Repeated-batch production of hydrogen using Rhodobacter sphaeroides S10

Photofermentation of acid hydrolyzed oil palm empty fruit bunch is reported for hydrogen production in repeated-batch fermentations using the bacterium Rhodobacter sphaeroides S10. Photofermentations were carried out at 35 °C at an incident light level of 10 klux. At specified times, different specified volumes of the culture broth were removed and replaced with an equal volume of the fresh medium. The initial mixed carbon (glucose, xylose, acetic acid) content in the medium of the repeated-batch reactors was adjusted to 20 mM. The kinetics of hydrogen production were evaluated in repeated-batch fermentations carried out in various ways: different volume exchange levels, different switch times from batch to repeated-batch operation, and different cycle times.     

Evaluation of hydrogen production by Rhodobacter sphaeroides O.U.001 and its hupSL deficient mutant using acetate and malate as carbon sources

Rhodobacter sphaeroides O.U.001 is one of the candidates for photobiological hydrogen production among purple non-sulfur bacteria. Hydrogen is produced by Mo-nitrogenase from organic acids such as malate or lactate. A hupSL in frame deletion mutant strain was constructed without using any antibiotic resistance gene. The hydrogen production potential of the R. sphaeroides O.U.001 and its newly constructed hupSL deleted mutant strain in acetate media was evaluated and compared with malate containing media. The hupSL⁻R. sphaeroides produced 2.42 l H₂/l culture and 0.25 l H₂/l culture in 15 mM malate and 30 mM acetate containing media, respectively, as compared to the wild type cells which evolved 1.97 l H₂/l culture and 0.21 l H₂/l culture in malate and acetate containing media, correspondingly. According to the results, hupSL⁻R. sphaeroides is a better hydrogen producer but acetate alone does not seem to be an efficient carbon source for photoheterotrophic H₂ production by R. sphaeroides.     

Fermentative hydrogen production from acetate using Rhodobacter sphaeroides RV

The study of photosynthetic hydrogen production by using Rhodobacter sphaeroides RV from acetate was described. We investigated the effects of light source (fluorescent, halogen and tungsten lamps), light intensity (1200–6000 lux), inoculum quantity (OD₆₆₀ 0.212–OD₆₆₀ 1.082) and initial pH (4.0–10.0) on biohydrogen production. The results indicated that the hydrogen production for halogen and tungsten lamps was better than it for fluorescent lamp as light source. The best light intensity of hydrogen production was 3600 lux for tungsten lamp as light source. Inoculum quantity experiments indicated that the higher hydrogen production volume and hydrogen conversion rate were obtained at initial OD₆₆₀ of 0.931. The effect of initial pH on hydrogen production indicated that the maximum hydrogen yield reached to 653.2 mmol H₂/mol acetate at initial pH 7.0.     

Effect of carbon sources on the photobiological production of hydrogen using Rhodobacter sphaeroides RV

Rhodobacter sphaeroides RV was employed to produce hydrogen for the photo-fermentation of sole (acetate, propionate, butyrate, lactate, malate, succinate, ethanol, glucose, citrate and sodium carbonate) and compound carbon sources (malate and succinate, lactate and succinate). The concentrations of sole carbon sources on hydrogen production were investigated in batch assays at 0.8 g/L sodium glutamate and the maximum hydrogen yield was 424 mmol H₂/mol-substrate obtained at 0.8 g/L sodium propionate. The maximum hydrogen yield reached 794 mmol H₂/mol-substrate for 2.02 g lactate and 2.0 g succinate as the compound carbon source. The results showed hydrogen production for the compound carbon source was better than the sole carbon source.     

Molecular hydrogen production by nitrogenase of Rhodobacter sphaeroides and by Fe-only hydrogenase of Rhodospirillum rubrum

The genes coding for two PII-like proteins, GlnB and GlnK, which play key roles in repressing the nitrogenase expression in the presence of ammonium ion, were interrupted from the chromosome of Rhodobacter sphaeroides. The glnB–glnK mutant exhibits the less ammonium ion-mediated repression for nitrogenase compared with its parental strain, which results in more H₂ accumulation by the mutant under the conditions. Rhodospirillum rubrum produces H₂ by both nitrogenase and hydrogenase. R. rubrum containing the recombinant pRK415 with an insert of hydC coding for its own Fe-only hydrogenase showed twofold higher accumulation of H₂ in the presence of pyruvate under photoheterotrophic conditions, which was not observed in the absence of pyruvate. The same was true with R. rubrum containing the recombinant pRK415 cloned with hydA coding for Fe-only hydrogenase of Clostridium acetobutylicum. Thus, Fe-only hydrogenase requires pyruvate as an electron donor for the production of H₂.     

Expression of aldehyde dehydrogenase gene increases hydrogen production from low concentration of acetate by Rhodobacter sphaeroides

Rhodobacter sphaeroides RV (RV) is a hydrogen-producing bacterium exhibiting the highest yield of hydrogen production from organic acids such as lactate and acetate, which are the byproducts of hydrogen fermentation by hydrogen-producing anaerobic bacteria. Co-fermentation of the RV strain with anaerobic bacteria is an efficient method of hydrogen production. However, less than 21 mM acetate is produced by the anaerobic bacteria, which is too low for efficient hydrogen production by the RV strain; it requires approximately 75 mM acetate. In this study, 2 distinct isozymes of aldehyde dehydrogenase from Rhodospirillum rubrum were separately overexpressed in the RV strain. The recombinant RV strains that were designated as RVAD1 and RVAD2, exhibited 13-fold higher ALDH activities than the wild-type RV strain. Hydrogen yields of both of the recombinant strains were 1.4-fold higher than that of the RV strain in 21 mM acetate. In 43 mM acetate, the RVAD1 strain showed higher yield, though the RVAD2 strain showed lower yield as compared to that of the RV strain. In 64 mM acetate and all concentrations of lactate tested (21, 43 and 64 mM), the yields of the recombinant strains were lower than those of the RV strain. The intact (empty) expression plasmid increased the ALDH activity and had little effect on the hydrogen production in acetate, however, it decreased the production in lactate. At the beginning of the fermentation process, when very little hydrogen had been produced, the recombinant strains expressing the ALDH gene consumed smaller amounts of acetate compared to the wild-type strain. We have discussed the effects of ALDH on hydrogen production in this report.     

Hydrogen gas production by combined systems of Rhodobacter sphaeroides O.U.001 and Halobacterium salinarum in a photobioreactor

Rhodobacter sphaeroides O.U.001 is a photosynthetic non-sulfur bacterium which produces hydrogen from organic compounds under anaerobic conditions. Halobacterium salinarum is an archaeon and lives under extremely halophilic conditions (4 M NaCl). H. salinarum contains a retinal protein bacteriorhodopsin in its purple membrane which acts as a light-driven proton pump. In this study the Rhodobacter sphaeroides O.U.001 culture was combined with different amounts of packed cells of H. salinarum S9 or isolated purple membrane fragments in order to increase the photofermentative hydrogen gas production. The packed cells of H. salinarum have the ability to pump protons upon illumination due to the presence of bacteriorhodopsin. The proton gradient produced may be used for the formation of ATP or protons may be used for H₂ production by R. sphaeroides. Similar to intact cells purple membrane fragments may also form vesicles around certain ions and may act like closed systems.     

Effect of ferrous ion on photo heterotrophic hydrogen production by Rhodobacter sphaeroides

The effect of ferrous ion (0–3.2 mg/l) on photo heterotrophic hydrogen production was studied in batch culture using sodium lactate as substrate. The results showed that hydrogen production by Rhodobacter sphaeroides   was significantly suppressed when Fe²⁺${\mathrm{Fe}}^{2+}$ was limited. Hydrogen production increased linearly with an increase in Fe²⁺${\mathrm{Fe}}^{2+}$ concentration in the range of 0–1.6 mg/l; reaching a maximum at 2.4 mg/l. When hydrogen production was suppressed in the above medium, a pH increase to 8.9 was observed, and the ratio of lactate utilized to total organic carbon removal was found to be increased, indicating that more soluble organic products were produced. Under the Fe²⁺${\mathrm{Fe}}^{2+}$ limited conditions, ferrous iron was shown to have a greater effect on hydrogen production by Rb. sphaeroides than that by the anaerobic heterotrophic bacterium Clostridium butyricum.     

Function of glucose catabolic pathways in hydrogen production from glucose in Rhodobacter sphaeroides 6016

Purple non-sulfur (PNS) bacteria can convert volatile fatty acids into hydrogen with a high substrate conversion efficiency. However, when PNS bacteria utilize sugars as a carbon source, such as glucose and sucrose, the substrate conversion efficiency is relatively low. In order to investigate the contributions of the glucose catabolic pathways in Rhodobacter sphaeroides 6016 to its hydrogen production, the cfxA gene from the Embden–Meyerhof–Parnas (EMP) pathway, edd from the Entner–Doudoroff (ED) pathway, and kdg from the semi-phosphorylative ED bypass were knocked out to construct the mutant strains edd⁻, cfxA⁻, and kdg⁻, respectively. Additionally, two of these three genes were knocked out to construct the mutant strains kdg⁻edd⁻, kdg⁻cfxA⁻, and cfxA⁻edd⁻. Hydrogen productions by these mutant strains were compared to that of the wild type strain 6016 using 25 mM glucose as a carbon source. Compared to 6016, variations in hydrogen production and growth were detected in the edd mutant strains (kdg⁻edd⁻, cfxA⁻edd⁻, and edd⁻), while no obvious changes were detected in the others. Notably, the kdg⁻edd⁻ mutant did not produce hydrogen, and its maximum growth was 70% less than that of R. sphaeroides 6016. These results indicate that the ED pathway and semi-phosphorylative ED bypass have a governing impact on cell growth and hydrogen production from glucose in R. sphaeroides 6016. The potential synergistic function of the ED pathway and semi-phosphorylative ED bypass and the reasons for the low hydrogen yield from sugar carbon sources in R. sphaeroides 6016 are discussed.     

Optimization of photosynthetic hydrogen production from acetate by Rhodobacter sphaeroides RV

In this study, hydrogen production by Rhodobacter sphaeroides RV from acetate was investigated. Ammonium sulphate and sodium glutamate were used to study the effects of nitrogen sources on photosynthetic hydrogen production. The results showed the optimal concentrations for ammonium sulphate and sodium glutamate were in the range of 0.4–0.8 g/L. Orthogonal array design was applied to optimize the hydrogen-producing conditions of the concentrations of yeast, FeSO₄ and NiCl₂. The theoretical optimal condition for hydrogen production was as follow: yeast 0.1 g/L, FeSO₄ 100 mg/L and NiCl₂ 20 mg/L.     

Biohydrogen and 5-aminolevulinic acid production from waste barley by Rhodobacter sphaeroides O.U.001 in a biorefinery concept

The production of biohydrogen and 5-aminolevulinic acid (5-ALA) by Rhodobacter sphaeroides O.U.001 was investigated in a biorefinery concept. Waste barley was used as a substrate after acid hydrolysis. The hydrolysate was analyzed in terms of its total simple sugar, organic acid, ammonium, element and total phenol contents. Four different growth media having 5 g/L, 7 g/L, 9 g/L and 11 g/L sugar content were prepared using the waste barley hydrolysate to produce biohydrogen and 5-ALA. The increased sugar concentrations resulted in higher cell density and hydrogen accumulation. Accordingly, the highest cell density (OD₆₆₀: 1.78) and hydrogen production (0.4 L H₂/L culture) were observed in the 11 g/L sugar-containing medium. A 67.4 μM 5-ALA was produced upon vitamin B₁₂ and levulinic acid additions. These results showed that waste barley can be used as a substrate for R. sphaeroides for biohydrogen and 5-ALA production within a biorefinery concept.     

Bacterial hydrogen production in recombinant Escherichia coli harboring a HupSL hydrogenase isolated from Rhodobacter sphaeroides under anaerobic dark culture

In this study, recombinant plasmid was constructed to analyze the effect of hydrogen production on the expression HupSL hydrogenase isolated from Rhodobacter sphaeroides in Escherichia coli. Although most of recombinant HupSL hydrogenase was produced as inclusion bodies the solubility of the protein increased significantly when the expression temperature shifted from 37 °C to 30 °C. Hydrogen production by expression of HupSL hydrogenase from recombinant E. coli increased 20.9-fold compared to control E. coli and 218-fold compared to wild type R. sphaeroides under anaerobic dark condition. The results demonstrate that HupSL hydrogenase, consisting of small and large subunits of hydrogenase isolated from R. sphaeroides, increases hydrogen production in recombinant E. coli. In addition conditions for enhancing the activity of HupSL hydrogenase in E. coli were suggested and were used to increase bacterial hydrogen production.     

Enhancement of phototrophic hydrogen production by Rhodobacter sphaeroides ZX-5 using fed-batch operation based on ORP level

In this study, a new outer-cycle flat-panel photobioreactor was designed for an anaerobic, photo-fermentation process by Rhodobacter sphaeroides ZX-5. In order to obtain the high hydrogen yield, photo-hydrogen production by fed-batch culture with on-line oxidation-reduction potential (ORP) feedback control was investigated. Meanwhile, the effects of feeding malic acid concentration and pH adjustment on the growth and hydrogen production of R. sphaeroides ZX-5 were studied. In the entire fed-batch culture, biomass (i.e., OD₆₆₀) rapidly increased up to 1.79 within 18 h, and then OD₆₆₀ value stayed constant within a range of 1.85-2.18 until the end of the photo-fermentation. The cumulative hydrogen volumes in each phase of fed-batch process were 2339, 1439, 1328, and 510 ml H₂/l-culture, respectively. Throughout the entire repeated fed-batch photo-fermentation, the maximum substrate conversion efficiency of 73.03% was observed in the first fed-batch process, obviously higher than that obtained from batch culture process (59.81%). In addition, compared to the batch culture, a much higher maximum hydrogen production rate (102.33 ml H₂/l h) was achieved during fed-batch culture. The results demonstrated that photo-hydrogen production using fed-batch operation based on ORP feedback control is a favorable choice of sustainable and feasible strategy to improve phototrophic hydrogen production efficiency.     

Effect of AI crude extract on PHB accumulation and hydrogen photoproduction in Rhodobacter sphaeroides

Poly-β-hydroxy butyric acid (PHB) accumulation and gaseous H₂ release are regarded as alternatives for expending reducing power. Some researchers suggested that quorum-sensing system affects PHB accumulation in Rhodobacter sphaeroides, but whether the system plays regulation role between hydrogen producing and PHB synthesis is still unknown. By adding autoinducer of R. sphaeroides into its culture solutions, measuring its total hydrogen production, PHB content and PHB synthase activity, the function of quorum-sensing on PHB accumulation and hydrogen production was preliminarily investigated. Compared with the control, the total gas productions in experimental groups increased accompanying slight decrease of PHB contents, which was partially caused by the reduction of PHB synthase activities. Biolog tests indicated the carbon source utilization profiles, especially those involving fatty acids and butanoate metabolism, had partly changed after exogenous signal molecules added. These results suggest that quorum-sensing is involved in signal regulation between PHB accumulation and hydrogen production in R. sphaeroides.     

Application of immobilized Rhodobacter sphaeroides bacteria in hydrogen generation process under semi-continuous conditions

The non-modified and modified (AEAPTMS) VitraPOR^®Filter porous glasses with thickness of 6.8 mm and diameter of 100 mm were applied as carriers for immobilization of Rhodobacter sphaeroides O.U. 001 bacteria. Two different glasses with pores of 40–100 and 100–160 μm were applied. The Van Niel's medium was applied for bacteria growth, whereas hydrogen generation reaction was performed with modified Biebl and Pfennig medium. Our own construction of Flat Plate Photobioreactor (FPP) with capacity of 200 cm³ operating under semi-continuous conditions was applied in this study. The maximum hydrogen production rate obtained was 0.059 dm³ H₂/dm³/h, while the maximum hydrogen yield was 4.2 mol H₂/mol malic acid. System was relatively stable because each series lasted about 3 months. Then the hydrogen production decreased. In order to introduce amine groups on the surface of porous glass, modification with AEAPTMS (3-(2-aminoethyl)aminopropyl)trimetoxysilane was performed. Obtained results proved that both modified and non-modified porous glasses are appropriate materials for stable immobilization of microbiological culture. The best activity and stability was achieved with porous glass matrix representing larger pores, whereas modification of the surface of these matrices with amine improved the amount of immobilized cells but did not improve the hydrogen yield.     

Valorization of sugar beet molasses for the production of biohydrogen and 5-aminolevulinic acid by Rhodobacter sphaeroides O.U.001 in a biorefinery concept

The production of biohydrogen and 5-aminolevulinic acid (5-ALA) from sugar beet molasses was investigated within a biorefinery framework. A purple non-sulfur photosynthetic bacterium, Rhodobacter sphaeroides O.U.001, was used for this purpose. The suitability of the molasses for biohydrogen and 5-ALA production was assessed in certain aspects and then five different culture media with various sugar contents (3 g/L, 7 g/L, 14 g/L, 21 g/L and 28 g/L) were prepared. Results have shown that molasses is a promising substrate for the production of biohydrogen and 5-ALA in a biorefinery concept and increasing sugar content results in enhanced product accumulation. Specifically, the highest amount of biohydrogen and 5-ALA was observed in 28 g/L sugar-containing medium (1.01 L H₂/L culture, 23,337 μM). In conclusion, this paper presents the new findings about the enhanced accumulation of biohydrogen and 5-ALA within a biorefinery context.     

Growth characteristics and hydrogen production by Rhodobacter sphaeroides using various amino acids as nitrogen sources and their combinations with carbon sources

Some amino acids (alanine, asparagine, glutamate, glycine, proline, and tyrosine) were used as nitrogen sources in combination with carbon sources (succinate and malate) to study growth properties and H₂ production by purple non-sulfur bacterium Rhodobacter sphaeroides strains A-10 and D-3. Both strains produced H₂ in succinate–glutamate and malate–glutamate media. Succinate was a better carbon source than malate. In comparison with strain D-3, strain A-10 was able to utilize proline, alanine or tyrosine as nitrogen sources in succinate medium and to produce H₂. Both strains were unable to produce H₂ in the presence of asparagine or glycine as nitrogen sources. N,N′-dicyclohexylcarbodiimide, the F₀F₁-ATPase inhibitor, led to marked inhibition of H₂ production activity of R. sphaeroides. The results suggest that the R. sphaeroides cells growth can be achieved by the use of a large diversity of substrates but only some of them can increase the H₂ production rate.     

Remarkable enhancement on hydrogen production performance of Rhodobacter sphaeroides by disrupting spbA and hupSL genes

The redox balance and bacteriochlorophyll (Bchl) synthesis are both significant to hydrogen generation in photosynthetic bacteria. In this study, spbA and hupSL genes were knocked out from the genome of Rhodobacter sphaeroides HY01. The UV–vis spectra showed that the Bchl contents of spbA mutants were enhanced under photosynthetic conditions. The hydrogen yields of WH04 (hupSL⁻) and WSH10 (spbA⁻, hupSL⁻) mutants increased by 19.4%, 21.8%, and the maximum hydrogen evolution rates increased by 29.9% and 55.0% respectively using glutamate as sole nitrogen source. The maximum hydrogen production rate of WSH10 was up to 141.9 mL/(L·h). The nifH expression levels of the mutants and the wild type supported the correlation between hydrogen production and nitrogenase activity. The results demonstrate that disruption of spbA in R. sphaeroides can partially derepress the ammonium inhibition in nitrogenase activity, and indicate that spbA is a negative regulator in nitrogenase synthesis in the presence of ammonium.