Slocombe Stephen P, Zúñiga-Burgos Tatiana, Chu Lili, Wood Nicola J, Camargo-Valero Miller Alonso, Baker Alison
Centre for Plant Sciences and Astbury Centre for Structural Molecular Biology, Faculty of Biological Sciences, School of Molecular and Cellular Biology, University of Leeds, Leeds, United Kingdom.
BioResource Systems Research Group, School of Civil Engineering, University of Leeds, Leeds, United Kingdom.
Front Plant Sci. 2020 Jun 30;11:982. doi: 10.3389/fpls.2020.00982. eCollection 2020.
Phosphorus (P), in the form of phosphate derived from either inorganic (P) or organic (P) forms is an essential macronutrient for all life. P undergoes a biogeochemical cycle within the environment, but anthropogenic redistribution through inefficient agricultural practice and inadequate nutrient recovery at wastewater treatment works have resulted in a sustained transfer of P from rock deposits to land and aquatic environments. Our present and near future supply of P is primarily mined from rock P reserves in a limited number of geographical regions. To help ensure that this resource is adequate for humanity's food security, an energy-efficient means of recovering P from waste and recycling it for agriculture is required. This will also help to address excess discharge to water bodies and the resulting eutrophication. Microalgae possess the advantage of polymeric inorganic polyphosphate (PolyP) storage which can potentially operate simultaneously with remediation of waste nitrogen and phosphorus streams and flue gases (CO, SO, and NO). Having high productivity in photoautotrophic, mixotrophic or heterotrophic growth modes, they can be harnessed in wastewater remediation strategies for biofuel production either directly (biodiesel) or in conjunction with anaerobic digestion (biogas) or dark fermentation (biohydrogen). Regulation of algal P uptake, storage, and mobilization is intertwined with the cellular status of other macronutrients (e.g., nitrogen and sulphur) in addition to the manufacture of other storage products (e.g., carbohydrate and lipids) or macromolecules (e.g., cell wall). A greater understanding of controlling factors in this complex interaction is required to facilitate and improve P control, recovery, and reuse from waste streams. The best understood algal genetic model is in terms of utility and shared resources. It also displays mixotrophic growth and advantageously, species of this genus are often found growing in wastewater treatment plants. In this review, we focus primarily on the molecular and genetic aspects of PolyP production or turnover and place this knowledge in the context of wastewater remediation and highlight developments and challenges in this field.
磷(P)以源自无机磷(P)或有机磷(P)形式的磷酸盐形式存在,是所有生命必需的大量营养素。磷在环境中经历生物地球化学循环,但由于农业实践效率低下以及废水处理厂营养物质回收不足导致的人为再分配,使得磷持续从岩石矿床转移到陆地和水生环境中。我们目前及不久的将来的磷供应主要来自少数地理区域的磷矿储备。为确保这种资源足以保障人类的粮食安全,需要一种节能方法从废物中回收磷并将其循环用于农业。这也将有助于解决向水体的过量排放以及由此导致的富营养化问题。微藻具有储存聚合无机多聚磷酸盐(PolyP)的优势,这有可能与废氮、磷流以及烟道气(CO、SO和NO)的修复同时进行。它们在光自养、混合营养或异养生长模式下具有高生产力,可直接(生物柴油)或与厌氧消化(沼气)或黑暗发酵(生物氢)结合用于废水修复策略以生产生物燃料。藻类对磷的吸收、储存和调动的调节,除了与其他储存产物(如碳水化合物和脂质)或大分子(如细胞壁)的合成有关外,还与其他大量营养素(如氮和硫)的细胞状态相互交织。为了促进和改善从废物流中控制、回收和再利用磷,需要更深入了解这种复杂相互作用中的控制因素。就实用性和共享资源而言,最被了解的藻类遗传模型是 。它还表现出混合营养生长,而且该属的物种经常在废水处理厂中生长。在本综述中,我们主要关注多聚磷酸盐产生或周转的分子和遗传方面,并将这些知识置于废水修复的背景下,突出该领域的发展和挑战。
