Experimentally exploring the conformational space sampled by domain reorientation in calmodulin.

The conformational space sampled by the two-domain protein calmodulin has been explored by an approach based on four sets of NMR observables obtained on Tb(3+)- and Tm(3+)-substituted proteins. The observables are the pseudocontact shifts and residual dipolar couplings of the C-terminal domain when lanthanide substitution is at the N-terminal domain. Each set of observables provides independent information on the conformations experienced by the molecule. It is found that not all sterically allowed conformations are equally populated. Taking the N-terminal domain as the reference, the C-terminal domain preferentially resides in a region of space inscribed in a wide elliptical cone. The axis of the cone is tilted by approximately 30 degrees with respect to the direction of the N-terminal part of the interdomain helix, which is known to have a flexible central part in solution. The C-terminal domain also undergoes rotation about the axis defined by the C-terminal part of the interdomain helix. Neither the extended helix conformation initially observed in the solid state for free calcium calmodulin nor the closed conformation(s) adopted by calcium calmodulin either alone or in its adduct(s) with target peptide(s) is among the most preferred ones. These findings are unique, both in terms of structural information obtained on a biomolecule that samples multiple conformations and in terms of the approach developed to achieve the results. The same approach is in principle applicable to other multidomain proteins, as well as to multiple interaction modes between two macromolecular partners.

[1]  S. Glaser,et al.  A general enhancement scheme in heteronuclear multidimensional NMR employing pulsed field gradients , 1994, Journal of biomolecular NMR.

[2]  J Meiler,et al.  Model-free approach to the dynamic interpretation of residual dipolar couplings in globular proteins. , 2001, Journal of the American Chemical Society.

[3]  Eva Thulin,et al.  Calcium-induced structural changes and domain autonomy in calmodulin , 1995, Nature Structural Biology.

[4]  L. Kay,et al.  What is the average conformation of bacteriophage T4 lysozyme in solution? A domain orientation study using dipolar couplings measured by solution NMR. , 2001, Journal of molecular biology.

[5]  B. Sykes,et al.  Quantification of the calcium‐induced secondary structural changes in the regulatory domain of troponin‐C , 1994, Protein science : a publication of the Protein Society.

[6]  Masaya Orita,et al.  A novel target recognition revealed by calmodulin in complex with Ca2+-calmodulin-dependent kinase kinase , 1999, Nature Structural Biology.

[7]  K. Wüthrich,et al.  Torsion angle dynamics for NMR structure calculation with the new program DYANA. , 1997, Journal of molecular biology.

[8]  Ivano Bertini,et al.  Solution NMR of Paramagnetic Molecules: Applications to metallobiomolecules and models , 2001 .

[9]  K Wüthrich,et al.  Efficient computation of three-dimensional protein structures in solution from nuclear magnetic resonance data using the program DIANA and the supporting programs CALIBA, HABAS and GLOMSA. , 1991, Journal of molecular biology.

[10]  K. Wüthrich,et al.  PSEUDYANA for NMR structure calculation of paramagnetic metalloproteins using torsion angle molecular dynamics , 1998, Journal of biomolecular NMR.

[11]  NMR solution structure of a complex of calmodulin with a binding peptide of the Ca2+ pump. , 1999 .

[12]  V. Saudek,et al.  Gradient-tailored excitation for single-quantum NMR spectroscopy of aqueous solutions , 1992, Journal of biomolecular NMR.

[13]  S. Martin,et al.  NMR approaches for monitoring domain orientations in calcium‐binding proteins in solution using partial replacement of Ca2+ by Tb3+ , 1999, FEBS letters.

[14]  Ad Bax,et al.  Magnetic Field Dependence of Nitrogen−Proton J Splittings in 15N-Enriched Human Ubiquitin Resulting from Relaxation Interference and Residual Dipolar Coupling , 1996 .

[15]  L. Caves,et al.  Inherent flexibility of calmodulin domains: a normal mode analysis study , 2002 .

[16]  M Ikura,et al.  Backbone dynamics of calmodulin studied by 15N relaxation using inverse detected two-dimensional NMR spectroscopy: the central helix is flexible. , 1992, Biochemistry.

[17]  A. Rosato,et al.  Paramagnetically induced residual dipolar couplings for solution structure determination of lanthanide binding proteins. , 2002, Journal of the American Chemical Society.

[18]  Ivano Bertini,et al.  Tuning the affinity for lanthanides of calcium binding proteins. , 2003, Biochemistry.

[19]  I. Bertini,et al.  Efficiency of paramagnetism-based constraints to determine the spatial arrangement of α-helical secondary structure elements , 2002, Journal of biomolecular NMR.

[20]  M Ikura,et al.  Molecular and structural basis of target recognition by calmodulin. , 1995, Annual review of biophysics and biomolecular structure.

[21]  A. Rosato,et al.  Partial Orientation of Oxidized and Reduced Cytochrome b5 at High Magnetic Fields: Magnetic Susceptibility Anisotropy Contributions and Consequences for Protein Solution Structure Determination , 1998 .

[22]  A. J. Shaka,et al.  Water Suppression That Works. Excitation Sculpting Using Arbitrary Wave-Forms and Pulsed-Field Gradients , 1995 .

[23]  J. Trewhella,et al.  Comparison of the crystal and solution structures of calmodulin and troponin C. , 1988, Biochemistry.

[24]  A. Rosato,et al.  Magnetic susceptibility tensor anisotropies for a lanthanide ion series in a fixed protein matrix. , 2001, Journal of the American Chemical Society.

[25]  K Schulten,et al.  Structure and dynamics of calmodulin in solution. , 1998, Biophysical journal.

[26]  A. Bax,et al.  Direct measurement of distances and angles in biomolecules by NMR in a dilute liquid crystalline medium. , 1997, Science.

[27]  L. Kay,et al.  Gradient-Enhanced Triple-Resonance Three-Dimensional NMR Experiments with Improved Sensitivity , 1994 .

[28]  S. Martin,et al.  Ca2+ coordination to backbone carbonyl oxygen atoms in calmodulin and other EF-hand proteins: 15N chemical shifts as probes for monitoring individual-site Ca2+ coordination. , 1998, Biochemistry.

[29]  A. Means,et al.  Calmodulin: a prototypical calcium sensor. , 2000, Trends in cell biology.

[30]  I. Bertini,et al.  Lanthanide-Induced Pseudocontact Shifts for Solution Structure Refinements of Macromolecules in Shells up to 40 Å from the Metal Ion , 2000 .

[31]  I. Bertini,et al.  Paramagnetic constraints: an aid for quick solution structure determination of paramagnetic metalloproteins , 2002 .

[32]  F. Quiocho,et al.  A closed compact structure of native Ca(2+)-calmodulin. , 2003, Structure.

[33]  Ernesto Carafoli,et al.  Calcium signaling: A tale for all seasons , 2002, Proceedings of the National Academy of Sciences of the United States of America.

[34]  G. Wider,et al.  A heteronuclear three-dimensional NMR experiment for measurements of small heteronuclear coupling constants in biological macromolecules , 1989 .

[35]  N. Tjandra,et al.  Analysis of slow interdomain motion of macromolecules using NMR relaxation data. , 2001, Journal of the American Chemical Society.

[36]  Nico Tjandra,et al.  Temperature dependence of domain motions of calmodulin probed by NMR relaxation at multiple fields. , 2003, Journal of the American Chemical Society.

[37]  Ivano Bertini,et al.  Magnetic susceptibility in paramagnetic NMR , 2002 .

[38]  J. Hus,et al.  A novel interactive tool for rigid-body modeling of multi-domain macromolecules using residual dipolar couplings , 2001, Journal of biomolecular NMR.

[39]  J. Adelman,et al.  Structure of the gating domain of a Ca2+-activated K+ channel complexed with Ca2+/calmodulin , 2001, Nature.

[40]  F A Quiocho,et al.  Target enzyme recognition by calmodulin: 2.4 A structure of a calmodulin-peptide complex. , 1992, Science.

[41]  Y. Izumi,et al.  Binding of both Ca2+ and mastoparan to calmodulin induces a large change in the tertiary structure. , 1989, Journal of biochemistry.

[42]  L. Kay,et al.  A Gradient-Enhanced HCCH-TOCSY Experiment for Recording Side-Chain 1H and 13C Correlations in H2O Samples of Proteins , 1993 .

[43]  J. Falke,et al.  Intermolecular tuning of calmodulin by target peptides and proteins: Differential effects on Ca2+ binding and implications for kinase activation , 1997, Protein science : a publication of the Protein Society.

[44]  Ad Bax,et al.  Quantitative J correlation: a new approach for measuring homonuclear three-bond J(HNH.alpha.) coupling constants in 15N-enriched proteins , 1993 .

[45]  A. Gronenborn,et al.  Solution structure of a calmodulin-target peptide complex by multidimensional NMR. , 1994, Science.

[46]  M. A. Wilson,et al.  The 1.0 A crystal structure of Ca(2+)-bound calmodulin: an analysis of disorder and implications for functionally relevant plasticity. , 2000, Journal of molecular biology.

[47]  Jens Meiler,et al.  Model-free analysis of protein backbone motion from residual dipolar couplings. , 2002, Journal of the American Chemical Society.

[48]  L. Kay,et al.  Orienting domains in proteins using dipolar couplings measured by liquid-state NMR: differences in solution and crystal forms of maltodextrin binding protein loaded with beta-cyclodextrin. , 2000, Journal of molecular biology.

[49]  A M Gronenborn,et al.  A robust method for determining the magnitude of the fully asymmetric alignment tensor of oriented macromolecules in the absence of structural information. , 1998, Journal of magnetic resonance.

[50]  A. Bax,et al.  Solution structure of calmodulin and its complex with a myosin light chain kinase fragment. , 1992, Cell calcium.

[51]  F M Richards,et al.  Calcium-induced increase in the radius of gyration and maximum dimension of calmodulin measured by small-angle X-ray scattering. , 1985, Biochemistry.

[52]  Ad Bax,et al.  Solution structure of Ca2+–calmodulin reveals flexible hand-like properties of its domains , 2001, Nature Structural Biology.

[53]  C. Bugg,et al.  Structure of calmodulin refined at 2.2 A resolution. , 1988, Journal of molecular biology.