Effect of changes in the level of light harvesting complexes of Rhodobacter sphaeroides on the photoheterotrophic production of hydrogen

Increase in levels of photosynthetic spectral complexes by maintaining the plasmids harboring DNA encoding puhA, pufBA, or pucBAC in trans in Rhodobacter sphaeroides resulted in decrease of the photoheterotrophic production of H₂. However, removal of B875 or B800–850 light-harvesting (LH) complexes affected H₂ production differently. Lack of B875 complex following in-frame deletion of pufBA (mutant PUF1) not only slowed photoheterotrophic growth but also decreased H₂ production, indicative of the essential requirement of the complex for LH process. However, the pucBA-deleted mutant, PUC1 lacking of B800–850 complex, increased H₂ production in comparison with its parental cell by approximately twofold, given irradiated with light (10 W/m²) saturating the growth of wild type. The H₂ production of PUC1 did not increase in proportion to the light intensity, which is also observed with wild type. Thus, we suggest that light is not limited for the H₂ production of the cells under the experimental conditions employed in this work, but the cellular energy to be used for the formation of B800–850 complex may flow into the metabolism leading to the H₂ production in PUC1.     

Relationship between molecular hydrogen production,proton transport and the F0F1-ATPase activity in Rhodobacter sphaeroides strains from mineral springs

This article aims to study hydrogen production and proton transport in two strains of purple non-sulfur bacterium Rhodobacter sphaeroides isolated from mineral springs of Armenia. This bacterium is able to grow and produce molecular hydrogen (H₂) in anaerobic conditions upon illumination. Along with H₂ production, a marked decrease in redox potential and the alkalization of the medium have been observed; the latter might be the evidence of proton influx. H₂ production and alkalization of the medium by whole cells both are suppressed by the F₀F₁-ATPase inhibitors – N,N′-dicyclohexylcarbodiimide (DCCD), sodium azide (NaN₃) and protonophore – carbonyl cyanide m-chlorophenylhydrazone (CCCP). Membrane vesicles of two strains of R. sphaeroides demonstrate ATPase activity, inhibited by DCCD and NaN₃, but not by CCCP. These results indicate a relationship between H₂ production, proton transport and the F₀F₁-ATPase activity that might be a pathway to regulate bacterial activity under anaerobic conditions.     

Disruption of multidrug resistance protein gene of Rhodobacter capsulatus results in improved photoheterotrophic hydrogen production

Rhodobacter capsulatus (R. capsulatus), which is a typical purple nonsulfur photosynthetic bacterium, is able to produce hydrogen under photosynthetic condition. A mutant of R. capsulatus named MC122 was obtained by Tn5 transposon mutagenesis. The transposon mutant had improved photoheterotrophic hydrogen production performance using acetic acid as substrate and its mutation site was located by sequencing the rescued plasmid containing the transposon insertion from the genome of the mutant. It was found for the first time that disruption of the multidrug resistance protein (mdtB) gene resulted in improved hydrogen production.     

Biohydrogen production by Ethanoligenens harbinense B49: Nutrient optimization

A new hydrogen-producing bacterial strain Ethanoligenens harbinense B49 was examined for its capability of H₂ production with glucose as sole carbon source. The H₂ production was significantly affected by the concentration of the yeast powder and phosphate in the synthetic medium. The optimized concentration of yeast powder was 0.3–0.5 g/L and the maximum hydrogen yield was obtained at the concentration of phosphate about 100–150 mmol/L. The dynamics of hydrogen production showed that rapid evolution of hydrogen appeared to start after the middle-phase of exponential growth (about 8 h). The maximum H₂ yield and specific hydrogen production rate were estimated to be 2.26 mol H₂/mol glucose and 27.74 mmol H₂/g cell, respectively, when 10 g/L of glucose was present in the medium. The possible pathway of hydrogen production by Ethanoligenens sp. B49 during glucose fermentation was oxidative decarboxylation of pyruvate and the NADH pathway.     

Biohydrogen production by Anabaena sp. PCC 7120 wild-type and mutants under different conditions: Light, nickel, propane, carbon dioxide and nitrogen

Increasing awareness of environmental problems caused by the current use of fossil fuel-based energy, has led to the search for alternatives. Hydrogen is a good alternative and the cyanobacterium Anabaena sp. PCC 7120 is naturally able to produce molecular hydrogen, photosynthetically from water and light. However, this H₂ is rapidly consumed by the uptake hydrogenase.This study evaluated the hydrogen production of Anabaena sp. PCC 7120 wild-type and mutants: hupL⁻ (deficient in the uptake hydrogenase), hoxH⁻ (deficient in the bidirectional hydrogenase) and hupL⁻/hoxH⁻ (deficient in both hydrogenases) on several experimental conditions, such as gas atmosphere (argon and propane with or without N₂ and/or CO₂ addition), light intensity (54 and 152 ??Em⁻²s⁻¹), light regime (continuous and light/dark cycles 16 h/8 h) and nickel concentrations in the culture medium.In every assay, the hupL⁻ and hupL⁻/hoxH⁻ mutants stood out over wild-type cells and the hoxH⁻ mutant. Nevertheless, the hupL⁻ mutant showed the best hydrogen production except in an argon atmosphere under 16 h light/8 h dark cycles at 54 ??Em⁻²s⁻¹ in the light period, with 1 ??M of NiCl₂ supplementation in the culture medium, and under a propane atmosphere.In all strains, higher light intensity leads to higher hydrogen production and if there is a daily 1% of CO₂ addition in the gas atmosphere, hydrogen production could increase 5.8 times, related to the great increase in heterocysts differentiation (5 times more, approximately), whereas nickel supplementation in the culture medium was not shown to increase hydrogen production. The daily incorporation of 1% of CO₂ plus 1% of N₂ did not affect positively hydrogen production rate.     

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.     

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.     

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.     

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.     

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.     

New fan blade-like core-shell Sb2TixSy photocatalytic nanorod for hydrogen production from methanol/water photolysis

New photocatalysts of Sb₂Ti_xS_y (x = 0, 0.5, 1.0, 1.5 mol and y = 3, 4, 5, 6 mol) fan blade-like core-shell nanorods have been designed ultimately to enhance hydrogen production. The nanorods of 500 nm long and 60–100 nm wide are Sb₂S₃ nanorod surrounded by an amorphous TiS₂ membrane, showing absorption band edges of above 600 nm. The evolution of H₂ from methanol/water (1:1) photo-splitting over Sb₂Ti_xS_y nanorods in the liquid system is doubled, compared to that over pure Sb₂S₃. Particularly, 52 μmol of H₂ gas is produced after 10 h when 0.5 g of Sb₂Ti_1.0S₅ nanorods is used at pH = 7, and the performance is increased by more than 50% at higher pH. Based on cyclic voltammetry (CV) and UV-Visible absorption spectra, the high photocatalytic activity can be attributed to the existence of an appropriate band-gap state, which includes the scope of the redox potential of water in Sb₂Ti_1.0S₅ nanorods, resulting in the promotion of the redox reaction of water.     

Enhanced H2 photoproduction by down-regulation of ferredoxin-NADP reductase (FNR) in the green alga Chlamydomonas reinhardtii

Renewable H₂ photoproduction by green algae such as Chlamydomonas reinhardtii is a promising system for solar fuels. However, large-scale application of the system has lagged virtually due to lack of high H₂-producing strains. We previously identified ferredoxin-NADP⁺ reductase (FNR) among the 105 proteins differentially expressed in Chlamydomonas during sulfur-deprived H₂ photoproduction. In this work, we used an RNA interference (RNAi) approach to generate Chlamydomonas mutant strains with reduced levels of FNR. We found that fnr-RNAi strains exhibited higher rates of H₂ photoproduction (2.5-fold) than wild type under sulfur-deprived condition. To elucidate the basis for this increase, we analyzed the physiological characteristics of the fnr-RNAi strains under such condition. Major changes, due to the down-regulation of FNR, included the lower rates of photosynthetic O₂ evolution (44%), greater reduction of Rubisco amounts (60%) and higher rates of starch degradation (140%). These may result in an earlier onset of anaerobiosis and increased electron supply to the hydrogenases in the mutant strains. The results provide new information of FNR in regulating H₂ metabolism as well as potential strains for further improvement of the organism toward application in solar-powered systems.     

Effect of Ni content on the hydrogen storage behavior of ZrCo1−xNix alloys

ZrCo_1−xNi_x (x = 0, 0.1, 0.2 and 0.3) alloys were prepared and their hydrogen storage behavior were studied. ZrCo_1−xNi_x alloys of compositions with x = 0, 0.1, 0.2 and 0.3 prepared by arc-melting method and characterized by X-ray diffraction analysis. XRD analysis showed that the alloys of composition with x = 0, 0.1, 0.2 and 0.3 forms cubic phase similar to ZrCo with traces of ZrCo₂ phase. A trace amount of an additional phase similar to ZrNi was found for the alloy with composition x = 0.3. Hydrogen desorption pressure–composition–temperature (PCT) measurements were carried out using Sievert's type volumetric apparatus and the hydrogen desorption pressure–composition isotherms (PCIs) were generated for all the alloys in the temperature range of 523–603 K. A single sloping plateau was observed for each isotherm and the plateau pressure was found to increase with increasing Ni content in ZrCo_1−xNi_x alloys at the same experimental temperature. A van't Hoff plot was constructed using plateau pressure data of each pressure–composition isotherm and the thermodynamic parameters were calculated for desorption of hydrogen in the ZrCo_1−xNi_x–H₂ systems. The enthalpy and entropy change for desorption of hydrogen were calculated. In addition, the hydrogen absorption–desorption cyclic life studies were performed on ZrCo_1−xNi_x alloys at 583 K up to 50 cycles. It was observed that with increasing Ni content the durability against disproportionation of alloys increases.     

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.     

Concentration-dependent effects of metronidazole,inhibiting nitrogenase,on hydrogen photoproduction and proton-translocating ATPase activity of Rhodobacter sphaeroides

Rhodobacter sphaeroides MDC6522 is able to produce hydrogen (H₂) during photofermentation. Metronidazole (2-methyl-5-nitroimidazole-1-ethanol) has been shown to affect bacterial growth under anaerobic nitrogen-limited conditions in a concentration-dependent manner (within the range of 0.1–2 mM) by increasing lag phase duration and decreasing growth rate. The addition of metronidazole into the growth medium resulted in a delayed decrease of redox potential (E_h): by the addition of 0.1 mM metronidazole E_h decreased to −590 ± 25 mV, whereas in the presence of 2 mM E_h drop down was to −175 ± 15 mV. H₂ production during R. sphaeroides growth disappeared in the presence of metronidazole. By addition of 0.5 mM metronidazole H₂ yield was ∼8 fold lower in comparison with control; whereas the bacterium was unable to produce H₂ in the presence of 1–2 mM. The effects of metronidazole on nitrogenase-dependent H₂ production by R. sphaeroides might be explained by change of general photosynthetic electron transport with metronidazole as an alternative electron acceptor instead of nitrogenase. ATPase activity of membrane vesicles was determined with and without N,N'-dicyclohexylcarbodiimide (DCCD), an inhibitor of the F₀F₁-ATPase. It was revealed that DCCD-inhibited ATPase activity increased in the presence of metronidazole. It is possible that this effect may be resulted in either by direct affect of metronidazole on the F₀F₁-ATPase, or by its effect on E_h regulating ATPase activity.     

Fermentative hydrogen production by Clostridium butyricum CGS5 using carbohydrate-rich microalgal biomass as feedstock

In this work, a carbohydrate-rich microalga, Chlorella vulgaris ESP6, was grown photoautotrophically to fix the CO₂. The resulting microalgal biomass was hydrolyzed by acid or alkaline/enzymatic treatment and was then used for biohydrogen production with Clostridium butyricum CGS5. The C. vulgaris biomass could be effectively hydrolyzed by acid pretreatment while similar hydrolysis efficiency was achieved by combination of alkaline pretreatment and enzymatic hydrolysis. The biomass of C. vulgaris ESP6 containing a carbohydrate content of 57% (dry weight basis) was efficiently hydrolyzed by acid treatment with 1.5% HCl, giving a reducing sugars (RS) yield of nearly 100%. C. butyricum CGS5 could utilize RS from C. vulgaris ESP6 biomass to produce hydrogen without any additional organic carbon sources. The optimal conditions for hydrogen production were 37 °C and a microalgal hydrolysate loading of 9 g RS/L with pH-controlled at 5.5. Under the optimal conditions, the cumulative H₂ production, H₂ production rate, and H₂ yield were 1476 ml/L, 246 ml/L/h, and 1.15 mol/mol RS, respectively. The results demonstrate that the C. vulgaris biomass has the potential to serve as effective feedstock for dark fermentative H₂ production.