A phcA− marker-free mutant of Ralstonia solanacearum as potential biocontrol agent of tomato bacterial wilt

A phcA⁻ mutant of Ralstonia solanacearum strain ZJ3721 was created in a marker-free method. Expression of virulence-associated genes such as xpsR, egl, tek and epsE was significantly suppressed in the phcA⁻ mutant. The ability of the mutant to control tomato bacterial wilt was evaluated by potting experiment. Results showed that application of mutant with wild type (WT) at the same time only delayed the development of wilt for about one day and the population of WT in tomato rhizosphere soil was nearly 70-fold higher than that of the mutant, resulting in a 90% disease incidence at last, as high as that of control. If the phcA⁻ mutant was applied three days earlier than WT pathogen, tomato wilt disease incidence was only 6%, 80% lower than that of control and population of WT was about 0.5-fold as much as that of mutant. Under hydroponic conditions, phcA⁻ mutant significantly triggered the expressions of genes in salicylic acid pathway but inhibited the expressions of genes in jasmonic acid (JA) and ethylene (ET) pathways. The expressions of PR-1a and GluA genes (salicylic acid pathway) in phcA⁻ mutant were 66-fold and 7.5-fold higher than in WT pathogen after three days of inoculation.     

A butenolide signaling system synergized with biosynthetic gene modules led to effective activation and enhancement of silent oviedomycin production in Streptomyces

Secondary metabolic gene clusters widely exist in the genomes of Streptomyces but mostly remain silent. To awaken this hidden reservoir of natural products, various strategies concerning secondary metabolic pathways are applied. Here, we describe that butenolide signaling molecule deficiency and glucose addition can interdependently activate the expression of silent oviedomycin biosynthetic gene clusters in Streptomyces ansochromogenes and Streptomyces antibioticus. Since oviedomycin is a promising anti-tumor lead compound, in order to improve its yield, we use the cluster-situated genes (ovmF, ovmG, ovmI and ovmH) encoding the enzymes for acyl carrier protein modification and precursor biosynthesis, and the discrete precursor biosynthetic genes (pyk2, gap1 and accA2) involved in glycolysis to assemble two gene modules (pFGIH and pPGA). Their co-overexpression in ΔsabA (a disruption mutant of sabA encoding SAB synthase) has superimposed effect on the yield of oviedomycin, which can be further increased to 59-fold in the presence of galactose as optimal carbon source. This is the most unambiguous evidence that butenolide signaling system can synergize with the optimization of primary metabolism to regulate the expression of secondary metabolic gene clusters, providing efficient strategies for mining natural products of Streptomyces.     

Expression of the sub-pathways of the Chloroflexus aurantiacus 3-hydroxypropionate carbon fixation bicycle in E. coli: Toward horizontal transfer of autotrophic growth

The 3-hydroxypropionate (3-HPA) bicycle is unique among CO₂-fixing systems in that none of its enzymes appear to be affected by oxygen. Moreover, the bicycle includes a number of enzymes that produce novel intermediates of biotechnological interest, and the CO₂-fixing steps in this pathway are relatively rapid. We expressed portions of the 3-HPA bicycle in a heterologous organism, E. coli K12. We subdivided the 3-HPA bicycle into four sub-pathways: (1) synthesis of propionyl-CoA from acetyl-CoA, (2) synthesis of succinate from propionyl-CoA, (3) glyoxylate production and regeneration of acetyl-CoA, and (4) assimilation of glyoxylate and propionyl-CoA to form pyruvate and regenerate acetyl-CoA. We expressed the novel enzymes of the 3-HPA bicycle in operon form and used phenotypic tests for activity. Sub-pathway 1 activated a propionate-specific biosensor. Sub-pathway 2, found in non-CO₂-fixing bacteria, was reassembled in E. coli using genes from diverse sources. Sub-pathway 3, operating in reverse, generated succinyl-CoA sufficient to rescue a sucAD⁻ double mutant of its diaminopimelic acid (DAP) auxotrophy. Sub-pathway 4 was able to reduce the toxicity of propionate and allow propionate to contribute to cell biomass in a prpC⁻(2 methylcitrate synthase) mutant strain. These results indicate that all of the sub-pathways of the 3-HPA bicycle can function to some extent in vivo in a heterologous organism, as indicated by growth tests. Overexpression of certain enzymes was deleterious to cell growth, and, in particular, expression of MMC-CoA lyase caused a mucoid phenotype. These results have implications for metabolic engineering and for bacterial evolution through horizontal gene transfer.     

Systems metabolic engineering of Corynebacterium glutamicum eliminates all by-products for selective and high-yield production of the platform chemical 5-aminovalerate

5-aminovalerate (AVA) is a platform chemical of substantial commercial value to derive nylon-5 and five-carbon derivatives like δ-valerolactam, 1,5-pentanediol, glutarate, and 5-hydroxyvalerate. De novo bio-production synthesis of AVA using metabolically engineered cell factories is regarded as exemplary route to provide this chemical in a sustainable way. So far, this route is limited by low titers, rates and yields and suffers from high levels of by-products. To overcome these limitations, we developed a novel family of AVA producing C. glutamicum cell factories. Stepwise optimization included (i) improved AVA biosynthesis by expression balancing of the heterologous davBA genes from P. putida, (ii) reduced formation of the by-product glutarate by disruption of the catabolic y-aminobutyrate pathway (iii), increased AVA export, and (iv) reduced AVA re-import via native and heterologous transporters to account for the accumulation of intracellular AVA up to 300 mM. Strain C. glutamicum AVA-5A, obtained after several optimization rounds, produced 48.3 g L⁻¹ AVA in a fed-batch process and achieved a high yield of 0.21 g g⁻¹. Surprisingly in later stages, the mutant suddenly accumulated glutarate to an extent equivalent to 30% of the amount of AVA formed, tenfold more than in the early process, displaying a severe drawback toward industrial production. Further exploration led to the discovery that ArgD, naturally aminating N-acetyl-l-ornithine during l-arginine biosynthesis, exhibits deaminating side activity on AVA towards glutarate formation. This promiscuity became relevant because of the high intracellular AVA level and the fact that ArgD became unoccupied with the gradually stronger switch-off of anabolism during production. Glutarate formation was favorably abolished in the advanced strains AVA-6A, AVA-6B, and AVA-7, all lacking argD. In a fed-batch process, C. glutamicum AVA-7 produced 46.5 g L⁻¹ AVA at a yield of 0.34 g g⁻¹ and a maximum productivity of 1.52 g L⁻¹ h⁻¹, outperforming all previously reported efforts and stetting a milestone toward industrial manufacturing of AVA. Notably, the novel cell factories are fully genome-based, offering high genetic stability and requiring no selection markers     

Mechanistic DNA damage simulations in Geant4-DNA Part 2: Electron and proton damage in a bacterial cell

We extended a generic Geant4 application for mechanistic DNA damage simulations to an Escherichia coli cell geometry, finding electron damage yields and proton damage yields largely in line with experimental results. Depending on the simulation of radical scavenging, electrons double strand breaks (DSBs) yields range from 0.004 to 0.010 DSB Gy⁻¹ Mbp⁻¹, while protons have yields ranging from 0.004 DSB Gy⁻¹ Mbp⁻¹ at low LETs and with strict assumptions concerning scavenging, up to 0.020 DSB Gy⁻¹ Mbp⁻¹ at high LETs and when scavenging is weakest. Mechanistic DNA damage simulations can provide important limits on the extent to which physical processes can impact biology in low background experiments. We demonstrate the utility of these studies for low dose radiation biology calculating that in E. coli, the median rate at which the radiation background induces double strand breaks is 2.8 × 10⁻⁸ DSB day⁻¹, significantly less than the mutation rate per generation measured in E. coli, which is on the order of 10⁻³.     

Enhancing fluxes through the mevalonate pathway in Saccharomyces cerevisiae by engineering the HMGR and β-alanine metabolism

Mevalonate (MVA) pathway is the core for terpene and sterol biosynthesis, whose metabolic flux influences the synthesis efficiency of such compounds. Saccharomyces cerevisiae is an attractive chassis for the native active MVA pathway. Here, the truncated form of Enterococcus faecalis MvaE with only 3-Hydroxy-3-methylglutaryl coenzyme A reductase (HMGR) activity was found to be the most effective enzyme for MVA pathway flux using squalene as the metabolic marker, resulting in 431-fold and 9-fold increases of squalene content in haploid and industrial yeast strains respectively. Furthermore, a positive correlation between MVA metabolic flux and β-alanine metabolic activity was found based on a metabolomic analysis. An industrial strain SQ3-4 with high MVA metabolic flux was constructed by combined engineering HMGR activity, NADPH regeneration, cytosolic acetyl-CoA supply and β-alanine metabolism. The strain was further evaluated as the chassis for terpenoids production. Strain SQ3-4-CPS generated from expressing β-caryophyllene synthase in SQ3-4 produced 11.86 ± 0.09 mg l⁻¹ β-caryophyllene, while strain SQ3-5 resulted from down-regulation of ERG1 in SQ3-4 produced 408.88 ± 0.09 mg l⁻¹ squalene in shake flask cultivations. Strain SQ3-5 produced 4.94 g l⁻¹ squalene in fed-batch fermentation in cane molasses medium, indicating the promising potential for cost-effective production of squalene.     

Restriction enzymes increase efficiencies of illegitimate DNA integration but decrease homologous integration in mammalian cells

Mammalian cells repair DNA double-strand breaks by illegitimate end-joining or by homologous recombination. We investigated the effects of restriction enzymes on illegitimate and homologous DNA integration in mammalian cells. A plasmid containing the neo^R expression cassette, which confers G418 resistance, was used to select for illegitimate integration events in CHO wild-type and xrcc5 mutant cells. Co-transfection with the restriction enzymes BamHI, BglII, EcoRI and KpnI increased the efficiency of linearized plasmid integration up to 5-fold in CHO cells. In contrast, the restriction enzymes did not increase the integration efficiency in xrcc5 mutant cells. Effects of restriction enzymes on illegitimate and homologous integration were also studied in mouse embryonic stem (ES) cells using a plasmid containing the neo^R gene flanked by exon 3 of Hprt. The enzymes BamHI, BglII and EcoRI increased the illegitimate integration efficiency of transforming DNA several-fold, similar to the results for CHO cells. However, all three enzymes decreased the absolute frequency of homologous integration ~2-fold, and the percentage of homologous integration decreased >10-fold. This suggests that random DNA breaks attract illegitimate recombination (IR) events that compete with homology search.     

Molecular cloning and sequence analysis of the lysR gene from the extremely thermophilic eubacterium, Thermus thermophilus HB27

We have isolated a lysine-auxotrophic and kanamycin-resistant mutant from an extreme thermophile, Thermus thermophilus HB27. This mutant showed the lysA⁻ or lysR⁻ genotype since it could not grow on the minimal plate which contained diaminopimelic acid. Sequence analysis of the clones which could rescue the Lys⁻ mutant indicated the lysR gene. The lysR gene overlapped with the rimK gene for the modification enzyme of ribosomal protein S6. In the Lys⁻ mutant, the lysR gene was disrupted and the C-terminus region of the RimK protein was different from that of the wild-type, which contributed to the Lys⁻ and kanamycin-resistant phenotype. The deduced amino acid sequence of the lysR gene showed 20.9% identity with the LysR protein of Escherichia coli. The percentage of use of cytosine or guanine in the third letter of the codons in the lysR gene was only 67.4%. We also determined that the argC gene encoding N-acetyl-γ-glutamyl phosphate reductase and the argB gene encoding acetylglutamate kinase were located immediately upstream of the lysR gene.     

The regulation of the ammonia assimilatory enzymes in Rel+ and Rel- strains of Salmonella typhimurium

Summary The influence of the relA1 mutation on the regulation of the ammonia assimilatory enzymes, glutamate dehydrogenase (EC 1.4.1.4), glutamine synthetase (EC 6.3.1.2), and glutamate synthase (EC 1.4.1.3), was examined. When cells grown in rich media (either Luria broth or glucose-ammonia plus casamino acids) were transferred to a glucose-ammonia medium, the relA mutant failed to resume growth and did not have the same increase in any of the assimilatory enzyme activities as the rel ⁺ strain. This effect was particularly dramatic for glutamate dehydrogenase, which increased 6-fold in the rel ⁺ strain. Measurements of the guanosine nucleotide concentrations showed that the rel ⁺ strain had a ppGpp concentration about 9 times that of the relA mutant 5 min after the shift to minimal medium. These results are consistent with those for other biosynthetic enzymes and show that the ammonia assimilatory enzymes require a relA product for their synthesis during shifts from rich to minimal media. In addition, we examined the response of these strains to a change in nitrogen source. The relA mutant again failed to resume growth after a shift from glucose-ammonia to glucose-arginine medium. Even though the ppGpp concentration did not increase, the rel ⁺ strain grew and increased glutamine synthetase activities about 2-fold. These changes in the absence of increased ppGpp levels suggest that some other relA-mediated function is important during this change in nitrogen source.     

Site-directing an intense multipoint covalent attachment (MCA) of mutants of the Geobacillus thermocatenulatus lipase 2 (BTL2): Genetic and chemical amination plus immobilization on a tailor-made support

Immobilized enzymes are preferred over their soluble counterparts due to their robustness in harsh industrial processes; the most stable enzyme derivatives are often produced through multipoint covalent attachment (MCA). However, most enzymes are unable to establish optimal MCA to electrophile-type supports given the heterogeneous distribution and/or low content of primary amino groups on their surfaces; this restricts both the diversity of areas prone to react and the number of attachments to the support. To overcome this we propose combining site-directed immobilization and protein engineering to increase the number of bonds between a specific enzyme surface and a tailor-made support. We applied this novel strategy to engineered mutants of the lipase 2 from Geobacillus thermocatenulatus with one Cys exposed residue, that after genetic amination and/or chemical amination, were immobilized on glyoxyl-disulfide support using a site-directed MCA protocol. Two highly stabilized derivatives of chemically aminated lipase variants, in which site-directed MCA implied the surrounding surface of residues Cys344 or Cys40, were produced: the first one was 2.4-fold more productive than the reference derivative (648 g of hydrolyzed ester); the second derivative was 40% more selective (EPA/DHA molar ratio) and as active (1 μmol g catalyst⁻¹ min⁻¹) as the reference in the production of PUFAs.     

Double mutants of saccharomyces cerevisiae harbour stable plasmids: stable expression of a eukaryotic gene and the influence of host physiology during continuous culture

An investigation of the inheritance of a plasmid in a Saccharomyces cerevisiae ura3 furl double mutant has been performed in chemostat culture. The plasmid, bearing the gene for human α₁-antitrypsin and the yeast URA3 gene was observed to be stable over a range of dilution rates (0.1 h⁻¹–0.3 h⁻¹) corresponding to those growth rates most relevant to industrial bioprocesses using S. cerevisiae yeasts. The plasmid copy number remained constant in the respirative and in the oxidoreductive phases of growth. Stability of expression of the eukaryotic gene coding for α₁-antitrypsin was maintained at all dilution rates. However, the yield of α₁-antitrypsin was highest when the culture's carbon and energy source, glucose, was not completely utilized. The maximum respiratory capacity of the double mutant was observed to be typical for laboratory strains of S. cerevisiae. These data show that S. cerevisiae double mutants can be made to harbour stable plasmids which will stably express a eukaryotic gene. However, to achieve optimal recombinant product formation, careful attention must be paid to these yeasts' complex physiology.     

Fermentation of a wheat straw acid hydrolysate by Bacillus stearothermophilus T-13 in continuous culture with partial cell recycle

The effects of pretreatment by overliming and addition of nutrients (yeast extract, tryptone and ammonium chloride) on fermentation of mixed sugars derived by acid hydrolysis of the hemicellulose fraction of wheat straw with Bacilllus stearothermophilus strain T-13, an l-lactate dehydrogenase deficient mutant was investigated in continuous culture with partial cell recycle. Pretreatment and addition of nutrients to the hydrolysate improved the fermentation considerably. Sugar utilization, ethanol yields and productivities obtained in the treated hydrolysate with added nutrients were comparable to those obtained in a synthetic medium. Sugar utilization in the synthetic medium and treated and crude hydrolysates with added nutrients were 86%, 89% and 56%, respectively, compared with 45% in the treated hydrolysate without extra nutrients. Ethanol yields obtained were 0.32 g g⁻¹ sugars and 0.38 g g⁻¹ sugars in the treated hydrolysate with and without extra nutrients, respectively, compared with 0.24 g g⁻¹ sugars in the crude hydrolysate with added nutrients. Continuous culture with partial cell recycle significantly increased the rate of ethanol production (0.60–1.02 g litre⁻¹ h⁻¹) in the various media and the stability of the mutant strain compared with conventional continuous culture.     

Characterization and directed evolution of BliGO,a novel glycine oxidase from Bacillus licheniformis

Glycine oxidase (GO) has great potential for use in biosensors, industrial catalysis and agricultural biotechnology. In this study, a novel GO (BliGO) from a marine bacteria Bacillus licheniformis was cloned and characterized. BliGO showed 62% similarity to the well-studied GO from Bacillus subtilis. The optimal activity of BliGO was observed at pH 8.5 and 40 °C. Interestingly, BliGO retained 60% of the maximum activity at 0 °C, suggesting it is a cold-adapted enzyme. The kinetic parameters on glyphosate (K_m, k_cat and k_cat/K_m) of BliGO were 11.22 mM, 0.08 s⁻¹, and 0.01 mM⁻¹ s⁻¹, respectively. To improve the catalytic activity to glyphosate, the BliGO was engineered by directed evolution. With error-prone PCR and two rounds of DNA shuffling, the most evolved mutant SCF-4 was obtained from 45,000 colonies, which showed 7.1- and 8-fold increase of affinity (1.58 mM) and catalytic efficiency (0.08 mM⁻¹ s⁻¹) to glyphosate, respectively. In contrast, its activity to glycine (the natural substrate of GO) decreased by 113-fold. Structure modeling and site-directed mutation study indicated that Ser51 in SCF-4 involved in the binding of enzyme with glyphosate and played a crucial role in the improvement of catalytic efficiency.     

Extension of the yeast metabolic model to include iron metabolism and its use to estimate global levels of iron-recruiting enzyme abundance from cofactor requirements

Metabolic networks adapt to changes in their environment by modulating the activity of their enzymes and transporters; often by changing their abundance. Understanding such quantitative changes can shed light onto how metabolic adaptation works, or how it can fail and lead to a metabolically dysfunctional state. We propose a strategy to quantify metabolic protein requirements for cofactor-utilising enzymes and transporters through constraint-based modelling. The first eukaryotic genome-scale metabolic model to comprehensively represent iron metabolism was constructed, extending the most recent community model of the Saccharomyces cerevisiae metabolic network. Partial functional impairment of the genes involved in the maturation of iron-sulphur (Fe-S) proteins was investigated employing the model and the in silico analysis revealed extensive rewiring of the fluxes in response to this functional impairment, despite its marginal phenotypic effect. The optimal turnover rate of enzymes bearing ion cofactors can be determined via this novel approach; yeast metabolism, at steady state, was determined to employ a constant turnover of its iron-recruiting enzyme at a rate of 3.02 × 10 ⁻¹¹ mmol·(g biomass) ⁻¹·h ⁻¹.     

Environmental and nuclear influences on microalgal chloroplast gene expression

Microalgal chloroplasts, such as those of the model organism Chlamydomonas reinhardtii, are emerging as a new platform to produce recombinant proteins, including industrial enzymes, diagnostics, as well as animal and human therapeutics. Improving transgene expression and final recombinant protein yields, at laboratory and industrial scales, require optimization of both environmental and cellular factors. Most studies on C. reinhardtii have focused on optimization of cellular factors. Here, we review the regulatory influences of environmental factors, including light (cycle time, intensity, and quality), carbon source (CO₂ and organic), and temperature. In particular, we summarize their influence via the redox state, cis-elements, and trans-factors on biomass and recombinant protein production to support the advancement of emerging large-scale light-driven biotechnology applications.     

cis-benzeneglycol production using a mutant Pseudomonas strain

The biotransformation of commodity aromatic chemicals into dihydroxy derivatives was studied. A strain isolated from the invironment, Pseudomonas JI104, used benzene, toluene, and other hydrocarbons as sole carbon and energy sources. We selected mutants unable to grow with benzene, and among these, screened for strains with deficient cis-benzenglycol dehydrogenase able to stably produce cis-benzeneglycol when another carbon source was co-metabolized.We exained the possibility of cis-benzeneglycol production by growing the mutant strain in the presence of benzene vapor. Ethanol was the carbon and energy source most adapted to the cis-benzeneglycol production phase, and lactate or propanol could also be used. Glucose inhibited the production of the metabolite.The growth rates were barely affected by the presence of benzene at a reduced partial pressure (less than 20% of saturation), showing that continuous culture is possible. In a batch process, 0.54g·1⁻¹ of a cell suspension produced 5.1 mmol·1⁻¹cis-benzeneglycol in 27 h, using ethanol as the energy source.     

De novo production of versatile oxidized kaurene diterpenes in Escherichia coli

The oxidized kaurene (Ox-Kau) compounds are the core structures of many important diterpenoids with biological activities and economical values. However, easy access to diverse Ox-Kau products is still limited by low natural abundance, and large-scale manufacture remain challenging due to lack of proper heterologous production. To achieve an abundant source alternative to natural extracts, we here report a highly effective Escherichia coli-based platform for the de novo production of multiple Ox-Kau molecules from simple carbon source. Pathway optimization in prokaryotic cells through modification of transmembrane CYP450 oxidases, cytochrome b₅ co-expression and AlphaFold-based protein engineering improved a 50-fold yield of steviol (1.07 g L⁻¹), a key intermediate in the kaurenoid biosynthesis. Combinatorial biosynthetic strategy further led to a series of oxidized derivatives (20–600 mg L⁻¹) with rich oxygenated functional groups on C3, C7, C16 and C19 previously hard to be introduced. Our engineered strains not only laid a foundation for realizing the industrial fermentation of gram-scale ent-kaurene diterpenoids, but also provided a reliable platform for characterization and utilization of kaurene-modifying oxidases, which may generate naturally rare or unnatural ent-kaurenoids with potential bioactivity.     

In vitro production of n-butanol from glucose

The heat treatment of recombinant mesophiles having heterologous thermotolerant enzymes results in the one-step preparation of highly selective biocatalytic modules. The assembly of these modules enables us to readily construct an artificial metabolic pathway in vitro. In this work, we constructed a non-natural, cofactor-balanced, and oxygen-insensitive pathway for n-butanol production using 16 thermotolerant enzymes. The whole pathway was divided into 7 parts, in each of which NAD(H)-dependent enzymes were assigned to be the last step, and the fluxes through each part were spectrophotometrically determined. This real-time monitoring technique enabled the experimental optimization of enzyme level to achieve a desired production rate. Through the optimized pathway, n-butanol could be produced from glucose with a molar yield of 82% at a rate of 8.2 µmol l⁻¹ min⁻¹. Our approach would be widely applicable to the rational optimization of artificial metabolic pathways as well as to the in vitro production of value-added biomolecules.     

Production of d-proline from l-arginine using Pseudomonas aeruginosa

Several microorganisms that can use (S)-5-[(amino-iminomethyl) amino]-2-chloropentanoic acid (l-Cl-arginine) as a nitrogen source have been isolated, the most interesting of which is a spontaneous mutant of Pseudomonas aeruginosa PAO1 (DSM 10581). In a fermenter, this unique biocatalyst hydrolysed l-Cl-arginine to (S)-5-amino-2-chloropentanoic acid (l-Cl-ornithine), which spontaneously converted to d-proline with inversion of configuration at an apparent average rate of 0.12 mmol ^−l h⁻¹ OD⁻¹. The enzyme, for which we suggest the name Cl-arginine amidinohydrolase, was best induced by using the substrate l-Cl-arginine as inducer and l-arginine as nitrogen source. The results presented here describe a new route for the production of d-proline from l-arginine, involving a chemical step and a biocatalytic step followed by a spontaneous chemical cyclisation.