The structure and reactivity of the HoxEFU complex from the cyanobacterium Synechocystis sp. PCC 6803

Cyanobacterial Hox is a [NiFe] hydrogenase that consists of the hydrogen (H2)-activating subunits HoxYH, which form a complex with the HoxEFU assembly to mediate reactions with soluble electron carriers like NAD(P)H and ferredoxin (Fdx), thereby coupling photosynthetic electron transfer to energy-transforming catalytic reactions. Researchers studying the HoxEFUYH complex have observed that HoxEFU can be isolated independently of HoxYH, leading to the hypothesis that HoxEFU is a distinct functional subcomplex rather than an artifact of Hox complex isolation. Moreover, outstanding questions about the reactivity of Hox with natural substrates and the site(s) of substrate interactions and coupling of H2, NAD(P)H, and Fdx remain to be resolved. To address these questions, here we analyzed recombinantly produced HoxEFU by electron paramagnetic resonance spectroscopy and kinetic assays with natural substrates. The purified HoxEFU subcomplex catalyzed electron transfer reactions among NAD(P)H, flavodoxin, and several ferredoxins, thus functioning in vitro as a shuttle among different cyanobacterial pools of reducing equivalents. Both Fdx1-dependent reductions of NAD+ and NADP+ were cooperative. HoxEFU also catalyzed the flavodoxin-dependent reduction of NAD(P)+, Fdx2-dependent oxidation of NADH and Fdx4- and Fdx11-dependent reduction of NAD+. MS-based mapping identified an Fdx1-binding site at the junction of HoxE and HoxF, adjacent to iron-sulfur (FeS) clusters in both subunits. Overall, the reactivity of HoxEFU observed here suggests that it functions in managing peripheral electron flow from photosynthetic electron transfer, findings that reveal detailed insights into how ubiquitous cellular components may be used to allocate energy flow into specific bioenergetic products.

[1]  Jian-Ren Shen,et al.  An alternative plant-like cyanobacterial ferredoxin with unprecedented structural and functional properties: Ferredoxin with low Em discriminating against FNR. , 2019, Biochimica et biophysica acta. Bioenergetics.

[2]  T. Ikegami,et al.  Structural adaptations of photosynthetic complex I enable ferredoxin-dependent electron transfer , 2019, Science.

[3]  J. W. Peters,et al.  The catalytic mechanism of electron-bifurcating electron transfer flavoproteins (ETFs) involves an intermediary complex with NAD+ , 2018, The Journal of Biological Chemistry.

[4]  A. Wilde,et al.  A unique ferredoxin acts as a player in the low-iron response of photosynthetic organisms , 2018, Proceedings of the National Academy of Sciences.

[5]  Peng Zhang,et al.  A new era for electron bifurcation. , 2018, Current opinion in chemical biology.

[6]  Lloyd M. Smith,et al.  Identification of MS-Cleavable and Noncleavable Chemically Cross-Linked Peptides with MetaMorpheus. , 2018, Journal of proteome research.

[7]  E. Salvadori,et al.  Principles and applications of EPR spectroscopy in the chemical sciences. , 2018, Chemical Society reviews.

[8]  R. Thauer,et al.  Flavin-Based Electron Bifurcation, A New Mechanism of Biological Energy Coupling. , 2018, Chemical reviews.

[9]  E. Aro,et al.  Interplay of SpkG kinase and the Slr0151 protein in the phosphorylation of ferredoxin 5 in Synechocystis sp. strain PCC 6803 , 2018, FEBS letters.

[10]  C. Foyer,et al.  Photosynthesis solutions to enhance productivity , 2017, Philosophical Transactions of the Royal Society B: Biological Sciences.

[11]  M. Ishii,et al.  Structural basis of the redox switches in the NAD+-reducing soluble [NiFe]-hydrogenase , 2017, Science.

[12]  J. W. Peters,et al.  The Electron Bifurcating FixABCX Protein Complex from Azotobacter vinelandii: Generation of Low-Potential Reducing Equivalents for Nitrogenase Catalysis. , 2017, Biochemistry.

[13]  Damian Szklarczyk,et al.  The STRING database in 2017: quality-controlled protein–protein association networks, made broadly accessible , 2016, Nucleic Acids Res..

[14]  J. W. Peters,et al.  Unification of [FeFe]-hydrogenases into three structural and functional groups. , 2016, Biochimica et biophysica acta.

[15]  J. W. Peters,et al.  Evidence That the Pi Release Event Is the Rate-Limiting Step in the Nitrogenase Catalytic Cycle. , 2016, Biochemistry.

[16]  Silvio C. E. Tosatto,et al.  Tools and data services registry: a community effort to document bioinformatics resources , 2015, Nucleic Acids Res..

[17]  Diogo B Lima,et al.  SIM-XL: A powerful and user-friendly tool for peptide cross-linking analysis. , 2015, Journal of proteomics.

[18]  M. Ghirardi,et al.  Crystal structure and biochemical characterization of Chlamydomonas FDX2 reveal two residues that, when mutated, partially confer FDX2 the redox potential and catalytic properties of FDX1 , 2015, Photosynthesis Research.

[19]  J. W. Peters,et al.  [FeFe]- and [NiFe]-hydrogenase diversity, mechanism, and maturation. , 2015, Biochimica et biophysica acta.

[20]  R. M. Walsh,et al.  Evidence of Kinetic Cooperativity in Dimeric Ketopantoate Reductase from Staphylococcus aureus. , 2015, Biochemistry.

[21]  Michael J E Sternberg,et al.  The Phyre2 web portal for protein modeling, prediction and analysis , 2015, Nature Protocols.

[22]  N. Khanna,et al.  Cyanobacterial Hydrogenases and Hydrogen Metabolism Revisited: Recent Progress and Future Prospects , 2015, International journal of molecular sciences.

[23]  Eystein Oveland,et al.  PeptideShaker enables reanalysis of MS-derived proteomics data sets , 2015, Nature Biotechnology.

[24]  C. Cassier-Chauvat,et al.  Function and Regulation of Ferredoxins in the Cyanobacterium, Synechocystis PCC6803: Recent Advances , 2014, Life.

[25]  C. Mullineaux,et al.  Solar powered biohydrogen production requires specific localization of the hydrogenase† †Electronic supplementary information (ESI) available: Supplementary Fig. 1–12 and supplementary Table 1. See DOI: 10.1039/c4ee02502d Click here for additional data file. , 2014, Energy & environmental science.

[26]  P. Sétif,et al.  NADPH fluorescence in the cyanobacterium Synechocystis sp. PCC 6803: a versatile probe for in vivo measurements of rates, yields and pools. , 2014, Biochimica et biophysica acta.

[27]  Akira Oikawa,et al.  Capillary electrophoresis-mass spectrometry reveals the distribution of carbon metabolites during nitrogen starvation in Synechocystis sp. PCC 6803. , 2014, Environmental microbiology.

[28]  Xi Chen,et al.  The Bidirectional NiFe-hydrogenase in Synechocystis sp. PCC 6803 Is Reduced by Flavodoxin and Ferredoxin and Is Essential under Mixotrophic, Nitrate-limiting Conditions* , 2013, The Journal of Biological Chemistry.

[29]  Dima Kozakov,et al.  How good is automated protein docking? , 2013, Proteins.

[30]  M. Ghirardi,et al.  Identification of Global Ferredoxin Interaction Networks in Chlamydomonas reinhardtii* , 2013, The Journal of Biological Chemistry.

[31]  P. Mulo,et al.  Plant type ferredoxins and ferredoxin-dependent metabolism. , 2013, Plant, cell & environment.

[32]  P. Maness,et al.  Genetic Analysis of the Hox Hydrogenase in the Cyanobacterium Synechocystis sp. PCC 6803 Reveals Subunit Roles in Association, Assembly, Maturation, and Function* , 2012, The Journal of Biological Chemistry.

[33]  P. King,et al.  Optimized Expression and Purification for High-Activity Preparations of Algal [FeFe]-Hydrogenase , 2012, PloS one.

[34]  Melissa Cano,et al.  Role of HoxE subunit in Synechocystis PCC6803 hydrogenase , 2011, The FEBS journal.

[35]  O. Lenz,et al.  Catalytic Properties of the Isolated Diaphorase Fragment of the NAD+-Reducing [NiFe]-Hydrogenase from Ralstonia eutropha , 2011, PloS one.

[36]  Carrie Eckert,et al.  The role of the bidirectional hydrogenase in cyanobacteria. , 2011, Bioresource technology.

[37]  R. Schulz,et al.  The [NiFe]-hydrogenase of the cyanobacterium Synechocystis sp. PCC 6803 works bidirectionally with a bias to H2 production. , 2011, Journal of the American Chemical Society.

[38]  O. Lenz,et al.  The Hydrogenase Subcomplex of the NAD+‐Reducing [NiFe] Hydrogenase from Ralstonia eutropha – Insights into Catalysis and Redox Interconversions , 2011 .

[39]  P. Nixon,et al.  Structure of CyanoP at 2.8 A: implications for the evolution and function of the PsbP subunit of photosystem II . , 2010, Biochemistry.

[40]  Michael J. E. Sternberg,et al.  3DLigandSite: predicting ligand-binding sites using similar structures , 2010, Nucleic Acids Res..

[41]  I. Zebger,et al.  Overexpression, Isolation, and Spectroscopic Characterization of the Bidirectional [NiFe] Hydrogenase from Synechocystis sp. PCC 6803* , 2009, The Journal of Biological Chemistry.

[42]  K. Medzihradszky,et al.  Electron‐transfer subunits of the NiFe hydrogenases in Thiocapsa roseopersicina BBS , 2009, The FEBS journal.

[43]  Y. Hihara,et al.  Difference in metabolite levels between photoautotrophic and photomixotrophic cultures of Synechocystis sp. PCC 6803 examined by capillary electrophoresis electrospray ionization mass spectrometry , 2008, Journal of Experimental Botany.

[44]  L. T. Serebryakova,et al.  Characterization of catalytic properties of hydrogenase isolated from the unicellular cyanobacterium Gloeocapsa alpicola CALU 743 , 2006, Biochemistry (Moscow).

[45]  Stephen R. Comeau,et al.  PIPER: An FFT‐based protein docking program with pairwise potentials , 2006, Proteins.

[46]  Ruth Nussinov,et al.  PatchDock and SymmDock: servers for rigid and symmetric docking , 2005, Nucleic Acids Res..

[47]  C. D. de Koster,et al.  The Soluble NAD+-Reducing [NiFe]-Hydrogenase from Ralstonia eutropha H16 Consists of Six Subunits and Can Be Specifically Activated by NADPH , 2005, Journal of bacteriology.

[48]  A. Cornish-Bowden,et al.  Glucokinase: A Monomeric Enzyme with Positive Cooperativity , 2004 .

[49]  Sandor Vajda,et al.  ClusPro: a fully automated algorithm for protein-protein docking , 2004, Nucleic Acids Res..

[50]  Paulette M. Vignais,et al.  Sustained Photoevolution of Molecular Hydrogen in a Mutant of Synechocystis sp. Strain PCC 6803 Deficient in the Type I NADPH-Dehydrogenase Complex , 2004, Journal of bacteriology.

[51]  G. Maróti,et al.  Cyanobacterial-Type, Heteropentameric, NAD+-Reducing NiFe Hydrogenase in the Purple Sulfur Photosynthetic Bacterium Thiocapsa roseopersicina , 2004, Applied and Environmental Microbiology.

[52]  R. Goodman,et al.  Differential binding of NAD+ and NADH allows the transcriptional corepressor carboxyl-terminal binding protein to serve as a metabolic sensor , 2003, Proceedings of the National Academy of Sciences of the United States of America.

[53]  D. Svergun,et al.  The active conformation of glutamate synthase and its binding to ferredoxin. , 2003, Journal of molecular biology.

[54]  Ruth Nussinov,et al.  Efficient Unbound Docking of Rigid Molecules , 2002, WABI.

[55]  T. Happe,et al.  HoxE--a subunit specific for the pentameric bidirectional hydrogenase complex (HoxEFUYH) of cyanobacteria. , 2002, Biochimica et biophysica acta.

[56]  Paula Tamagnini,et al.  Hydrogenases and Hydrogen Metabolism of Cyanobacteria , 2002, Microbiology and Molecular Biology Reviews.

[57]  D. E. Anderson,et al.  Tobacco etch virus protease: mechanism of autolysis and rational design of stable mutants with wild-type catalytic proficiency. , 2001, Protein engineering.

[58]  C. Kent,et al.  Negative cooperativity of substrate binding but not enzyme activity in wild-type and mutant forms of CTP:glycerol-3-phosphate cytidylyltransferase. , 2001, The Journal of biological chemistry.

[59]  U. Schreiber,et al.  Light-induced dynamic changes of NADPH fluorescence in Synechocystis PCC 6803 and its ndhB-defective mutant M55. , 2000, Plant & cell physiology.

[60]  R. Schulz,et al.  The bidirectional hydrogenase of Synechocystis sp. PCC 6803 works as an electron valve during photosynthesis , 2000, Archives of Microbiology.

[61]  J. Zhao,et al.  Measurement of photosystem I activity with photoreduction of recombinant flavodoxin. , 1998, Analytical biochemistry.

[62]  J. Weber,et al.  Specific placement of tryptophan in the catalytic sites of Escherichia coli F1-ATPase provides a direct probe of nucleotide binding: maximal ATP hydrolysis occurs with three sites occupied. , 1993, The Journal of biological chemistry.

[63]  B. Lagoutte,et al.  Ferrodoxin and flavodoxin from the cyanobacterium Synechocystis sp PCC 6803 , 1992 .

[64]  A. Cornish-Bowden,et al.  Co-operativity in monomeric enzymes. , 1987, Journal of theoretical biology.

[65]  C. Tanford,et al.  Thermodynamic and kinetic cooperativity in ligand binding to multiple sites on a protein: Ca2+ activation of an ATP-driven Ca pump. , 1985, Proceedings of the National Academy of Sciences of the United States of America.

[66]  S. Mayhew The redox potential of dithionite and SO-2 from equilibrium reactions with flavodoxins, methyl viologen and hydrogen plus hydrogenase. , 1978, European journal of biochemistry.

[67]  D E Koshland,et al.  Negative cooperativity in regulatory enzymes. , 1969, Proceedings of the National Academy of Sciences of the United States of America.

[68]  Arthur Schweiger,et al.  EasySpin, a comprehensive software package for spectral simulation and analysis in EPR. , 2006, Journal of magnetic resonance.

[69]  Sandor Vajda,et al.  ClusPro: an automated docking and discrimination method for the prediction of protein complexes , 2004, Bioinform..

[70]  Robin F. B. Turner,et al.  Increasing the efficiency of SAGE adaptor ligation by directed ligation chemistry. , 2004, Nucleic acids research.

[71]  H. Bothe,et al.  NAD( P)+-dependent hydrogenase activity in extracts from the cyanobacterium Anacystis nidulans , 1996 .

[72]  G. Hammes,et al.  Kinetics of allosteric enzymes. , 1974, Annual review of biophysics and bioengineering.