2rfm Citations

Structural insights into an equilibrium folding intermediate of an archaeal ankyrin repeat protein.

Löw C, Weininger U, Neumann P, Klepsch M, Lilie H, Stubbs MT, Balbach J
Proc Natl Acad Sci U S A 105 3779-84 (2008)
Cited: 19 times
EuropePMC logo PMID: 18305166

Abstract

Repeat proteins are widespread in nature, with many of them functioning as binding molecules in protein-protein recognition. Their simple structural architecture is used in biotechnology for generating proteins with high affinities to target proteins. Recent folding studies of ankyrin repeat (AR) proteins revealed a new mechanism of protein folding. The formation of an intermediate state is rate limiting in the folding reaction, suggesting a scaffold function of this transient state for intrinsically less stable ARs. To investigate a possible common mechanism of AR folding, we studied the structure and folding of a new thermophilic AR protein (tANK) identified in the archaeon Thermoplasma volcanium. The x-ray structure of the evolutionary much older tANK revealed high homology to the human CDK inhibitor p19(INK4d), whose sequence was used for homology search. As for p19(INK4d), equilibrium and kinetic folding analyses classify tANK to the family of sequential three-state folding proteins, with an unusual fast equilibrium between native and intermediate state. Under equilibrium conditions, the intermediate can be populated to >90%, allowing characterization on a residue-by-residue level using NMR spectroscopy. These data clearly show that the three C-terminal ARs are natively folded in the intermediate state, whereas native cross-peaks for the rest of the molecule are missing. Therefore, the formation of a stable folding unit consisting of three ARs is the necessary rate-limiting step before AR 1 and 2 can assemble to form the native state.

Articles - 2rfm mentioned but not cited (1)

  1. Structural insights into an equilibrium folding intermediate of an archaeal ankyrin repeat protein. Löw C, Weininger U, Neumann P, Klepsch M, Lilie H, Stubbs MT, Balbach J. Proc Natl Acad Sci U S A 105 3779-3784 (2008)


Reviews citing this publication (2)

  1. Folding and Stability of Ankyrin Repeats Control Biological Protein Function. Kumar A, Balbach J. Biomolecules 11 840 (2021)
  2. Folding cooperativity and allosteric function in the tandem-repeat protein class. Perez-Riba A, Synakewicz M, Itzhaki LS. Philos Trans R Soc Lond B Biol Sci 373 20170188 (2018)

Articles citing this publication (16)

  1. Exploring the folding energy landscape of a series of designed consensus tetratricopeptide repeat proteins. Javadi Y, Main ER. Proc Natl Acad Sci U S A 106 17383-17388 (2009)
  2. Asparaginyl beta-hydroxylation of proteins containing ankyrin repeat domains influences their stability and function. Hardy AP, Prokes I, Kelly L, Campbell ID, Schofield CJ. J Mol Biol 392 994-1006 (2009)
  3. Mechanical unfolding of an ankyrin repeat protein. Serquera D, Lee W, Settanni G, Marszalek PE, Paci E, Itzhaki LS. Biophys J 98 1294-1301 (2010)
  4. Folding kinetics of the cooperatively folded subdomain of the IκBα ankyrin repeat domain. DeVries I, Ferreiro DU, Sánchez IE, Komives EA. J Mol Biol 408 163-176 (2011)
  5. Modulation of the multistate folding of designed TPR proteins through intrinsic and extrinsic factors. Phillips JJ, Javadi Y, Millership C, Main ER. Protein Sci 21 327-338 (2012)
  6. Phosphorylation-induced unfolding regulates p19INK4d during the human cell cycle. Kumar A, Gopalswamy M, Wolf A, Brockwell DJ, Hatzfeld M, Balbach J. Proc Natl Acad Sci U S A 115 3344-3349 (2018)
  7. A disorder-induced domino-like destabilization mechanism governs the folding and functional dynamics of the repeat protein IκBα. Sivanandan S, Naganathan AN. PLoS Comput Biol 9 e1003403 (2013)
  8. Modulation of folding kinetics of repeat proteins: interplay between intra- and interdomain interactions. Hagai T, Azia A, Trizac E, Levy Y. Biophys J 103 1555-1565 (2012)
  9. PyFolding: Open-Source Graphing, Simulation, and Analysis of the Biophysical Properties of Proteins. Lowe AR, Perez-Riba A, Itzhaki LS, Main ERG. Biophys J 114 516-521 (2018)
  10. Diffuse transition state structure for the unfolding of a leucine-rich repeat protein. Kelly SE, Meisl G, Rowling PJ, McLaughlin SH, Knowles T, Itzhaki LS. Phys Chem Chem Phys 16 6448-6459 (2014)
  11. Notch ankyrin domain: evolutionary rise of a thermodynamic sensor. Vujovic F, Hunter N, Farahani RM. Cell Commun Signal 20 66 (2022)
  12. Testing the length limit of loop grafting in a helical repeat protein. Ripka JF, Perez-Riba A, Chaturbedy PK, Itzhaki LS. Curr Res Struct Biol 3 30-40 (2021)
  13. Monitoring protein unfolding transitions by NMR-spectroscopy. Dreydoppel M, Balbach J, Weininger U. J Biomol NMR 76 3-15 (2022)
  14. Protein folding by interaction. Buchner J, Kessler H. Structure 22 936-937 (2014)
  15. The Right-Handed Parallel β-Helix Topology of Erwinia chrysanthemi Pectin Methylesterase Is Intimately Associated with Both Sequential Folding and Resistance to High Pressure. Guillerm J, Frère JM, Meersman F, Matagne A. Biomolecules 11 1083 (2021)
  16. Resolving the fine structure in the energy landscapes of repeat proteins. Sanches MN, Parra RG, Viegas RG, Oliveira AB, Wolynes PG, Ferreiro DU, Leite VBP. QRB Discov 3 e7 (2022)


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