Chang-Hao Wu

High-yield hydrogen production from biomass by in vitro metabolic engineering: Mixed sugars coutilization and kinetic modeling

Significance Hydrogen (H2) has great potential to be used to power passenger vehicles. One solution to these problems is to distribute and store renewable carbohydrate instead, converting it to hydrogen as required. In this work more than 10 purified enzymes were combined into artificial enzymatic pathways and a high yield from both glucose and xylose to hydrogen was achieved. Also, gaseous hydrogen can be separated from aqueous substrates easily, greatly decreasing product separation costs, and avoid reconcentrating sugar solutions. This study describes high-yield enzymatic hydrogen production from biomass sugars and an engineered reaction rate increase achieved through the use of kinetic modeling. Distributed hydrogen production based on evenly distributed less-costly biomass could accelerate the implementation of the hydrogen economy. The use of hydrogen (H2) as a fuel offers enhanced energy conversion efficiency and tremendous potential to decrease greenhouse gas emissions, but producing it in a distributed, carbon-neutral, low-cost manner requires new technologies. Herein we demonstrate the complete conversion of glucose and xylose from plant biomass to H2 and CO2 based on an in vitro synthetic enzymatic pathway. Glucose and xylose were simultaneously converted to H2 with a yield of two H2 per carbon, the maximum possible yield. Parameters of a nonlinear kinetic model were fitted with experimental data using a genetic algorithm, and a global sensitivity analysis was used to identify the enzymes that have the greatest impact on reaction rate and yield. After optimizing enzyme loadings using this model, volumetric H2 productivity was increased 3-fold to 32 mmol H2⋅L−1⋅h−1. The productivity was further enhanced to 54 mmol H2⋅L−1⋅h−1 by increasing reaction temperature, substrate, and enzyme concentrations—an increase of 67-fold compared with the initial studies using this method. The production of hydrogen from locally produced biomass is a promising means to achieve global green energy production.

Proton-coupled electron transfer dynamics in the catalytic mechanism of a [NiFe]-hydrogenase.

The movement of protons and electrons is common to the synthesis of all chemical fuels such as H2. Hydrogenases, which catalyze the reversible reduction of protons, necessitate transport and reactivity between protons and electrons, but a detailed mechanism has thus far been elusive. Here, we use a phototriggered chemical potential jump method to rapidly initiate the proton reduction activity of a [NiFe] hydrogenase. Coupling the photochemical initiation approach to nanosecond transient infrared and visible absorbance spectroscopy afforded direct observation of interfacial electron transfer and active site chemistry. Tuning of intramolecular proton transport by pH and isotopic substitution revealed distinct concerted and stepwise proton-coupled electron transfer mechanisms in catalysis. The observed heterogeneity in the two sequential proton-associated reduction processes suggests a highly engineered protein environment modulating catalysis and implicates three new reaction intermediates; Nia-I, Nia-D, and Nia-SR(-). The results establish an elementary mechanistic understanding of catalysis in a [NiFe] hydrogenase with implications in enzymatic proton-coupled electron transfer and biomimetic catalyst design.

Proton Inventory and Dynamics in the Nia-S to Nia-C Transition of a [NiFe] Hydrogenase

Hydrogenases (H2ases) represent one of the most striking examples of biological proton-coupled electron transfer (PCET) chemistry, functioning in facile proton reduction and H2 oxidation involving long-range proton and electron transport. Spectroscopic and electrochemical studies of the [NiFe] H2ases have identified several catalytic intermediates, but the details of their interconversion are still a matter of debate. Here we use steady state and time-resolved infrared spectroscopy, sensitive to the CO ligand of the active site iron, as a probe of the proton inventory as well as electron and proton transfer dynamics in the soluble hydrogenase I from Pyrococcus furiosus. Subtle shifts in infrared signatures associated with the Nia-C and Nia-S states as a function of pH revealed an acid-base equilibrium associated with an ionizable amino acid near the active site. Protonation of this residue was found to correlate with the photoproduct distribution that results from hydride photolysis of the Nia-C state, in which one of the two photoproduct states becomes inaccessible at low pH. Additionally, the ability to generate Nia-S via PCET from Nia-C was weakened at low pH, suggesting prior protonation of the proton acceptor. Kinetic and thermodynamic analysis of electron and proton transfer with respect to the various proton inventories was utilized to develop a chemical model for reversible hydride oxidation involving two intermediates differing in their hydrogen bonding character.

High yield purification of a tagged cytoplasmic [NiFe]-hydrogenase and a catalytically-active nickel-free intermediate form

The cytoplasmic [NiFe]-hydrogenase I (SHI) of the hyperthermophile Pyrococcus furiosus evolves hydrogen gas (H2) from NADPH. It has been previously used for biohydrogen production from sugars using a mixture of enzymes in an in vitro cell-free synthetic pathway. The theoretical yield (12 H2/glucose) is three times greater than microbial fermentation (4 H2/glucose), making the in vitro approach very promising for large scale biohydrogen production. Further development of this process at an industrial scale is limited by the availability of the H2-producing SHI. To overcome the obstacles of the complex biosynthetic and maturation pathway for the [NiFe] site of SHI, the four gene operon encoding the enzyme was overexpressed in P. furiosus and included a polyhistidine affinity tag. The one-step purification resulted in a 50-fold increase in yield compared to the four-step purification procedure for the native enzyme. A trimeric form was also identified that lacked the [NiFe]-catalytic subunit but catalyzed NADPH oxidation with a specific activity similar to that of the tetrameric form. The presence of an active trimeric intermediate confirms the proposed maturation pathway where, in the terminal step, the NiFe-containing catalytic subunit assembles with NADPH-oxidizing trimeric form to give the active holoenzyme.

Exceptionally High Rates of Biological Hydrogen Production by Biomimetic in vitro Synthetic Enzymatic Pathways

Hydrogen production by water splitting energized by biomass sugars is one of the most promising technologies for distributed green H2 production. Direct H2 generation from NADPH, catalysed by an NADPH-dependent, soluble [NiFe]-hydrogenase (SH1) is thermodynamically unfavourable, resulting in slow volumetric productivity. We designed the biomimetic electron transport chain from NADPH to H2 by the introduction of an oxygen-insensitive electron mediator benzyl viologen (BV) and an enzyme (NADPH rubredoxin oxidoreductase, NROR), catalysing electron transport between NADPH and BV. The H2 generation rates using this biomimetic chain increased by approximately five-fold compared to those catalysed only by SH1. The peak volumetric H2 productivity via the in vitro enzymatic pathway comprised of hyperthermophilic glucose 6-phosphate dehydrogenase, 6-phosphogluconolactonase, and 6-phosphogluconate dehydrogenase, NROR, and SH1 was 310 mmol H2 /L h-1 , the highest rate yet reported. The concept of biomimetic electron transport chains could be applied to both in vitro and in vivo H2 production biosystems and artificial photosynthesis.

Balancing electron transfer rate and driving force for efficient photocatalytic hydrogen production in CdSe/CdS nanorod–[NiFe] hydrogenase assemblies

We describe a hybrid photocatalytic system for hydrogen production consisting of nanocrystalline CdSe/CdS dot-in-rod (DIR) structures coupled to [NiFe] soluble hydrogenase I (SHI) from Pyrococcus furiosus. Electrons are shuttled to the catalyst by a redox mediator, either methyl viologen (MV2+, E0 = −446 mV vs. NHE) or propyl-bridged 2-2′-bipyridinium (PDQ2+, E0 = −550 mV vs. NHE). We demonstrate nearly equal photoreduction efficiencies for the two mediators, despite extracting ∼100 mV of additional driving force for proton reduction by PDQ2+. Femtosecond to microsecond transient absorption reveals that while electron transfer (ET) from the DIR to PDQ2+ is slower than for MV2+, in both cases the ET process is complete by 1 ns and thus it efficiently outcompetes radiative decay. Long-lived charge separation is observed for both mediators, resulting in similar net efficiencies of photoreduction. Whereas both mediators are readily photoreduced, only PDQ2+ yields measurable H2 production, demonstrating the importance of optimizing the electron shuttling pathway to take advantage of the available reducing power of the DIR excited state. H2 production in the PDQ2+ system is highly efficient, with an internal quantum efficiency (IQE) as high as 77% and a TONSHI of 1.1 × 106 under mild (RT, pH = 7.35) conditions.

The role of geochemistry and energetics in the evolution of modern respiratory complexes from a proton-reducing ancestor ☆

Complex I or NADH quinone oxidoreductase (NUO) is an integral component of modern day respiratory chains and has a close evolutionary relationship with energy-conserving [NiFe]-hydrogenases of anaerobic microorganisms. Specifically, in all of biology, the quinone-binding subunit of Complex I, NuoD, is most closely related to the proton-reducing, H2-evolving [NiFe]-containing catalytic subunit, MbhL, of membrane-bound hydrogenase (MBH), to the methanophenzine-reducing subunit of a methanogenic respiratory complex (FPO) and to the catalytic subunit of an archaeal respiratory complex (MBX) involved in reducing elemental sulfur (S°). These complexes also pump ions and have at least 10 homologous subunits in common. As electron donors, MBH and MBX use ferredoxin (Fd), FPO uses either Fd or cofactor F420, and NUO uses either Fd or NADH. In this review, we examine the evolutionary trajectory of these oxidoreductases from a proton-reducing ancestral respiratory complex (ARC). We hypothesize that the diversification of ARC to MBH, MBX, FPO and eventually NUO was driven by the larger energy yields associated with coupling Fd oxidation to the reduction of oxidants with increasing electrochemical potential, including protons, S° and membrane soluble organic compounds such as phenazines and quinone derivatives. Importantly, throughout Earths history, the availability of these oxidants increased as the redox state of the atmosphere and oceans became progressively more oxidized as a result of the origin and ecological expansion of oxygenic photosynthesis. ARC-derived complexes are therefore remarkably stable respiratory systems with little diversity in core structure but whose general function appears to have co-evolved with the redox state of the biosphere. This article is part of a Special Issue entitled Respiratory Complex I, edited by Volker Zickermann and Ulrich Brandt.

Water Splitting for High‐Yield Hydrogen Production Energized by Biomass Xylooligosaccharides Catalyzed by an Enzyme Cocktail

Green hydrogen production through water splitting at low temperatures is highly desired for hydrogen economy. Herein, we demonstrate an in vitro non‐natural enzymatic pathway to utilize the chemical energy stored in xylooligosaccharides from biomass to split water to produce a nearly theoretical yield of H2 (i.e., ≈9.5 H2 per xylose plus water). This pathway was constructed on the basis of the novel activities of phosphopentomutase catalyzing the conversion of d‐xylose 1‐phosphate into d‐xylose 5‐phosphate and of ribose 5‐phosphate isomerase catalyzing the conversions of d‐xylose 5‐phosphate and d‐xylulose 5‐phosphate. This study suggests that the discovery of novel promiscuous enzyme activities is important to implement complicated biotransformations catalyzed by synthetic enzymatic pathways.

Advanced water splitting for green hydrogen gas production through complete oxidation of starch by in vitro metabolic engineering

Starch is a natural energy storage compound and is hypothesized to be a high-energy density chemical compound or solar fuel. In contrast to industrial hydrolysis of starch to glucose, an alternative ATP-free phosphorylation of starch was designed to generate cost-effective glucose 6-phosphate by using five thermophilic enzymes (i.e., isoamylase, alpha-glucan phosphorylase, 4-α-glucanotransferase, phosphoglucomutase, and polyphosphate glucokinase). This enzymatic phosphorolysis is energetically advantageous because the energy of α-1,4-glycosidic bonds among anhydroglucose units is conserved in the form of phosphorylated glucose. Furthermore, we demonstrated an in vitro 17-thermophilic enzyme pathway that can convert all glucose units of starch, regardless of branched and linear contents, with water to hydrogen at a theoretic yield (i.e., 12 H2 per glucose), three times of the theoretical yield from dark microbial fermentation. The use of a biomimetic electron transport chain enabled to achieve a maximum volumetric productivity of 90.2mmol of H2/L/h at 20g/L starch. The complete oxidation of starch to hydrogen by this in vitro synthetic (enzymatic) biosystem suggests that starch as a natural solar fuel becomes a high-density hydrogen storage compound with a gravimetric density of more than 14% H2-based mass and an electricity density of more than 3000Wh/kg of starch.

Electricity generation by Pyrococcus furiosus in microbial fuel cells operated at 90°C

Hyperthermophiles are microorganisms that thrive in extremely hot environments with temperatures near and even above 100°C. They are the most deeply rooted microorganisms on phylogenetic trees suggesting they may have evolved to survive in the early hostile earth. The simple respiratory systems of some of these hyperthermophiles make them potential candidates to develop microbial fuel cells (MFC) that can generate power at temperatures approaching the boiling point. We explored extracellular electron transfer in the hyperthermophilic archaeon Pyrococcus furiosus (Pf) by studying its ability to generate electricity in a two‐chamber MFC. Pf growing in defined medium functioned as an anolyte in a MFC operated at 90°C, generating a maximum current density of 2 A m−2 and a peak power density of 225 mW m−2 without the addition of any external redox mediator. Electron microscopy and electrochemical impedance spectroscopy of the anode with the attached Pf biofilm demonstrated bio‐electrochemical behavior that led to electricity generation in the MFC via direct electron transfer. This proof of concept study reveals for the first time that a hyperthermophile such as Pf can generate electricity in MFC at extreme temperatures. Biotechnol. Bioeng. 2017;114: 1419–1427.