1ir2 Citations

Crystal structure of activated ribulose-1,5-bisphosphate carboxylase/oxygenase from green alga Chlamydomonas reinhardtii complexed with 2-carboxyarabinitol-1,5-bisphosphate.

Mizohata E, Matsumura H, Okano Y, Kumei M, Takuma H, Onodera J, Kato K, Shibata N, Inoue T, Yokota A, Kai Y
J Mol Biol 316 679-91 (2002)
Cited: 29 times
EuropePMC logo PMID: 11866526

Abstract

Ribulose-1,5-bisphosphate carboxylase/oxygenase (rubisco) catalyzes the initial steps of photosynthetic carbon reduction and photorespiratory carbon oxidation cycles by combining CO(2) and O(2), respectively, with ribulose-1,5-bisphosphate. Many photosynthetic organisms have form I rubiscos comprised of eight large (L) and eight small (S) subunits. The crystal structure of the complex of activated rubisco from the green alga Chlamydomonas reinhardtii and the reaction intermediate analogue 2-carboxyarabinitol-1,5-bisphosphate (2-CABP) has been solved at 1.84 A resolution (R(cryst) of 15.2 % and R(free) of 18.1 %). The subunit arrangement of Chlamydomonas rubisco is the same as those of the previously solved form I rubiscos. Especially, the present structure is very similar to the activated spinach structure complexed with 2-CABP in the L-subunit folding and active-site conformation, but differs in S-subunit folding. The central insertion of the Chlamydomonas S-subunit forms the longer betaA-betaB loop that protrudes deeper into the solvent channel of rubisco than higher plant, cyanobacterial, and red algal (red-like) betaA-betaB loops. The C-terminal extension of the Chlamydomonas S-subunit does not protrude into the solvent channel, unlike that of the red algal S-subunit, but lies on the protein surface anchored by interactions with the N-terminal region of the S-subunit. Further, the present high-resolution structure has revealed novel post-translational modifications. Residue 1 of the S-subunit is N(alpha)-methylmethionine, residues 104 and 151 of the L-subunit are 4-hydroxyproline, and residues 256 and 369 of the L-subunit are S(gamma)-methylcysteine. Furthermore, the unusual electron density of residue 471 of the L-subunit, which has been deduced to be threonine from the genomic DNA sequence, suggests that the residue is isoleucine produced by RNA editing or O(gamma)-methylthreonine.

Reviews - 1ir2 mentioned but not cited (1)

  1. Red Rubiscos and opportunities for engineering green plants. Oh ZG, Askey B, Gunn LH. J Exp Bot 74 520-542 (2023)

Articles - 1ir2 mentioned but not cited (6)

  1. Parallel Generalized Born Implicit Solvent Calculations with NAMD. Tanner DE, Chan KY, Phillips JC, Schulten K. J Chem Theory Comput 7 3635-3642 (2011)
  2. Evolutionary plasticity of protein families: coupling between sequence and structure variation. Panchenko AR, Wolf YI, Panchenko LA, Madej T. Proteins 61 535-544 (2005)
  3. GPU/CPU Algorithm for Generalized Born/Solvent-Accessible Surface Area Implicit Solvent Calculations. Tanner DE, Phillips JC, Schulten K. J Chem Theory Comput 8 2521-2530 (2012)
  4. Comparison of Protein Extracts from Various Unicellular Green Sources. Teuling E, Wierenga PA, Schrama JW, Gruppen H. J Agric Food Chem 65 7989-8002 (2017)
  5. The state of oligomerization of Rubisco controls the rate of synthesis of the Rubisco large subunit in Chlamydomonas reinhardtii. Wietrzynski W, Traverso E, Wollman FA, Wostrikoff K. Plant Cell 33 1706-1727 (2021)
  6. Molecular surface mesh generation by filtering electron density map. Giard J, Macq B. Int J Biomed Imaging 2010 923780 (2010)


Reviews citing this publication (4)

  1. Structure and function of Rubisco. Andersson I, Backlund A. Plant Physiol Biochem 46 275-291 (2008)
  2. Role of the small subunit in ribulose-1,5-bisphosphate carboxylase/oxygenase. Spreitzer RJ. Arch Biochem Biophys 414 141-149 (2003)
  3. The life of ribulose 1,5-bisphosphate carboxylase/oxygenase--posttranslational facts and mysteries. Houtz RL, Portis AR. Arch Biochem Biophys 414 150-158 (2003)
  4. Structural framework for catalysis and regulation in ribulose-1,5-bisphosphate carboxylase/oxygenase. Andersson I, Taylor TC. Arch Biochem Biophys 414 130-140 (2003)

Articles citing this publication (18)

  1. A proposed mechanism for the inhibitory effects of oxidative stress on Rubisco assembly and its subunit expression. Cohen I, Knopf JA, Irihimovitch V, Shapira M. Plant Physiol 137 738-746 (2005)
  2. Structural mechanism of RuBisCO activation by carbamylation of the active site lysine. Stec B. Proc Natl Acad Sci U S A 109 18785-18790 (2012)
  3. Revisiting the methionine salvage pathway and its paralogues. Sekowska A, Ashida H, Danchin A. Microb Biotechnol 12 77-97 (2019)
  4. Examination of metabolic responses to phosphorus limitation via proteomic analyses in the marine diatom Phaeodactylum tricornutum. Feng TY, Yang ZK, Zheng JW, Xie Y, Li DW, Murugan SB, Yang WD, Liu JS, Li HY. Sci Rep 5 10373 (2015)
  5. Crystal structure of rice Rubisco and implications for activation induced by positive effectors NADPH and 6-phosphogluconate. Matsumura H, Mizohata E, Ishida H, Kogami A, Ueno T, Makino A, Inoue T, Yokota A, Mae T, Kai Y. J Mol Biol 422 75-86 (2012)
  6. The nitrogen costs of photosynthesis in a diatom under current and future pCO2. Li G, Brown CM, Jeans JA, Donaher NA, McCarthy A, Campbell DA. New Phytol 205 533-543 (2015)
  7. X-ray structure of Galdieria Rubisco complexed with one sulfate ion per active site. Okano Y, Mizohata E, Xie Y, Matsumura H, Sugawara H, Inoue T, Yokota A, Kai Y. FEBS Lett 527 33-36 (2002)
  8. Bioinformatic tools uncover the C-terminal strand of Rubisco's large subunit as hot-spot for specificity-enhancing mutations. Burisch C, Wildner GF, Schlitter J. FEBS Lett 581 741-748 (2007)
  9. Calcium supports loop closure but not catalysis in Rubisco. Karkehabadi S, Taylor TC, Andersson I. J Mol Biol 334 65-73 (2003)
  10. Automated flow-based anion-exchange method for high-throughput isolation and real-time monitoring of RuBisCO in plant extracts. Suárez R, Miró M, Cerdà V, Perdomo JA, Galmés J. Talanta 84 1259-1266 (2011)
  11. Deletion of nine carboxy-terminal residues of the Rubisco small subunit decreases thermal stability but does not eliminate function. Esquível MG, Anwaruzzaman M, Spreitzer RJ. FEBS Lett 520 73-76 (2002)
  12. Interactive effects of nitrogen and light on growth rates and RUBISCO content of small and large centric diatoms. Li G, Campbell DA. Photosynth Res 131 93-103 (2017)
  13. A step forward to building an algal pyrenoid in higher plants. Sharwood RE. New Phytol 214 496-499 (2017)
  14. Chemical modification of arginine alleviates the decline in activity during catalysis of spinach Rubisco. Mizohata E, Anwaruzzaman M, Okuno H, Tomizawa K, Shigeoka S, Kai Y, Yokota A. Biochem Biophys Res Commun 301 591-597 (2003)
  15. Quantum chemical modeling of the kinetic isotope effect of the carboxylation step in RuBisCO. Götze JP, Saalfrank P. J Mol Model 18 1877-1883 (2012)
  16. A.N.Bach--a revolutionary in politics and science. Commemorating 150th anniversary of academician A.N. Bach. Popov VO, Zvyagilskaya RA. Biochemistry (Mosc) 72 1029-1038 (2007)
  17. Cryo-EM structures of GroEL:ES2 with RuBisCO visualize molecular contacts of encapsulated substrates in a double-cage chaperonin. Kim H, Park J, Lim S, Jun SH, Jung M, Roh SH. iScience 25 103704 (2022)
  18. Structural basis of substrate progression through the bacterial chaperonin cycle. Gardner S, Darrow MC, Lukoyanova N, Thalassinos K, Saibil HR. Proc Natl Acad Sci U S A 120 e2308933120 (2023)


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