A structure refinement protocol combining NMR residual dipolar couplings and small angle scattering restraints

We present the implementation of a target function based on Small Angle Scattering data (Gabel et al. Eur Biophys J 35(4):313-327, 2006) into the Crystallography and NMR Systems (CNS) and demonstrate its utility in NMR structure calculations by simultaneous application of small angle scattering (SAS) and residual dipolar coupling (RDC) restraints. The efficiency and stability of the approach are demonstrated by reconstructing the structure of a two domain region of the 31 kDa nuclear export factor TAP (TIP-associated protein). Starting with the high resolution X-ray structures of the two individual TAP domains, the translational and orientational domain arrangement is refined simultaneously. We tested the stability of the protocol against variations of the SAS target parameters and the number of RDCs and their uncertainties. The activation of SAS restraints results in an improved translational clustering of the domain positions and lifts part of the fourfold degeneracy of their orientations (associated with a single alignment tensor). The resulting ensemble of structures reflects the conformational space that is consistent with the experimental SAS and RDC data. The SAS target function is computationally very efficient. SAS restraints can be activated at different levels of precision and only a limited SAS angular range is required. When combined with additional data from chemical shift perturbation, paramagnetic relaxation enhancement or mutational analysis the SAS refinement is an efficient approach for defining the topology of multi-domain and/or multimeric biomolecular complexes in solution based on available high resolution structures (NMR or X-ray) of the individual domains.

Synchrotron radiation solution X-ray scattering study of the pH dependence of the quaternary structure of yeast pyruvate decarboxylase

The pH dependence of the quaternary structure of pyruvate decarboxylase from yeast was studied in the range 6.2 less than pH less than 8.4. There is an equilibrium with a midpoint around pH 7.5 between tetramers and dimers, and the catalytic activity of the enzyme depends on the volume fraction of tetramer. This equilibrium may provide an additional regulating mechanism besides substrate activation since accumulation of pyruvate would lead to a reduction in pH and hence an increase of the concentration of the catalytically active tetramer. Radiation damage during the X-ray scattering experiments results in a shift of this equilibrium and in the formation of octamers. These effects could be circumvented and analyzed using experimental and data processing methods which can be readily applied to other radiation-sensitive systems. The low-resolution shapes of the dimers and tetramers were determined from the scattering curves using spherical harmonics. The results indicate that a conformational change must occur in the dimers upon formation of the tetramers, in agreement with earlier circular dichroism measurements.

The influence of the effectors of yeast pyruvate decarboxylase (PDC) on the conformation of the dimers and tetramers and their pH-dependent equilibrium

The influence of effectors of yeast pyruvate decarboxylase, phosphate, pyruvamide, thiamin diphosphate and Mg++, on the pH-dependent equilibrium between dimers and tetramers was studied by synchrotron radiation X-ray solution scattering. Thiamin diphosphate and phosphate shift the equilibrium to higher pH values without altering the structure of the oligomers. Pyruvamide, a substrate analogue activator, induces a significant change in the structure of the tetramer. By eliminating radiation damage by addition of dithioerythrol to the buffers, the scattering curves could be measured accurately over a large angular range. They were expanded in terms of spherical harmonics to obtain the shapes of the dimers and tetramers with higher resolution than was hitherto possible. This also allowed us to position the dimers, which are centrosymmetric at low resolution, in the tetramers which have 222 symmetry. The results indicate that addition of pyruvamide results in a less compact tetramer owing to structural changes in the dimers and to their displacements.

A molecular envelope of the ligand-binding domain of a glutamate receptor in the presence and absence of agonist

Solution scattering studies were performed on a ligand-binding domain (S1S2) of a glutamate receptor ion channel (GluR) in order to study GluR-binding and signal-transduction mechanisms. The core of the ligand-binding domain is homologous to prokaryotic periplasmic binding proteins (PBP), whose binding mechanism involves a dramatic cleft closure: the "Venus flytrap". Several models of GluR function have proposed that a similar cleft closure is induced by agonist binding. We have directly tested this putative functional homology by measuring the radius of gyration of S1S2 in the presence and absence of saturating concentrations of agonists. In contrast to the PBP, S1S2 shows no reduction in radius of gyration upon agonist binding, excluding a comparably large conformational change. Furthermore, we determined an ab initio molecular envelope for our S1S2 construct, which also contains the peptides that connect the PBP homology core to the three transmembrane domains and to an N-terminal domain. By fitting an atomic model of the ligand-binding domain core to the envelope of our extended construct, we were able to establish the likely position of these connecting peptides. Their positions relative to one another and to the expected sites of an agonist-induced conformational change suggest that ion channel gating and desensitization may involve more subtle and complex mechanisms than have been assumed based on the structural homology to the PBP.

Small-angle X-ray solution scattering study on the dimerization of the FKBP25mem from Legionella pneumophila

The dimerization of the FK506-binding peptidyl-prolyl cis/trans-isomerase (PPIase) FKBP25mem (Mip (macrophage infectivity potentiator) protein) from Legionella pneumophila was studied by small-angle X-ray solution scattering. A value of 44 kDa, independent on the protein concentration between 2 and 13 mg/ml, confirming that FKBP25mem is a dimer was found for the molecular mass of the protein. The radius of gyration of the protein is 3.3 nm and the Porod volume 87 nm3. A model of the shape of FKBP25mem was evaluated from the scattering curve. Each monomer consists of a proximal and a peripheral domain, which are perpendicular to each other. The envelope of the crystallographic model of human FKBP12 fits well into the peripheral domain. The contact regions between the two monomers in the dimeric protein are probably located between the N-terminal parts of the monomers.

The overall conformation of conventional kinesins studied by small angle X-ray and neutron scattering

The quaternary structures of several monomeric and dimeric kinesin constructs from Homo sapiens and Drosophila melanogaster were analyzed using small angle x-ray and neutron scattering. The experimental scattering curves of these proteins were compared with simulated scattering curves calculated from available crystallographic coordinates. These comparisons indicate that the overall conformations of the solution structures of D. melanogaster and H. sapiens kinesin heavy chain dimers are compatible with the crystal structure of dimeric kinesin from Rattus norvegicus. This suggests that the unusual asymmetric conformation of dimeric kinesin in the microtubule-independent ADP state is likely to be a general feature of the kinesin heavy chain subfamily. An intermediate length Drosophila construct (365 residues) is mostly monomeric at low protein concentration whereas at higher concentrations it is dimeric with a tendency to form higher oligomers.

Low-resolution structure of the proteolytic fragments of the Rapana venosa hemocyanin in solution

Rapana venosa hemocyanin (Hc) is a giant oxygen-binding protein consisting of different subunits assembled in a hollow cylinder. The polypeptide chain of each subunit is believed to be folded in several oxygen-binding functional units of molecular mass 50 kDa, each containing a binuclear copper active site. Limited proteolysis with alpha-chymotrypsin of native R. venosa hemocyanin allows the separation of three functional proteolytic fragments with molecular masses of approximately 150, 100, and 50 kDa. The functional fragments, purified by combining gel filtration chromatography and ion-exchange FPLC, were analyzed by means of small-angle X-ray scattering (SAXS). The gyration radius of the 50-kDa Rapana Hc fraction (2.4 nm) agrees well with that calculated on the basis of the dimensions determined by X-ray crystallography for one functional unit of Octopus Hc (2.1 nm). Independent shape determination of the 50- and 100-kDa proteolytic fragments yields consistent low-resolution models. Simultaneous fitting of the SAXS data from these fragments provides a higher-resolution model of the 100-kDa species made of two functional units tilted with respect to each other. The model of the 150-kDa proteolytic fragment consistent with the SAXS data displays a linear chain-like aggregation of the 50-kDa functional units. These observations provide valuable information for the reconstruction of the three-dimensional structure of the minimal functional subunit of gastropod hemocyanin in solution. Furthermore, the spatial relationships among the different functional units within the subunit will help in elucidation of the overall quaternary structure of the oligomeric native protein.

The ribosomal elongation cycle and the movement of tRNAs across the ribosome

Ribosome research has reached an exciting state, where two lines of experimental research have considerably improved our understanding of the ribosomal functions. On one hand, functional analysis has elucidated principles of both the decoding process and the tRNA movement on the ribosome during translocation. Experimental data leading to current competing models of the ribosomal elongation cycle can be reconciled by a new model, the alpha-epsilon model, according to which both tRNAs are tightly bound to a movable ribosomal domain. This alpha-epsilon domain carries the tRNA2.mRNA complex from the A and P sites to the P and E sites in the course of translocation maintaining the binding of both tRNAs. On the other hand, the location of tRNAs within the elongating ribosome can be directly determined for the first time by neutron scattering and electron microscopy. Both lines of evidence complement each other and define a frame for the first experimentally sound functional model of the elongating ribosome.

Structure of a beheaded 30 S ribosomal subunit from Thermus thermophilus

The 22 S ribonucleoproten particles containing the 5' (body) and the central (platform) domains of the Thermus thermophilus 30 S subunit has been studied by sedimentation, neutron scattering and electron microscopy. The RNP particles have been obtained by oligonucleotide-directed cleavage of 16 S RNA with ribonulease H in the region of the 900th nucleotide of the protein-deficient derivatives of the 30 S subunits. It is shown that these RNP particles are very compact, though their form and dimensions differ slightly from those expected from the electron microscopy model of the 30 S subunit beheaded by computer simulation. The particles are subdivided into two structural domains whose mutual arrangement differs from that of the corresponding morphological parts of the native 30 S subunit. Electron microscopy demonstrates that the mutual arrangement of domains in the RNP particles is not strictly fixed suggesting that interaction with the third domain of the 30 S subunit is a requisite for their correct fitting.