Stress-induced dissociations between intracellular calcium signaling and insulin secretion in pancreatic islets

In healthy pancreatic islets, glucose-stimulated changes in intracellular calcium ([Ca²⁺]_i) provide a reasonable reflection of the patterns and relative amounts of insulin secretion. We report that [Ca²⁺]_i in islets under stress, however, dissociates with insulin release in different ways for different stressors. Islets were exposed for 48 h to a variety of stressors: cytokines (low-grade inflammation), 28 mM glucose (28G, glucotoxicity), free fatty acids (FFAs, lipotoxicity), thapsigargin (ER stress), or rotenone (mitochondrial stress). We then measured [Ca²⁺]_i and insulin release in parallel studies. Islets exposed to all stressors except rotenone displayed significantly elevated [Ca²⁺]_i in low glucose, however, increased insulin secretion was only observed for 28G due to increased nifedipine-sensitive calcium-channel flux. Following 3–11 mM glucose stimulation, all stressors substantially reduced the peak glucose-stimulated [Ca²⁺]_i response (first phase). Thapsigargin and cytokines also substantially impacted aspects of calcium influx and ER calcium handling. Stressors did not significantly impact insulin secretion in 11 mM glucose for any stressor, although FFAs showed a borderline reduction, which contributed to a significant decrease in the stimulation index (11:3 mM glucose) observed for FFAs and also for 28G. We also clamped [Ca²⁺]_i using 30 mM KCl + 250 μM diazoxide to test the amplifying pathway. Only rotenone-treated islets showed a robust increase in 3–11 mM glucose-stimulated insulin secretion under clamped conditions, suggesting that low-level mitochondrial stress might activate the metabolic amplifying pathway. We conclude that different stressors dissociate [Ca²⁺]_i from insulin secretion differently: ER stressors (thapsigargin, cytokines) primarily affect [Ca²⁺]_i but not conventional insulin secretion and ‘metabolic’ stressors (FFAs, 28G, rotenone) impacted insulin secretion.     

Mitochondrial aldehyde dehydrogenase obliterates endoplasmic reticulum stress-induced cardiac contractile dysfunction via correction of autophagy

ER stress triggers myocardial contractile dysfunction while effective therapeutic regimen is still lacking. Mitochondrial aldehyde dehydrogenase (ALDH2), an essential mitochondrial enzyme governing mitochondrial and cardiac function, displays distinct beneficial effect on the heart. This study was designed to evaluate the effect of ALDH2 on ER stress-induced cardiac anomalies and the underlying mechanism involved with a special focus on autophagy. WT and ALDH2 transgenic mice were subjected to the ER stress inducer thapsigargin (1 mg/kg, i.p., 48 h). Echocardiographic, cardiomyocyte contractile and intracellular Ca^2 + properties as well as myocardial histology, autophagy and autophagy regulatory proteins were evaluated. ER stress led to compromised echocardiographic indices (elevated LVESD, reduced fractional shortening and cardiac output), cardiomyocyte contractile and intracellular Ca^2 + properties and cell survival, associated with upregulated autophagy, dampened phosphorylation of Akt and its downstream signal molecules TSC2 and mTOR, the effects of which were alleviated or mitigated by ALDH2. Thapsigargin promoted ER stress proteins Gadd153 and GRP78 without altering cardiomyocyte size and interstitial fibrosis, the effects of which were unaffected by ALDH2. Treatment with thapsigargin in vitro mimicked in vivo ER stress-induced cardiomyocyte contractile anomalies including depressed peak shortening and maximal velocity of shortening/relengthening as well as prolonged relengthening duration, the effect of which was abrogated by the autophagy inhibitor 3-methyladenine and the ALDH2 activator Alda-1. Interestingly, Alda-1-induced beneficial effect against ER stress was obliterated by autophagy inducer rapamycin, Akt inhibitor AktI and mTOR inhibitor RAD001. These data suggest a beneficial role of ALDH2 against ER stress-induced cardiac anomalies possibly through autophagy reduction.     

Cloning and structural analysis of the murine GCN5L1 gene

We recently cloned the murine 11-cis retinol dehydrogenase gene. A second gene, the murine GCN5L1 gene, was found to be situated upstream of the murine 11-cis retinol dehydrogenase gene. We have isolated and sequenced the complete coding sequence of the murine GCN5L1 gene. The distance between the 3′-end of the murine GCN5L1 gene and the 5′-end of the 11-cis retinol dehydrogenase gene is only 776 nt. The murine GCN5L1 gene consists of four exons encompassing approximately 3.5 kb of genomic DNA. Intron/exon splice sites conform to the GT/AG rule. The open reading frame consists of 375 nucleotides encoding a 14 kDa protein. The murine GCN5L1, like the human GCN5L1 protein, displays weak homology (27%) to yeast GCN5. The distance between the murine, human and bovine GCN5L1 and 11-cis retinol dehydrogenase genes appeared to be conserved.     

Production of l-phenylalanine from glucose by metabolic engineering of wild type Escherichia coli W3110

The market of l-phenylalanine has been stimulated by the great demand for the low-calorie sweetener aspartame. In this paper, the effects of pivotal genes on l-phenylalanine production were evaluated by metabolic engineering of wild type Escherichia coli. The bifunctional PheA protein contains two catalytic domains (chorismate mutase and prephenate dehydratase activities) as well as one R-domain (for feedback inhibition by l-phenylalanine). The catalytic domain of PheA was overexpressed to increase l-phenylalanine production. It was firstly indicated that this domain could enhance the metabolic influx to overproduce l-phenylalanine and improve the survival ability under m-Fluoro-dl-phenylalanine stress. Furthermore, the fermentation performance of aroG feedback inhibition resistant mutants was firstly compared, aroG29 and aroG15 increased the l-phenylalanine concentration by 5-fold. After that the expression of aroK and ydiB was also elevated, and the l-phenylalanine yield on cell (0.79 g/g) and maximum l-phenylalanine productivity (0.073 g/L/h) were subsequently doubled. Meanwhile, the l-phenylalanine yield on glucose increased from 0.124 g/g to 0.153 g/g. It was found that genes ydiB and aroK could elevate the l-phenylalanine yield and productivity and shorten the lag phase.     

Over expression of GroESL in Cupriavidus necator for heterotrophic and autotrophic isopropanol production

We previously reported a metabolic engineering strategy to develop an isopropanol producing strain of Cupriavidus necator leading to production of 3.4 g L⁻¹ isopropanol. In order to reach higher titers, isopropanol toxicity to the cells has to be considered. A toxic effect of isopropanol on the growth of C. necator has been indeed observed above a critical value of 15 g L⁻¹. GroESL chaperones were first searched and identified in the genome of C. necator. Native groEL and groES genes from C. necator were over-expressed in a strain deleted for PHA synthesis. We demonstrated that over-expressing groESL genes led to a better tolerance of the strain towards exogenous isopropanol. GroESL genes were then over-expressed within the best engineered isopropanol producing strain. A final isopropanol concentration of 9.8 g L⁻¹ was achieved in fed-batch culture on fructose as the sole carbon source (equivalent to 16 g L⁻¹ after taking into account evaporation). Cell viability was slightly improved by the chaperone over-expression, particularly at the end of the fermentation when the isopropanol concentration was the highest. Moreover, the strain over-expressing the chaperones showed higher enzyme activity levels of the 2 heterologous enzymes (acetoacetate carboxylase and alcohol dehydrogenase) of the isopropanol synthetic operon, translating to a higher specific production rate of isopropanol at the expense of the specific production rate of acetone. Over-expressing the native chaperones led to a 9–18% increase in the isopropanol yield on fructose.     

Influence of specific growth rate over the secretory expression of recombinant potato carboxypeptidase inhibitor in fed-batch cultures of Escherichia coli

A high cell density cultivation protocol was developed for the secretory production of potato carboxypeptidase inhibitor (PCI) in Escherichia coli. The strain BW25113 (pIMAM3) was cultured in fed-batch mode employing minimal media and an exponential feed profile where the specific growth rate was fixed by limitation of the fed carbon source (glycerol). Plasmid loss rates were found to be proportional to the specific growth rate. Distribution of PCI along the cell compartments and the culture media was also dependent on the fixed growth rate. When specific growth rate was kept at μ = 0.10 h⁻¹, 1.4 g PCI L⁻¹ were obtained when adding the product present in periplasmic extracts and supernatant fractions, with a 50% of the total expressed protein recovered from the extracellular medium. This constituted a 1.2-fold increase compared to growth at μ = 0.15 h⁻¹, and 2.0-fold compared to μ = 0.25 h⁻¹. Last, a cell permeabilization treatment with Triton X-100 and glycine was employed to direct most of the product to the culture media, achieving over 81% of extracellular PCI. Overall, our results point out that production yields of secretory proteins in fed-batch cultures of E. coli can be improved by means of process variables, with applications to the production of small disulfide-bridged proteins. Overall, our results point out that control of the specific growth rate is a successful strategy to improve the production yields of secretory expression in fed-batch cultures of E. coli, with applications to the production of small disulfide-bridged proteins.     

Effect of vitamin E and menadione supplementation on riboflavin production and stress parameters in Ashbya gossypii

Ashbya gossypii is a filamentous fungus which overproduces riboflavin as a pseudo-secondary metabolite. Vitamin E supplemented at 1, 2.5 and 5 μM levels in the growth medium of A. gossypii increased the extracellular secretion of riboflavin and at 50, 100 and 240 μM levels reduced the biomass and riboflavin yield. With 2.5 μM vitamin E total riboflavin production and extracellular riboflavin secretion on day 2 was higher than non-supplemented control. By day 3 the production in supplemented was nearly the same as in non-supplemented, but the intracellular riboflavin levels were lower and extracellular levels higher. Supplemented cells showed increased levels of catalase, glutathione peroxidase, lipid peroxides and membrane lipid peroxides, and decreased glutathione indicating that vitamin E, a well-known antioxidant, had acted as a pro-oxidant at low levels of 2.5 μM and had increased the oxidative stress. Menadione, a well known oxidant also increased riboflavin production and secretion at 1.0, 2.5 and 5.0 μM level. This is the first report were vitamin E and menadione effects support the concept that overproduction of riboflavin is a stress induced phenomenon. These findings are not only of scientific interest but also useful for improving the industrial production of riboflavin.     

Development of a recombinant Escherichia coli-based biocatalyst to enable high styrene epoxidation activity with high product yield on energy source

A highly active recombinant whole-cell biocatalyst, Escherichia coli pETAB2/pG-KJE1, was developed for the efficient production of (S)-styrene oxide from styrene. The recombinant E. coli overexpressed styAB the genes of styrene monooxygenase of Pseudomonas putida SN1 and coexpressed the genes encoding chaperones (i.e., GroEL–GroES and DnaK–DnaJ–GrpE). The styrene monooxygenases were produced to ca. 40% of the total soluble proteins, enabling the whole-cell activity of the recombinant of 180 U/g CDW. The high StyAB activity in turn appeared to direct cofactors and molecular oxygen to styrene epoxidation. The product yield on energy source (i.e., glucose) reached ca. 40%. In addition, biotransformation in an organic/aqueous two-liquid phase system allowed the product to accumulate to 400 mM in the organic phase within 6 h, resulting in an average specific and volumetric productivity of 6.4 mmol/g dry cells/h (106 U/g dry cells) and 67 mM/h (1110 U/L_aq), respectively, under mild reaction conditions. These results indicated that the high productivity and the high product yield on energy source were driven by the high enzyme activity. Therefore, it was concluded that oxygenase activity of whole-cell biocatalysts is one of the critical factors to determine their catalytic performance.     

Evolutionary adaptation of Kluyveromyces marxianus strain for efficient conversion of whey lactose to bioethanol

The aim of the present work is to develop an osmotolerant yeast strain with high lactose utilization and further use it to ferment lactose rich whey permeate for high ethanol titer and to reduce energy consumption. Ethanol production and growth rate of selected MTCC 1389 strain were quite high in whey containing lactose up to 150 g/L but it remains constant in lactose concentration (200 g/L) as cells encountered osmotic stress. Thus, strain MTCC 1389 was used for an adaptation to lactose concentration 200 g/L for 65 days and used further for fermentation of lactose rich whey. Fermentation with an adapted K. marxianus MTCC 1389 strain in laboratory fermenter resulted in ethanol titer of 79.33 g/L which is nearly 17.5% higher than the parental strain (66.75 g/L). Expression analysis of GPD1, TPS1and TPS2 found upregulated in lactose adapted K. marxianus strain as compared to the parental strain. These results suggest that an adapted K. marxianus strain accumulates glycerol and trehalose in response to lactose stress and improve osmotolerance in K. marxianus cells. Thus, the study illustrates that evolutionary engineering is an efficient strategy to obtain a superior biofuel yeast strain, which efficiently ferments four-fold concentrated cheese whey.     

Cloning,heterologous expression and characterization of two keratinases from Stenotrophomonas maltophilia BBE11-1

The keratin-degrading strain Stenotrophomonas maltophilia BBE11-1 secretes two keratinolytic proteases, KerSMD and KerSMF. However, the genes encoding these proteases remain unknown. Here, we have isolated these two genes with a modified TAIL-PCR (thermal asymmetric interlaced PCR) method based on the N-terminal amino acid sequences of mature keratinases. These two keratinase genes encode serine proteases with PPC (bacterial pre-peptidase C-terminal) domain, which are successfully expressed with the help of pelB leader in Escherichia coli cells. Recombinant KerSMD (48 kDa) shows a better activity in feather degradation, higher thermostability and substrate specificity than KerSMF (40 kDa). KerSMD has a t_1/2 of 90 min at 50 °C and 64 min at 60 °C, and a better tolerance to surfactants SDS and triton X-100. The predicted model of KerSMD helps to explain the phenomenon of auto-catalytic C-terminal propeptide truncation, the special function of PPC domain, and the molecular weight of the C-terminal-processed mature keratinase KerSMD. This work not only provides a new way to overproduce keratinases but also helps to explore keratinases folding mechanism.     

Modulation of guanosine 5′-diphosphate-d-mannose metabolism in recombinant Escherichia coli for production of guanosine 5′-diphosphate-l-fucose

Guanosine 5’-diphosphate (GDP)-l-fucose, an activated form of a nucleotide sugar, plays an important role in a wide range of biological functions. In this study, the enhancement of GDP-l-fucose production was attempted by supplementation of mannose, which is a potentially better carbon source to be converted into GDP-l-fucose than glucose, and combinatorial overexpression of the genes involved in the biosynthesis of GDP-d-mannose, a precursor of GDP-l-fucose. Supply of a mannose and glucose led to a 1.3-fold-increase in GDP-l-fucose concentration (52.5 ± 0.8 mg l^?1) in a fed-batch fermentation of recombinant E. coli BL21star(DE3) overexpressing the gmd and wcaG genes, compared with the case using glucose as a sole carbon source. A maximum GDP-l-fucose concentration of 170.3 ± 2.3 mg l^?1, corresponding to a 4.4-fold enhancement compared with the control strain overexpressing gmd and wcaG genes only, was achieved in a glucose-limited fed-batch fermentation of a recombinant E. coli BL21star(DE3) strain overexpressing manB, manC, gmd and wcaG genes. Further improvement of GDP-l-fucose production was not obtained by additional overexpression of the manA gene.     

Cellular cholesterol accumulation modulates high fat high sucrose (HFHS) diet-induced ER stress and hepatic inflammasome activation in the development of non-alcoholic steatohepatitis

Non-alcoholic steatohepatitis (NASH), is the form of non-alcoholic fatty liver disease posing risk to progress into serious long term complications. Human and pre-clinical models implicate cellular cholesterol dysregulation playing important role in its development. Mouse model studies suggest synergism between dietary cholesterol and fat in contributing to NASH but the mechanisms remain poorly understood. Our laboratory previously reported the primary importance of hepatic endoplasmic reticulum cholesterol (ER-Chol) in regulating hepatic ER stress by comparing the responses of wild type, Ldlr −/− xLcat +/+ and Ldlr −/− xLcat −/− mice, to a 2% high cholesterol diet (HCD). Here we further investigated the roles of ER-Chol and ER stress in HFHS diet-induced NASH using the same strains. With HFHS diet feeding, both WT and Ldlr −/− xLcat +/+ accumulate ER-Chol in association with ER stress and inflammasome activation but the Ldlr −/− xLcat −/− mice are protected. By contrast, all three strains accumulate cholesterol crystal, in correlation with ER-Chol, albeit less so in Ldlr −/− xLcat −/− mice. By comparison, HCD feeding per se (i) is sufficient to promote steatosis and activate inflammasomes, and (ii) results in dramatic accumulation of cholesterol crystal which is linked to inflammasome activation in Ldlr −/− xLcat −/− mice, independent of ER-Chol. Our data suggest that both dietary fat and cholesterol each independently promote steatosis, cholesterol crystal accumulation and inflammasome activation through distinct but complementary pathways. In vitro studies using palmitate-induced hepatic steatosis in HepG2 cells confirm the key roles by cellular cholesterol in the induction of steatosis and inflammasome activations. These novel findings provide opportunities for exploring a cellular cholesterol-focused strategy for treatment of NASH.     

Enhanced parkin levels favor ER-mitochondria crosstalk and guarantee Ca2 + transfer to sustain cell bioenergetics

Loss-of-function mutations in PINK1 or parkin genes are associated with juvenile-onset autosomal recessive forms of Parkinson disease. Numerous studies have established that PINK1 and parkin participate in a common mitochondrial-quality control pathway, promoting the selective degradation of dysfunctional mitochondria by mitophagy. Upregulation of parkin mRNA and protein levels has been proposed as protective mechanism against mitochondrial and endoplasmic reticulum (ER) stress. To better understand how parkin could exert protective function we considered the possibility that it could modulate the ER–mitochondria inter-organelles cross talk. To verify this hypothesis we investigated the effects of parkin overexpression on ER–mitochondria crosstalk with respect to the regulation of two key cellular parameters: Ca^2 + homeostasis and ATP production. Our results indicate that parkin overexpression in model cells physically and functionally enhanced ER–mitochondria coupling, favored Ca^2 + transfer from the ER to the mitochondria following cells stimulation with an 1,4,5 inositol trisphosphate (InsP₃) generating agonist and increased the agonist-induced ATP production. The overexpression of a parkin mutant lacking the first 79 residues (ΔUbl) failed to enhance the mitochondrial Ca^2 + transients, thus highlighting the importance of the N-terminal ubiquitin like domain for the observed phenotype. siRNA-mediated parkin silencing caused mitochondrial fragmentation, impaired mitochondrial Ca^2 + handling and reduced the ER–mitochondria tethering. These data support a novel role for parkin in the regulation of mitochondrial homeostasis, Ca^2 + signaling and energy metabolism under physiological conditions.     

Hexokinase—A limiting factor in lipid production from fructose in Yarrowia lipolytica

Microbial biolipid production has become an important part of making biofuel production economically feasible. Genetic engineering has been used to improve the ability of Yarrowia lipolytica, an oleaginous yeast, to produce lipids using glucose-based media. However, few studies have examined lipid accumulation by Y. lipolytica׳s ability to utilize other hexose sugars, and as of yet, the rate-limiting steps in this process are unidentified. In this study, we investigated the de novo accumulation of lipids by Y. lipolytica when grown in glucose, fructose, and sucrose. Three Y. lipolytica wild-type (WT) strains of varied origin differed significantly in their lipid production, growth, and fructose utilization. Hexokinase (ylHXK1p) activity partially explained these differences. Overexpression of the ylHXK1 gene led to increased hexokinase activity (6.5–12 times higher) in the mutants versus the WT strains; a pronounced reduction in cell filamentation in mutants grown in fructose-based media; and improved biomass production, particularly in the mutant whose parent had shown the lowest growth capacity in fructose (French strain W29). All mutants showed improved lipid yield and production when grown on fructose, although the effect was strain dependent (23–55% improvement). Finally, we overexpressed ylHXK1 in a highly modified strain of Y. lipolytica W29 engineered to optimize oil production. This modification was combined with Saccharomyces cerevisiae invertase gene expression to evaluate the resulting mutant׳s ability to produce lipids using cheap industrial substrates, namely sucrose (a major component of molasses). Sucrose turned out to be a better substrate than either of its building blocks, glucose or fructose. Over its 96 h of growth in the bioreactors, this highly modified strain produced 9.15 g L⁻¹ of lipids, yielding 0.262 g g⁻¹ of biomass.     

Metabolic engineering of Escherichia coli for the production of 5-aminovalerate and glutarate as C5 platform chemicals

5-Aminovalerate (5AVA) is the precursor of valerolactam, a potential building block for producing nylon 5, and is a C5 platform chemical for synthesizing 5-hydroxyvalerate, glutarate, and 1,5-pentanediol. Escherichia coli was metabolically engineered for the production of 5-aminovalerate (5AVA) and glutarate. When the recombinant E. coli WL3110 strain expressing the Pseudomonas putida davAB genes encoding delta-aminovaleramidase and lysine 2-monooxygenase, respectively, were cultured in a medium containing 20 g/L of glucose and 10 g/L of l-lysine, 3.6 g/L of 5AVA was produced by converting 7 g/L of l-lysine. When the davAB genes were introduced into recombinant E. coli strainXQ56allowing enhanced l-lysine synthesis, 0.27 and 0.5 g/L of 5AVA were produced directly from glucose by batch and fed-batch cultures, respectively. Further conversion of 5AVA into glutarate could be demonstrated by expression of the P. putida gabTD genes encoding 5AVA aminotransferase and glutarate semialdehyde dehydrogenase. When recombinant E. coli WL3110 strain expressing the davAB and gabTD genes was cultured in a medium containing 20 g/L glucose, 10 g/L l-lysine and 10 g/L α-ketoglutarate, 1.7 g/L of glutarate was produced.     

Immobilized glucose oxidase on different supports for biotransformation removal of glucose from oligosaccharide mixtures

Four immobilized forms of glucose oxidase (GOD) were used for biotransformation removal of glucose from its mixture with dextran oligosaccharides. GOD was biospecifically bound to Concanavalin A-bead cellulose (GOD-ConA-TBC) and covalently to triazine-bead cellulose (GOD-TBC). Eupergit C and Eupergit CM were used for preparation of other two forms of immobilized GOD: GOD-EupC and GOD-EupCM. GOD-ConA-TBC and GOD-EupC exhibited the best operational and storage stabilities. pH and temperature optima of these two immobilized enzyme forms were broadened and shifted to higher values (pH 7 and 35 °C) in comparison with those of free GOD. The decrease of V_max values after immobilization was observed, from 256.8 ± 7.0 μmol min⁻¹ mg_GOD⁻¹ for free enzyme to 63.8 ± 4.2 μmol min⁻¹ mg_GOD⁻¹ for GOD-ConA-TBC and 45 ± 2.7 μmol min⁻¹ mg_GOD⁻¹ for GOD-EupC, respectively. Depending on the immobilization mode, the immobilized GODs were able to decrease the glucose content in solution to 3.8–15.6% of its initial amount The best glucose conversion, was achieved by an action of GOD-EupCM on a mixture of 100 g dextran with 9 g of glucose (i.e. 98.7% removal of glucose).     

The first crenarchaeon capable of growth by anaerobic carbon monoxide oxidation coupled with H2 production

The ability to grow by anaerobic CO oxidation with production of H₂ from water is known for some thermophilic bacteria, most of which belong to Firmicutes, as well as for a few hyperthermophilic Euryarchaeota isolated from deep-sea hydrothermal habitats. A hyperthermophilic, neutrophilic, anaerobic filamentous archaeon strain 1505 = VKM B-3180 = KCTC 15798 was isolated from a terrestrial hot spring in Kamchatka (Russia) in the presence of 30% CO in the gas phase. Strain 1505 could grow lithotrophically using carbon monoxide as the energy source with the production of hydrogen according to the equation CO + H₂O → CO₂ + H₂; mixotrophically on CO plus glucose; and organotrophically on peptone, yeast extract, glucose, sucrose, or Avicel. The genome of strain 1505 was sequenced and assembled into a single chromosome. Based on 16S rRNA gene sequence analysis and in silico genome-genome hybridization, this organism was shown to be closely related to the Thermofilum adornatum species. In the genome of Thermofilum sp. strain 1505, a gene cluster (TCARB_0867-TCARB_0879) was found that included genes of anaerobic (Ni,Fe-containing) carbon monoxide dehydrogenase and genes of energy-converting hydrogenase ([Ni,Fe]-CODH–ECH gene cluster). Compared to the [Ni,Fe]-CODH–ECH gene clusters occurring in the sequenced genomes of other H₂-producing carboxydotrophs, the [Ni,Fe]-CODH–ECH gene cluster of Thermofilum sp. strain 1505 presented a novel type of gene organization. The results of the study provided the first evidence of anaerobic CO oxidation coupled with H₂ production performed by a crenarchaeon, as well as the first documented case of lithotrophic growth of a Thermofilaceae representative.     

Metabolic engineering of Bacillus sp. for diacetyl production

Diacetyl, a highly valuable product that is extensively used as an ingredient of food, tobacco, and daily chemicals such as perfumes, can be produced from the nonenzymatic oxidative decarboxylation of α-acetolactate during bacterial fermentation and converted to acetoin and 2,3-butanediol by 2,3-butanediol dehydrogenase. In the present study, Bacillus sp. DL01, which gives high acetoin production, was metabolically engineered to improve diacetyl production. After the deletion of α-acetolactate decarboxylase (ALDC)-encoding gene (alsD) by homologous recombination, the engineered strain, named Bacillus sp. DL01-ΔalsD, lost ALDC activity and produced 1.53 g/L diacetyl without acetoin and 2,3-butanediol accumulation. The channeling of carbon flux into diacetyl biosynthetic pathway was amplified by an overexpressed α-acetolactate synthase (ALS)-encoding gene (alsS) in Bacillus sp. DL01-ΔalsD-alsS, which produced 4.02 g/L α-acetolactate and 1.94 g/L diacetyl, and the conversion from α-acetolactate to diacetyl was increased by 1-fold after 20 mM Fe³⁺ was added to the fermentation medium. A titer of 8.69 g/L diacetyl, the highest reported diacetyl production, was achieved by fed-batch fermentation in optimal conditions using the metabolically engineered strain of Bacillus sp. DL01-ΔalsD-alsS. These results are of great importance as a new method for the efficient production of diacetyl by food-safe bacteria.     

Xylose isomerase overexpression along with engineering of the pentose phosphate pathway and evolutionary engineering enable rapid xylose utilization and ethanol production by Saccharomyces cerevisiae

Xylose is the main pentose and second most abundant sugar in lignocellulosic feedstocks. To improve xylose utilization, necessary for the cost-effective bioconversion of lignocellulose, several metabolic engineering approaches have been employed in the yeast Saccharomyces cerevisiae. In this study, we describe the rational metabolic engineering of a S. cerevisiae strain, including overexpression of the Piromyces xylose isomerase gene (XYLA), Pichia stipitis xylulose kinase (XYL3) and genes of the non-oxidative pentose phosphate pathway (PPP). This engineered strain (H131-A3) was used to initialize a three-stage process of evolutionary engineering, through first aerobic and anaerobic sequential batch cultivation followed by growth in a xylose-limited chemostat. The evolved strain H131-A3-AL^CS displayed significantly increased anaerobic growth rate (0.203±0.006 h^?1) and xylose consumption rate (1.866 g g^?1 h^?1) along with high ethanol conversion yield (0.41 g/g). These figures exceed by a significant margin any other performance metrics on xylose utilization and ethanol production by S. cerevisiae reported to-date. Further inverse metabolic engineering based on functional complementation suggested that efficient xylose assimilation is attributed, in part, to the elevated expression level of xylose isomerase, which was accomplished through the multiple-copy integration of XYLA in the chromosome of the evolved strain.