1lyd Citations

Crystal structure of T4-lysozyme generated from synthetic coding DNA expressed in Escherichia coli.

Rose DR, Phipps J, Michniewicz J, Birnbaum GI, Ahmed FR, Muir A, Anderson WF, Narang S
Protein Eng 2 277-82 (1988)
Cited: 21 times
EuropePMC logo PMID: 3074306

Abstract

The polypeptide produced by expressing a chemically synthesized gene coding for the amino-acid sequence of T4-lysozyme has been crystallized and subjected to X-ray diffraction. The crystal structure has been refined to a standard R-factor of 0.191 for data between 8 and 2 A resolution. The refined model is essentially the same as the well-known structure of wild-type T4-lysozyme determined previously by Matthews et al. (1987). Some small changes in the C-terminal region, which is important in maintaining the folded structure, have been noted. In addition to confirming that the synthetic gene product is very close to the wild type, this structure provides a benchmark for protein engineering experiments on the folding and the catalytic activity of this molecule by the method of gene synthesis.

Reviews - 1lyd mentioned but not cited (1)

  1. Bacteriophage T4 genome. Miller ES, Kutter E, Mosig G, Arisaka F, Kunisawa T, Rüger W. Microbiol Mol Biol Rev 67 86-156, table of contents (2003)

Articles - 1lyd mentioned but not cited (10)

  1. Evidence for the role of PrP(C) helix 1 in the hydrophilic seeding of prion aggregates. Morrissey MP, Shakhnovich EI. Proc Natl Acad Sci U S A 96 11293-11298 (1999)
  2. Structure of KAP1 tripartite motif identifies molecular interfaces required for retroelement silencing. Stoll GA, Oda SI, Chong ZS, Yu M, McLaughlin SH, Modis Y. Proc Natl Acad Sci U S A 116 15042-15051 (2019)
  3. Prediction of protein thermostability with a direction- and distance-dependent knowledge-based potential. Hoppe C, Schomburg D. Protein Sci 14 2682-2692 (2005)
  4. Amino acid interaction preferences in proteins. Jha AN, Vishveshwara S, Banavar JR. Protein Sci 19 603-616 (2010)
  5. Modular endolysin of Burkholderia AP3 phage has the largest lysozyme-like catalytic subunit discovered to date and no catalytic aspartate residue. Maciejewska B, Źrubek K, Espaillat A, Wiśniewska M, Rembacz KP, Cava F, Dubin G, Drulis-Kawa Z. Sci Rep 7 14501 (2017)
  6. Connecting two proteins using a fusion alpha helix stabilized by a chemical cross linker. Jeong WH, Lee H, Song DH, Eom JH, Kim SC, Lee HS, Lee H, Lee JO. Nat Commun 7 11031 (2016)
  7. DROIDS 1.20: A GUI-Based Pipeline for GPU-Accelerated Comparative Protein Dynamics. Babbitt GA, Mortensen JS, Coppola EE, Adams LE, Liao JK. Biophys J 114 1009-1017 (2018)
  8. Mapping hydrophobicity on the protein molecular surface at atom-level resolution. Nicolau DV, Paszek E, Fulga F, Nicolau DV. PLoS One 9 e114042 (2014)
  9. A search for energy minimized sequences of proteins. Jha AN, Ananthasuresh GK, Vishveshwara S. PLoS One 4 e6684 (2009)
  10. Protein molecular surface mapped at different geometrical resolutions. Nicolau DV, Paszek E, Fulga F, Nicolau DV. PLoS One 8 e58896 (2013)


Articles citing this publication (10)

  1. Polarization-enhanced NMR spectroscopy of biomolecules in frozen solution. Hall DA, Maus DC, Gerfen GJ, Inati SJ, Becerra LR, Dahlquist FW, Griffin RG. Science 276 930-932 (1997)
  2. Four helix bundle diversity in globular proteins. Harris NL, Presnell SR, Cohen FE. J Mol Biol 236 1356-1368 (1994)
  3. Accessibility to internal cavities and ligand binding sites monitored by protein crystallographic thermal factors. Carugo O, Argos P. Proteins 31 201-213 (1998)
  4. What is the average conformation of bacteriophage T4 lysozyme in solution? A domain orientation study using dipolar couplings measured by solution NMR. Goto NK, Skrynnikov NR, Dahlquist FW, Kay LE. J Mol Biol 308 745-764 (2001)
  5. Protein phi and psi dihedral restraints determined from multidimensional hypersurface correlations of backbone chemical shifts and their use in the determination of protein tertiary structures. Beger RD, Bolton PH. J Biomol NMR 10 129-142 (1997)
  6. Evolution of iron(II)-finger peptides by using a bipyridyl amino acid. Kang M, Light K, Ai HW, Shen W, Kim CH, Chen PR, Lee HS, Solomon EI, Schultz PG. Chembiochem 15 822-825 (2014)
  7. Vibrational Stark spectroscopy for assessing ligand-binding strengths in a protein. Mondal P, Meuwly M. Phys Chem Chem Phys 19 16131-16143 (2017)
  8. Interaction-component analysis of the effects of urea and its alkylated derivatives on the structure of T4-lysozyme. Yamamori Y, Matubayasi N. J Chem Phys 146 225103 (2017)
  9. Parametric models to compute tryptophan fluorescence wavelengths from classical protein simulations. Lopez AJ, Martínez L. J Comput Chem 39 1249-1258 (2018)
  10. Site Identification by Ligand Competitive Saturation-Biologics Approach for Structure-Based Protein Charge Prediction. Orr AA, Tao A, Guvench O, MacKerell AD. Mol Pharm 20 2600-2611 (2023)


Related citations provided by authors (2)

  1. Hierarchical Strategy for Protein Folding and Design. Synthesis and Expression of T4 Lysozyme Gene and Two Putative Folding Mutants. Narang SA, Yao F-L, Michniewicz JJ, Dubuc G, Phipps J, Somorjai RL Protein Eng. 1 481- (1987)
  2. Structure of Bacteriophage T4 Lysozyme Refined at 1.7 Angstroms Resolution. Weaver LH, Matthews BW J. Mol. Biol. 193 189- (1987)

Quick links