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Two homologous rat cellular retinol-binding proteins differ in local conformational flexibility.

Lu J, Cistola DP, Li E
J Mol Biol 330 799-812 (2003)
Cited: 23 times
EuropePMC logo PMID: 12850148

Abstract

Cellular retinol-binding protein I (CRBP I) and cellular retinol-binding protein II (CRBP II) are closely homologous proteins that play distinct roles in the maintenance of vitamin A homeostasis. The solution structure and dynamics of CRBP I and CRBP II were compared by multidimensional NMR techniques. These studies indicated that differences in the mean backbone structures of CRBP I and CRBP II were localized primarily to the alphaII helix. Intraligand NOE cross-peaks were detected for the hydroxyl proton in the NOESY spectrum of CRBP I-bound retinol, but not for CRBP II-bound retinol, indicating that the conformational dynamics of retinol binding are different for these two proteins. As determined by Lipari-Szabo formalism, both the apo and holo forms of CRBP I and CRBP II are conformationally rigid on the pico- to nanosecond timescale. transverse relaxation optimized spectroscopy-Carr-Purcell-Meiboom-Gill -based 15N relaxation dispersion experiments at both 500 MHz and 600 MHz magnetic fields revealed that 84 and 62 residues for apo-CRBP I and II, respectively, showed detectable conformational exchange on a micro- to millisecond timescale, in contrast to three and seven residues for holo-CRBP I and II, respectively. Thus binding of retinol markedly reduced conformational flexibility in both CRBP I and CRBP II on the micro- to millisecond timescale. The 15N relaxation dispersion curves of apo-CRBP I and II were fit to a two-state conformational exchange model by a global iterative fitting process and by an individual (residue) fitting process. In the process of carrying out the global fit, more than half of the residue sites were eliminated. The individual chemical exchange rates k(ex), and chemical shift differences, Deltadelta, were increased in the putative portal region (alphaII helix and betaC-betaD turn) of apo-CRBP II compared to apo-CRBP I. These differences in conformational flexibility likely contribute to differences in how CRBP I and CRBP II interact with ligands, membranes and retinoid metabolizing enzymes.

Reviews citing this publication (4)

  1. Cellular retinoid binding-proteins, CRBP, CRABP, FABP5: Effects on retinoid metabolism, function and related diseases. Napoli JL. Pharmacol Ther 173 19-33 (2017)
  2. Functions of Intracellular Retinoid Binding-Proteins. Napoli JL. Subcell Biochem 81 21-76 (2016)
  3. The role of dynamics in modulating ligand exchange in intracellular lipid binding proteins. Ragona L, Pagano K, Tomaselli S, Favretto F, Ceccon A, Zanzoni S, D'Onofrio M, Assfalg M, Molinari H. Biochim Biophys Acta 1844 1268-1278 (2014)
  4. Structural and Dynamic Determinants of Molecular Recognition in Bile Acid-Binding Proteins. Toke O. Int J Mol Sci 23 505 (2022)

Articles citing this publication (19)

  1. A ligand-activated nuclear localization signal in cellular retinoic acid binding protein-II. Sessler RJ, Noy N. Mol Cell 18 343-353 (2005)
  2. Ligand Binding Induces Conformational Changes in Human Cellular Retinol-binding Protein 1 (CRBP1) Revealed by Atomic Resolution Crystal Structures. Silvaroli JA, Arne JM, Chelstowska S, Kiser PD, Banerjee S, Golczak M. J Biol Chem 291 8528-8540 (2016)
  3. Ligand binding promiscuity of human liver fatty acid binding protein: structural and dynamic insights from an interaction study with glycocholate and oleate. Favretto F, Assfalg M, Gallo M, Cicero DO, D'Onofrio M, Molinari H. Chembiochem 14 1807-1819 (2013)
  4. Retinoid-binding proteins: similar protein architectures bind similar ligands via completely different ways. Zhang YR, Zhao YQ, Huang JF. PLoS One 7 e36772 (2012)
  5. Binding affinities of CRBPI and CRBPII for 9-cis-retinoids. Kane MA, Bright FV, Napoli JL. Biochim Biophys Acta 1810 514-518 (2011)
  6. Structural determinants of ligand binding in the ternary complex of human ileal bile acid binding protein with glycocholate and glycochenodeoxycholate obtained from solution NMR. Horváth G, Bencsura Á, Simon Á, Tochtrop GP, DeKoster GT, Covey DF, Cistola DP, Toke O. FEBS J 283 541-555 (2016)
  7. Xanthine dehydrogenase processes retinol to retinoic acid in human mammary epithelial cells. Taibi G, Di Gaudio F, Nicotra CM. J Enzyme Inhib Med Chem 23 317-327 (2008)
  8. Crystal structure of human cellular retinol-binding protein II to 1.2 A resolution. Tarter M, Capaldi S, Carrizo ME, Ambrosi E, Perduca M, Monaco HL. Proteins 70 1626-1630 (2008)
  9. Mass spectrometry techniques for detection of ligand-dependent changes in the conformational flexibility of cellular retinol-binding protein type I localized by hydrogen/deuterium exchange. Careri M, Elviri L, Mangia A, Zagnoni I, Torta F, Cavazzini D, Rossi GL. Rapid Commun Mass Spectrom 20 1973-1980 (2006)
  10. New insights on the protein-ligand interaction differences between the two primary cellular retinol carriers. Franzoni L, Cavazzini D, Rossi GL, Lücke C. J Lipid Res 51 1332-1343 (2010)
  11. Predicting protein dynamics from structural ensembles. Copperman J, Guenza MG. J Chem Phys 143 243131 (2015)
  12. Transporter-to-trap conversion: a disulfide bond formation in cellular retinoic acid binding protein I mutant triggered by retinoic acid binding irreversibly locks the ligand inside the protein. Sjoelund V, Kaltashov IA. Biochemistry 46 13382-13390 (2007)
  13. Effect of a load of Vitamin A after acute thioacetamide intoxication on dolichol, dolichol isoprenoids and retinol content in isolated rat liver cells. Bassi AM, Canepa C, Maloberti G, Casu A, Nanni G. Toxicology 199 97-107 (2004)
  14. Structural insight into a partially unfolded state preceding aggregation in an intracellular lipid-binding protein. Horváth G, Biczók L, Majer Z, Kovács M, Micsonai A, Kardos J, Toke O. FEBS J 284 3637-3661 (2017)
  15. Ligand entry in human ileal bile acid-binding protein is mediated by histidine protonation. Horváth G, Egyed O, Tang C, Kovács M, Micsonai A, Kardos J, Toke O. Sci Rep 9 4825 (2019)
  16. Mass spectrometry and hydrogen/deuterium exchange measurements of alcohol-induced structural changes in cellular retinol-binding protein type I. Torta F, Elviri L, Careri M, Mangia A, Cavazzini D, Rossi GL. Rapid Commun Mass Spectrom 22 330-336 (2008)
  17. Multiple Timescale Dynamic Analysis of Functionally-Impairing Mutations in Human Ileal Bile Acid-Binding Protein. Horváth G, Balterer B, Micsonai A, Kardos J, Toke O. Int J Mol Sci 23 11346 (2022)
  18. Universality and Specificity in Protein Fluctuation Dynamics. Copperman J, Dinpajooh M, Beyerle ER, Guenza MG. Phys Rev Lett 119 158101 (2017)
  19. Discovery of Nonretinoid Inhibitors of CRBP1: Structural and Dynamic Insights for Ligand-Binding Mechanisms. Plau J, Morgan CE, Fedorov Y, Banerjee S, Adams DJ, Blaner WS, Yu EW, Golczak M. ACS Chem Biol 18 2309-2323 (2023)


Related citations provided by authors (5)

  1. Binding of retinol induces changes in rat cellular retinol-binding protein II conformation and backbone dynamics. Lu J, Lin CL, Tang C, Ponder JW, Kao JL, Cistola DP, Li E J. Mol. Biol. 300 619-632 (2000)
  2. The structure and dynamics of rat apo-cellular retinol-binding protein II in solution: comparison with the X-ray structure. Lu J, Lin CL, Tang C, Ponder JW, Kao JLF, Cistola DP, Li E J. Mol. Biol. 286 1179-1195 (1999)
  3. Crystallographic studies on a family of cellular lipophilic transport proteins. Refinement of P2 myelin protein and the structure determination and refinement of cellular retinol-binding protein in complex with all-trans-retinol. Cowan SW, Newcomer ME, Jones TA J. Mol. Biol. 230 1225-1246 (1993)
  4. Crystal structures of holo and apo-cellular retinol-binding protein II. Winter NS, Bratt JM, Banaszak LJ J. Mol. Biol. 230 1247-1259 (1993)
  5. Structure and backbone dynamics of apo- and holo-cellular retinal-binding protein in solution. Franzoni L, Lucke C, Perez C, Cavazzini D, Rademacher M, Ludwig C, Spisni A, Rossi GL, Ruterjans H J. Biol. Chem. 277 21983-21997 (2002)

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