Henri Ingelman , James K. Heffernan , Audrey Harris , Steven D. Brown , Kurshedaktar Majibullah Shaikh , Asfand Yar Saqib , Marina J. Pinheiro , Lorena Azevedo de Lima , Karen Rodriguez Martinez , Ricardo A. Gonzalez-Garcia , Grant Hawkins , Jim Daleiden , Loan Tran , Hunter Zeleznik , Rasmus O. Jensen , Vinicio Reynoso , Heidi Schindel , Jürgen Jänes , Séan D. Simpson , Michael Köpke , Kaspar Valgepea
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In this work, we used three different and independent adaptive laboratory evolution (ALE) strategies to evolve the wild-type <em>C. autoethanogenum</em> to grow faster, without yeast extract and to be robust in operating continuous bioreactor cultures. Multiple evolved strains with improved phenotypes were isolated on minimal media with one strain, named “LAbrini”, exhibiting superior performance regarding the maximum specific growth rate, product profile, and robustness in continuous cultures. Whole-genome sequencing of the evolved strains identified 25 mutations. Of particular interest are two genes that acquired seven different mutations across the three ALE strategies, potentially as a result of convergent evolution. Reverse genetic engineering of mutations in potentially sporulation-related genes CLAU_3129 (<em>spo0A</em>) and CLAU_1957 recovered all three superior features of our ALE strains through triggering significant proteomic rearrangements. 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引用次数: 0
摘要
能够转化气态一碳(C1)废物原料的微生物对于过渡到可持续生产可再生化学品和燃料越来越重要。由于使用自乙烷梭菌进行气体发酵已经商业化,因此乙酸菌是一种有趣的生物催化剂。然而,大多数醋酸菌株需要复杂的营养物质,生长缓慢,而且不适合生物反应器发酵。在这项工作中,我们使用了三种不同且独立的适应性实验室进化(ALE)策略,使野生型自乙醇梭菌在不使用酵母提取物的情况下生长得更快,并能在连续生物反应器培养过程中保持稳定。在最小培养基上分离出了多个具有改进表型的进化菌株,其中一个名为 "LAbrini "的菌株在最大特定生长率、产品特征和连续培养的稳健性方面表现出了卓越的性能。对进化菌株的全基因组测序发现了 25 个基因突变。特别值得关注的是,有两个基因在三种 ALE 策略中获得了 7 个不同的突变,这可能是趋同进化的结果。对可能与孢子有关的基因 CLAU_3129 (spo0A) 和 CLAU_1957 的突变进行反向遗传工程,通过引发显著的蛋白质组重排,恢复了 ALE 菌株的所有三个优势特征。这项工作为加速表型分析和基因工程以及更好地了解乙酰胆碱代谢提供了一个强大的自乙酰胆碱菌株 "LAbrini"。
Autotrophic adaptive laboratory evolution of the acetogen Clostridium autoethanogenum delivers the gas-fermenting strain LAbrini with superior growth, products, and robustness
Microbes able to convert gaseous one-carbon (C1) waste feedstocks are increasingly important to transition to the sustainable production of renewable chemicals and fuels. Acetogens are interesting biocatalysts since gas fermentation using Clostridium autoethanogenum has been commercialised. However, most acetogen strains need complex nutrients, display slow growth, and are not robust for bioreactor fermentations. In this work, we used three different and independent adaptive laboratory evolution (ALE) strategies to evolve the wild-type C. autoethanogenum to grow faster, without yeast extract and to be robust in operating continuous bioreactor cultures. Multiple evolved strains with improved phenotypes were isolated on minimal media with one strain, named “LAbrini”, exhibiting superior performance regarding the maximum specific growth rate, product profile, and robustness in continuous cultures. Whole-genome sequencing of the evolved strains identified 25 mutations. Of particular interest are two genes that acquired seven different mutations across the three ALE strategies, potentially as a result of convergent evolution. Reverse genetic engineering of mutations in potentially sporulation-related genes CLAU_3129 (spo0A) and CLAU_1957 recovered all three superior features of our ALE strains through triggering significant proteomic rearrangements. This work provides a robust C. autoethanogenum strain “LAbrini” to accelerate phenotyping and genetic engineering and to better understand acetogen metabolism.
期刊介绍:
New Biotechnology is the official journal of the European Federation of Biotechnology (EFB) and is published bimonthly. It covers both the science of biotechnology and its surrounding political, business and financial milieu. The journal publishes peer-reviewed basic research papers, authoritative reviews, feature articles and opinions in all areas of biotechnology. It reflects the full diversity of current biotechnology science, particularly those advances in research and practice that open opportunities for exploitation of knowledge, commercially or otherwise, together with news, discussion and comment on broader issues of general interest and concern. The outlook is fully international.
The scope of the journal includes the research, industrial and commercial aspects of biotechnology, in areas such as: Healthcare and Pharmaceuticals; Food and Agriculture; Biofuels; Genetic Engineering and Molecular Biology; Genomics and Synthetic Biology; Nanotechnology; Environment and Biodiversity; Biocatalysis; Bioremediation; Process engineering.