Bioreactor for glycerol conversion into H2 by bacterium Enterobacter aerogenes

Glycerol was used as a substrate for H₂ production by bacterium Enterobacter aerogenes in the test tubes and bioreactor. A BioFlo/CelliGen 115 bioreactor (10 L working volume) was utilized to conduct the experiments for conversion of glycerol into H₂ by E. aerogenes cells. The highest H₂ production rate was observed under 2% glycerol in the culture medium. The glycerol uptake efficiency by bacteria in the bioreactor was found to be 65% during the 6 day period, matching glycerol uptake efficiency observed in the test tubes experiment (65%).Hydrogen production from glycerol (2% glycerol, v/v) by E. aerogenes in the bioreactor and test tubes was measured over the 6 days, showing the maximal H₂ rate at 650 mL g⁻¹ dry weight h⁻¹. The yield of H₂ production from glycerol at 0.89 mol/mol in the bioreactor was high, corresponding to the theoretical yield of 1 mol of H₂ per 1 mol of glycerol.     

Simultaneous production of hydrogen and ethanol from waste glycerol by Enterobacter aerogenes KKU-S1

Factors affecting simultaneous hydrogen and ethanol production from waste glycerol by a newly isolated bacterium Enterobacter aerogenes KKU-S1 were investigated employing response surface methodology (RSM) with central composite design (CCD). The Plackett-Burman design was first used to screen the factors influencing simultaneous hydrogen and ethanol production, i.e., initial pH, temperature, amount of vitamin solution, yeast extract (YE) concentration and glycerol concentration. Results indicated that initial pH, temperature, YE concentration, and glycerol concentration had a statistically significant effect (p ≤ 0.05) on hydrogen production rate (HPR) and ethanol production. The significant factors were further optimized using CCD. Optimum conditions for simultaneously maximizing HPR and ethanol production were YE concentration of 1.00 g/L, glycerol concentration of 37 g/L, initial pH of 8.14, and temperature of 37 °C in which a maximum HPR and ethanol production of 0.24 mmol H₂/L h and 120 mmol/L were achieved.     

Regulation of hydrogen production by Enterobacter aerogenes by external NADH and NAD

Experiments involving the addition of external nicotinamide adenine dinucleotide, reduced form (NADH) or nicotinamide adenine dinucleotide (NAD⁺) have been designed to examine how the hydrogen in Enterobacter aerogenes is liberated by NADH or NAD⁺. The addition of external NADH or NAD⁺ was found to regulate hydrogen production by E. aerogenes in resting cells, batch cultures, and chemostat cultures. Particularly in chemostat cultivation, with the external addition of NADH, hydrogen production via the NADH pathway was decreased, while that via the formate pathway was increased; in the end, the overall hydrogen p was decreased. The addition of NAD⁺, on the other hand, gave the opposite results. The membrane-bound hydrogenase was found to play a central role in regulating hydrogen production. The occurrence of NADH oxidation (NAD⁺ reduction) on the cell membrane resulted in an electron flow across the membrane; this changed the oxidation state and metabolic pattern of the cells, which eventually affected the hydrogen evolution.     

Effects of increasing the NAD(H) pool on hydrogen production and metabolic flux distribution in Enterobacter aerogenes mutants

The effects of combining two strategies, recycling NAD and improving the availability of NADH, on hydrogen production in Enterobacter aerogenes were investigated. The NAD synthetase encoded by nadE gene was homologously overexpressed in AB91002-O, which had been obtained previously, to increase the intracellular concentration of the NAD(H/⁺) pool. This overexpression was duplicated in mutant strains in which the phosphoenolpyruvate carboxylase (PEPC) gene (ppc) and hybO gene were knocked out, yielding AB91102-OP (ΔhybO/Δppc), AB91102-ON (ΔhybO/nadE), and AB91102-OP/N (ΔhybO/Δppc/nadE). Chemostat experiments showed that the total NAD(H) pool size in AB91102-ON increased 2-fold compared with the control strain AB91102-OC, but the NADH/NAD⁺ ratio decreased by 24%. Metabolic analysis of batch experiments indicated that a larger NAD(H/⁺) pool and inactivation of PEPC led to a significant shift in metabolic patterns, whereas a smaller NADH/NAD⁺ ratio improved glucose uptake. Thus, compared with the control strain, the hydrogen yields per glucose of the mutant strains AB91102-OP, AB91102-ON, and AB91102-OP/N were enhanced by 36.2%, 66.0%, and 149%, respectively, and the total volumes of hydrogen production increased by 27%, 165%, and 301%, respectively. The maximum hydrogen production of 5.1 L/L was achieved by AB91102-OP/N, suggesting that the double modification strategy exhibits markedly positive synergistic effects on hydrogen production.     

Optimization of media composition for the production of biohydrogen from waste glycerol

Enterobacter aerogenes has a known ability to convert glycerol during a fermentative process to yield hydrogen and ethanol as the main products. A Box-Behnken design and response surface methodology were used to determine the optimal concentration of some media constituents and oxygen to maximize the yield of biohydrogen. Results indicated that the concentration of the salts studied: NH₄NO₃, FeSO₄, and Na₂HPO₄ and; the presence of oxygen in the pre-culture significantly influence the production of biohydrogen. Optimal conditions were determined to be 7.5% O₂ in the inoculum transfer step, ratio of inocula 18%, 8 g/L of Na₂HPO₄, 0.00625 g/L of FeSO₄ and 1.5 g/L of NH₄NO₃. These optimal conditions resulted in a measured yield of 0.85 mol H₂/mol glycerol at a substrate concentration of 15 g/L and a maximum predicted yield of 0.95 mol H₂/mol glycerol at a substrate concentration of 21 g/L. These results were obtained using lower concentrations of salts than in previous studies, corresponding to a 76% cost savings. These experimental results also demonstrated the importance of optimizing the amount of oxygen present in the biological system rather than maintaining complete anaerobic conditions.     

Perturbation of formate pathway for hydrogen production by expressions of formate hydrogen lyase and its transcriptional activator in wild Enterobacter aerogenes and its mutants

To examine perturbation effects of formate pathway on hydrogen productivity in Enterobacter aerogenes (Ea), formate dehydrogenase FDH-H gene (fdhF) and formate hydrogen lyase activator protein FHLA gene (fhlA) originated from Escherichia coli, were overexpressed in the wild strain Ea, its hycA-deleted mutant (A) by knockout the formate hydrogen lyase repressor and hybO-deleted mutant (O) by knockout of the uptake hydrogenase, respectively. Overexpression of fdhF and fhlA promoted cell growth and volumetric hydrogen production rates of all the strains, and the hydrogen production per gram cell dry weight (CDW) for Ea, A and O was increased by 38.5%, 21.8% and 5.25%, respectively. The fdhF and fhlA overexpression improved the hydrogen yield per mol glucose of strains Ea and A, but declined that of strain O. The increase of hydrogen yield of the strain Ea with fdhF and fhlA expression was mainly attributed to the increase of formate pathway, while for the mutant A, the improved hydrogen yield with fdhF and fhlA expression was mainly due to the increase of NADH pathway. Analysis of the metabolites and ratio of ethanol-to-acetate showed that the cellular redox state balance and energy level were also changed for these strains by fdhF and fhlA expression. These findings demonstrated that the hydrogen production was not only dependent on the hydrogenase genes, but was also affected by the regulation of the whole metabolism. Therefore, fdhF and fhlA expression in different strains of E. aerogenes could exhibit different perturbation effects on the metabolism and the hydrogen productivity.     

Impairment of NADH dehydrogenase for increased hydrogen production and its effect on metabolic flux redistribution in wild strain and mutants of Enterobacter aerogenes

An NADH dehydrogenase encoded by the nuo cluster was isolated and impaired by knocking out the nuoB gene in Enterobacter aerogenes to examine its effect on hydrogen production. Three nuoB-deleted mutant strains were constructed from the wild-type strain E. aerogenes IAM1183 and two recombinant strains, IAM1183-A (ΔhycA) and IAM1183-O (ΔhybO), from which the hycA and hybO genes had already been deleted previously, respectively. Compared with the performance of the wild-type strain, the overall hydrogen production of the mutants IAM1183-B (ΔnuoB), IAM1183-AB (ΔhycA/ΔnuoB) and IAM1183-BO (ΔhybO/ΔnuoB) was increased by 49.2%, 54.0%, and 52.4% in batch culture, respectively. The hydrogen yields from glucose by the three mutants IAM1183-B, IAM1183-AB, IAM1183-BO were 1.38, 1.49, and 1.39 mol H₂/mol glucose, respectively, while it was 1.16 mol H₂/mol glucose in the wild-type strain. Metabolic flux analysis indicated that all three mutants exhibited reduced fluxes to lactate production, and enhanced fluxes toward the generation of hydrogen, acetate, ethanol, succinate and 2,3-butanediol. Both the formate pathway and the NADH pathway contributed to increased hydrogen production in the mutant strains. The assay of 4 NADH-mediated enzyme activities (H₂ase, LDH, ADH and BDDH) was in accordance with the redistributions of the metabolic fluxes in the mutant strains.     

Hydrogen production performance by Enterobacter cloacae KBH3 isolated from termite guts

Two out of six bacterial isolates obtained from the guts of Globitermes sp. termites were identified as hydrogen-producing bacteria. One isolate, Enterobacter cloacae KBH3, was characterised using the BIOLOG identification system and 16S rRNA gene analysis. In a batch fermentation study to evaluate its growth in defined medium, E. cloacae KBH3 produced 154 ml H₂ per litre medium with approximately 50% hydrogen content. The carbon utilisation results suggest that E. cloacae KBH3 have the potential to be a good hydrogen producer. This strain is also able to produce hydrogen within a wide range of temperatures (28–40 °C) and pH (4.5–8). In several fermentation runs, the pH of the culture dropped from 6.5 to 5.36 within the first 3 h, which was mostly due to the biosynthesis of formate. An increase of cumulative hydrogen production was recorded as well as a decrease in the concentration of formate, indicating the importance of the formate pathway for hydrogen production. The highest rate of hydrogen production of 180.74 ml H₂/l/h was achieved when lactate and acetate were at their highest concentrations. Most of the hydrogen gas was produced during the exponential growth phase, and the biogas continued to be produced during the stationary phase. The specific growth rate was calculated to be 0.224 per hour while the hydrogen yield was 1.8 mol of hydrogen per mol of glucose. At the end of the batch study, the highest cumulative hydrogen production was 2404 ml H₂ per litre of fermentation medium.     

Cloning and knockout of formate hydrogen lyase and H2-uptake hydrogenase genes in Enterobacter aerogenes for enhanced hydrogen production

A 5431-bp DNA fragment partially encoding the formate hydrogen lyase (FHL) gene cluster hycABCDE was isolated and identified from Enterobacter aerogenes IAM1183 chromosomal DNA. All the five putative gene products showed a high degree of homology to the reported bacterial FHL proteins. The gene hycA, encoding the FHL repressor protein, and hybO, encoding the small subunit of the uptake hydrogenase, were targeted for genetic knockout for improving the hydrogen production. The pYM-Red recombination system was adopted to form insertional mutations in the E. aerogenes genome, thereby creating mutant strains of IAM1183-A (△hycA), IAM1183-O (△hybO), and IAM1183-AO (△hycA/△hybO double knockout). The hydrogen production experiments with these mutants showed that the maximum specific hydrogen productivities of IAM1183-A, IAM1183-O, and IAM1183-AO were 2879.466 ± 38.59, 2747.203 ± 13.25 and 3372.019 ± 4.39 (ml h⁻¹ g⁻¹dry cell weight), respectively, higher than that of the wild strain (2321.861 ± 15.34 ml h⁻¹ g⁻¹dry cell weight). The total H₂ yields by the three mutants IAM1183-A, IAM1183-O and IAM1183-AO were 0.73, 0.78, and 0.83 mol-H₂/mol glucose, respectively, while the wild-type IAM1183 was only 0.65 mol-H₂/mol glucose. The metabolites of the mutants including acetate, ethanol, 2,3-butanediol and succinate were all increased compared with that of the wild type, implying the changed metabolic flux by the mutation. In the fermentor cultivation with IAM1183△hycA/△hybO, the total hydrogen volume after 16 h cultivation reached 4.4 L, while that for the wild type was only 2.9 L.     

Biohydrogen production from crude glycerol by immobilized Klebsiella sp. TR17 in a UASB reactor and bacterial quantification under non-sterile conditions

Biohydrogen production from crude glycerol by immobilized Klebsiella sp. TR17 was investigated in an up-flow anaerobic sludge blanket (UASB) reactor. The reactor was operated under non-sterile conditions at 40^○C and initial pH 8.0 at different hydraulic retention times (HRTs) (2–12 h) and glycerol concentrations (10–30 g/L). Decreasing the HRT led to an increase in hydrogen production rate (HPR) and hydrogen yield (HY). The highest HPR of 242.15 mmol H₂/L/d and HY of 44.27 mmol H₂/g glycerol consumed were achieved at 4 h HRT and glycerol concentrations of 30 and 10 g/L, respectively. The main soluble metabolite was 1,3-propanediol, which implies that Klebsiella sp. was dominant among other microorganisms. Fluorescence in situ hybridization (FISH) revealed that the microbial community was dominated by Klebsiella sp. with 56.96, 59.45, and 63.47% of total DAPI binding cells, at glycerol concentrations of 10, 20, and 30 g/L, respectively.     

Biohydrogen production from Enterobacter cloacae IIT-BT 08 using distillery effluent

Distillery effluent poses severe environmental pollution problem mainly due to its high organic content. During alcohol fermentation, most of the essential macro- and micro-nutrients get utilized. Therefore, supplementation of these nutrients becomes imperative for the improvement of biohydrogen production. In the present study, starch based distillery effluent was used for dark fermentative hydrogen production using Enterobacter cloacae IIT-BT 08. Hence, this study was undertaken to evaluate the effect of supplementation of yeast extract, malt extract, Fe⁺⁺, Cu⁺⁺ and Mg⁺⁺ on biohydrogen production. The interaction among supplements and their mutual effect on the hydrogen production was studied using five factor–five level central composite design). Optimum hydrogen yield of 7.4 mol H₂/kg COD_reduced was predicted by the model, which showed an excellent correlation with experimental hydrogen yield of 7.38 ± 0.24 mol H₂/kg COD_reduced. An average hydrogen production rate of 80 mL/L h was achieved after supplementation, having 2.2 times higher hydrogen yield as compared to non-supplemented distillery effluent.     

Optimization of culture conditions for biohydrogen production from sago wastewater by Enterobacter aerogenes using Response Surface Methodology

Sago wastewater (SWW) causes pollution to the environment due to its high organic content. Annually, about 2.5 million tons of SWW is produced in Malaysia. In this study, the potential of SWW as a substrate for biohydrogen production by Enterobacter aerogenes (E. aerogenes) was evaluated. Response Surface Methodology (RSM) was employed to find the optimum conditions. From preliminary optimization, it was found that the most significant factors were yeast extract, temperature, and inoculum size. According to Face Centered Central Composite Design (FCCCD), the maximum hydrogen concentration and yield were 630.67 μmol/L and 7.42 mmol H₂/mol glucose, respectively, which is obtained from the sample supplemented with 4.8 g/L yeast extract concentration, 5% inoculum, and incubated at the temperature of 31 °C. Cumulative hydrogen production curve fitted by the modified Gompertz equation suggested that H_max, R_max, and λ from this study were 15.10 mL, 2.18 mL/h, and 9.84 h, respectively.     

Bio-hydrogen production enhancement by co-cultivating Rhodopseudomonas palustris WP3-5 and Anabaena sp. CH3

Photobiological H₂ production is a promising method for renewable energy development. An innovative system that co-cultivating Rhodopseudomonas palustris WP3-5 and Anabaena sp. CH3 was carried out to estimate the effect of co-cultivation on H₂ production enhancement. H₂ production prolongation and enhancement were observed due to the light and metabolic compatibility of these two strains. Co-culture system served by acetate and fructose as carbon source can accumulate H₂ in 140.8 mL, almost double than the sum of individuals. Moreover, the enhancement of H₂ production was significantly affected by the mixed ratio of two strains. The mixed ratio (WP3-5:CH3) of 1:2 showed a highest H₂ production rate in 44.8 mL-H₂/L-culture/h, and both 2:1 and 1:2 exhibited a relatively high substrate conversion efficiency during the latest period of cultivation, whereas the mixed ratio of 1:1 and 3:1 only revealed a prolongation in H₂ production due to metabolic compatibility of two strains.     

Hydrogen production from the monomeric sugars hydrolyzed from hemicellulose by Enterobacter aerogenes

Relatively large percentages of xylose with glucose, arabinose, mannose, galactose and rhamnose constitute the hydrolysis products of hemicellulose. In this paper, hydrogen production performance of facultative anaerobe (Enterobacter aerogenes) has been investigated from these different monomeric sugars except glucose. It was shown that the stereoisomers of mannose and galactose were more effective for hydrogen production than those of xylose and arabinose. The substrate of 5 g/l xylose resulted in a relative high level of hydrogen yield (73.8 mmol/l), hydrogen production efficiency (2.2 mol/mol) and a maximum hydrogen production rate (249 ml/l/h). The hydrogen yield, hydrogen production efficiency and the maximum hydrogen production rate reached 104 mmol/l, 2.35 mol/mol and 290 ml/l/h, respectively, on a substrate of 10 g/l galactose. The hydrogen yields and the maximum hydrogen production rates increased with an increase of mannose concentrations and reached 119 mmol/l and 518 ml/l/h on the culture of 25 g/l mannose. However, rhamnose was a relative poor carbon resource for E. aerogenes to produce hydrogen, from which the hydrogen yield and hydrogen production efficiency were about one half of that from the mannose substrate. E. aerogenes was found to be a promising strain for hydrogen production from hydrolysis products of hemicellulose.     

Characteristics of cured and wild strains of Enterobacter cloacae IIT-BT 08 for the improvement of biohydrogen production

Enterobacter cloacae IIT-BT 08 was found to harbor multiple endogenous plasmids. The plasmids were successfully cured by the combined action of SDS and mitomycin C. The cured strain exhibited an altered pattern of antibiotic and metal resistance. The effect of plasmid curing on biohydrogen production was determined. LP model showed that hydrogen was a growth associated product for both the wild type and the cured strain. However, modified Gompertz equation showed that the productivity of the cured strain was comparable to the wild type. Further, comparative kinetic parameter analysis showed that the maximum specific growth rate (μ_max) and saturation constant (K_s) were 1.26 and 2.2 times higher respectively, for the cured strain as compared to the wild type. Similarly, maintenance coefficient (m) was determined to be function of fermentation time and was lower for the cured strain. This was related to the decrease in plasmid load in the cured strain.     

Hydrogen production of Enterobacter aerogenes altered by extracellular and intracellular redox states

Enterobacter aerogenes HU-101, tested for its hydrogen production in batch cultures on various substrates, produced the highest amount of hydrogen when the substrate was glycerol. The yield of hydrogen is a function of the degree to which the substrates are reduced. To examine the effect of intracellular redox state on hydrogen yield, glucose-limiting chemostat cultures were carried out at various pH using strain HU-101 and its mutant AY-2. For both strains, the molar yield and the production rate of hydrogen and the hydrogenase activity in the cell-free extract were optimal at the culture pH of 6.3. The highest NADH/NAD ratio in both strains was also observed at pH 6.3, at which the ratio in AY-2 was more than two-fold that of HU-101. Furthermore, NAD(P)H-dependent hydrogen formation was observed in the cell-free extract of AY-2, and hydrogenase activity was found not in the cytoplasmic but in the cell membrane fraction, suggesting that a high intracellular redox state, that is a high NADH/NAD ratio, would accelerate hydrogen production by driving membrane-bound NAD(P)H-dependent hydrogenase.     

Comparative study on the production of biohydrogen from rice mill wastewater

This study presents the production of biohydrogen from rice mill wastewater. The acid hydrolysis and enzymatic hydrolysis operating conditions were optimized, for better reducing sugar production. The effect of pH and fermentation time on biohydrogen production from acid and enzymatic hydrolyzed rice mill wastewater was investigated, using Enterobacter aerogenes and Citrobacter ferundii. The enzymatic hydrolysis produced the maximum reducing sugar (15.8 g/L) compared to acid hydrolysis (14.2 g/L). The growth data obtained for E. aerogenes and C. ferundii, fitted well with the Logistic equation. The hydrogen yields of 1.74 mol H₂/mol reducing sugar, and 1.40 mol H₂/mol reducing sugar, were obtained from the hydrolyzate obtained from enzymatic and acid hydrolysis, respectively. The maximum hydrogen yield was obtained from E. aerogenes compared to C. ferundii, and the optimum pH for better hydrogen production was found to be in the range from 6.5 to 7.0. The chemical oxygen demand (COD) reduction obtained was around 71.8% after 60 h of fermentation.     

Fermentative hydrogen production by the newly isolated Enterobacter asburiae SNU-1

A new fermentative hydrogen-producing bacterium was isolated from a domestic landfill and identified as Enterobacter asburiae using 16S rRNA gene sequencing and DNA–DNA hybridization methods. The isolated bacterium, designated as Enterobacter asburiae SNU-1, is a new species that has never been examined as a potential hydrogen-producing bacterium. This study examined the hydrogen-producing ability of Enterobacter asburiae SNU-1. During fermentation, the hydrogen was mainly produced in the stationary phase. The hydrogen yield based on the formate consumption was 0.43 mol hydrogen/mol formate. This strain was able to produce hydrogen over a wide range of pH (4–7.5), with the optimum pH being pH 7. The level of hydrogen production was also affected by the initial glucose concentration, and the optimum value was found to be 25 g glucose/l. The maximum and overall hydrogen productivities were 398 and 174 ml/l/hr, respectively, at pH 7 with an initial glucose concentration of 25 g/l. This strain could produce hydrogen from glucose and many other carbon sources such as fructose, sucrose, and sorbitol.     

Enhanced bio-hydrogen production from sugarcane juice by immobilized Clostridium butyricum on sugarcane bagasse

Immobilized Clostridium butyricum TISTR 1032 on sugarcane bagasse improved hydrogen production rate (HPR) approximately 1.2 times in comparison to free cells. The optimum conditions for hydrogen production by immobilized C. butyricum were initial pH 6.5 and initial sucrose concentration of 25 g COD/L. The maximum HPR and hydrogen yield (HY) of 3.11 L H₂/L substrate·d and 1.34 mol H₂/mol hexose consumed, respectively, were obtained. Results from repeated batch fermentation indicated that the highest HPR of 3.5 L H₂/L substrate·d and the highest HY of 1.52 mol H₂/mol hexose consumed were obtained at the medium replacement ratio of 75% and 50% respectively. The major soluble metabolites in both batch and repeated batch fermentation were butyric and acetic acids.     

Closing the 1,3-propanediol route enhances hydrogen production from glycerol by Halanaerobium saccharolyticum subsp. saccharolyticum

The effect of vitamin B₁₂ on hydrogen (H₂) and 1,3-propanediol (1,3-PD) production in glycerol fermentation of Halanaerobium saccharolyticum subsp. saccharolyticum was studied in batch cultivations. In addition, the effect of vitamin B₁₂ on glucose fermentation of H. saccharolyticum subsp. saccharolyticum and on glycerol fermentation of H. saccharolyticum subsp. senegalensis, that is a non-1,3-PD producing bacterium, and of Clostridium butyricum, that is known for vitamin B₁₂-independent 1,3-PD production, were studied for comparison. 1,3-PD production of H. saccharolyticum subsp. saccharolyticum was observed to be vitamin B₁₂-dependent and the H₂ production in glycerol fermentation was remarkably enhanced when 1,3-PD production was blocked by the lack of vitamin B₁₂ supplementation. The highest H₂ yield obtained by H. saccharolyticum subsp. saccharolyticum was 2.16 mol/mol glycerol. No significant effects of vitamin B₁₂ on metabolite production in glucose fermentation of H. saccharolyticum subsp. saccharolyticum or in glycerol fermentation of H. saccharolyticum subsp. senegalensis or C. butyricum were observed.