Genomic characterization of bacteria reveals their bioaugmentation and pre-treatment potential for improved hydrolysis and biomethanation of protein-rich substrates

IF 3.5 4区 工程技术 Q3 ENERGY & FUELS
Bhagyashri J. Poddar, Anshuman Arun Khardenavis
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Abstract

The present study explored the genomic capacities of bacterial isolates Enterobacter cloacae AAK_M13, Bacillus subtilis AAK_M29, and Serratia marcescens EGD-HP20 for enhanced hydrolysis of proteinaceous wastes. Genome annotation showed conditionally expressed genes for degrading complex organic substrates thus indicating the metabolic versatility of the isolates which was also validated by plate assay. Of the different subsystems, 28, 24, and 54 annotation hits were associated with protein degradation in the three isolates respectively coding for peptidases of the di-, serine-, omega-, amino-, metalloendo-, and metallocarboxy-peptidase groups. Considering that high concentration of metals in the environment could interfere with the spatial structure of enzymes thereby inhibiting the microbial metabolism, the annotation of genes encoding metal resistance enzymes such as CopA (copper resistance), ArsC and ArsB (arsenic resistance), and yieF (chromium resistance) was significant. Validation of genomic capacities for extracellular proteolytic enzymes revealed the highest protease production between 100 and 200 U/mL min in case of strain EGD-HP20 that was also reflected from the highest soluble protein generation of 198–416 mg/mL during pre-treatment and hydrolysis of protein rich substrates (PRS). Batch studies on biomethanation led to highest methane yield from PRS hydrolysed in presence of strain EGD-HP20, such as soybean flour (270–275 mL/g VS added) followed by meat extract (266 mL/g VS added) and egg white (227 mL/g VS added) in comparison to the respective untreated/un-augmented PRS thus indicating the advantage of bioaugmentation/pre-treatment. The study suggests that deciphering the genes governing the protein degradation pathways and conversion of complex organics could enable the development of bioaugmentation strategies using bacterial strains for efficient biomenthanation.

Abstract Image

细菌的基因组特征揭示了其生物增殖和预处理潜力,以改进富含蛋白质的底物的水解和生物甲烷化
本研究探讨了细菌分离物肠杆菌 AAK_M13、枯草芽孢杆菌 AAK_M29 和侯氏沙雷氏菌 EGD-HP20 的基因组能力,以增强水解蛋白质废物的能力。基因组注释显示了降解复杂有机底物的条件表达基因,这表明分离菌的代谢能力很强,平板试验也验证了这一点。在三个分离物的不同子系统中,分别有 28、24 和 54 个注释命中与蛋白质降解有关,编码的肽酶包括二肽酶、丝氨酸肽酶、欧米茄肽酶、氨基肽酶、金属内肽酶和金属羧基肽酶。考虑到环境中高浓度金属会干扰酶的空间结构,从而抑制微生物的新陈代谢,对编码金属抗性酶的基因如 CopA(铜抗性)、ArsC 和 ArsB(砷抗性)以及 yieF(铬抗性)进行注释意义重大。对细胞外蛋白水解酶基因组能力的验证表明,菌株 EGD-HP20 的蛋白酶产量最高,达到 100 至 200 U/mL/min,这也反映在预处理和水解富含蛋白质的底物(PRS)过程中产生的可溶性蛋白质最高,达到 198-416 mg/mL。批量生物甲烷化研究表明,与未经处理/未添加菌株的 PRS 相比,在菌株 EGD-HP20 存在下水解的 PRS(如大豆粉(添加 270-275 毫升/克 VS))甲烷产量最高,其次是肉提取物(添加 266 毫升/克 VS)和鸡蛋清(添加 227 毫升/克 VS),这表明了生物添加/预处理的优势。这项研究表明,破译支配蛋白质降解途径和复杂有机物转化的基因可以利用细菌菌株开发生物增量策略,实现高效的生物门烷化。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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来源期刊
Biomass Conversion and Biorefinery
Biomass Conversion and Biorefinery Energy-Renewable Energy, Sustainability and the Environment
CiteScore
7.00
自引率
15.00%
发文量
1358
期刊介绍: Biomass Conversion and Biorefinery presents articles and information on research, development and applications in thermo-chemical conversion; physico-chemical conversion and bio-chemical conversion, including all necessary steps for the provision and preparation of the biomass as well as all possible downstream processing steps for the environmentally sound and economically viable provision of energy and chemical products.
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