1hz5 Citations

Structures of the B1 domain of protein L from Peptostreptococcus magnus with a tyrosine to tryptophan substitution.

O'Neill JW, Kim DE, Baker D, Zhang KY
Acta Crystallogr D Biol Crystallogr 57 480-7 (2001)
Cited: 44 times
EuropePMC logo PMID: 11264576

Abstract

The three-dimensional structure of a tryptophan-containing variant of the IgG-binding B1 domain of protein L has been solved in two crystal forms to 1.7 and 1.8 A resolution. In one of the crystal forms, the entire N-terminal histidine-tag region was immobilized through the coordination of zinc ions and its structural conformation along with the zinc coordination scheme were determined. However, the ordering of the histidine tag by zinc does not affect the overall structure of the rest of the protein. Structural comparisons of the tryptophan-containing variant with an NMR-derived wild-type structure, which contains a tyrosine at position 47, reveals a common fold, although the overall backbone root-mean-square difference is 1.5 A. The Y47W substitution only caused local rearrangement of several side chains, the most prominent of which is the rotation of the Tyr34 side chain, resulting in a 6 A displacement of its hydroxyl group. A small methyl-sized cavity bounded by beta-strands 1, 2 and 4 and the alpha-helix was found in the structures of the Y47W-substituted protein L B1 domain. This cavity may be created as the result of subsequent side-chain rearrangements caused by the Y47W substitution. These high-resolution structures of the tryptophan-containing variant provide a reference frame for the analysis of thermodynamic and kinetic data derived from a series of mutational studies of the protein L B1 domain.

Articles - 1hz5 mentioned but not cited (12)

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  7. The use of Co2+ for crystallization and structure determination, using a conventional monochromatic X-ray source, of flax rust avirulence protein. Guncar G, Wang CI, Forwood JK, Teh T, Catanzariti AM, Ellis JG, Dodds PN, Kobe B. Acta Crystallogr Sect F Struct Biol Cryst Commun 63 209-213 (2007)
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Reviews citing this publication (1)

  1. 3D domain swapping: as domains continue to swap. Liu Y, Eisenberg D. Protein Sci 11 1285-1299 (2002)

Articles citing this publication (31)

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  8. Structure and action of the C-C bond-forming glycosyltransferase UrdGT2 involved in the biosynthesis of the antibiotic urdamycin. Mittler M, Bechthold A, Schulz GE. J Mol Biol 372 67-76 (2007)
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  14. Molecular origin of constant m-values, denatured state collapse, and residue-dependent transition midpoints in globular proteins. O'Brien EP, Brooks BR, Thirumalai D. Biochemistry 48 3743-3754 (2009)
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  16. Prediction of methyl-side chain dynamics in proteins. Ming D, Brüschweiler R. J Biomol NMR 29 363-368 (2004)
  17. Importance of individual side chains for the stability of a protein fold: computational alanine scanning of the insulin monomer. Zoete V, Meuwly M. J Comput Chem 27 1843-1857 (2006)
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  19. Calculation of proteins' total side-chain torsional entropy and its influence on protein-ligand interactions. DuBay KH, Geissler PL. J Mol Biol 391 484-497 (2009)
  20. Probing the protein-folding mechanism using denaturant and temperature effects on rate constants. Guinn EJ, Kontur WS, Tsodikov OV, Shkel I, Record MT. Proc Natl Acad Sci U S A 110 16784-16789 (2013)
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  24. Internal protein dynamics shifts the distance to the mechanical transition state. West DK, Paci E, Olmsted PD. Phys Rev E Stat Nonlin Soft Matter Phys 74 061912 (2006)
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  29. DsbA is a redox-switchable mechanical chaperone. Eckels EC, Chaudhuri D, Chakraborty S, Echelman DJ, Haldar S. Chem Sci 12 11109-11120 (2021)
  30. Energetic Calculations to Decipher pH-Dependent Oligomerization and Domain Swapping of Proteins. Shingate P, Warwicker J, Sowdhamini R. PLoS One 10 e0127716 (2015)
  31. Nonexponential kinetics captured in sequential unfolding of polyproteins over a range of loads. Chetrit E, Sharma S, Maayan U, Pelah MG, Klausner Z, Popa I, Berkovich R. Curr Res Struct Biol 4 106-117 (2022)


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