroscopy (FTIR) spectroscopy revealed characteristics bands for carbonyl, methine and ester groups along with intermolecular hydrogen bonds in the biopolymer. Sudan Black B and FTIR spectrum demonstrate that PHB biosynthesis successfully bioaccumulates inside the cells of Ralstonia Eutropha using cellulose from Lignocellulosic biomass (LCB) as carbon source. Hence, the process needs to be optimized in terms of variables such as inoculum size, inoculum concentration, incubation time and salt medium conditions in order to maximise the production of PHB from Furcraea Foetida in Ralstonia Eutropha cultivation.
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