Hydrogen bonding and the stability of the polypeptide backbone

Maccallum, Peter Hugh

January 1996

No description available.

572

Proteins; Biomolecular structure

The Genesis of Ribosome Structure: A Tale of Two Proteins

Woolstenhulme, Christopher James

15 June 2009

Living cells are dependent upon protein synthesis for virtually all cellular functions. The cellular machine responsible for protein synthesis, called the ribosome, is formed through the association of two unequally sized subunits, each composed of RNA and proteins. Proper assembly of each subunit is essential to ribosome function and therefore essential to the cellular life cycle. Previous studies focused on dissecting the assembly of the small ribosomal subunit (30S subunit) from E. coli have shown that 21 proteins sequentially assemble on the 16S rRNA at multiple nucleation sites. For the first time, we are able to monitor changes in the secondary and tertiary structure of the 16S rRNA upon the addition of single proteins during assembly by using time-dependent chemical probing. Results from these studies suggest that protein S17 induces multiple structural changes in 16S rRNA by first binding to helix 11 and then helix 7. S20 also induces changes in the rRNA by interacting with helix 9, 11, 44 and 13 in that order. These structural formations and rearrangements then prepare the binding sites for additional proteins (S12 and S16, respectively). This study demonstrates that time-dependent chemical probing is able to monitor the assembly of the 30S subunit at a level of detail never before seen. These studies also suggest that many motifs in the 16S rRNA structure are formed as a result of the proteins binding, lending evidence to the hypothesis that the function of ribosomal proteins is to shape and/or hold the RNA structure in place.

Biomolecular Structure & Dynamics

Distance measurements using pulsed EPR : noncovalently bound nitroxide and trityl spin labels

Reginsson, Gunnar Widtfeldt

January 2013

The function of biomacromolecules is controlled by their structure and conformational flexibility. Investigating the structure of biologically important macromolecules can, therefore, yield information that could explain their complex biological function. In addition to X ray crystallography and nuclear magnetic resonance (NMR) methods, pulsed electron paramagnetic resonance (EPR) methods, in particular the pulsed electron electron double resonance (PELDOR) technique has, during the last decade, become a valuable tool for structural determination of macromolecules. Long range distance constraints obtained from pulsed EPR measurements, make it possible to carry out structural refinements on structures from NMR and X ray methods. In addition, EPR yields distance distributions that give information about structural flexibility. The use of EPR for structural studies of biomacromolecules requires in most cases site specific incorporation of paramagnetic centres known as spin labelling. To date, spin labelling nucleic acids has required complex spin labelling chemistry. The first application of a site directed and noncovalent spin labelling method for distance measurements on DNA is described. It is demonstrated that noncovalent spin labelling with a rigid spin label can afford detailed information on internal DNA dynamics using PELDOR. Furthermore, it is shown that noncovalent spin labelling can be used to study DNA protein complexes. PELDOR can also yield information about spin label orientation. Therefore, spin labels with limited flexibility can be used to measure the relative orientation of the spin labelled sites. Although information on orientation can be obtained from 9.7 GHz PELDOR measurements in selected applications, measurements at 97 GHz or higher, increases orientation selection. It is shown that PELDOR measurements on semi rigid and rigid nitroxide biradicals using a home built high power 97 GHz EPR spectrometer (Hiper) and model based simulations yield quantitative information on spin label orientations and dynamics. The most widely used spin labels for EPR studies on biomacromolecules are the aminoxyl (nitroxide) radicals. The major drawbacks of nitroxide spin labels include low sensitivity for distance measurements, fast spin spin relaxation in solution and limited stability in reducing environments. Carbon centered triarylmethyl (trityl) radicals have properties that could eliminate some of the limitations of nitroxide spin labels. To evaluate the use of trityl spin labels for nanometer distance measurements, models systems with trityl and nitroxide spin labels were measured using PELDOR and Double Quantum Coherence (DQC). This study shows that trityl spin labels yield reliable information on interlabel distances and dynamics, establishing the trityl radical as a viable spin label for structural studies on biomacromolecules.

572

Extending the boundaries of the usage of NMR chemical shifts in deciphering biomolecular structure and dynamics

Sahakyan, Aleksandr B.

January 2012

NMR chemical shifts have an extremely high information content on the behaviour of macromolecules, owing to their non-trivial dependence on myriads of structural and environmental factors. Although such complex dependence creates an initial barrier for their use for the characterisation of the structures of protein and nucleic acids, recent developments in prediction methodologies and their successful implementation in resolving the structures of these molecules have clearly demonstrated that such barrier can be crossed. Furthermore, the significance of chemical shifts as useful observables in their own right has been substantially increased since the development of the NMR techniques to study low populated 'excited' states of biomolecules. This work is aimed at increasing our understanding of the multiple factors that affect chemical shifts in proteins and nucleic acids, and at developing high-quality chemical shift predictors for atom types that so far have largely escaped the attention in chemical shift restrained molecular dynamics simulations. A general approach is developed to optimise the models for structure-based chemical shift prediction, which is then used to construct CH3Shift and ArShift chemical shift predictors for the nuclei of protein side-chain methyl and aromatic moieties. These results have the potential of making a significant impact in structural biology, in particular when taking into account the advent of recent techniques for specific isotope labelling of protein side-chain atoms, which make large biomolecules accessible to NMR techniques. Through their incorporation as restraints in molecular dynamics simulations, the chemical shifts predicted by the approach described in this work create the opportunity of studying the structure and dynamics of proteins in a wide range of native and non-native states in order to characterise the mechanisms underlying the function and dysfunction of these molecules.

540

Structural and Evolutionary Studies on Bio-Molecular Complexes

Sudha, G

January 2014

No description available.

Bio-Molecular Complexes

Protein Complexes

Protein-Protein Interactions

Human Casein Kinase

Hepatitis C Virus (HCV) Proteins

Adeno Associated Virus (AAV) Proteins

Protein Structural Bioinformatics

Homomeric Proteins

Heteromers

Paralogous Proteins

Biomolecular Structure

Computational Structural Biology

AAV2 Capsid

NS3 protease

HCV IRES

Molecular Biophysics

Structural Investigation of Processing α-Glucosidase I from Saccharomyces cerevisiae

Barker, Megan

20 August 2012

N-glycosylation is the most common eukaryotic post-translational modification, impacting on protein stability, folding, and protein-protein interactions. More broadly, N-glycans play biological roles in reaction kinetics modulation, intracellular protein trafficking, and cell-cell communications. The machinery responsible for the initial stages of N-glycan assembly and processing is found on the membrane of the endoplasmic reticulum. Following N-glycan transfer to a nascent glycoprotein, the enzyme Processing α-Glucosidase I (GluI) catalyzes the selective removal of the terminal glucose residue. GluI is a highly substrate-specific enzyme, requiring a minimum glucotriose for catalysis; this glycan is uniquely found in biology in this pathway. The structural basis of the high substrate selectivity and the details of the mechanism of hydrolysis of this reaction have not been characterized. Understanding the structural foundation of this unique relationship forms the major aim of this work. To approach this goal, the S. cerevisiae homolog soluble protein, Cwht1p, was investigated. Cwht1p was expressed and purified in the methyltrophic yeast P. pastoris, improving protein yield to be sufficient for crystallization screens. From Cwht1p crystals, the structure was solved using mercury SAD phasing at a resolution of 2 Å, and two catalytic residues were proposed based upon structural similarity with characterized enzymes. Subsequently, computational methods using a glucotriose ligand were applied to predict the mode of substrate binding. From these results, a proposed model of substrate binding has been formulated, which may be conserved in eukaryotic GluI homologs.

Biomolecular structure

Eukaryotic glycosylation

glycosylation

N-glycan

N-linked glycosylation

Carbohydrate

biochemistry

Inhibitor

antiviral therapeutic

Structure-based drug design

glucosidase

glycosidase

glycoside hydrolase

post-translational modification

enzyme

enzyme mechanism

inverting mechanism

structural biology

protein structure

6xHis tag

Crystal packing

sugar

substrate

X-ray crystallography

single anomalous dispersion

PHENIX

heavy-atom phasing

docking

autodock

autodock vina

biophysical methods

tryptophan fluorescence

glucose oxidase

activity assay

enzyme inhibition

Protein expression

Protein purification

Pichia pastoris

Saccharomyces cerevisiae

fondue

AOX1 promoter

glycoside hydrolysis

substrate binding model

molecular dynamics

molecular dynamics

Binding site

Active site cleft

Endoplasmic reticulum

Glycan processing

Glycan trimming

protein-protein interactions

cell-cell communication

X-ray diffraction

crystallization

secreted protein

substrate selectivity

kojibiose

glucotriose

miglitol

deoxynojirimycin

Glc3Man9GlcNAc2

free oligosaccharide species

GluI

Cwh41

Cwh41p

Cwht1p

0306

0307

0760

Structural Investigation of Processing α-Glucosidase I from Saccharomyces cerevisiae

Barker, Megan

20 August 2012

N-glycosylation is the most common eukaryotic post-translational modification, impacting on protein stability, folding, and protein-protein interactions. More broadly, N-glycans play biological roles in reaction kinetics modulation, intracellular protein trafficking, and cell-cell communications. The machinery responsible for the initial stages of N-glycan assembly and processing is found on the membrane of the endoplasmic reticulum. Following N-glycan transfer to a nascent glycoprotein, the enzyme Processing α-Glucosidase I (GluI) catalyzes the selective removal of the terminal glucose residue. GluI is a highly substrate-specific enzyme, requiring a minimum glucotriose for catalysis; this glycan is uniquely found in biology in this pathway. The structural basis of the high substrate selectivity and the details of the mechanism of hydrolysis of this reaction have not been characterized. Understanding the structural foundation of this unique relationship forms the major aim of this work. To approach this goal, the S. cerevisiae homolog soluble protein, Cwht1p, was investigated. Cwht1p was expressed and purified in the methyltrophic yeast P. pastoris, improving protein yield to be sufficient for crystallization screens. From Cwht1p crystals, the structure was solved using mercury SAD phasing at a resolution of 2 Å, and two catalytic residues were proposed based upon structural similarity with characterized enzymes. Subsequently, computational methods using a glucotriose ligand were applied to predict the mode of substrate binding. From these results, a proposed model of substrate binding has been formulated, which may be conserved in eukaryotic GluI homologs.

Biomolecular structure

Eukaryotic glycosylation

glycosylation

N-glycan

N-linked glycosylation

Carbohydrate

biochemistry

Inhibitor

antiviral therapeutic

Structure-based drug design

glucosidase

glycosidase

glycoside hydrolase

post-translational modification

enzyme

enzyme mechanism

inverting mechanism

structural biology

protein structure

6xHis tag

Crystal packing

sugar

substrate

X-ray crystallography

single anomalous dispersion

PHENIX

heavy-atom phasing

docking

autodock

autodock vina

biophysical methods

tryptophan fluorescence

glucose oxidase

activity assay

enzyme inhibition

Protein expression

Protein purification

Pichia pastoris

Saccharomyces cerevisiae

fondue

AOX1 promoter

glycoside hydrolysis

substrate binding model

molecular dynamics

molecular dynamics

Binding site

Active site cleft

Endoplasmic reticulum

Glycan processing

Glycan trimming

protein-protein interactions

cell-cell communication

X-ray diffraction

crystallization

secreted protein

substrate selectivity

kojibiose

glucotriose

miglitol

deoxynojirimycin

Glc3Man9GlcNAc2

free oligosaccharide species

GluI

Cwh41

Cwh41p

Cwht1p

0306

0307

0760