About the Authors:
Y.-H. Percival Zhang
*To whom correspondence should be addressed. E-mail: [email protected]
Affiliation: Biological Systems Engineering Department, Virginia Tech, Blacksburg, Virginia, United States of America
Barbara R. Evans
Affiliation: Chemical Sciences Division, Oak Ridge National Laboratory, Oak Ridge, Tennessee, United States of America
Jonathan R. Mielenz
Affiliation: Biosciences Division, Oak Ridge National Laboratory, Oak Ridge, Tennessee, United States of America
Robert C. Hopkins
Affiliation: Department of Biochemistry and Molecular Biology, University of Georgia, Athens, Georgia, United States of America
Michael W.W. Adams
Affiliation: Department of Biochemistry and Molecular Biology, University of Georgia, Athens, Georgia, United States of America
Introduction
Photosynthesis is the biological process that converts light energy to chemical energy and stores it in carbohydrates as “6 CO2 + 6 H2O→C6H12O6+6 O2”, and fixes atmospheric carbon into biomass (living carbon). Before the industrial revolution, the global economy was largely based on carbon extracted directly or indirectly (via animals) from plants; now the economy is mainly dependent on fossil fuels (dead carbon). At the dawn of the 21st century, a combination of economic, technological, resource, and political developments is driving the emergence of a new carbohydrate economy [1], [2].
Climate change, mainly due to CO2 emissions from fossil fuel burning, and the eventual depletion of the world's fossil-fuel reserves, are threatening sustainable development [2]–[4]. Abundant, clean, and carbon-neutral hydrogen is widely believed to be the ultimate mobile energy carrier replacing gasoline, diesel, and ethanol; a high energy conversion efficiency (∼50–70%) can be achieved via fuel cells without producing pollutants [3]. Four main R&D priorities for the future hydrogen economy are: 1) decreasing hydrogen production costs via a number of means, 2) finding viable methods for high-density hydrogen storage, 3) establishing a safe and effective infrastructure for seamless delivery of hydrogen from production to storage to use, and 4) dramatically lowering the costs of fuel cells and improving their durability [5]–[7]. Hydrogen production from less costly abundant biomass is a shortcut for producing low-cost hydrogen without net carbon emissions [8]–[15].
Synthetic biology is interpreted as the engineering-driven building of increasingly complex biological entities for novel applications, involving the steps of standardization, decoupling, abstraction, and evolution [16]. One main goal of synthetic biology is to assemble interchangeable parts from natural biology into the systems that function unnaturally [17]. The simplest synthetic biology example is to assemble enzymes to implement an unnatural process, in which the gene regulatory systems do not exist. Here we apply the principles of synthetic biology to implement an important reaction by using 13 well-known enzymes, which form an unnatural enzymatic pathway. The most obvious advantage of this process is that the hydrogen yield is far higher than the theoretical yield (4 H2/glucose) of biological hydrogen fermentations [9], [15], [18]. This novel enzymatic high-yield hydrogen production method is anticipated to have great impacts on the future hydrogen and carbohydrate economy.
Results
We designed a new enzymatic method for producing hydrogen from starch and water,(1)
Figure 1 shows the synthetic enzymatic pathway that does not exist in nature. It is comprised of 13 reversible enzymatic reactions: a) a chain-shortening phosphorylation reaction catalyzed by starch phosphorylase yielding glucose-1-phosphate (Equation 2) [19]; b) the conversion of glucose-1-phosphate (G-1-P) to glucose-6-phosphate (G-6-P) catalyzed by phosphoglucomutase (Equation 3) [20]; c) a pentose phosphate pathway containing 10 enzymes (Equation 4) [21]; and d) hydrogen generation from NADPH catalyzed by hydrogenase (Equation 5) [22].(2)(3)(4)(5)
[Figure omitted. See PDF.]
Figure 1. The synthetic metabolic pathway for conversion of polysaccharides and water to hydrogen and carbon dioxide.
The abbreviations are: PPP, pentose phosphate pathway; G1P, glucose-1-phosphate; G6P, glucose-6-phosphate; 6PG, 6-phosphogluconate; Ru5P, ribulose-5-phosphate; and Pi, inorganic phosphate. The enzymes are: #1, glucan phosphorylase; #2, phosphoglucomutase; #3, G-6-P dehydrogenase; #4, 6-phosphogluconate dehydrogenase, #5 Phosphoribose isomerase; #6, Ribulose 5-phosphate epimerase; #7, Transaldolase; #8, Transketolase, #9, Triose phosphate isomerase; #10, Aldolase, #11, Phosphoglucose isomerase: #12, Fructose-1, 6-bisphosphatase; and #13, Hydrogenase.
https://doi.org/10.1371/journal.pone.0000456.g001
We first validated the reaction scheme of Woodward et al. [23], in which hydrogen was produced from G-6-P via 11 enzymes, based on the reaction of G-6-P+6 H2O→12 H2+6 CO2+Pi (top curve in Fig. 2). The proof-of-principle experiment was then conducted to validate whether hydrogen can be produced from starch and water at 30°C using 13 enzymes (see Materials and Methods). Clearly, hydrogen was produced as expected (bottom curve in Fig. 2). As compared to using G-6-P as the substrate, hydrogen production from starch exhibits a) a longer lag phase, b) a lower peak production rate (0.44 mmol/h/L), and c) an extended reaction time, all of which are consistent with the reaction mechanism (Fig. 1). The CO2 production for both cases was measured at the same time (Fig. 3). Clearly, CO2 was produced before H2 generation, which was in a good agreement with the mechanism in Figure 1. The integrated yields (mol/mol) of hydrogen and CO2, based on substrate consumption of G-6-P and starch, were 8.35 H2/G-6-P and 5.4 CO2/G-6-P, and 5.19 H2/glucose unit and 5.37 CO2/glucose unit, respectively. The yields of hydrogen and CO2 from G-6-P were approximately 70% and 86% of theoretical yields. The corresponding value for hydrogen from starch was lower (43%) although the CO2 yield was the same. The lower hydrogen yield was anticipated and its causes, such as the unfinished reaction, batch operation, and accumulation of metabolites (e.g., NADPH), are currently under study.
[Figure omitted. See PDF.]
Figure 2. Hydrogen production from either 2 mM G-6-P or 2 mM starch (glucose equivalent).
The reaction based on G-6-P contained the pentose phosphate cycle enzymes (#3-12, 1 unit each), ∼70 units of P. furiosus hydrogenase (#13), 0.5 mM thiamine pyrophosphate, 2 mM NADP+, 10 mM MgCl2, and 0.5 mM MnCl2 in 2.0 ml of 0.1 M HEPES buffer (pH 7.5), at 30°C. The reaction based on starch rather than G-6-P was supplemented by 10 units of α-glucan phosphorylase (#1), 10 units of phosphoglucomutase (#2), and 4 mM phosphate at 30°C.
https://doi.org/10.1371/journal.pone.0000456.g002
[Figure omitted. See PDF.]
Figure 3. Carbon dioxide production from either 2 mM G-6-P or 2 mM starch (glucose equivalent).
The experimental conditions were the same as those in Figure 2.
https://doi.org/10.1371/journal.pone.0000456.g003
Thermodynamic analysis (Fig. 4) shows that the overall reaction (Equation 1) is a spontaneous process (i.e., ΔG° = −48.9 kJ/mol) and is a weakly endothermic reaction (i.e., ΔH° = 595.6 kJ/mol), based on data elsewhere [21], [24]. Since the gaseous products (H2 and CO2) are simultaneously removed from the liquid reaction solution, the real Gibbs free energy at 30°C and atmospheric pressure is much less than −48.9 kJ/mol, according to Le Chatelier's principle. The fairly large negative values of Gibbs free energy suggest a complete conversion. Sugar chain-shortening substrate phosphorylation (Eq. 2) utilizes the energy stored in the glucosidic bonds of polysaccharides (15.5 kJ/mol glucosidic bond) to produce the activated phosphorylated monosaccharide (G-1-P) without ATP consumption [20], [25] and avoids using expensive substrates such as glucose-6-phosphate [23]. The endothermic reaction suggests that some low-temperature heat energy from the environment is used to produce high quality energy carrier hydrogen, an extra 22% net energy gain. Although photosynthesis efficiency from solar energy to chemical energy is not so high as that of solar cells [26], hydrogen production based on inexpensive abundant biomass will be a shortcut to realization of the hydrogen economy without net carbon emissions, will avoid large capital investments for the hydrogen infrastructure, and will save the huge energy consumption currently required for production of solar cells [3].
[Figure omitted. See PDF.]
Figure 4. An energy diagram showing the standard enthalpy (ΔH°) and free energy changes (ΔG°) in kJ/mol for the reactions in a renewable energy cycle operating among H2O, CO2, glucose, and starch.
https://doi.org/10.1371/journal.pone.0000456.g004
Discussion
There are four other means converting biomass to hydrogen: 1) direct polysaccharide gasification [8], [13]; 2) direct glucose chemical catalysis after polysaccharide hydrolysis [10], [11]; 3) anaerobic fermentations [9], [15], [18]; and 4) polysaccharide- or glucose-ethanol fermentations [27]–[29] followed by ethanol chemical reforming [12]. The chemical methods have low hydrogen yields (50∼57%) due to poor selectivity of catalysts and requires high reaction temperatures (e.g., 500∼900 K) [8], [10], [11], [13]. Anaerobic hydrogen fermentation is well known for its low hydrogen yield of 4 H2/glucose [9], [15], [18]. The combination of ethanol fermentation and ethanol-to-hydrogen reforming has a theoretical yield of 10 H2/glucose unit (e.g. 83% of the maximum). Allowing 5∼10% fermentation loss [30] and ∼5% reforming loss [12], the practical hydrogen yield through ethanol could be ca. 75% of the maximum yield. Assembly of the high-substrate-selectivity enzymes results in an artificial cascade enzymatic pathway, accompanied by a high hydrogen yield (12 H2/glucose), three time higher than the theoretical yield (4 H2/glucose) from biological hydrogen fermentations [9], [15], [18] and much higher than those from chemical catalysis [8], [10], [11].
Distinct from the severe reaction conditions of chemical catalysis [8], [10]–[14], the mild reaction conditions mediated by enzymes (∼20–100°C, depending on the enzymes employed) provide two obvious benefits: 1) easy implementation in a small space, especially for mobile applications, and 2) simple process configurations due to easy separation of the gaseous products (H2 and CO2) from the reactants (starch and water).
Costs of hydrogen production from less-costly starch (e.g., $∼0.15/kg) would be ∼$2/kg H2, assuming that feedstock costs account for half of overall costs and enzymes and co-enzyme account for another half. In general, approximately 40–75% of prices of commodities, such as gasoline from crude oil, hydrogen from natural gas, and ethanol from corn kernels, come from feedstock costs [31]. For example, current crude recombinant enzyme production costs are estimated to range ∼$10/kg; commercial cellulase production cost is as low as $1–2/kg [29]. Based on the rule of thumb for commodity production costs, the likely hydrogen-producing costs (∼$2/kg H2) could meet or exceed the hydrogen cost goals ($2–3/kg H2), established by the US DOE [32]. For example, the soaring prices of natural gas drove hydrogen costs from $1.40/kg H2 in 2003 to $2.70/kg H2 in 2005. We improve the method first described by Woodward [23] by starting with a less costly and abundant substrate–starch. Thus we avoid several major shortcomings of Woodward's method: 1) costly glucose-6-phosphate, 2) accumulation of phosphate, which is a strong inhibitor of fructose-1,6-bisphosphatase, 3) increasing ionic strength in the buffer, which slows down overall reaction rates, and 4) a pH shift in the buffer.
Solid starch has a relatively high energy density, with a mass-storage density of 14.8 H2-mass % and a volume-storage density of 104 kg H2/m3. These densities are higher than most of the solid hydrogen storage technologies [7], as well as exceeding the DOE goals of 4.5 mass%, 6 mass%, and 9 mass% in 2005, 2010, and 2015, respectively [5]. Replacement of conventional solid hydrogen storage technologies by the on-board starch-H2 converter and starch container will also solve several problems for solid hydrogen storage devices, e.g., energy loss for hydrogen compression or liquefaction, durability of reversible adsorption/desorption materials, high temperatures for desorption, and a long refilling time [5], [7]. Easy and safe storage and distribution of solid starch will address many issues of the hydrogen economy infrastructure. For example, setting up the infrastructure to store and distribute gaseous hydrogen to vehicles might cost hundreds of billions in the USA alone [33].
This robust synthetic enzymatic pathway that does not function in nature was assembled by 12 mesophilic enzymes from animal, plant, bacterial, and yeast sources, plus an archaeal hyperthermophilic hydrogenase. The performance (e.g., reaction rate and enzyme stability) is anticipated to be improved by several orders of magnitude by using the combination of (a) enzyme component optimization via metabolic engineering modeling [34], (b) interchangeable substitution of mesophilic enzymes by recombinant thermophilic or even hyperthermophilic enzymes [23], (c) protein engineering technologies, and (d) higher concentrations of enzymes and substrates. We have increased the hydrogen production rates by nearly 4 times greater than Woodward's results [23] through a) decreasing the ion strength of the buffer and b) substituting one mesophilic enzyme (#11). This research approach will naturally benefit from on-going improvements by others in synthetic biology systems that are addressing cofactor stability [35], enzyme stability by additives [36], and co-immobilization [37], and development of minimal microorganisms [38] that can be built upon to create an in vivo enzyme system that produces H2 in high yields.
The concept of cell-free synthetic enzymatic pathway engineering is anticipated to be applied to other commodity chemical production because of its unique benefits: high product yields (i.e., no formation of by-products and cell mass), modest reaction conditions as compared to chemical catalysis, no toxic chemicals required or produced, broad reaction conditions (e.g., high temperature and low pH) as compared with microorganisms, and easy operation and control. For example, it has been argued that cell-free ethanol fermentation systems would replace microbe-based ethanol fermentation someday [39].
With technology development and integration with PEM fuel cells, the starch-to-hydrogen conversion technology is anticipated to have wide mobile applications. We envision that future mobile appliances will store solid starch, produce hydrogen from starch and water via this reaction, and then generate electricity by hydrogen fuel cells at the same compact place.
Materials and Methods
All chemicals and enzymes were purchased from Sigma Co, unless otherwise noted. All enzymes and their catalysis reactions are listed in Table 1.
[Figure omitted. See PDF.]
Table 1. The enzymes used for hydrogen production from starch and water, and their reaction mechanisms, sources, and amounts used in the reaction.
https://doi.org/10.1371/journal.pone.0000456.t001
The experiments were carried out in a continuous flow system as described previously [23], with the modification that the moisture traps were cooled with ice instead of liquid nitrogen, and that oxygen as well as hydrogen and carbon dioxide were monitored in the gas stream [23] (Fig. 5). The working volume of the custom reactor was 2 mL. The system was continuously purged with helium at a flow rate of 50 mL/min. The temperature of the jacketed reaction vessel was maintained at 30°C with a Polyscience (Niles, IL 60714) circulating water bath. Hydrogen evolution was measured with a Figaro TGS 822 tin oxide sensor connected over a bridge amplifier to a Keithley Model 2000 multimeter (Keithley Instruments, Cleveland, OH). Oxygen concentration was monitored with a modified Hersh galvanic cell using 24% KOH as the electrolyte connected to a Keithley autoranging picoammeter. Carbon dioxide production was measured with a LI-COR CO2 Analyzer Model LI-6252 connected to a Keithley 2000 multimeter. The multimeters and picoammeter were connected to a 486 computer through IEEE 488 general-purpose interface boards. Electrolysis for calibration of hydrogen and oxygen by Faraday's law of electrochemical equivalence was carried out with a Keithley 220 programmable current source connected to an in-line electrolysis cell. Calibration for carbon dioxide was carried out with an analyzed gas mixture consisting of 735 ppm carbon dioxide and 1000 ppm oxygen in helium (Air Liquide America Corp., Houston, TX 77056). Data collection and analysis was carried out with ASYST 4.0 software (ASYST Technologies, Inc., Rochester, NY).
[Figure omitted. See PDF.]
Figure 5. The hydrogen cell system configured for monitoring H2 with the ORNL in-house sensor based on the Figaro TGS 822 and O2 with a modified Hersh galvanic cell [43].
The CO2 analyzer (not shown) is attached between the reaction cell and the electrolysis cell.
https://doi.org/10.1371/journal.pone.0000456.g005
The integrated molar/molar yields of hydrogen (YH2) and carbon dioxide (YCO2) are calculated asin which rH2 and rCO2 are the volumetric production rates in terms of mmole of H2 or CO2 per liter of reaction volume per hour, as shown in Figs. 2 and 3; ΔGEis the net consumption of glucose equivalent in terms of mM. Residual G-6-P can be measured using Sigma glucose HK kit [40]. The mixtures were incubated at 35°C for 5 minutes and the change in absorbance at 340 nm was determined. In the case of starch, the residual starch, G-1-P, and G-6-P were hydrolyzed to glucose by addition of dilute H2SO4 and hydrolysis at 121°C for 1 hour. The neutralized glucose solutions were measured by a glucose HK kit [40].
Acknowledgments
We thank Dr. Larson at Virginia Tech for supplying the strain containing the recombinant fructose-1,6-bisphosphatase.
Author Contributions
Conceived and designed the experiments: YZ JM. Performed the experiments: YZ BE. Analyzed the data: MA YZ BE. Contributed reagents/materials/analysis tools: YZ RH. Wrote the paper: MA YZ BE JM.
Citation: Zhang Y-HP, Evans BR, Mielenz JR, Hopkins RC, Adams MW (2007) High-Yield Hydrogen Production from Starch and Water by a Synthetic Enzymatic Pathway. PLoS ONE2(5): e456. https://doi.org/10.1371/journal.pone.0000456
1. Ragauskas AJ, Williams CK, Davison BH, Britovsek G, Cairney J, et al. (2006) The path forward for biofuels and biomaterials. Science 311: 484–489.AJ RagauskasCK WilliamsBH DavisonG. BritovsekJ. Cairney2006The path forward for biofuels and biomaterials.Science311484489
2. Morris D (2006) The next economy: from dead carbon to living carbon. J Sci Food Agric 86: 1743–1746.D. Morris2006The next economy: from dead carbon to living carbon.J Sci Food Agric8617431746
3. Hoffert MI, Caldeira K, Benford G, Criswell DR, Green C, et al. (2002) Advanced technology paths to global climate stability: energy for a greenhouse planet. Science 298: 981–987.MI HoffertK. CaldeiraG. BenfordDR CriswellC. Green2002Advanced technology paths to global climate stability: energy for a greenhouse planet.Science298981987
4. Farrell AE, Plevin RJ, Turner BT, Jones AD, O'Hare M, et al. (2006) Ethanol can contribute to energy and environmental goals. Science 311: 506–508.AE FarrellRJ PlevinBT TurnerAD JonesM. O'Hare2006Ethanol can contribute to energy and environmental goals.Science311506508
5. DOE (2004) Basic Research Needs for the Hydrogen Economy. DOE2004Basic Research Needs for the Hydrogen Economy.http://www.sc.doe.gov/bes/hydrogen.pdf. http://www.sc.doe.gov/bes/hydrogen.pdf.
6. Steele BCH, Heinzel A (2001) Materials for fuel-cell technologies. Nature 414: 345–352.BCH SteeleA. Heinzel2001Materials for fuel-cell technologies.Nature414345352
7. Schlapbach L, Zuttel A (2001) Hydrogen-storage materials for mobile applications. Nature 414: 353–358.L. SchlapbachA. Zuttel2001Hydrogen-storage materials for mobile applications.Nature414353358
8. Antal MJ, Allen SG, Schulman D, Xu X, Divilio RJ (2000) Biomass gasification in supercritical water. Ind Eng Chem Res 39: 4040–4053.MJ AntalSG AllenD. SchulmanX. XuRJ Divilio2000Biomass gasification in supercritical water.Ind Eng Chem Res3940404053
9. Hallenbeck PC, Benemann JR (2002) Biological hydrogen production: fundamentals and limiting processes. Int J Hydrogen Energy 27: 1185–1193.PC HallenbeckJR Benemann2002Biological hydrogen production: fundamentals and limiting processes.Int J Hydrogen Energy2711851193
10. Cortright RD, Davda RR, Dumesic JA (2002) Hydrogen from catalytic reforming of biomass-derived hydrocarbons in liquid water. Nature 418: 964–967.RD CortrightRR DavdaJA Dumesic2002Hydrogen from catalytic reforming of biomass-derived hydrocarbons in liquid water.Nature418964967
11. Huber GW, Shabaker JW, Dumesic JA (2003) Raney Ni-Sn catalyst for H2 production from biomass-derived hydrocarbons. Science 300: 2075–2077.GW HuberJW ShabakerJA Dumesic2003Raney Ni-Sn catalyst for H2 production from biomass-derived hydrocarbons.Science30020752077
12. Deluga GA, Salge JR, Schmidt LD, Verykios XE (2004) Renewable hydrogen from ethanol by autothermal reforming. Science 303: 993–997.GA DelugaJR SalgeLD SchmidtXE Verykios2004Renewable hydrogen from ethanol by autothermal reforming.Science303993997
13. Matsumura Y, Minowa T, Potic B, Kersten SRA, Prins W, et al. (2005) Biomass gasification in near- and super-critical water: Status and prospects. Biomass Bioenergy 29: 269–292.Y. MatsumuraT. MinowaB. PoticSRA KerstenW. Prins2005Biomass gasification in near- and super-critical water: Status and prospects.Biomass Bioenergy29269292
14. Salge JR, Dreyer BJ, Dauenhauer PJ, Schmidt LD (2006) Renewable hydrogen from nonvolatile fuels by reactive flash volatilization. Science 314: 801–804.JR SalgeBJ DreyerPJ DauenhauerLD Schmidt2006Renewable hydrogen from nonvolatile fuels by reactive flash volatilization.Science314801804
15. Adams MWW, Stiefel EI (1998) Biological hydrogen production: Not so elementary. Science 282: 1842–1843.MWW AdamsEI Stiefel1998Biological hydrogen production: Not so elementary.Science28218421843
16. Endy D (2005) Foundations for engineering biology. Nature 438: 449–453.D. Endy2005Foundations for engineering biology.Nature438449453
17. Benner SA, Sismour AM (2005) Synthetic biology. Nat Rev Genetics 6: 533–543.SA BennerAM Sismour2005Synthetic biology.Nat Rev Genetics6533543
18. Das D, Veziroglu TN (2001) Hydrogen production by biological processes: a survey of literature. Int J Hydrogen Energy 26: 13–28.D. DasTN Veziroglu2001Hydrogen production by biological processes: a survey of literature.Int J Hydrogen Energy261328
19. Blennow A, Nielsen TH, Baunsgaard L, Mikkelsen R, Engelsen SB (2002) Starch phosphorylation: a new front line in starch research. Trends Plant Sci 7: 445–450.A. BlennowTH NielsenL. BaunsgaardR. MikkelsenSB Engelsen2002Starch phosphorylation: a new front line in starch research.Trends Plant Sci7445450
20. Zhang Y-HP, Lynd LR (2005) Cellulose utilization by Clostridium thermocellum: Bioenergetics and hydrolysis product assimilation. Proc Natl Acad Sci USA 102: 7321–7325.Y-HP ZhangLR Lynd2005Cellulose utilization by Clostridium thermocellum: Bioenergetics and hydrolysis product assimilation.Proc Natl Acad Sci USA10273217325
21. Berg JM, Tymoczko JL, Stryer L (2002) Biochemistry (fifth edition). New York: W. H. Freeman & Co. JM BergJL TymoczkoL. Stryer2002Biochemistry (fifth edition).New YorkW. H. Freeman & Co380
22. Ma K, Zhou ZH, Adams MWW (1994) Hydrogen production from pyruvate by enzymes purified from the hyperthermophilic archaeon, Pyrococcus furiosus: A key role for NADPH. FEMS Microbiol Lett 122: 245–250.K. MaZH ZhouMWW Adams1994Hydrogen production from pyruvate by enzymes purified from the hyperthermophilic archaeon, Pyrococcus furiosus: A key role for NADPH.FEMS Microbiol Lett122245250
23. Woodward J, Orr M, Cordray K, Greenbaum E (2000) Enzymatic production of biohydrogen. Nature 405: 1014–1015.J. WoodwardM. OrrK. CordrayE. Greenbaum2000Enzymatic production of biohydrogen.Nature40510141015
24. Atkins PW, De Paula J (2005) Elements of Physical Chemistry (4th edition). New York: W.H. Freeman & Co. pp. 605–613.PW AtkinsJ. De Paula2005Elements of Physical Chemistry (4th edition).New YorkW.H. Freeman & Co605613
25. Muir M, Williams L, Ferenci T (1985) Influence of transport energization on the growth yield of Escherichia coli. J Bacteriol 163: 1237–1242.M. MuirL. WilliamsT. Ferenci1985Influence of transport energization on the growth yield of Escherichia coli.J Bacteriol16312371242
26. Smil V (1999) Energies: An illustrated guide to the biosphere and civilization. Cambridge, MA: The MIT Press. pp. 1–10.V. Smil1999Energies: An illustrated guide to the biosphere and civilization.Cambridge, MAThe MIT Press110
27. Zhang Y-HP, Lynd LR (2004) Toward an aggregated understanding of enzymatic hydrolysis of cellulose: Noncomplexed cellulase systems. Biotechnol Bioeng 88: 797–824.Y-HP ZhangLR Lynd2004Toward an aggregated understanding of enzymatic hydrolysis of cellulose: Noncomplexed cellulase systems.Biotechnol Bioeng88797824
28. Lynd LR, Weimer PJ, van Zyl WH, Pretorius IS (2002) Microbial cellulose utilization: fundamentals and biotechnology. Microbiol Mol Biol Rev 66: 506–577.LR LyndPJ WeimerWH van ZylIS Pretorius2002Microbial cellulose utilization: fundamentals and biotechnology.Microbiol Mol Biol Rev66506577
29. Zhang Y-HP, Himmel M, Mielenz JR (2006) Outlook for cellulase improvement: Screening and selection strategies. Biotechnol Adv 24: 452–481.Y-HP ZhangM. HimmelJR Mielenz2006Outlook for cellulase improvement: Screening and selection strategies.Biotechnol Adv24452481
30. Wheals AE, Basso LC, Alves DMG, Amorim HV (1999) Fuel ethanol after 25 years. Trends Biotechnol 17: 482–487.AE WhealsLC BassoDMG AlvesHV Amorim1999Fuel ethanol after 25 years.Trends Biotechnol17482487
31. Lynd LR, Wyman CE, Gerngross TU (1999) Biocommodity engineering. Biotechnol Prog 15: 777–793.LR LyndCE WymanTU Gerngross1999Biocommodity engineering.Biotechnol Prog15777793
32. U.S. Department of Energy - Hydrogen Program (2005) U.S. Department of Energy - Hydrogen Program2005DOE announces new hydrogen cost goal at http://www.hydrogen.energy.gov/news_cost_goal.html?print. DOE announces new hydrogen cost goal at http://www.hydrogen.energy.gov/news_cost_goal.html?print.
33. Moore RB, Raman V (1998) Hydrogen infrastructure for fuel cell transportation. Int J Hydrogen Energy 23: 617–620.RB MooreV. Raman1998Hydrogen infrastructure for fuel cell transportation.Int J Hydrogen Energy23617620
34. Stephanopoulos GN, Aristidou AA, Nielsen J (1998) Metabolic Engineering: Principles and Methodologies. San Diego: Academic Press. GN StephanopoulosAA AristidouJ. Nielsen1998Metabolic Engineering: Principles and Methodologies.San DiegoAcademic Press
35. Ohno A, Oda S, Ishikawa Y, Yamazaki N (2000) NAD(P)+-NAD(P)H models. 90. Stereoselection controlled by electronic effect of a carbonyl group in oxidation of NAD(P)H analog. J Org Chem 65: 6381–6387.A. OhnoS. OdaY. IshikawaN. Yamazaki2000NAD(P)+-NAD(P)H models. 90. Stereoselection controlled by electronic effect of a carbonyl group in oxidation of NAD(P)H analog.J Org Chem6563816387
36. Ramos A, Raven NDH, Sharp RJ, Bartolucci S, Rossi M, et al. (1997) Stabilization of enzymes against thermal stress and freeze-drying by mannosylglycerate. Appl Environ Microbiol 63: 4020–4025.A. RamosNDH RavenRJ SharpS. BartolucciM. Rossi1997Stabilization of enzymes against thermal stress and freeze-drying by mannosylglycerate.Appl Environ Microbiol6340204025
37. Jung GY, Stephanopoulos G (2004) A functional protein chip for pathway optimization and in vitro metabolic engineering. Science 428–431: GY JungG. Stephanopoulos2004A functional protein chip for pathway optimization and in vitro metabolic engineering.Science428–431
38. Glass JI, Assad-Garcia N, Alperovich N, Yooseph S, Lewis MR, et al. (2006) Essential genes of a minimal bacterium. Proc Natl Acad Sci USA 103: 425–430.JI GlassN. Assad-GarciaN. AlperovichS. YoosephMR Lewis2006Essential genes of a minimal bacterium.Proc Natl Acad Sci USA103425430
39. Allain EJ (2007) Cell-free ethanol production: the future of fuel ethanol? J Chem Technol Biotechnol 82: 117–120.EJ Allain2007Cell-free ethanol production: the future of fuel ethanol?J Chem Technol Biotechnol82117120
40. Zhang Y-HP, Lynd LR (2004) Kinetics and relative importance of phosphorolytic and hydrolytic cleavage of cellodextrins and cellobiose in cell extracts of Clostridium thermocellum. Appl Environ Microbiol 70: 1563–1569.Y-HP ZhangLR Lynd2004Kinetics and relative importance of phosphorolytic and hydrolytic cleavage of cellodextrins and cellobiose in cell extracts of Clostridium thermocellum.Appl Environ Microbiol7015631569
41. Donahue JL, Bownas JL, Niehaus WG, Larson TJ (2000) Purification and characterization of glpX-encoded fructose 1,6-bisphosphatase, a new enzyme of the glycerol 3-phosphate regulon of Escherichia coli. J Bacteriol 182: 5624–5627.JL DonahueJL BownasWG NiehausTJ Larson2000Purification and characterization of glpX-encoded fructose 1,6-bisphosphatase, a new enzyme of the glycerol 3-phosphate regulon of Escherichia coli.J Bacteriol18256245627
42. Ma K, Schicho RN, Kelly RM, Adams MWW (1993) Hydrogenase of the hyperthermophile Pyrococcus furiosus is an elemental sulfur reductase or sulfhydrogenase: Evidence for a sulfur-reducing hydrogenase ancestor. Proc Natl Acad Sci USA 90: 5341–5344.K. MaRN SchichoRM KellyMWW Adams1993Hydrogenase of the hyperthermophile Pyrococcus furiosus is an elemental sulfur reductase or sulfhydrogenase: Evidence for a sulfur-reducing hydrogenase ancestor.Proc Natl Acad Sci USA9053415344
43. Millsaps JF, Bruce BD, Lee JW, Greenbaum E (2001) Nanoscale photosynthesis: Photocatalytic production of hydrogen by platinized photosystem I reaction centers Photochem Photobiol 73: 630–635.JF MillsapsBD BruceJW LeeE. Greenbaum2001Nanoscale photosynthesis: Photocatalytic production of hydrogen by platinized photosystem I reaction centersPhotochem Photobiol73630635
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Abstract
Background
The future hydrogen economy offers a compelling energy vision, but there are four main obstacles: hydrogen production, storage, and distribution, as well as fuel cells. Hydrogen production from inexpensive abundant renewable biomass can produce cheaper hydrogen, decrease reliance on fossil fuels, and achieve zero net greenhouse gas emissions, but current chemical and biological means suffer from low hydrogen yields and/or severe reaction conditions.
Methodology/Principal Findings
Here we demonstrate a synthetic enzymatic pathway consisting of 13 enzymes for producing hydrogen from starch and water. The stoichiometric reaction is C6H10O5 (l)+7 H2O (l)→12 H2 (g)+6 CO2 (g). The overall process is spontaneous and unidirectional because of a negative Gibbs free energy and separation of the gaseous products with the aqueous reactants.
Conclusions
Enzymatic hydrogen production from starch and water mediated by 13 enzymes occurred at 30°C as expected, and the hydrogen yields were much higher than the theoretical limit (4 H2/glucose) of anaerobic fermentations.
Significance
The unique features, such as mild reaction conditions (30°C and atmospheric pressure), high hydrogen yields, likely low production costs ($∼2/kg H2), and a high energy-density carrier starch (14.8 H2-based mass%), provide great potential for mobile applications. With technology improvements and integration with fuel cells, this technology also solves the challenges associated with hydrogen storage, distribution, and infrastructure in the hydrogen economy.
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