Using flow cytometry and genomics to characterise and optimise microalgal-bacterial consortia cultivated on Wastewater to produce biomass for Biofuel

使用流式细胞术和基因组学来表征和优化在废水中培养的微藻-细菌群落，以生产生物燃料的生物质

• 批准号: BB/K020617/1
• 负责人: Carole Llewellyn
• 金额: $ 89.36万
• 依托单位: Plymouth Marine Laboratory
• 依托单位国家: 英国
• 项目类别: Research Grant
• 财政年份: 2013
• 资助国家: 英国
• 起止时间: 2013 至 无数据
• 项目状态: 已结题
• 来源: https://gtr.ukri.org/projects?ref=BB%2FK020617%2F1
• 关键词: Using; flow; cytometry; genomics; characterise

Currently producing biofuel from microalgae is commercially prohibited. This is partly due to the high economic costs associated with the nitrogen and phosphorus nutrients required to sustain photosynthetic production. These inorganic nutrients can be found in abundance in industrial wastewater. There are also issues with the requirement of water for cultivating microalgae. Marine microalgae need to be situated near to the coast for utilisation of seawater and freshwater microalgae systems are dependent on large and continuous freshwater supplies, diverting supply away from arable farming etc. Therefore, producing biofuel from microalgae cultivated onwastewater has clear environmental and economic advantages. In any large scale microalgal cultivation system, and particularly when using wastewater, a consortia will be present consisting of a single or several species of algae together with a complement of inherent bacteria; these associated bacteria have been shown to boost lipid production. There are many challenges associated with understanding such a complex and dynamic system. For example, interactions in the system will include metabolic changes occurring both within individual species and between the species. Ultimately the quantity and quality of the biomass suitable for biofuel will be related directly with the growth and the composition of the consortia which will dependent on interactions within it. Currently we have a poor understanding on the composition, development, function and interactions occurring with microalgae consortia.This project will bring the three centres to develop new understanding on developing microalga-bacterial consortia cultivated on industrial water to produce biomass for biofuel. Bharathidasan University (BDU) has expertise on molecular techniques and cultivation of microalgae for bioenergy products. Phycospectrum Environmental Research Centre (PERC) has expertise on robust algal consortia and working with industry on wastewater treatment. Plymouth Marine Laboratory (PML) has expertise on the biology and chemistry to understand microbial community structure and on microbial dynamics. BDU and PERC will focus on optimising strains under industrially relevant conditions and results will be brought together with those from PML who will focus on understanding the microbial dynamics in controlled synthetic wastewater experiments. The project will undertake community composition analysis to obtain understanding on how microalgal consortia change and function at both the cellular and molecular level. We will test the effect that both bacteria and addtional organic carbon have on influencing the growth and composition of the algal biomass as a biofuel feedstock. We will assess both the lipid and carbohydrate content of the algae for potential in biodiesel and bioethanol respectively. Put simplistically we will measure 'who is there? (community/taxonomic analysis), 'how do they compare? (comparative analysis)' and 'what are they doing? (functional analysis)' under the different conditions to optimise the amount and type of biomass suitable for conversion into biofuel.To do this we will use the novel and powerful combination of flow cytometry tools to separate both algal and bacterial populations and genomic tools to characterise the communities. Whilst these tools have recently been applied to study marine microbial ecosystems, they have not been applied to any great extent to understanding wastewater microalgal-bacterial consortia. Knowledge gained will lead to potential to optimise consortia to improve growth rates and the amounts of lipids and/or carbohydrates. This could be achieved through controlling or adding bacteria, the addition of a waste carbon source, or through manipulation of metabolic pathways. The research will contribute to creating solutions to producing biofuel from microalgae grown on wastewater with consideration to both the environment and the economy.

目前，从微藻中生产生物燃料在商业上是被禁止的。这部分是由于与维持光合生产所需的氮和磷营养物相关的高经济成本。这些无机营养物可以在工业废水中大量发现。还存在用于培养微藻的水的需求的问题。海洋微藻需要位于靠近海岸的海水和淡水微藻系统的利用依赖于大量和持续的淡水供应，转移供应远离耕地养殖等，因此，生产生物燃料从微藻养殖废水具有明显的环境和经济优势。在任何大规模的微藻培养系统中，特别是当使用废水时，将存在由单一或几种藻类以及补充的固有细菌组成的聚生体;这些相关的细菌已显示出促进脂质产生。理解这样一个复杂而动态的系统存在许多挑战。例如，系统中的相互作用将包括在个体物种内和物种之间发生的代谢变化。最终，适合生物燃料的生物质的数量和质量将直接关系到财团的生长和组成，而财团的生长和组成取决于财团内部的相互作用。目前，我们对财团的组成、发展、功能和相互作用。该项目将使三个中心对微藻的发展有新的认识，在工业用水上培养细菌聚生体，以生产生物燃料的生物质。印度婆罗蒂达桑大学（BDU）在分子技术和用于生物能源产品的微藻培养方面拥有专业知识。藻谱环境研究中心（PERC）拥有强大的藻类财团的专业知识，并与工业界合作进行废水处理。普利茅斯海洋实验室（PML）拥有生物学和化学方面的专业知识，以了解微生物群落结构和微生物动力学。BDU和PERC将专注于在工业相关条件下优化菌株，结果将与PML的结果结合在一起，后者将专注于了解受控合成废水实验中的微生物动力学。该项目将进行群落组成分析，以了解微藻群体如何在细胞和分子水平上变化和发挥作用。我们将测试细菌和额外的有机碳对作为生物燃料原料的藻类生物质的生长和组成的影响。我们将评估藻类的脂质和碳水化合物含量，分别用于生物柴油和生物乙醇的潜力。简单地说，我们将衡量“谁在那里？（群落/分类学分析），它们如何比较？（比较分析）“和”他们在做什么？（功能分析）“，以优化适于转化为生物燃料的生物质的量和类型。为此，我们将使用流式细胞术工具的新颖和强大的组合来分离藻类和细菌种群，并使用基因组工具来鉴定群落。虽然这些工具最近被应用于研究海洋微生物生态系统，但它们还没有在很大程度上被应用于了解废水微藻-细菌联合体。所获得的知识将导致优化聚生体以提高生长速率和脂质和/或碳水化合物的量的潜力。这可以通过控制或添加细菌、添加废碳源或通过操纵代谢途径来实现。该研究将有助于创造从废水中生长的微藻生产生物燃料的解决方案，同时考虑到环境和经济。

项目成果

Characterisation of bacteria from the cultures of a Chlorella strain isolated from textile wastewater and their growth enhancing effects on the axenic cultures of Chlorella vulgaris in low nutrient media

• DOI: 10.1016/j.algal.2019.101666
• 发表时间: 2019-12
• 期刊: Algal Research
• 作者: K. Tait;D. White;Susan A. Kimmance;G. Tarran;Paul A Rooks;Mark Jones;C. Llewellyn

Comparing Nutrient Removal from Membrane Filtered and Unfiltered Domestic Wastewater Using Chlorella vulgaris.

• DOI: 10.3390/biology7010012
• 发表时间: 2018-01-19
• 期刊: Biology
• 影响因子: 4.2
• 作者: Mayhead E;Silkina A;Llewellyn CA;Fuentes-Grünewald C
• 通讯作者: Fuentes-Grünewald C

In vitro antibacterial activity of ZnO and Nd doped ZnO nanoparticles against ESBL producing Escherichia coli and Klebsiella pneumoniae.

• DOI: 10.1038/srep24312
• 发表时间: 2016-04-13
• 期刊: Scientific reports
• 影响因子: 4.6
• 作者: Hameed AS;Karthikeyan C;Ahamed AP;Thajuddin N;Alharbi NS;Alharbi SA;Ravi G
• 通讯作者: Ravi G

Modulation of Polar Lipid Profiles in Chlorella sp. in Response to Nutrient Limitation

• DOI: 10.3390/metabo9030039
• 发表时间: 2019-02
• 期刊: Metabolites
• 影响因子: 4.1
• 作者: D. White;Paul A Rooks;Susan A. Kimmance;K. Tait;Mark Jones;G. Tarran;Charlotte Cook;C. Llewellyn