Wolfgang Lubitz Explained

Wolfgang Lubitz
Birth Place:Berlin, Germany
Nationality:German
Fields:Chemistry
Biochemistry
Biophysics
Education:Chemistry Free University Berlin (1969–1974)
Dr. rer. nat Free University Berlin (1977)
Habilitation Free University Berlin (1982)
Known For:hydrogenases
oxygen-evolving complex
bacterial and plant photosynthesis
Electron paramagnetic resonance
Workplaces:Free University Berlin (1977–1989)
UC San Diego (1983–1984)
University of Stuttgart (1989–1991)
Technische Universität Berlin (1991–2000)
Max Planck Institute for Chemical Energy Conversion (2000–present)

Wolfgang Lubitz (born in 1949) is a German chemist and biophysicist. He is currently a director emeritus at the Max Planck Institute for Chemical Energy Conversion. He is well known for his work on bacterial photosynthetic reaction centres,[1] [2] [3] hydrogenase enzymes,[4] and the oxygen-evolving complex[5] [6] using a variety of biophysical techniques. He has been recognized by a Festschrift for his contributions to electron paramagnetic resonance (EPR) and its applications to chemical and biological systems.[7]

Education and career

He studied chemistry at the Free University Berlin from 1969 to 1974 and continued with his Dr. rer. nat. until 1977. From 1977 to 1982 he worked for his habilitation in organic chemistry at the Free University Berlin with a focus on electron paramagnetic resonance (EPR) and double resonance methods, such as ENDOR/TRIPLE. From 1979 to 1989 the FU Berlin employed him as an assistant professor, and as an associate professor at the Chemistry Department. From 1983 to 1984 he worked as a Max Kade Fellow at UC San Diego in the Physics Department with George Feher on EPR and ENDOR in photosynthesis. In 1989 he became an associate professor of experimental physics at the University of Stuttgart. In 1991 he returned to Berlin as a Full Professor and Chair of Physical Chemistry at the Max Volmer Institute at Technische Universität Berlin. He stayed until 2000 when he became a Scientific Member of the Max Planck Society and Director at the Max Planck Institute for Radiation Chemistry (in 2003 renamed Max Planck Institute for Bioinorganic Chemistry and in 2012 Max Planck Institute for Chemical Energy Conversion) in Mülheim an der Ruhr, North Rhine-Westphalia, Germany. In the same year, he became honorary professor of the Heinrich-Heine-University of Düsseldorf. From 2004 to 2012, he was managing director of the Max Planck Institute and is currently a director emeritus of the Max Planck Institute for Chemical Energy Conversion.[8] Since 2004, he has been a member of the council for the Lindau Nobel Laureate Meetings, and has been its vice-president since 2015.[9]

Research

His research focuses on the elementary processes of photosynthesis and catalytic metal centers in metalloproteins. He is an expert in the application of EPR spectroscopy and quantum chemical calculations. He has over 500 publications with more than 25,000 citations.[10]

EPR spectroscopy

Throughout his career, EPR has played an important role as a biophysical technique to gain information about radicals, radical pairs, triplet states and metal centers in chemistry and biochemistry.[11] Particular emphasis has been placed on methods that are able to resolve the electron-nuclear hyperfine couplings between the electron spin and the nuclear spins. Next to the more established techniques, electron spin echo modulation (ESEEM) and electron-nuclear double resonance (ENDOR), his group further developed and used electron-electron double resonance- (ELDOR) detected NMR (EDNMR) at a range of mw frequencies.[12] [13] [14] These techniques have been used by him and his group to extensively study bacterial photosynthetic reaction centres, their donor-acceptor model complexes, photosystem I, photosystem II, and a number of different hydrogenases.

Oxygen-evolving Complex

During his early career, bacterial photosynthetic reaction centres and oxygenic photosystem I and photosystem II have been a main focus. He and his group studied light-induced chlorophyll donor and quinone acceptor radical ions of the primary electron-transfer chain. Later his research focused on the water splitting cycle (S-states) of photosystem II using advanced multifrequency pulse EPR, ENDOR and EDNMR techniques. His group was able to detect and characterize the flash-generated, freeze-trapped paramagnetic states S0, S2 and S3 (S1 is diamagnetic and S4 is a transient state) of the Mn4Ca1Ox catalytic cluster. By a careful spectral analysis–backed up by quantum chemical calculations the site oxidation and spin states of all Mn ions and their spin coupling for all intermediates of the catalytic cycle could be detected.[15] [16] [17] Further work using advanced Pulse EPR techniques, such as EDNMR, has led to information on the binding of water[18] and a proposal of an efficient O-O bond formation in the final state of the cycle.

[NiFe]- and [FeFe]-hydrogenase

Extensive work was performed on the [NiFe]-Hydrogenase where the magnetic tensors were measured and related to quantum chemical calculations. Through his work, the structures of all intermediates in the activation path and catalytic cycle of [NiFe]-hydrogenases were obtained. In the course of this work a 0.89 Ångström resolution X-ray crystallography diffraction model of [NiFe]-hydrogenase was achieved.[19]

Similar work has been accomplished for the [FeFe]-hydrogenases. A key contribution of his research was the EPR spectroscopic evidence of an azapropane-dithiolate-ligand (ADT-ligand) in the dithiol bridge of the [FeFe]-hydrogenase active site [20] and the determination of the magnitude and orientation of the g-tensor using single crystal EPR.[21] The ADT-ligand was later confirmed by artificial maturation of [FeFe]-hydrogenases.[22] Using artificial maturation, the protein could be generated without the co-factor (apoprotein) using E. coli mutagenesis and a synthetically created active site could be inserted,[23] [24] which has opened new vistas in hydrogenase research.[25]

Awards and recognition

Notes and References

  1. Lubitz. Wolfgang. Lendzian. Friedhelm. Bittl. Robert. Radicals, Radical Pairs and Triplet States in Photosynthesis. Accounts of Chemical Research. 35. 5. 2002. 313–320. 0001-4842. 10.1021/ar000084g. 12020169.
  2. Lendzian. F.. Huber. M.. Isaacson. R. A.. Endeward. B.. Plato. M.. Bönigk. B.. Möbius. K.. Lubitz. W.. Feher. G.. The electronic structure of the primary donor cation radical in Rhodobacter sphaeroides R-26: ENDOR and TRIPLE resonance studies in single crystals of reaction centers. Biochimica et Biophysica Acta (BBA) - Bioenergetics. 1183. 1. 1993. 139–160. 0005-2728. 10.1016/0005-2728(93)90013-6.
  3. Lubitz. W.. Feher. G.. The primary and secondary acceptors in bacterial photosynthesis III. Characterization of the quinone radicals QA− ⋅ and QB− ⋅ by EPR and ENDOR. Applied Magnetic Resonance. 17. 1. 1999. 1–48. 0937-9347. 10.1007/BF03162067. 95064414.
  4. Lubitz. W.. Ogata. H.. Rüdiger. O.. Reijerse. E. J.. 2014. Hydrogenases. Chemical Reviews. 114. 8. 4081–4148. 10.1021/cr4005814. 24655035.
  5. Cox. N.. Pantazis. D. A.. Neese. F.. Lubitz. W.. 2013. Biological Water Oxidation. Accounts of Chemical Research. 46. 7. 1588–1596. 10.1021/ar3003249. 23506074.
  6. Lubitz. Wolfgang. Chrysina. Maria. Cox. Nicholas. Water oxidation in photosystem II. Photosynthesis Research. 142. 1. 2019. 105–125. 0166-8595. 10.1007/s11120-019-00648-3. 31187340. 6763417. 2019PhoRe.142..105L .
  7. Web site: Wolfgang Lubitz Festschrift Special Issue. Journal of Physical Chemistry B Volume 119, Issue 43 (2015). ACS Publications. December 5, 2019.
  8. Web site: Wolfgang Lubitz (Emeriti). Max Planck for Chemical Energy Conversion. Open Publishing. July 17, 2019.
  9. Web site: Wolfgang Lubitz . The Lindau Nobel Laureate Meetings. Open Publishing. July 17, 2019.
  10. Web site: Wolfgang Lubitz (Google Scholar). Google Scholar. Open Publishing. December 5, 2019.
  11. Lubitz. Wolfgang. Reijerse. Eduard. van Gastel. Maurice. [NiFe] and [FeFe] Hydrogenases Studied by Advanced Magnetic Resonance Techniques. Chemical Reviews. 107. 10. 2007. 4331–4365. 0009-2665. 10.1021/cr050186q. 17845059.
  12. Cox. N.. Lubitz. W.. Savitsky. A.. 2013. W-band ELDOR-detected NMR (EDNMR) spectroscopy as a versatile technique for the characterisation of transition metal–ligand interactions. Molecular Physics. 111. 18–19. 2788–2808. 10.1080/00268976.2013.830783. 2013MolPh.111.2788C. 97147588. 0026-8976.
  13. Nalepa. A.. Möbius. K.. Lubitz. W.. Savitsky. A.. 2014. High-field ELDOR-detected NMR study of a nitroxide radical in disordered solids: Towards characterization of heterogeneity of microenvironments in spin-labeled systems. Journal of Magnetic Resonance. 242. 203–213. 10.1016/j.jmr.2014.02.026. 24685717. 2014JMagR.242..203N. 1090-7807.
  14. Book: Cox. N.. Electron Paramagnetic Resonance Investigations of Biological Systems by Using Spin Labels, Spin Probes, and Intrinsic Metal Ions, Part A. Nalepa. A.. Pandelia. M.-E.. Lubitz. W.. Savitsky. A.. 2015. Pulse Double-Resonance EPR Techniques for the Study of Metallobiomolecules. 563. 211–249. 10.1016/bs.mie.2015.08.016. 0076-6879. Methods in Enzymology. 26478487. 9780128028346.
  15. Cox. N.. Retegan. M.. Neese. F.. Pantazis. D. A.. Boussac. A.. Lubitz. W.. Electronic structure of the oxygen-evolving complex in photosystem II prior to O-O bond formation. Science. 345. 6198. 2014. 804–808. 0036-8075. 10.1126/science.1254910. 25124437. 2014Sci...345..804C. 13503746.
  16. Krewald. V.. Retegan. M.. Cox. N.. Messinger. J.. Lubitz. W.. DeBeer. S.. Neese. F.. Pantazis. D. A.. 2015. Metal oxidation states in biological water splitting. Chemical Science. 6. 3. 1676–1695. 10.1039/C4SC03720K. 29308133. 5639794. 2041-6520. free.
  17. Krewald. V.. Retegan. M.. Neese. F.. Lubitz. W.. Pantazis. D. A.. Cox. N.. 2016. Spin State as a Marker for the Structural Evolution of Nature's Water-Splitting Catalyst. Inorganic Chemistry. 55. 2. 488–501. 10.1021/acs.inorgchem.5b02578. 26700960. 0020-1669. 1885/230998. free.
  18. Rapatskiy. Leonid. Cox. Nicholas. Savitsky. Anton. Ames. William M.. Sander. Julia. Nowaczyk. Marc. M.. Rögner. Matthias. Boussac. Alain. Neese. Frank. Messinger. Johannes. Lubitz. Wolfgang. Detection of the Water-Binding Sites of the Oxygen-Evolving Complex of Photosystem II Using W-Band 17O Electron–Electron Double Resonance-Detected NMR Spectroscopy. Journal of the American Chemical Society. 134. 40. 2012. 16619–16634. 0002-7863. 10.1021/ja3053267. 22937979.
  19. Ogata. H.. Nishikawa. K.. Lubitz. W.. 2015. Hydrogens detected by subatomic resolution protein crystallography in a [NiFe] hydrogenase. Nature. 520. 7548. 571–574. 10.1038/nature14110. 25624102. 2015Natur.520..571O. 4464257. 0028-0836.
  20. Silakov. A.. Wenk. B.. Reijerse. E.J.. Lubitz. W.. 2009. 14N HYSCORE investigation of the H-cluster of [FeFe] hydrogenase: evidence for a nitrogen in the dithiol bridge. Physical Chemistry Chemical Physics. 11. 31. 6592–9. 10.1039/b905841a. 19639134. 2009PCCP...11.6592S. 1463-9076.
  21. Sidabras. Jason W.. Duan. Jifu. Winkler. Martin. Happe. Thomas. Hussein. Rana. Zouni. Athina. Suter. Dieter. Schnegg. Alexander. Lubitz. Wolfgang. Reijerse. Edward J.. Extending electron paramagnetic resonance to nanoliter volume protein single crystals using a self-resonant microhelix. Science Advances. 5. 10. 2019. eaay1394. 2375-2548. 10.1126/sciadv.aay1394. 31620561. 6777973. 2019SciA....5.1394S. free.
  22. Berggren. G.. Adamska. A.. Lambertz. C.. Simmons. T. R.. Esselborn. J.. Atta. M.. Gambarelli. S.. Mouesca. J.-M.. Reijerse. E.. 2013. Biomimetic assembly and activation of [FeFe]-hydrogenases. Nature. 499. 7456. 66–69. 10.1038/nature12239. 23803769. 0028-0836. Lubitz. W.. Happe. T.. Artero. V.. Fontecave. M.. 3793303. 2013Natur.499...66B.
  23. Esselborn. J.. Lambertz. C.. Adamska-Venkatesh. A.. Simmons. T.. Berggren. G.. Noth. J.. Siebel. J.. Hemschemeier. A.. Artero. V.. 2013. Spontaneous activation of [FeFe]-hydrogenases by an inorganic [2Fe] active site mimic. Nature Chemical Biology. 9. 10. 607–609. 10.1038/nchembio.1311. 23934246. 1552-4450. Reijerse. E. J.. Fontecave. M.. Lubitz. W.. Happe. T.. 3795299.
  24. Siebel. Judith F.. Adamska-Venkatesh. Agnieszka. Weber. Katharina. Rumpel. Sigrun. Reijerse. Edward. Lubitz. Wolfgang. Hybrid [FeFe]-Hydrogenases with Modified Active Sites Show Remarkable Residual Enzymatic Activity. Biochemistry. 54. 7. 2015. 1474–1483. 0006-2960. 10.1021/bi501391d. 25633077.
  25. Birrell. James A.. Rüdiger. Olaf. Reijerse. Edward J.. Lubitz. Wolfgang. Semisynthetic Hydrogenases Propel Biological Energy Research into a New Era. Joule. 1. 1. 2017. 61–76. 2542-4351. 10.1016/j.joule.2017.07.009. free.