Sustained hydrogen photoproduction by Chlamydomonas reinhardtii: Effects of culture parameters

The green alga, Chlamydomonas reinhardtii, is capable of sustained H(2) photoproduction when grown under sulfur-deprived conditions. This phenomenon is a result of the partial deactivation of photosynthetic O(2)-evolution activity in response to sulfur deprivation. At these reduced rates of water-oxidation, oxidative respiration under continuous illumination can establish an anaerobic environment in the culture. After 10-15 hours of anaerobiosis, sulfur-deprived algal cells induce a reversible hydrogenase and start to evolve H(2) gas in the light. Using a computer-monitored photobioreactor system, we investigated the behavior of sulfur-deprived algae and found that: (1) the cultures transition through five consecutive phases: an aerobic phase, an O(2)-consumption phase, an anaerobic phase, a H(2)-production phase and a termination phase; (2) synchronization of cell division during pre-growth with 14:10 h light:dark cycles leads to earlier establishment of anaerobiosis in the cultures and to earlier onset of the H(2)-production phase; (3) re-addition of small quantities of sulfate (12.5-50 microM MgSO(4), final concentration) to either synchronized or unsynchronized cell suspensions results in an initial increase in culture density, a higher initial specific rate of H(2) production, an increase in the length of the H(2)-production phase, and an increase in the total amount of H(2) produced; and (4) increases in the culture optical density in the presence of 50 microM sulfate result in a decrease in the initial specific rates of H(2) production and in an earlier start of the H(2)-production phase with unsynchronized cells. We suggest that the effects of sulfur re-addition on H(2) production, up to an optimal concentration, are due to an increase in the residual water-oxidation activity of the algal cells. We also demonstrate that, in principle, cells synchronized by growth under light:dark cycles can be used in an outdoor H(2)-production system without loss of efficiency compared to cultures that up until now have been pre-grown under continuous light conditions.     

Biochemical and morphological characterization of sulfur-deprived and H2-producing Chlamydomonas reinhardtii (green alga)

Sulfur deprivation in green algae causes reversible inhibition of photosynthetic activity. In the absence of S, rates of photosynthetic O2 evolution drop below those of O2 consumption by respiration. As a consequence, sealed cultures of the green alga Chlamydomonas reinhardtii become anaerobic in the light, induce the "Fe-hydrogenase" pathway of electron transport and photosynthetically produce H2 gas. In the course of such H2-gas production cells consume substantial amounts of internal starch and protein. Such catabolic reactions may sustain, directly or in directly, the H2-production process. Profile analysis of selected photosynthetic proteins showed a precipitous decline in the amount of ribulose-1,5-bisphosphate carboxylase-oxygenase (Rubisco) as a function of time in S deprivation, a more gradual decline in the level of photosystem (PS) II and PSI proteins, and a change in the composition of the PSII light-harvesting complex (LHC-II). An increase in the level of the enzyme Fe-hydrogenase was noted during the initial stages of S deprivation (0-72 h) followed by a decline in the level of this enzyme during longer (t >72 h) S-deprivation times. Microscopic observations showed distinct morphological changes in C. reinhardtii during S deprivation and H2 production. Ellipsoid-shaped cells (normal photosynthesis) gave way to larger and spherical cell shapes in the initial stages of S deprivation and H2 production, followed by cell mass reductions after longer S-deprivation and H2-production times. It is suggested that, under S-deprivation conditions, electrons derived from a residual PSII H2O-oxidation activity feed into the hydrogenase pathway, thereby contributing to the H2-production process in Chlamydomonas reinhardtii. Interplay between oxygenic photosynthesis, mitochondrial respiration, catabolism of endogenous substrate, and electron transport via the hydrogenase pathway is essential for this light-mediated H2-production process.     

The dependence of algal H2 production on Photosystem II and O2 consumption activities in sulfur-deprived Chlamydomonas reinhardtii cells

Chlamydomonas reinhardtii cultures, deprived of inorganic sulfur, undergo dramatic changes during adaptation to the nutrient stress [Biotechnol. Bioeng. 78 (2002) 731]. When the capacity for Photosystem II (PSII) O(2) evolution decreases below that of respiration, the culture becomes anaerobic [Plant Physiol. 122 (2000) 127]. We demonstrate that (a) the photochemical activity of PSII, monitored by in situ fluorescence, also decreases slowly during the aerobic period; (b) at the exact time of anaerobiosis, the remaining PSII activity is rapidly down regulated; and (c) electron transfer from PSII to PSI abruptly decreases at that point. Shortly thereafter, the PSII photochemical activity is partially restored, and H(2) production starts. Hydrogen production, which lasts for 3-4 days, is catalyzed by an anaerobically induced, reversible hydrogenase. While most of the reductants used directly for H(2) gas photoproduction come from water, the remaining electrons must come from endogenous substrate degradation through the NAD(P)H plastoquinone (PQ) oxido-reductase pathway. We propose that the induced hydrogenase activity provides a sink for electrons in the absence of other alternative pathways, and its operation allows the partial oxidation of intermediate photosynthetic carriers, including the PQ pool, between PSII and PSI. We conclude that the reduced state of this pool, which controls PSII photochemical activity, is one of the main factors regulating H(2) production under sulfur-deprived conditions. Residual O(2) evolved under these conditions is probably consumed mostly by the aerobic oxidation of storage products linked to mitochondrial respiratory processes involving both the cytochrome oxidase and the alternative oxidase. These functions maintain the intracellular anaerobic conditions required to keep the hydrogenase enzyme in the active, induced form.     

Photoproduction of hydrogen by sulfur-deprived <Emphasis Type="Italic">C. reinhardtii</Emphasis> mutants with impaired Photosystem II photochemical activity

Photoproduction of H₂ was examined in a series of sulfur-deprived Chlamydomonas reinhardtii D1-R323 mutants with progressively impaired PSII photochemical activity. In the R323H, R323D, and R323E D1 mutants, replacement of arginine affects photosystem II (PSII) function, as demonstrated by progressive decreases in O₂-evolving activity and loss of PSII photochemical activity. Significant changes in PSII activity were found when the arginine residue was replaced by negatively charged amino acid residues (R323D and R323E). However, the R323H (positively charged or neutral, depending on the ambient pH) mutant had minimal changes in PSII activity. The R323H, R323D, and R323E mutants and the pseudo-wild-type (pWt) with restored PSII function were used to study the effects of sulfur deprivation on H₂-production activity. All of these mutants exhibited significant changes in the normal parameters associated with the H₂-photoproduction process, such as a shorter aerobic phase, lower accumulation of starch, a prolonged anaerobic phase observed before the onset of H₂-production, a shorter duration of H₂-production, lower H₂ yields compared to the pWt control, and slightly higher production of dark fermentation products such as acetate and formate. The more compromised the PSII photochemical activity, the more dramatic was the effect of sulfur deprivation on the H₂-production process, which depends both on the presence of residual PSII activity and the amount of stored starch.     

The effect of light intensity on hydrogen production by sulfur-deprived Chlamydomonas reinhardtii

The effect of light intensity on hydrogen production by sulfur-deprived Chlamydomonas reinhardtii was studied in situ using either long- or short-term experiments, or alternatively, with samples withdrawn from the photobioreactor. Overall hydrogen production by S-deprived culture was shown to depend on the light intensity and to exhibit regions of light limitation and light inhibition. The optimal incident light intensity for hydrogen production was independent of the method of sulfur deprivation or the initial acetate concentration in the medium (12-34 mM). However, it varied with the Chl concentration and the thickness of the photobioreactor. To calculate the average light intensity in the photobioreactor under different experimental conditions, a special mathematics approach was developed. The optimal average light intensity for H(2) production appeared to be 30-40 microE m(-2)s(-1) and was independent of the Chl or acetate concentrations and the method of S deprivation. The inhibitory effect of high light intensity was related to the enhanced O(2) evolution activity during the photosynthetic stage of sulfur deprivation and to the high activity of photosystem II at the beginning of the H(2)-production phase. Data support the major role of photosystem II in supplying reductants through photosystem I to the hydrogenase throughout the H(2)-production phase.     

The Effect of Sulfur Re-Addition on H<Subscript>2</Subscript> Photoproduction by Sulfur-Deprived Green Algae

Sulfur deprivation of algal cultures selectively and partially inactivates photosystem II (PSII)-catalyzed O₂ evolution, induces anaerobiosis and hydrogenase expression, and results in sustained H₂ photoproduction for several days. We show that re-addition of limiting amounts of sulfate (1–10 μM final concentration) to the cultures during the H₂-production phase temporarily reactivates PSII photochemical and O₂-evolution activity and re-establishes higher rates of electron transport through the photosynthetic electron transport chain. The reactivation of PSII occurs by de novo D1 protein synthesis, but does not result in the re-establishment of aerobic conditions in the reactor, detectable by dissolved-O₂ sensors. However, concomitant H₂ photoproduction is inhibited, possibly due to excessive intra-cellular levels of photosynthetically-evolved O₂. The partial recovery of electron transport rates correlates with the re-oxidation of the plastoquinone (PQ) pool, as observed by pulse-amplitude modulated (PAM) and fluorescence-induction measurements. These results show that the presence of a more oxidized PQ pool releases some of the down-regulation of electron transport caused by the anaerobic conditions.     

Plastidial Expression of Type II NAD(P)H Dehydrogenase Increases the Reducing State of Plastoquinones and Hydrogen Photoproduction Rate by the Indirect Pathway in Chlamydomonas reinhardtii

Biological conversion of solar energy into hydrogen is naturally realized by some microalgae species due to a coupling between the photosynthetic electron transport chain and a plastidial hydrogenase. While promising for the production of clean and sustainable hydrogen, this process requires improvement to be economically viable. Two pathways, called direct and indirect photoproduction, lead to sustained hydrogen production in sulfur-deprived Chlamydomonas reinhardtii cultures. The indirect pathway allows an efficient time-based separation of O₂ and H₂ production, thus overcoming the O₂ sensitivity of the hydrogenase, but its activity is low. With the aim of identifying the limiting step of hydrogen production, we succeeded in overexpressing the plastidial type II NAD(P)H dehydrogenase (NDA2). We report that transplastomic strains overexpressing NDA2 show an increased activity of nonphotochemical reduction of plastoquinones (PQs). While hydrogen production by the direct pathway, involving the linear electron flow from photosystem II to photosystem I, was not affected by NDA2 overexpression, the rate of hydrogen production by the indirect pathway was increased in conditions, such as nutrient limitation, where soluble electron donors are not limiting. An increased intracellular starch was observed in response to nutrient deprivation in strains overexpressing NDA2. It is concluded that activity of the indirect pathway is limited by the nonphotochemical reduction of PQs, either by the pool size of soluble electron donors or by the PQ-reducing activity of NDA2 in nutrient-limited conditions. We discuss these data in relation to limitations and biotechnological improvement of hydrogen photoproduction in microalgae.A number of microalgal and cyanobacterial species are able to convert solar energy into hydrogen by photobiological processes and are therefore considered promising organisms for developing clean and sustainable hydrogen production (Benemann, 2000; Ghirardi et al., 2000; Rupprecht et al., 2006). In microalgae, hydrogen photoproduction results from coupling the photosynthetic electron transport chain and a plastidial [FeFe] hydrogenase. Under most conditions, hydrogen photoproduction is a transient phenomenon that lasts from several seconds to a few minutes (Ghirardi et al., 2000; Melis and Happe, 2001). It has been considered a relic of evolution that may now serve, under certain environmental conditions, such as induction of photosynthesis in anoxia (Ghysels et al., 2013), as a safety valve that protects the photosynthetic electron transport chain from photodamage that results from overreduction of electron acceptors (Kessler, 1973; Tolleter et al., 2011). A major limitation to sustained hydrogen photoproduction is due to the oxygen sensitivity of the [FeFe] hydrogenase (Happe et al., 2002; Stripp et al., 2009). Melis et al. (2000) proposed an elegant way to overcome this oxygen sensitivity through a time-based separation of hydrogen and oxygen production phases occurring, for instance, in response to sulfur deficiency in a closed environment. Another limitation is related to the electron supply for the hydrogenase coming from the photosynthetic electron transport chain (Cournac et al., 2002). This limitation is partly due to the fact that other metabolic pathways, such as ferredoxin-NADP⁺ reductase and CO₂ fixation, compete with the hydrogenase for the use of reduced ferredoxin (Gaffron and Rubin, 1942; Hemschemeier et al., 2008). This is also due to upstream regulation of the electron transport chain, recently evidenced from the study of a Chlamydomonas reinhardtii mutant affected in proton gradient regulation-like1 (PGRL1)-mediated cyclic electron flow (CEF) around PSI. The strong enhancement of hydrogen production rates observed in the pgrl1 mutant was interpreted as the release of a control exerted by the transthylakoidal pH gradient on electron supply to the hydrogenase (Tolleter et al., 2011).Two pathways, direct or indirect, can supply electrons to the hydrogenase (Benemann, 2000; Melis and Happe, 2001; Chochois et al., 2009). In the direct pathway, the whole electron transport chain is engaged, with PSII supplying electrons to the plastoquinone (PQ) pool, the cytochrome b₆/f complex, and, in turn, PSI, ferredoxin, and the [FeFe] hydrogenase. Due to the high oxygen sensitivity of the [FeFe] hydrogenase and to the fact that O₂ is produced during photosynthesis at PSII, the direct pathway only operates when PSII activity is lower than mitochondrial respiration, thereby allowing anaerobiosis to be maintained. Such conditions can be obtained by decreasing PSII activity either by means of sulfur deprivation (Melis et al., 2000) or by decreasing light intensity in the photobioreactor (Degrenne et al., 2010). In the indirect pathway, reducing equivalents, stored as starch during the aerobic phase, are subsequently used to fuel hydrogen production. This implies a nonphotochemical reduction of the PQ pool that is at least in part mediated by NDA2, a type II NADH dehydrogenase discovered in C. reinhardtii chloroplasts (Desplats et al., 2009). RNA interference lines expressing lower levels of NDA2 show lower hydrogen production rates, and it was concluded that NDA2 is involved in hydrogen production by the indirect pathway (Jans et al., 2008; Mignolet et al., 2012). The indirect pathway allows for an efficient time-based separation of O₂- and H₂-producing phases because it does not involve PSII activity and does not produce O₂. However, the indirect pathway has a much lower rate than the direct pathway (Cournac et al., 2002; Antal et al., 2009; Chochois et al., 2009). With the aim to identify limiting steps of hydrogen production in microalgae, we attempted to overexpress NDA2 in C. reinhardtii chloroplasts. We report that algal strains displaying a 2-fold increase in NDA2 show an increased nonphotochemical reduction of PQs and an increased rate of hydrogen production by the indirect pathway, the latter being only observed in conditions where stromal reducing equivalents are available in sufficient amounts.     

A comparison of hydrogen photoproduction by sulfur-deprived Chlamydomonas reinhardtii under different growth conditions

Continuous photoproduction of H(2) by the green alga, Chlamydomonas reinhardtii, is observed after incubating the cultures for about a day in the absence of sulfate and in the presence of acetate. Sulfur deprivation causes the partial and reversible inactivation of photosynthetic O(2) evolution in algae, resulting in the light-induced establishment of anaerobic conditions in sealed photobioreactors, expression of two [FeFe]-hydrogenases in the cells, and H(2) photoproduction for several days. We have previously demonstrated that sulfur-deprived algal cultures can produce H(2) gas in the absence of acetate, when appropriate experimental protocols were used (Tsygankov, A.A., Kosourov, S.N., Tolstygina, I.V., Ghirardi, M.L., Seibert, M., 2006. Hydrogen production by sulfur-deprived Chlamydomonas reinhardtii under photoautotrophic conditions. Int. J. Hydrogen Energy 31, 1574-1584). We now report the use of an automated photobioreactor system to compare the effects of photoautotrophic, photoheterotrophic and photomixotrophic growth conditions on the kinetic parameters associated with the adaptation of the algal cells to sulfur deprivation and H(2) photoproduction. This was done under the experimental conditions outlined in the above reference, including controlled pH. From this comparison we show that both acetate and CO(2) are required for the most rapid inactivation of photosystem II and the highest yield of H(2) gas production. Although, the presence of acetate in the system is not critical for the process, H(2) photoproduction under photoautotrophic conditions can be increased by optimizing the conditions for high starch accumulation. These results suggest ways of engineering algae to improve H(2) production, which in turn may have a positive impact on the economics of applied systems for H(2) production.     

Autotrophic and mixotrophic hydrogen photoproduction in sulfur-deprived chlamydomonas cells

In Chlamydomonas reinhardtii cells, H2 photoproduction can be induced in conditions of sulfur deprivation in the presence of acetate. The decrease in photosystem II (PSII) activity induced by sulfur deprivation leads to anoxia, respiration becoming higher than photosynthesis, thereby allowing H2 production. Two different electron transfer pathways, one PSII dependent and the other PSII independent, have been proposed to account for H2 photoproduction. In this study, we investigated the contribution of both pathways as well as the acetate requirement for H2 production in conditions of sulfur deficiency. By using 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), a PSII inhibitor, which was added at different times after the beginning of sulfur deprivation, we show that PSII-independent H2 photoproduction depends on previously accumulated starch resulting from previous photosynthetic activity. Starch accumulation was observed in response to sulfur deprivation in mixotrophic conditions (presence of acetate) but also in photoautotrophic conditions. However, no H2 production was measured in photoautotrophy if PSII was not inhibited by DCMU, due to the fact that anoxia was not reached. When DCMU was added at optimal starch accumulation, significant H2 production was measured. H2 production was enhanced in autotrophic conditions by removing O2 using N2 bubbling, thereby showing that substantial H2 production can be achieved in the absence of acetate by using the PSII-independent pathway. Based on these data, we discuss the possibilities of designing autotrophic protocols for algal H2 photoproduction.     

Effect of anaerobiosis on photosynthetic reactions and nitrogen metabolism of algae with and without hydrogenase

Summary The effect of anaerobic (N₂+CO₂) pre-incubation in the dark on photosynthetic reactions (O₂ evolution, measured manometrically and with the oxygraph; fluorescence; and photoproduction of H₂, measured with the mass spectrometer) was studied in algae with hydrogenase (strains of Chlorella fusca, C. kessleri, C. vulgaris f. tertia, and Ankistrodesmus braunii) and in algae without hydrogenase (strains of Chlorella vulgaris, C. saccharophila, and C. minutissima).The inhibition by anaerobic incubation of photosynthetic O₂ evolution is much stronger in algae without hydrogenase than it is in algae with hydrogenase. The effect of anaerobiosis is most pronounced at rather low light intensity (about 1000 lux), in acid medium (pH 4), and after prolonged anaerobic incubation in the dark (about 20 h). These results indicate that the presence of hydrogenase might be ecologically advantageous for algae under certain conditions.Chlorophyll fluorescence showed the fastest response to anaerobic incubation, and the most pronounced difference between algae with and without hydrogenase. After only 30 min under N₂+CO₂, fluorescence in algae with hydrogenase starts with a peak and decreases within 10 to 20 sec to a rather low steady-state level which is only slightly higher than that found under aerobic conditions. In algae without hydrogenase, fluorescence is rather low during the first 1 to 2 sec and then rises to a higher steady-state level which is much higher than that of the aerobic controls. This indicates an inhibition due to anaerobiosis of photosystem II in algae without hydrogenase.Algae with hydrogenase can react in different ways during the first minutes of illumination. In some cases there is an immediate photoproduction of H₂, which is followed after a few minutes by photosynthetic O₂ evolution; in other algae there is a simultaneous production of H₂ and O₂ from the very beginning; in a few experiments there was no photoproduction of H₂ at all, and in this case there was no photosynthetic O₂ evolution either. Thus, photoproduction of H₂ seems to be the process which normally enables algae with hydrogenase to oxidise and thereby activate their photosynthetic electron transport system after anaerobic incubation.A mass spectrometric search for nitrogen fixation (using N₂ and acetylene) in eucaryotic green algae gave negative results, even with species containing hydrogenase and under anaerobic conditions.     

Synechococcus sp. strain PCC 7002 nifJ mutant lacking pyruvate:ferredoxin oxidoreductase

The nifJ gene codes for pyruvate:ferredoxin oxidoreductase (PFOR), which reduces ferredoxin during fermentative catabolism of pyruvate to acetyl-coenzyme A (acetyl-CoA). A nifJ knockout mutant was constructed that lacks one of two pathways for the oxidation of pyruvate in the cyanobacterium Synechococcus sp. strain PCC 7002. Remarkably, the photoautotrophic growth rate of this mutant increased by 20% relative to the wild-type (WT) rate under conditions of light-dark cycling. This result is attributed to an increase in the quantum yield of photosystem II (PSII) charge separation as measured by photosynthetic electron turnover efficiency determined using fast-repetition-rate fluorometry (F(v)/F(m)). During autofermentation, the excretion of acetate and lactate products by nifJ mutant cells decreased 2-fold and 1.2-fold, respectively. Although nifJ cells displayed higher in vitro hydrogenase activity than WT cells, H(2) production in vivo was 1.3-fold lower than the WT level. Inhibition of acetate-CoA ligase and pyruvate dehydrogenase complex by glycerol eliminated acetate production, with a resulting loss of reductant and a 3-fold decrease in H(2) production by nifJ cells compared to WT cells. Continuous electrochemical detection of dissolved H(2) revealed two temporally resolved phases of H(2) production during autofermentation, a minor first phase and a major second phase. The first phase was attributed to reduction of ferredoxin, because its level decreased 2-fold in nifJ cells. The second phase was attributed to glycolytic NADH production and decreased 20% in nifJ cells. Measurement of the intracellular NADH/NAD(+) ratio revealed that the reductant generated by PFOR contributing to the first phase of H(2) production was not in equilibrium with bulk NADH/NAD(+) and that the second phase corresponded to the equilibrium NADH-mediated process.     

Spatial coordination of chloroplast and plasma membrane activities in <Emphasis Type="Italic">chara</Emphasis> cells and its disruption through inactivation of 14-3-3 proteins

In Chara corallina cells exposed to continuous light, external pH (pH(o)) and photosystem II (PSII) photochemical yield show correlated banding patterns. Photosynthetic activity is low in cell regions producing alkaline zones and high in the acid regions. We addressed the question whether (and how) photosynthetic activity and plasma membrane (PM) H+-pumping and H+-conductance are coupled in the different bands. First, PM H+-pump activity was stimulated with fusicoccin. This resulted in a more acidic pH in the acid bands without disturbing the correlation of photosynthetic electron transport and H+ fluxes across the PM. Next, H+-pump activity was reduced through microinjection of a phosphorylated peptide matching the canonical 14-3-3 binding motif RSTpSTP in the acid cell region. Microinjection induced a rapid (~5 min) rise in pH(o) by ca. 1.0 unit near the injection site, whereas the injection of the non-phosphorylated peptide had no effect. This pH rise confirms the supposed inhibition of the H+-pump upon the detachment of 14-3-3 proteins from the H+-ATPase. However, the PSII yield in the cell regions corresponding to the new alkaline peak remained high, which violated the normal inverse relations between the pH(o) and PSII photochemical yield. We conclude that the injection of the competitive inhibitor of the H+-ATPase disrupts the balanced operation of PM H+-transport and photosynthetic electron flow and promotes electron flow through alternative pathways.     

Hydrogen Production in Chlamydomonas: Photosystem II-Dependent and -Independent Pathways Differ in Their Requirement for Starch Metabolism

Under sulfur deprivation conditions, the green alga Chlamydomonas reinhardtii produces hydrogen in the light in a sustainable manner thanks to the contribution of two pathways, direct and indirect. In the direct pathway, photosystem II (PSII) supplies electrons to hydrogenase through the photosynthetic electron transport chain, while in the indirect pathway, hydrogen is produced in the absence of PSII through a photosystem I-dependent process. Starch metabolism has been proposed to contribute to both pathways by feeding respiration and maintaining anoxia during the direct pathway and by supplying reductants to the plastoquinone pool during the indirect pathway. At variance with this scheme, we report that a mutant lacking starch (defective for sta6) produces similar hydrogen amounts as the parental strain in conditions of sulfur deprivation. However, when PSII is inhibited by 3-(3,4-dichlorophenyl)-1,1-dimethylurea, conditions where hydrogen is produced by the indirect pathway, hydrogen production is strongly reduced in the starch-deficient mutant. We conclude that starch breakdown contributes to the indirect pathway by feeding electrons to the plastoquinone pool but is dispensable for operation of the direct pathway that prevails in the absence of DCMU. While hydrogenase induction was strongly impaired in the starch-deficient mutant under dark anaerobic conditions, wild-type-like induction was observed in the light. Because this light-driven hydrogenase induction is DCMU insensitive and strongly inhibited by carbonyl cyanide-p-trifluoromethoxyphenylhydrazone or 2,5-dibromo-3-methyl-6-isopropyl-p-benzoquinone, we conclude that this process is regulated by the proton gradient generated by cyclic electron flow around PSI.In the context of economical and environmental concerns around fossil fuel depletion and global warming, the interest in hydrogen as an energy carrier for the future has considerably grown. Because molecular hydrogen is scarce on our planet, the development of a hydrogen economy strongly depends on our ability to propose clean and sustainable technologies of hydrogen production. In this context, the ability of some photosynthetic microorganisms, and particularly cyanobacteria and microalgae, to convert solar energy into hydrogen has been considered as very promising (Ghirardi et al., 2000; Rupprecht et al., 2006). When cells of the unicellular green alga Chlamydomonas reinhardtii are illuminated after adaptation to anaerobic conditions, electrons originating from water splitting at PSII are driven by the photosynthetic electron transport chain to ferredoxin and to a reversible iron hydrogenase, thereby enabling the production of molecular hydrogen from water and solar energy. Because both hydrogenase activity and expression are highly sensitive to the presence of O₂ (Happe et al., 1994; Ghirardi et al., 1997; Happe and Kaminski, 2002) and because O₂ is produced at PSII, hydrogen photoproduction stops after a few minutes of illumination. Melis et al. (2000) proposed an experimental protocol based on sulfur (S) deprivation, allowing long-term hydrogen production. This protocol relies on a two-stage process: during a first stage, oxygenic photosynthesis drives production of biomass and carbohydrate stores, and during a second anaerobic stage, the hydrogenase is induced and hydrogen is produced. Sulfur starvation has two important effects regarding hydrogen production: (1) a massive accumulation of starch that defines a common response to nutrient starvation and (2) a gradual drop in PSII activity (Wykoff et al., 1998). Once the rate of photosynthetic O₂ evolution drops below the rate of respiration, anaerobic conditions are reached, enabling the induction of hydrogenase and the production of significant amounts of hydrogen for several days. In parallel to hydrogen production, starch is degraded (Melis et al., 2000; Melis, 2007).The importance of starch fermentation in hydrogen production has been recognized early from the pioneering work of Gibbs and coworkers (Gfeller and Gibbs, 1984; Gibbs et al., 1986). Based on the observation that starchless C. reinhardtii mutants sta6 and sta7 are strongly affected in their ability to produce hydrogen, Posewitz et al. (2004) proposed that starch metabolism plays a central role in C. reinhardtii hydrogen production. Actually, two different pathways can supply reductants (i.e. reduced ferredoxin) for hydrogen production in the light, a direct pathway involving PSII and an indirect PSII-independent pathway that relies on a nonphotochemical reduction of plastoquinones (PQs; Fouchard et al., 2005; Melis, 2007). Starch catabolism was proposed to play a role in both pathways (Melis, 2007) by (1) sustaining mitochondrial respiration and allowing the maintenance of anaerobic conditions for the PSII-dependent direct pathway and (2) by supplying electrons to the chlororespiratory pathway and to the hydrogenase through a PSI-dependent process during the indirect pathway (Fouchard et al., 2005; Mus et al., 2005; Melis, 2007). Such a dual role of starch was first confirmed by the study of a Rubisco-deficient mutant (CC2653), unable to accumulate starch and to produce hydrogen in conditions of S deprivation (White and Melis, 2006), but was recently challenged by the study of another Rubisco-less mutant (CC2803), which was reported to produce significant amounts of hydrogen in S starvation conditions, although not accumulating starch (Hemschemeier et al., 2008). These conflicting results obtained on two different Rubisco-deficient mutants prompted us to reexamine the contribution of starch to both direct and indirect pathways of hydrogen production. For this purpose, we complemented the initial work of Posewitz et al. (2004) by revisiting the ability of C. reinhardtii mutants deficient in starch metabolism to produce hydrogen. We thus tested the ability to produce hydrogen in a starchless strain carrying defect in the structural gene encoding the small subunit of ADP-Glc pyrophosphorylase (AGPase; sta6; Zabawinski et al., 2001). We found that sta6 mutant produces significant hydrogen amounts in condition of S deprivation but shows a strongly reduced PSII-independent hydrogen production. We conclude that while the PSII-independent hydrogen production pathway strictly relies on starch catabolism, the PSII-dependent pathway may require either starch or acetate as a respiratory substrate to maintain anaerobiosis.     

Photosynthetic generation of O2 and H2 by photosystem I-deficient chlamydomonas mutants

A comparative study of aerobic generation of O2 and anaerobic photoproduction of H2 in whole cells of a wild-type strain of Chlamydomonas reinhardtii and its photosystem I-deficient mutants B4 and F8 found no contribution of photosystem II to ferredoxin photoreduction, which is not consistent with data of recent studies by Greenbaum et al. (Nature, 1995, 376, 438-441; and Science, 1996, 273, 364-367) who reported that they had discovered such a capacity in these mutant strains. In the wild-type and mutant strains, action spectra showed that O2 was evolved by photosystem II, whereas photoinhibition of chlororespiration and evolution of H2 depended on the activity of photosystem I. Single-turnover flash measurements of H2 evolution showed that the contents of photosystem I in mutant strains amounted to 3-35% of that in the wild-type strain. This fraction of photosystem I in "leaky" mutants displayed abnormal kinetic features and was highly sensitive to photoinhibition.     

Ascorbate as a substrate for photoproduction of hydrogen by photosystem I of chloroplasts

The photoproduction of hydrogen by 2-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU)-inhibited chloroplasts from ascorbate under anaerobic conditions was studied in the pH range 5.0 to 7.5 using methyl viologen (MV), N,N,N′,N′-tetramethyl-P-phenylenediamine (TMPD), and excess hydrogenase from Desulfovibrio desulfuricans. (a) At neutral and basic pHs, the photoreduction of MV, which reacted back with photoxidized ascorbate (dehydroascorbate [DHASC]), and the rates of H₂ photoproduction were very low. The slow H₂ photoproduction was explained by the reversible reduction of MV by the photoproduced H₂ (catalyzed by hydrogenase) and its reoxidation by DHASC resulting in H₂ uptake. (b) At pH 5.2, relatively high initial rates of H₂ photoproduction were obtained, which were comparable to the rates of O₂ consumption at pH 5.2 by photosystem I (catalyzed by photoreduced MV). However, accumulation of photoreduced MV under anaerobic conditions was not detected. In the presence of high concentrations of protons, the H₂ uptake by DHASC was very slow because the equilibrium concentration of H₂-reduced MV was very small, thus allowing H₂ evolution mediated by photoreduced MV to compete with the back reaction with DHASC. (c) The continuous accumulation of DHASC, which was generated together with H₂, gradually slowed the H₂ evolution until it stopped after about 3 hours. At high concentrations, DHASC was able to compete with the coupling of photoreduced MV to hydrogenase and H₂ evolution. (d) Dithiothreitol (DTT) reduced the DHASC and consequently competed with the back reaction of the photoreduced and H₂-reduced MV with DHASC. DTT thus prolonged the time period of H₂ photoproduction from ascorbate and abolished the dependence of its rate on pH in the range of 5.2 to 7.5 (e) A study of H₂ uptake by chemically oxidized ascorbate (in the dark) showed that MV and hydrogenase were both required to catalyze electron transfer from H₂ to DHASC. TMPD prevented this H₂ consumption by DHASC (in a chloroplast reaction mixture containing MV and hydrogenase). Illumination restored the H₂ uptake presumably by generating reduced MV which activated the hydrogenase.     

Sustained photobiological hydrogen gas production upon reversible inactivation of oxygen evolution in the green alga Chlamydomonas reinhardtii

The work describes a novel approach for sustained photobiological production of H(2) gas via the reversible hydrogenase pathway in the green alga Chlamydomonas reinhardtii. This single-organism, two-stage H(2) production method circumvents the severe O(2) sensitivity of the reversible hydrogenase by temporally separating photosynthetic O(2) evolution and carbon accumulation (stage 1) from the consumption of cellular metabolites and concomitant H(2) production (stage 2). A transition from stage 1 to stage 2 was effected upon S deprivation of the culture, which reversibly inactivated photosystem II (PSII) and O(2) evolution. Under these conditions, oxidative respiration by the cells in the light depleted O(2) and caused anaerobiosis in the culture, which was necessary and sufficient for the induction of the reversible hydrogenase. Subsequently, sustained cellular H(2) gas production was observed in the light but not in the dark. The mechanism of H(2) production entailed protein consumption and electron transport from endogenous substrate to the cytochrome b(6)-f and PSI complexes in the chloroplast thylakoids. Light absorption by PSI was required for H(2) evolution, suggesting that photoreduction of ferredoxin is followed by electron donation to the reversible hydrogenase. The latter catalyzes the reduction of protons to molecular H(2) in the chloroplast stroma.     

Hydrogen production by <Emphasis Type="Italic">Chlamydomonas reinhardtii</Emphasis>: an elaborate interplay of electron sources and sinks

The unicellular green alga Chlamydomonas reinhardtii possesses a [FeFe]-hydrogenase HydA1 (EC 1.12.7.2), which is coupled to the photosynthetic electron transport chain. Large amounts of H₂ are produced in a light-dependent reaction for several days when C. reinhardtii cells are deprived of sulfur. Under these conditions, the cells drastically change their physiology from aerobic photosynthetic growth to an anaerobic resting state. The understanding of the underlying physiological processes is not only important for getting further insights into the adaptability of photosynthesis, but will help to optimize the biotechnological application of algae as H₂ producers. Two of the still most disputed questions regarding H₂ generation by C. reinhardtii concern the electron source for H₂ evolution and the competition of the hydrogenase with alternative electron sinks. We analyzed the H₂ metabolism of S-depleted C. reinhardtii cultures utilizing a special mass spectrometer setup and investigated the influence of photosystem II (PSII)- or ribulosebisphosphate-carboxylase/oxygenase (Rubisco)-deficiency. We show that electrons for H₂-production are provided both by PSII activity and by a non-photochemical plastoquinone reduction pathway, which is dependent on previous PSII activity. In a Rubisco-deficient strain, which produces H₂ also in the presence of sulfur, H₂ generation seems to be the only significant electron sink for PSII activity and rescues this strain at least partially from a light-sensitive phenotype. The latter indicates that the down-regulation of assimilatory pathways in S-deprived C. reinhardtii cells is one of the important prerequisites for a sustained H₂ evolution.     

Autotrophic and Mixotrophic Hydrogen Photoproduction in Sulfur-Deprived Chlamydomonas Cells

In Chlamydomonas reinhardtii cells, H₂ photoproduction can be induced in conditions of sulfur deprivation in the presence of acetate. The decrease in photosystem II (PSII) activity induced by sulfur deprivation leads to anoxia, respiration becoming higher than photosynthesis, thereby allowing H₂ production. Two different electron transfer pathways, one PSII dependent and the other PSII independent, have been proposed to account for H₂ photoproduction. In this study, we investigated the contribution of both pathways as well as the acetate requirement for H₂ production in conditions of sulfur deficiency. By using 3-(3,4-dichlorophenyl)-1,1-dimethylurea (DCMU), a PSII inhibitor, which was added at different times after the beginning of sulfur deprivation, we show that PSII-independent H₂ photoproduction depends on previously accumulated starch resulting from previous photosynthetic activity. Starch accumulation was observed in response to sulfur deprivation in mixotrophic conditions (presence of acetate) but also in photoautotrophic conditions. However, no H₂ production was measured in photoautotrophy if PSII was not inhibited by DCMU, due to the fact that anoxia was not reached. When DCMU was added at optimal starch accumulation, significant H₂ production was measured. H₂ production was enhanced in autotrophic conditions by removing O₂ using N₂ bubbling, thereby showing that substantial H₂ production can be achieved in the absence of acetate by using the PSII-independent pathway. Based on these data, we discuss the possibilities of designing autotrophic protocols for algal H₂ photoproduction.     

Maximizing reductant flow into microbial H2 production

Developing microbes into a sustainable source of hydrogen gas (H2) will require maximizing intracellular reductant flow toward the H2-producing enzymes. Recent attempts to increase H2 production in dark fermentative bacteria include increasing oxidation of organic substrates through metabolic engineering and expression of exogenous hydrogenases. In photofermentative bacteria, H2 production can be increased by minimizing reductant flow into competing pathways such as biomass formation and the Calvin cycle. One method of directing reductant toward H2 production being investigated in oxygenic phototrophs, which could potentially be applied to other H2-producing organisms, is the tethering of electron donors and acceptors, such as hydrogenase and photosystem I, to create new intermolecular electron transfer pathways.     

The photochemical activity of photosystem II in sulfur-deprived Chlamydomonas reinhardtii cells depends on the redox state of the quinone pool during the transition to anaerobiosis

Measurements with a PAM fluorometer showed that the photochemical activity of photosystem II (PS II) in sulfur-deprived Chlamydomonas reinhardtii cells (media TAP-S) decreases slowly under aerobic conditions. In a closed cultivator, when the rate of O2 photosynthetic evolution declines below the rate of respiration, the cell culture is under anaerobic conditions in which the activation of hydrogenase and the production of hydrogen take place. We found that the slow decrease in PS II activity is followed by an abrupt inactivation of PS II centers just after the onset of anaerobiosis. This fast PS II inactivation is reversed by aeration of the media and is accompanied by an increase in the fluorescence parameter Ft. Moreover, the rate of the abrupt PS II inactivation diminished after the addition into the medium of electron acceptors such as CO2 (carbonate-bicarbonate buffer), NO3- and SO4(2-) , the assimilation of which in chloroplasts requires a lot of reductants. We suggest that the PS II inactivation is due to the overreduction of the plastoquinone pool after the onset of anaerobiosis.