R. Sharon

Potential energy function and parameters for simulations of the molecular dynamics of proteins and nucleic acids in solution

We present the complete set of energy parameters used in the ENCAD (Energy Calculation and Dynamics) simulation program [J. Mol. Biol. 168 (1983) 595]. Full details are given of the form of the potential, which has been designed for efficient simulation of trajectories of macromolecules in solution. Emphasis is placed on energy conservation and the nonbonded truncation schemes needed to achieve it. Simulations of macromolecules in solution with ENCAD are both very stable in that the native structure is preserved at room temperature and efficient in that nanosecond simulations take a few weeks on an ordinary workstation.

Characterization and preliminary crystallographic studies on large ribosomal subunits from Thermus thermophilus.

Diffracting crystals, suitable for X-ray crystallographic analysis, have been obtained from large (50 S) ribosomal subunits from Thermus thermophilus. These crystals, with P4(1)2(1)2 symmetry and a unit cell of 495 A x 495 A x 196 A, reach typically a size of 0.15 mm x 0.25 mm x 0.35 mm. Using synchrotron radiation at cryo-temperature, these crystals diffract X-rays to better than 9 A resolution, and do not show any measurable decay after a few days of irradiation. They complete a series of crystals, grown by us, from ribosomal particles of the same source, including a 30 S subunits, 70 S ribosomes and complexes of the latter with: (1) an oligomer of 35 uridine residues and (2) the same oligonucleotide together with approximately two Phe-tRNA(Phe) molecules. Crystallographic analysis of the various members of this series should provide information for investigating the conformational changes that take place upon the association of ribosomes from their subunits as well as upon binding of non-ribosomal components that participate in protein biosynthesis.

The interplay between X-ray crystallography, neutron diffraction, image reconstruction, organo-metallic chemistry and biochemistry in structural studies of ribosomes

Crystals of ribosomes, their complexes with components of protein biosynthesis, their natural, mutated and modified subunits, have been subjected to X-ray and neutron crystallographic analyses. Electron microscopy and 3-dimensional image reconstruction, supported by biochemistry, genetic, functional and organo-metallic studies were employed for facilitating phasing of the crystallographic data. For example, a monofunctional multi heavy-atom cluster (undecagold) was designed for covalent and quantitative binding to ribosomes. The modified particles were crystallized isomorphously with the native ones. Their difference-Patterson maps contain indications for the usefulness of these derivatives for subsequent phasing. Models of the ribosome and its large subunit were reconstructed from tilt series of 2-dimensional sheets. The comparison of the various reconstructed images enabled an initial assessment of the reliability of these models and led to tentative assignments of several functional features. These include the presumed sites for binding mRNA and for codon-anticodon interactions, the path taken by the nascent protein chain and the mode for tRNA binding to ribosomes. These assignments assisted in the design of biologically meaningful crystal systems. The reconstructed models are being used to identify structural features in initial density maps derived from X-ray and neutron diffraction data.

Towards Atomic Resolution of Prokaryotic Ribosomes: Crystallographic, Genetic and Biochemical Studies

The studies reported here were initiated and inspired by the late Prof. H.G. Wittmann. From the early stages of this project, when it was widely believed that even the initial steps in determining the molecular structure of ribosomes are impossible, until his last days, Prof. Wittmann was actively involved in the experimental design and in the actual studies. We have no doubt that without his motivation, optimism, guidance and support, this project would not have reached its current stage.

Ribosomal crystallography : from crystal growth to initial phasing

Preliminary phases were determined by the application of the isomorphous replacement method at low and intermediate resolution for structure factor amplitudes collected from crystals of large and small ribosomal subunits from halophilic and thermophilic bacteria. Derivatization was performed with dense heavy atom clusters, either by soaking or by specific covalent binding prior to the crystallization. The resulting initial electron density maps contain features comparable in size to those expected for the corresponding particles. The packing arrangements of these maps have been compared with motifs observed by electron microscopy in positively stained thin sections of embedded three-dimensional as well as with phase sets obtained by ab-initio computations. Aimed at higher resolution phasing, procedures are being developed for multi-site binding of relatively small dense metal clusters at selected locations. Potential sites are being inserted either by mutagenesis or by chemical modifications to facilitate cluster binding to the large halophilic and the small thermophil!c ribosomal subunits which yield crystals diffracting to the highest resolution obtained so far for ribosomes, 2.9 and 7.3 A, respectively. For this purpose the surfaces of these ribosomal particles have been characterized and conditions for quantitative reversible detachment of selected ribosomal proteins have been found. The corresponding genes are being cloned, sequenced, mutated to introduce the reactive side-groups (mainly cysteines) and overexpressed. To assist the interpretation of the anticipated electron density maps, sub-ribosomal stable complexes were isolated from H50S. One of these complexes is composed of two proteins and the other is made of a stretch of the rRNA and a protein. For exploiting the exposed parts of the surface of these complexes for heavy atom binding and for attempting the determination of their three-dimensional structure, their components are being produced genetically. The low resolution models reconstructed from tilt series of crystalline arrays of ribosomal particles are being employed for initial phasing. The tentative functional interpretation of these models stimulated the design and the crystallization of complexes mimicking

Crystals of 70S ribosomes from thermophilic bacteria are suitable for X-ray amalysis at low resolution

Single crystals of 70S ribosomes from Thermus thermophilus and from the wild-type and a mutant of Bacillus stearothermophilus have been obtained. Using synchroton X-ray beam, these crystals diffract to 19 A and 35 A, respectively, and can be irradiated at temperatures of 110–120 K for days without noticeable decay. Diffraction data sets to 22 A and to 33 A with reasonable R scale were collected from the crystals of 70S from T. thermophilus. The cell dimensions (a = b = 524 A, c = 315 A), the symmetry (P41212 or P43212) and the density (1.063 g/cm3) of these crystals indicate that there is one 70S ribosome per asymmetric unit.

Simulating Protein Dynamics in Solution: Bovine Pancreatic Trypsin Inhibitor

Aqueous solution provides the natural environment for protein and nucleic acid molecules. Water molecules interact with these biological macromolecules by attracting polar groups of atoms through hydrogen bonds and by repelling nonpolar groups through hydrophobic interactions. Both types of interaction have a clear effect on macromolecular stability in that intramolecular hydrogen bonding is weakened by the alternative hydrogen bonds to water and nonpolar group are forced to come together by the hydrophobic interaction.