Main-chain Topology Research Articles

Double-stranded vinyl polymer with transformable side chains synthesized in a metal‒organic framework

AbstractPost-polymerization modification (PPM) via active ester chemistry is a valuable method for modulating side-chain structures without altering their main-chain topology. Herein, we synthesized a double-stranded vinyl polymer with an active ester by crosslinking radical polymerization within the nanochannels of a metal‒organic framework (MOF) with a pore diameter comparable to that of the duplex. The resulting double-stranded poly(1,1,1,3,3,3-hexafluoroisopropyl acrylate) (DPHFIPA) was readily converted into acrylates and acrylamides with side chains derived from the nucleophile used in the PPM. This approach offers a pathway for creating double-stranded vinyl polymers with repeating units that are otherwise difficult to synthesize, even when MOF-templated polymerization is used.

Investigating the Influence of Sequence on Protein Folding Mechanism using a Structure Based Model

There are two major sources of frustration in a protein folding - energetic and topological. Energy landscape theory posits that main-chain topology is the major determinant in the folding mechanism of a protein. What is less well understood is the role that sequence effects play. To gain insight into this challenging problem, we utilize ancestral sequences reconstructed along mesophilic and thermophilic lineages of ribonuclease H (RNaseH) leading back to a common ancestor. This family of proteins share function and topology and have high sequence homology but differ in their biophysical properties.

Itinerary profiling to analyze a large number of protein-folding trajectories.

Understanding how proteins fold through a vast number of unfolded states is a major subject in the study of protein folding. Herein, we present itinerary profiling as a simple method to analyze molecular dynamics trajectories, and apply this method to Trp-cage. In itinerary profiling, structural clusters included in a trajectory are represented by a bit sequence, and a number of trajectories, as well as the structural clusters, can be compared and classified. As a consequence, the structural clusters that characterize the foldability of trajectories were able to be identified. The connections between the clusters were then illustrated as a network and the structural features of the clusters were examined. We found that in the true folding funnel, Trp-cage formed a left-handed main-chain topology and the Trp6 side-chain was located at the front of the main-chain ring, even in the initial unfolded states. In contrast, in the false folding funnel of the pseudo-native states, in which the Trp6 side-chain is upside down in the protein core, Trp-cage had a right-handed main-chain topology and the Trp side-chain was at the back. The initial topological partition, as determined by the main-chain handedness and the location of the Trp residue, predetermines Trp-cage foldability and the destination of the trajectory to the native state or the pseudo-native states.

New method for protein secondary structure assignment based on a simple topological descriptor

A simple, five-element descriptor, derived from the Delaunay tessellation of a protein structure in a single point per residue representation, can be assigned to each residue in the protein. The descriptor characterizes main-chain topology and connectivity in the neighborhood of the residue and does not explicitly depend on putative hydrogen bonds or any geometric parameter, including bond length, angles, and areas. Rules based on this descriptor can be used for accurate, robust, and computationally efficient secondary structure assignment that correlates well with the existing methods.

Stereoselective synthesis of chiral coordination polymers with partial control of the rigid main chain topology

The condensation polymerization between the appropriate enantiomers of [Ru(1,10-phenanthroline-5,6-dione)2- (bpy)]2+ 1 and [Ru(1,10-phenanthroline-5,6-diamine)2- (bpy)]2+ 2 in meta-cresol gave the homochiral coordination polymers Δ-3 and Λ-3 as well as the meso polymer, ΔΛ-3, which exhibit rigid, ribbon-like structures with different main chain topologies.

Protein similarities beyond disulphide bridge topology

Structural superimposition is an important procedure to analyse the relationships between proteins. A new approach and program, KNOT-MATCH, has been developed for automated structural superimposition of proteins by means of their disulphide bridge topology. As a result of the superimposition, regular secondary structures, loops and clusters of residues become correctly aligned. This fact allows us to find out important structural overlaps of residues, sometimes with functional significance, not only among proteins belonging to the same family but also between apparently non-related proteins. Different disulphide-rich protein families, such as EGF-like, defensin-like and plant protease inhibitors, have been self or cross analysed with this approach. Some amino acids that have been experimentally determined to be structural and/or functional key residues for these proteins are conserved in the three-dimensional space after superimposition by KNOT-MATCH. The program can be very useful for finding relationships among proteins that would be hidden to the current alignment methods based on sequence and on main-chain topology.

Applying experimental data to protein fold prediction with the genetic algorithm.

Specific residue interactions as revealed from a few and readily available experiments can be quite important in shaping a protein's tertiary topology by complementing basic and general folding principles. This experimental information is employed in structure prediction (mainchain topology) based on sequence knowledge and the genetic algorithm with its ability to optimize simultaneously many parameters. Examples investigated include the distribution of cysteinyl S-S bonds, protein side-chain ligands to iron-sulfur cages, cofactor-ligands, crosslinks amongst side-chains, and conserved hydrophobic and catalytic residues. Such interactions yield an improvement in the predicted topology (0.4-6.6 A root mean square deviation in the positions of the backbone C alpha-atoms relative to those observed) compared with those resulting from simulations relying only on basic protein folding principles. For several examples the resultant topology depended critically on knowledge of the few and specific interactions such that the relationship between predicted and observed C alpha-positions was near random without their use. The combined methodology (experimental data and the genetic algorithm) should prove helpful in settings where experiment and theory can cooperate in successive steps to elucidate an unknown structure.

The three-dimensional crystal structure of the catalytic core of cellobiohydrolase I from Trichoderma reesei.

Cellulose is the major polysaccharide of plants where it plays a predominantly structural role. A variety of highly specialized microorganisms have evolved to produce enzymes that either synergistically or in complexes can carry out the complete hydrolysis of cellulose. The structure of the major cellobiohydrolase, CBHI, of the potent cellulolytic fungus Trichoderma reesei has been determined and refined to 1.8 angstrom resolution. The molecule contains a 40 angstrom long active site tunnel that may account for many of the previously poorly understood macroscopic properties of the enzyme and its interaction with solid cellulose. The active site residues were identified by solving the structure of the enzyme complexed with an oligosaccharide, o-iodobenzyl-1-thio-beta-cellobioside. The three-dimensional structure is very similar to a family of bacterial beta-glucanases with the main-chain topology of the plant legume lectins.

The structure of tumour necrosis factor - implications for biological function

The three-dimensional structure of TNF has been determined at 0.29 nm using the technique of X-ray crystallography. Published data on site-directed mutagenesis and antibody binding may now be assessed in the light of the structure, thus the links between structure and function for TNF may be addressed. TNF is a compact trimer composed of three identical subunits of 157 amino acids. The main-chain topology for a single subunit is essentially a beta-sandwich structure formed by two anti-parallel beta-pleated sheets. This mainchain fold corresponds to the 'jelly roll' motif observed in viral coat proteins such as VP1, VP2 and VP3 of rhinovirus, or the hemagglutinin molecule of influenza. TNF is the first non-viral protein to contain this motif. The subunits associate tightly about a threefold axis interacting through a simple edge-to-face packing of the beta-sandwich to form the solid, conical shaped trimer. A large number of the residues conserved between the amino acid sequences of TNF and lymphotoxin lie within the beta-sandwich or at the threefold axis of the trimer. This implies the presence of the same beta-sandwich motif in the lymphotoxin monomer and preservation of the edge-to-face mode of trimeric association. The detailed three dimensional structure for TNF explains a wide range of observations, including data on antibody binding and site directed mutagenesis. The currently available evidence points to a region of biological importance situated at the interface between two subunits on the lower half of the trimer.