Aguilar César, Flores Noemí, Riveros-McKay Fernando, Sahonero-Canavesi Diana, Carmona Susy Beatriz, Geiger Otto, Escalante Adelfo, Bolívar Francisco
Departamento de Ingeniería Celular y Biocatálisis, Instituto de Biotecnología, Universidad Nacional Autónoma de México (UNAM), 62210, Cuernavaca, Morelos, Mexico.
Winter Genomics, Manizales 906, Colonia Lindavista, Delegación Gustavo A. Madero, 07300, México D.F., México.
Microb Cell Fact. 2015 Dec 1;14:194. doi: 10.1186/s12934-015-0382-6.
As a metabolic engineering tool, an adaptive laboratory evolution (ALE) experiment was performed to increase the specific growth rate (µ) in an Escherichia coli strain lacking PTS, originally engineered to increase the availability of intracellular phosphoenolpyruvate and redirect to the aromatic biosynthesis pathway. As result, several evolved strains increased their growth fitness on glucose as the only carbon source. Two of these clones isolated at 120 and 200 h during the experiment, increased their μ by 338 and 373 %, respectively, compared to the predecessor PB11 strain. The genome sequence and analysis of the genetic changes of these two strains (PB12 and PB13) allowed for the identification of a novel strategy to enhance carbon utilization to overcome the absence of the major glucose transport system.
Genome sequencing data of evolved strains revealed the deletion of chromosomal region of 10,328 pb and two punctual non-synonymous mutations in the dhaM and glpT genes, which occurred prior to their divergence during the early stages of the evolutionary process. Deleted genes related to increased fitness in the evolved strains are rppH, aas, lplT and galR. Furthermore, the loss of mutH, which was also lost during the deletion event, caused a 200-fold increase in the mutation rate.
During the ALE experiment, both PB12 and PB13 strains lost the galR and rppH genes, allowing the utilization of an alternative glucose transport system and allowed enhanced mRNA half-life of many genes involved in the glycolytic pathway resulting in an increment in the μ of these derivatives. Finally, we demonstrated the deletion of the aas-lplT operon, which codes for the main components of the phosphatidylethanolamine turnover metabolism increased the further fitness and glucose uptake in these evolved strains by stimulating the phospholipid degradation pathway. This is an alternative mechanism to its regeneration from 2-acyl-glycerophosphoethanolamine, whose utilization improved carbon metabolism likely by the elimination of a futile cycle under certain metabolic conditions. The origin and widespread occurrence of a mutated population during the ALE indicates a strong stress condition present in strains lacking PTS and the plasticity of this bacterium that allows it to overcome hostile conditions.
作为一种代谢工程工具,进行了适应性实验室进化(ALE)实验,以提高缺乏磷酸转移酶系统(PTS)的大肠杆菌菌株的比生长速率(µ),该菌株最初经过工程改造以提高细胞内磷酸烯醇丙酮酸的可用性并重新导向芳香族生物合成途径。结果,几个进化菌株在以葡萄糖作为唯一碳源的情况下提高了生长适应性。在实验过程中于120和200小时分离出的其中两个克隆,与前身PB11菌株相比,其µ分别提高了338%和373%。对这两个菌株(PB12和PB13)的基因组序列及遗传变化分析,使得一种增强碳利用以克服主要葡萄糖转运系统缺失的新策略得以确定。
进化菌株的基因组测序数据显示,在进化过程早期它们分化之前,染色体区域有10328 pb的缺失以及dhaM和glpT基因中的两个点突变(非同义突变)。在进化菌株中与适应性增加相关的缺失基因有rppH、aas、lplT和galR。此外,mutH的缺失(在缺失事件中也丢失了)导致突变率增加了200倍。
在ALE实验期间,PB12和PB13菌株均丢失了galR和rppH基因,从而允许利用替代葡萄糖转运系统,并使参与糖酵解途径的许多基因的mRNA半衰期延长,导致这些衍生物的µ增加。最后,我们证明了编码磷脂酰乙醇胺周转代谢主要成分的aas - lplT操纵子的缺失,通过刺激磷脂降解途径,进一步提高了这些进化菌株的适应性和葡萄糖摄取。这是一种与其从2 - 酰基 - 甘油磷酸乙醇胺再生的替代机制,其利用可能通过在某些代谢条件下消除无效循环改善了碳代谢。ALE期间突变群体的起源和广泛出现表明缺乏PTS的菌株中存在强烈的应激条件以及该细菌具有使其克服不利条件的可塑性。
