Engineering the lycopene synthetic pathway in <Emphasis Type="Italic">E. coli</Emphasis> by comparison of the carotenoid genes of <Emphasis Type="Italic">Pantoea agglomerans</Emphasis> and <Emphasis Type="Italic">Pantoea ananatis</Emphasis>

The lycopene synthetic pathway was engineered in Escherichia coli using the carotenoid genes (crtE, crtB, and crtI) of Pantoea agglomerans and Pantoea ananatis. E. coli harboring the P. agglomerans crt genes produced 27 mg/l of lycopene in 2YT medium without isopropyl-beta-d-thiogalactopyranoside (IPTG) induction, which was twofold higher than that produced by E. coli harboring the P. ananatis crt genes (12 mg/l lycopene) with 0.1 mM IPTG induction. The crt genes of P. agglomerans proved better for lycopene production in E. coli than those of P. ananatis. The crt genes of the two bacteria were also compared in E. coli harboring the mevalonate bottom pathway, which was capable of providing sufficient carotenoid building blocks, isopentenyl diphosphate (IPP) and dimethylallyl diphosphate (DMAPP), with exogenous mevalonate supplementation. Lycopene production significantly increased using the mevalonate bottom pathway and 60 mg/l of lycopene was obtained with the P. agglomerans crt genes, which was higher than that obtained with the P. ananatis crt genes (35 mg/l lycopene). When crtE among the P. ananatis crt genes was replaced with P. agglomerans crtE or Archaeoglobus fulgidus gps, both lycopene production and cell growth were similar to that obtained with P. agglomerans crt genes. The crtE gene was responsible for the observed difference in lycopene production and cell growth between E. coli harboring the crt genes of P. agglomerans and P. ananatis. As there was no significant difference in lycopene production between E. coli harboring P. agglomerans crtE and A. fulgidus gps, farnesyl diphosphate (FPP) synthesis was not rate-limiting in E. coli. Sang-Hwal Yoon and Ju-Eun Kim: These authors contributed equally to this work.     

Production of lycopene by metabolically-engineered Escherichia coli

Escherichia coli strain CAR001 that produces β-carotene was genetically engineered to produce lycopene by deleting genes encoding zeaxanthin glucosyltransferase (crtX) and lycopene β-cyclase (crtY) from the crtEXYIB operon. The resulting strain, LYC001, produced 10.5 mg lycopene/l (6.5 mg/g dry cell weight, DCW). Modulating expression of genes encoding α-ketoglutarate dehydrogenase, succinate dehydrogenase and transaldolase B within central metabolic modules increased NADPH and ATP supplies, leading to a 76 % increase of lycopene yield. Ribosome binding site libraries were further used to modulate expression of genes encoding 1-deoxy-d-xylulose-5-phosphate synthase (dxs) and isopentenyl diphosphate isomerase (idi) and the crt gene operon, which improved the lycopene yield by 32 %. The optimal strain LYC010 produced 3.52 g lycopene/l (50.6 mg/g DCW) in fed-batch fermentation.     

Lysine Overproduction Mutations in the YeastSaccharomyces cerevisiae Are Introduced into Industrial Yeast Strains

Yeast mutants resistant to a toxic lysine analog, thialysine were obtained by a method described in the literature [1]. A strain excreting the maximum amount of lysine (0.45 g/l) was selected from these mutants. The intracellular content of lysine was also increased by 30%. The genetic nature of lysine overproduction was studied in this strain. An increase in the amount of excreted lysine was shown to be determined by at least two genes, one of which carries a mutation of thialysine resistance manifesting the pleiotropic effect of lysine overproduction (Th1 ^R) and the other is involved in the regulation of lysine production (PRL). Linkage groups of these genes were determined: the first gene was mapped to the IV chromosome and the second, to the XV chromosome. Both genetic characters were introduced into industrial baker's yeast strains via a series of backcrosses. The stabilization of the genome in the newly derived strains was confirmed by electrokaryotyping.     

High versus low level expression of the lycopene biosynthesis genes from <Emphasis Type="Italic">Pantoea ananatis</Emphasis> in <Emphasis Type="Italic">Escherichia coli</Emphasis>

The heterologous synthesis of lycopene in non-carotenogenic Escherichia coli required the introduction of the biosynthesis genes crtE, crtB, and crtI. Recombinant E. coli strains, expressing each lycopene biosynthesis gene from Pantoea ananatis using multi-copy plasmid or single-copies after stable chromosomal integration, were cultivated and the formation of lycopene was investigated. The different expression conditions significantly influenced the lycopene formation as well as the growth behaviour. High plasmid expression levels of crtI with a single copy background of crtE and crtB in E. coli led to a predominate synthesis of tetradehydrolycopene at 253 μg g⁻¹ (cdw).     

Efficient synthesis of functional isoprenoids from acetoacetate through metabolic pathway-engineered <Emphasis Type="Italic">Escherichia coli</Emphasis>

We show here an efficient synthesis system of isoprenoids from acetoacetate as the main substrate. We expressed in Escherichia coli a Streptomyces mevalonate pathway gene cluster starting from HMG-CoA synthase and including isopentenyl diphosphate isomerase (idi) type 2 gene and the yeast idi type 1 and rat acetoacetate-CoA ligase (Aacl) genes. When the α-humulene synthase (ZSS1) gene of shampoo ginger was expressed in this transformant, the resultant E. coli produced 958 μg/mL culture of α-humulene with a lithium acetoacetate (LAA) supplement, which was a 13.6-fold increase compared with a control E. coli strain expressing only ZSS1. Next, we investigated if this E. coli strain engineered to utilize acetoacetate can synthesize carotenoids effectively. When the crtE, crtB, and crtI genes required for lycopene synthesis were expressed in the transformant, lycopene amounts reached 12.5 mg/g dry cell weight with addition of LAA, an 11.8-fold increase compared with a control expressing only the three crt genes. As for astaxanthin production with the E. coli transformant, in which the crtE, crtB, crtI, crtY, crtZ, and crtW genes were expressed, the total amount of carotenoids produced (astaxanthin, lycopene, and phytoene) was significantly increased to 7.5 times that of a control expressing only the six crt genes.     

Cloning and Sequencing of Two New Verotoxin 2 Variant Genes of Escherichia coli Isolated from Cases of Human and Bovine Diarrhea

We cloned and sequenced two new Verotoxin 2 (VT2) variant genes: one from an Escherichia coli strain from a case of bovine diarrhea and the other from an E. coli strain from a patient with diarrhea. The nucleotide and amino acid sequences of these two genes were highly homologous with, but distinct from those of the VT2, VT2vha, VT2vhb, SLT-IIv (VT2vp1) and SLT-IIva (VT2vp2) genes. Their nucleotide sequences were much more closely homologous to that of VT2vh than to that of VT2vp. Search for these two new genes in other Verocytotoxin-producing E. coli strains resulted in the isolation of 2 strains carrying one of the new VT2 variant genes, one strain from Tokyo and the other from Canada.     

SMET: Systematic multiple enzyme targeting – a method to rationally design optimal strains for target chemical overproduction

Identifying multiple enzyme targets for metabolic engineering is very critical for redirecting cellular metabolism to achieve desirable phenotypes, e.g., overproduction of a target chemical. The challenge is to determine which enzymes and how much of these enzymes should be manipulated by adding, deleting, under-, and/or over-expressing associated genes. In this study, we report the development of a systematic multiple enzyme targeting method (SMET), to rationally design optimal strains for target chemical overproduction. The SMET method combines both elementary mode analysis and ensemble metabolic modeling to derive SMET metrics including l-values and c-values that can identify rate-limiting reaction steps and suggest which enzymes and how much of these enzymes to manipulate to enhance product yields, titers, and productivities. We illustrated, tested, and validated the SMET method by analyzing two networks, a simple network for concept demonstration and an Escherichia coli metabolic network for aromatic amino acid overproduction. The SMET method could systematically predict simultaneous multiple enzyme targets and their optimized expression levels, consistent with experimental data from the literature, without performing an iterative sequence of single-enzyme perturbation. The SMET method was much more efficient and effective than single-enzyme perturbation in terms of computation time and finding improved solutions.     

Overproduction and excretion ofβ-lactamase and alkaline phosphatase byEscherichia coli olp mutants

Summary We have isolated spontaneousolp mutants ofEscherichia coli K-12 overproducing the periplasmic enzymes -lactamase (Bla) and alkaline phosphatase (PhoA). Enzyme overproduction was maintained inolp strains transformed with plasmids carryingbla ⁺ andphoA ⁺ structural genes, and synthesizing high levels of Bla and PhoA. Transformedolp strains excreted up to 40% of these enzymes into the growth medium. The introduction of atolA excretory mutation intoolp strains led to an increase of enzyme overproduction and a release of 85% of Bla and PhoA enzyme activities into the culture medium.     

Novel strategy for yeast construction using δ-integration and cell fusion to efficiently produce ethanol from raw starch

We developed a novel strategy for constructing yeast to improve levels of amylase gene expression and the practical potential of yeast by combining δ-integration and polyploidization through cell fusion. Streptococcus bovis α-amylase and Rhizopus oryzae glucoamylase/α-agglutinin fusion protein genes were integrated into haploid yeast strains. Diploid strains were constructed from these haploid strains by mating, and then a tetraploid strain was constructed by cell fusion. The α-amylase and glucoamylase activities of the tetraploid strain were increased up to 1.5- and tenfold, respectively, compared with the parental strain. The diploid and tetraploid strains proliferated faster, yielded more cells, and fermented glucose more effectively than the haploid strain. Ethanol productivity from raw starch was improved with increased ploidy; the tetraploid strain consumed 150 g/l of raw starch and produced 70 g/l of ethanol after 72 h of fermentation. Our strategy for constructing yeasts resulted in the simultaneous overexpression of genes integrated into the genome and improvements in the practical potential of yeasts.     

Genome sequence analyses of two isolates from the recent <Emphasis Type="Italic">Escherichia coli</Emphasis> outbreak in Germany reveal the emergence of a new pathotype: Entero-Aggregative-Haemorrhagic <Emphasis Type="Italic">Escherichia coli</Emphasis> (EAHEC)

The genome sequences of two Escherichia coli O104:H4 strains derived from two different patients of the 2011 German E. coli outbreak were determined. The two analyzed strains were designated E. coli GOS1 and GOS2 (German outbreak strain). Both isolates comprise one chromosome of approximately 5.31 Mbp and two putative plasmids. Comparisons of the 5,217 (GOS1) and 5,224 (GOS2) predicted protein-encoding genes with various E. coli strains, and a multilocus sequence typing analysis revealed that the isolates were most similar to the entero-aggregative E. coli (EAEC) strain 55989. In addition, one of the putative plasmids of the outbreak strain is similar to pAA-type plasmids of EAEC strains, which contain aggregative adhesion fimbrial operons. The second putative plasmid harbors genes for extended-spectrum β-lactamases. This type of plasmid is widely distributed in pathogenic E. coli strains. A significant difference of the E. coli GOS1 and GOS2 genomes to those of EAEC strains is the presence of a prophage encoding the Shiga toxin, which is characteristic for enterohemorrhagic E. coli (EHEC) strains. The unique combination of genomic features of the German outbreak strain, containing characteristics from pathotypes EAEC and EHEC, suggested that it represents a new pathotype Entero-Aggregative-Haemorrhagic E scherichia c oli (EAHEC).     

Isolation and functional characterisation of a novel type of carotenoid biosynthetic gene from Xanthophyllomyces dendrorhous

The red heterobasidiomycetous yeast Xanthophyllomyces dendrorhous (perfect state of Phaffia rhodozyma) contains a novel type of carotenoid biosynthetic enzyme. Its structural gene, designated crtYB, was isolated by functional complementation in a genetically modified, carotenogenic Escherichia coli strain. Expression studies in different carotenogenic E. coli strains demonstrated that the crtYB gene encodes a bifunctional protein involved both in synthesis of phytoene from geranylgeranyl diphosphate and in cyclisation of lycopene to β-carotene. By sequence comparison with other phytoene synthases and complementation studies in E. coli with various deletion derivatives of the crtYB gene, the regions responsible for phytoene synthesis and lycopene cyclisation were localised within the protein. Received: 20 January 1999 / Accepted: 21 May 1999     

Type 2 IDI performs better than type 1 for improving lycopene production in metabolically engineered E. coli strains

In this study a comparison was made between type 1 and type 2 isopentenyl diphosphate isomerases (IDI) in improving lycopene production in Escherichia coli. The corresponding genes of Bacillus licheniformis and the host (i _Bl and i _Ec , respectively) were expressed in lycopene producing E. coli strains by pTlyci_Bl and pTlyci_Ec plasmids, under the control of tac promoter. The results showed that the overexpression of i _Ec improved the lycopene production from 33 ± 1 in E. coli Tlyc to 68 ± 3 mg/gDCW in E. coli Tlyci_Ec. In contrast, the expression of i _Bl increased the lycopene production more efficiently up to 80 ± 9 mg/gDCW in E. coli Tlyci_Bl. The introduction of a heterologous mevalonate pathway to elevate the IPP abundance resulted in a lycopene production up to 132 ± 5 mg/gDCW with i _Ec in E. coli Tlyci_Ec-mev and 181 ± 9 mg/gDCW with i _Bl in E. coli Tlyci_Bl-mev, that is, 4 and 5.6 times respectively. When fructose, mannose, arabinose, and acetate were each used as an auxiliary substrate with glycerol, lycopene production was inhibited by different extents. Among auxiliary substrates tested, only citrate was an improving one for lycopene production in all strains with a maximum of 198 ± 3 mg/gDCW in E. coli Tlyci_Bl-mev. It may be concluded that the type 2 IDI performs better than the type 1 in metabolic engineering attempts for isoprenoid production in E. coli. In addition, the metabolic engineering of citrate pathway seems a promising approach to have more isoprenoid accumulation in E. coli.     

A co-fermentation strategy to consume sugar mixtures effectively

We report a new approach for the simultaneous conversion of xylose and glucose sugar mixtures into products by fermentation. The process simultaneously uses two substrate-selective strains of Escherichia coli, one which is unable to consume glucose and one which is unable to consume xylose. The xylose-selective (glucose deficient) strain E. coli ZSC113 has mutations in the glk, ptsG and manZ genes while the glucose-selective (xylose deficient) strain E. coli ALS1008 has a mutation in the xylA gene. By combining these two strains in a single process, xylose and glucose are consumed more quickly than by a single-organism approach. Moreover, we demonstrate that the process is able to adapt to changing concentrations of these two sugars, and therefore holds promise for the conversion of variable sugar feed streams, such as lignocellulosic hydrolysates.     

The essential cell division protein FtsN contains a critical disulfide bond in a non‐essential domain

Disulfide bonds are found in many proteins associated with the cell wall of Escherichia coli, and for some of these proteins the disulfide bond is critical to their stability and function. One protein found to contain a disulfide bond is the essential cell division protein FtsN, but the importance of this bond to the protein's structural integrity is unclear. While it evidently plays a role in the proper folding of the SPOR domain of FtsN, this domain is non‐essential, suggesting that the disulfide bond might also be dispensable. However, we find that FtsN mutants lacking cysteines give rise to filamentous growth. Furthermore, FtsN protein levels in strains expressing these mutants were significantly lower than in a strain expressing the wild‐type allele, as were FtsN levels in strains incapable of making disulfide bonds (dsb^‐) exposed to anaerobic conditions. These results strongly suggest that FtsN lacking a disulfide bond is unstable, thereby making this disulfide critical for function. We have previously found that dsb^‐ strains fail to grow anaerobically, and the results presented here suggest that this growth defect may be due in part to misfolded FtsN. Thus, proper cell division in E. coli is dependent upon disulfide bond formation.     

Biotin biosynthetic pathway in recombinant strains of Escherichia coli overexpressing bio genes: evidence for a limiting step upstream from KAPA

The effect of the overexpression of the bioABFCD operon on the biotin biosynthetic pathway was investigated in an Escherichia coli K12 bioR mutant with a chromosomal deletion for the biotin operon. When transformed with a multicopy number plasmid containing bioABFCD, this strain synthetized 10,000 times more biotin than a wild-type E. coli strain. In order to further increase biotin production, the bioA and bioB operons were subcloned into plasmids with stronger promoters and in some cases optimal ribosome binding sites. The new constructions led to the accumulation of large amounts of soluble Bio proteins (although not BioC) but did not improve biotin production. In all the constructed strains, BioA, BioD, and BioB activities were greatly amplified but these activitie did not correlate with the level of protein syntthesis. These strains accumulated only low levels of vitamers, auggesting that the major limiting step for higher biotin production occurs upstream from the first intermediate of the Bio pathway we assayed (7,keto-8-aminopelargonic acid). As BioC overproduction was shown to impair cell growth, we could not determine if this early step of pathway was limiting. Correspondence to: S. Lévy-Schil     

Regulation of the biosynthesis of aminoacyl-tRNA synthetases and of tRNA in Escherichia coli. IV. Mutants with increased levels of leucyl- or seryl-tRNA synthetase.

Summary Spontaneous revertants of a temperature-sensitive Escherichia coli strain harboring a thermolabile leucyl-tRNA synthetase and seryl-tRNA synthetase were selected for growth at 40°C. Among these, strains were found with increased levels of both thermolabile synthetases. Two distinct genetic loci were found responsible for enzyme overproduction. leuR, located near xyl, causes elevated levels of leucyl-tRNA synthetase; while serR, located near leu, causes elevated levels of seryl-tRNA synthetase.The preceding paper in this series is by R. LaRossa, J. Mao, K.B. Low and D. Söll. J. Mol. Biol. 117, 1049 (1977)     

Biosynthesis of zeaxanthin in recombinant Pseudomonas putida

Pseudomonas putida KT2440 strain was investigated for biosynthesis of the valuable xanthophyll zeaxanthin. A new plasmid was constructed harboring five carotenogenic genes from Pantoea ananatis and three genes from Escherichia coli under control of an l-rhamnose-inducible promoter. Pseudomonas putida KT2440 wild type hardly tolerated the plasmids for carotenoid production. Mating experiments with E. coli S17-1 strains revealed that the carotenoid products are toxic to the Pseudomonas putida cells. Several carotenoid-tolerant transposon mutants could be isolated, and different gene targets for relief of carotenoid toxicity were identified. After optimization of cultivation conditions and product processing, 51 mg/l zeaxanthin could be produced, corresponding to a product yield of 7 mg zeaxanthin per gram cell dry weight. The effect of various additives on production of hydrophobic zeaxanthin was investigated as well. Particularly, the addition of lecithin during cell cultivation increased volumetric productivity of Pseudomonas putida by a factor of 4.7 (51 mg/l vs. 239 mg/l).     

挖掘与调控乙酸胁迫响应基因提高重组酿酒酵母合成番茄红素水平

【背景】乙酰辅酶A是酿酒酵母异源合成番茄红素的重要中间产物,胞质中乙酰辅酶A主要来自乙酰辅酶A合成酶催化乙酸合成。【目的】通过外源添加乙酸盐结合调控乙酸胁迫应答基因增加胞内乙酰辅酶A含量,改善细胞生长,促进番茄红素合成。【方法】在合成番茄红素的重组酵母菌中过表达乙酰辅酶A合成酶编码基因(acs2),在发酵过程中添加10g/L乙酸盐,结合转录组学分析挖掘乙酸胁迫响应基因,进行单一和组合调控。【结果】添加乙酸盐后,重组菌Y02中番茄红素含量增加了19.14%,但细胞生长受到抑制,转录组学结果表明adk2、fap7、hem13、elo3、pdc5、set5、pmt5、hst4、clb2和swe1表达水平增加,因此构建了单基因和双基因过表达菌株,其中Y02-set5-hst4菌在添加乙酸盐后细胞生长得到了显著改善,同时胞内乙酰辅酶A浓度提高了78.21%,番茄红素含量和产量达到12.62 mg/g-DCW和108.67 mg/L,与对照菌Y02相比分别提高了42.76%和67.13%。同时该菌中甲羟戊酸途径中关键基因erg12、erg20和hmg1的表达量与对照菌相比分别上调了1.70、1.4...     

Engineering Escherichia coli for enhanced sensitivity to the autoinducer-2 quorum sensing signal

The autoinducer-2 (AI-2) quorum sensing system is involved in a range of population-based bacterial behaviors and has been engineered for cell–cell communication in synthetic biology systems. Investigation into the cellular mechanisms of AI-2 processing has determined that overexpression of uptake genes increases AI-2 uptake rate, and genomic deletions of degradation genes lowers the AI-2 level required for activation of reporter genes. Here, we combine these two strategies to engineer an Escherichia coli strain with enhanced ability to detect and respond to AI-2. In an E. coli strain that does not produce AI-2, we monitored AI-2 uptake and reporter protein expression in a strain that overproduced the AI-2 uptake or phosphorylation units LsrACDB or LsrK, a strain with the deletion of AI-2 degradation units LsrF and LsrG, and an “enhanced” strain with both overproduction of AI-2 uptake and deletion of AI-2 degradation elements. By adding up to 40 μM AI-2 to growing cell cultures, we determine that this “enhanced” AI-2 sensitive strain both uptakes AI-2 more rapidly and responds with increased reporter protein expression than the others. This work expands the toolbox for manipulating AI-2 quorum sensing processes both in native environments and for synthetic biology applications.