Flexibility of the DNA‐binding domains of trp repressor

An orthorhombic crystal form of trp repressor (aporepressor plus L‐tryptophan ligand) was solved by molecular replacement, refined to 1.65 Å resolution, and compared to the structure of the repressor in trigonal crystals. Even though these two crystal forms of repressor were grown under identical conditions, the refined structures have distinctly different conformations of the DNA‐binding domains. Unlike the repressor/aporepressor structural transition, the conformational shift is not caused by the binding or loss of the L‐tryptophan ligand. We conclude that while L‐tryptophan binding is essential for forming a specific complex with trp operator DNA, the corepressor ligand does not lock the repressor into a single conformation that is complementary to the operator. This flexibility may be required by the various binding modes proposed for trp repressor in its search for and adherence to its three different operator sites.

[1]  B. Matthews,et al.  The molecular basis of DNA–protein recognition inferred from the structure of cro repressor , 1982, Nature.

[2]  A M Lesk,et al.  Mechanisms of domain closure in proteins. , 1984, Journal of molecular biology.

[3]  R. Sauer,et al.  The lambda repressor contains two domains. , 1979, Proceedings of the National Academy of Sciences of the United States of America.

[4]  P. V. von Hippel,et al.  Diffusion-driven mechanisms of protein translocation on nucleic acids. 1. Models and theory. , 1981, Biochemistry.

[5]  Thomas A. Steitz,et al.  Structure of catabolite gene activator protein at 2.9 Å resolution suggests binding to left-handed B-DNA , 1981, Nature.

[6]  A. McPherson,et al.  The growth and preliminary investigation of protein and nucleic acid crystals for X-ray diffraction analysis. , 2006, Methods of biochemical analysis.

[7]  F M Richards,et al.  Crystal structure of hen egg-white lysozyme at a hydrostatic pressure of 1000 atmospheres. , 1987, Journal of molecular biology.

[8]  C. Yanofsky,et al.  Regulation of in vitro transcription of the tryptophan operon by purified RNA polymerase in the presence of partially purified repressor and tryptophan. , 1973, Nature: New biology.

[9]  R. A. Crowther,et al.  A method of positioning a known molecule in an unknown crystal structure , 1967 .

[10]  A. Joachimiak,et al.  Crystals of the trp repressor-operator complex suitable for X-ray diffraction analysis. , 1987, The Journal of biological chemistry.

[11]  R. Doolittle,et al.  Homology among DNA-binding proteins suggests use of a conserved super-secondary structure , 1982, Nature.

[12]  C. Yanofsky,et al.  RNA polymerase interaction at the promoter--operator region of the tryptophan operon of Escherichia coli and Salmonella typhimurium. , 1978, Journal of molecular biology.

[13]  T. Steitz,et al.  Structure of catabolite gene activator protein at 2.9-A resolution. Incorporation of amino acid sequence and interactions with cyclic AMP. , 1982, The Journal of biological chemistry.

[14]  O. Jardetzky,et al.  Differential mobility of the N-terminal headpiece in the lac-repressor protein. , 1979, Journal of molecular biology.

[15]  C. Yanofsky,et al.  Functional inferences from crystals of Escherichia coli trp repressor. , 1983, The Journal of biological chemistry.

[16]  A. Joachimiak,et al.  The crystal structure of trp aporepressor at 1.8 Å shows how binding tryptophan enhances DNA affinity , 1987, Nature.

[17]  B. Matthews,et al.  Structure of the cro repressor from bacteriophage λ and its interaction with DNA , 1981, Nature.

[18]  P. Fitzgerald MERLOT: a package of computer programs for the determination of phases using the molecular replacement method , 1987 .

[19]  T. Steitz,et al.  A model for the non-specific binding of catabolite gene activator protein to DNA. , 1984, Nucleic acids research.

[20]  D W Hukins,et al.  Optimised parameters for A-DNA and B-DNA. , 1972, Biochemical and biophysical research communications.

[21]  C. Yanofsky,et al.  Trp aporepressor production is controlled by autogenous regulation and inefficient translation. , 1982, Proceedings of the National Academy of Sciences of the United States of America.

[22]  T. Jovin,et al.  Amino-terminal fragments of Escherichia coli lac repressor bind to DNA , 1977, Nature.

[23]  C. Yanofsky,et al.  Purification and characterization of trp aporepressor. , 1983, Proceedings of the National Academy of Sciences of the United States of America.

[24]  S. Harrison,et al.  Structure of the represser–operator complex of bacteriophage 434 , 1987, Nature.

[25]  K. Weber,et al.  Isolation of amino-terminal fragment of lactose repressor necessary for DNA binding. , 1977, Biochemistry.

[26]  C. Pabo,et al.  The operator-binding domain of λ repressor: structure and DNA recognition , 1982, Nature.

[27]  A M Lesk,et al.  Computer-generated schematic diagrams of protein structures. , 1982, Science.

[28]  C. Yanofsky,et al.  Nucleotide sequence and expression of Escherichia coli trpR, the structural gene for the trp aporepressor. , 1980, Proceedings of the National Academy of Sciences of the United States of America.

[29]  B. Finzel Incorporation of fast Fourier transforms to speed restrained least‐squares refinement of protein structures , 1987 .

[30]  A. M. Lesk,et al.  A toolkit for computational molecular biology. II. On the optimal superposition of two sets of coordinates , 1986 .

[31]  George M. Church,et al.  A structure-factor least-squares refinement procedure for macromolecular structures using constrained and restrained parameters , 1977 .

[32]  L. G. Hoard,et al.  A Gauss–Seidel least‐squares refinement procedure with rigid‐group and parameter restraint capabilities , 1979 .

[33]  K. Wüthrich,et al.  Sequence-specific resonance assignments in the 1H nuclear-magnetic-resonance spectrum of the lac repressor DNA-binding domain 1-51 from Escherichia coli by two-dimensional spectroscopy. , 1983, European journal of biochemistry.

[34]  C. Yanofsky,et al.  Structure and regulation of aroH, the structural gene for the tryptophan-repressible 3-deoxy-D-arabino-heptulosonic acid-7-phosphate synthetase of Escherichia coli. , 1981, Journal of molecular biology.

[35]  W. Kidd,et al.  Relative and Latitudinal Motion of Atlantic Hot Spots , 1973, Nature.

[36]  A. Lesk,et al.  Helix movements in proteins , 1985 .

[37]  Catherine L. Lawson,et al.  The three-dimensional structure of trp repressor , 1985, Nature.

[38]  Cyrus Chothia,et al.  Transmission of conformational change in insulin , 1983, Nature.

[39]  S. Harrison,et al.  A phage repressor–operator complex at 7 Å resolution , 1985, Nature.

[40]  C. Yanofsky,et al.  Interaction of the trp repressor and RNA polymerase with the trp operon. , 1975, Journal of molecular biology.

[41]  S. Sheriff Addition of symmetry‐related contact restraints to PROTIN and PROLSQ , 1987 .

[42]  C Chothia,et al.  Haemoglobin: the structural changes related to ligand binding and its allosteric mechanism. , 1979, Journal of molecular biology.

[43]  C. Yanofsky,et al.  Escherichia coli RNA polymerase and trp repressor interaction with the promoter-operator region of the tryptophan operon of Salmonella typhimurium. , 1980, Journal of molecular biology.

[44]  Nobuhiko Saitô,et al.  Tertiary Structure of Proteins. I. : Representation and Computation of the Conformations , 1972 .

[45]  W. Hendrickson,et al.  STEREOCHEMICALLY RESTRAINED CRYSTALLOGRAPHIC LEAST-SQUARES REFINEMENT OF MACROMOLECULE STRUCTURES , 1981 .

[46]  S. Strub Pattern regulation and transdetermination in Drosophila imaginal leg disk reaggregates , 1977, Nature.