R. Andrew Byrd

Structure of the type 5 capsular polysaccharide of Staphylococcus aureus

The Staphylococcus aureus type 5 capsular polysaccharide is composed of 2-acetamido-2-deoxy-L-fucose (1 part), 2-acetamido-2-deoxy-D-fucose (1 part), and 2-acetamido-2-deoxy-D-mannuronic acid (1 part). On the basis of methylation analysis, optical rotation, high-field one- and two-dimensional 1H- and 13C-n.m.r. experiments, and selective cleavage with 70% aqueous hydrogen fluoride, the polysaccharide was found to be a partially O-acetylated (50%) polymer of the repeating trisaccharide unit, [----4)-3-O-Ac-beta-D-ManpNAcA-(1----4)-a-L-FucpNAc-(1----3) -beta-D-FucpNAc-(1----]n.

Breaking symmetry in the structure determination of (large) symmetric protein dimers

We demonstrate a novel methodology to disrupt the symmetry in the NMR spectra of homodimers. A paramagnetic probe is introduced sub-stoichiometrically to create an asymmetric system with the paramagnetic probe residing on only one monomer within the dimer. This creates sufficient magnetic anisotropy for resolution of symmetry-related overlapped resonances and, consequently, detection of pseudocontact shifts and residual dipolar couplings specific to each monomeric component. These pseudocontact shifts can be readily incorporated into existing structure refinement calculations and enable determination of monomer orientation within the dimeric protein. This methodology can be widely used for solution structure determination of symmetric dimers.

New N.M.R.-spectroscopic approaches for structural studies of polysaccharides: Application to the Haemophilus influenzae type a capsular polysaccharide

The extension of several modern nuclear magnetic resonance (n.m.r.) spectroscopic techniques to polysaccharides is discussed and illustrated, using the native Haemophilus influenzae type a capsular polysaccharide. These techniques provide for the unambiguous assignment of all n.m.r. resonances (1H, 13C, and 31P) via high-sensitivity homonuclear and 1H-detected heteronuclear correlations, and they are capable of locating the intersaccharide linkages (both O-linked and phosphoric diester-linked) and appended groups (e.g. O-acetyl groups). To illustrate the power and sensitivity of these methods, a 10-mg sample of the H. Influenzae type a polysaccharide (repeat unit mol. wt. = 376) was studied. The combined acquisition time for the two-dimensional 1H-13C correlation data (one-bond and multiple-bond), the 1H-31P correlation data, and the 1H-1H (homonuclear Hartmann-Hahn) data was approximately 18 h.

Synthesis and absolute configuration of P-chiral O-isopropyl oligonucleotide triesters

Abstract New O -isopropylphosphomorpholidite reagents provided the title compounds as mixtures of P-chiral diastereomers, which were separated by HPLC for enzymatic digestion studies and assignment of configuration at phosphorus by chemical correlation with known phosphorothioates.

Intramolecular binding of a proximal PPII helix to an SH3 domain in the fusion protein SH3Hck : PPIIhGAP.

SH3 domains are a conserved feature of many nonreceptor protein tyrosine kinases, such as Hck, and often function in substrate recruitment and regulation of kinase activity. SH3 domains modulate kinase activity by binding to polyproline helices (PPII helix) either intramolecularly or in target proteins. The preponderance of bimolecular and distal interactions between SH3 domains and PPII helices led us to investigate whether proximal placement of a PPII helix relative to an SH3 domain would result in tight, intramolecular binding. We have fused the PPII helix region of human GAP to the C-terminus of Hck SH3 and expressed the recombinant fusion protein in Eschericheria coli. The fusion protein, SH3Hck: PPIIhGAP, folded spontaneously into a structure in which the PPII helix was bound intramolecularly to the hydrophobic crevice of the SH3 domain. The SH3Hck: PPIIhGAP fusion protein is useful for investigating SH3: PPII helix interactions, for studying concepts in protein folding and design, and may represent a protein structural motif that is widely distributed in nature.

Compact Parkin only: insights into the structure of an autoinhibited ubiquitin ligase

Mutations in Parkin represent ~50% of disease-causing defects in autosomal recessive-juvenile onset Parkinsons disease (AR-JP). Recently, there have been four structural reports of autoinhibited forms of this RING-IBR-RING (RBR) ubiquitin ligase (E3) by the Gehring, Komander, Johnston and Shaw groups. The important advances from these studies set the stage for the next steps in understanding the molecular basis for Parkinsons disease (PD).

Structural Biophysics of the NusB:NusE Antitermination Complex

In prokaryotic transcription regulation, several host factors form a complex with RNA polymerase and the nascent mRNA. As part of a process known as antitermination, two of these host factors, NusB and NusE, bind to form a heterodimer, which interacts with a specific boxA site on the RNA. The NusB/NusE/boxA RNA ternary complex interacts with the RNA polymerase transcription complex, stabilizing it and allowing transcription past premature termination points. The NusB protein also binds boxA RNA individually and retains all specificity for boxA. However, NusE increases the affinity of RNA to NusB in the ternary complex, which contributes to efficient antitermination. To understand the molecular mechanism of the process, we have determined the structure of NusB from the thermophilic bacterium Aquifex aeolicus and studied the interaction of NusB and NusE. We characterize this binding interaction using NMR, isothermal titration calorimetry, gel filtration, and analytical ultracentrifugation. The binding site of NusE on NusB was determined using NMR chemical shift perturbation studies. We have also determined the NusE binding site in the ternary Escherichia coli NusB/NusE/boxA RNA complex and show that it is very similar to that in the NusB/NusE complex. There is one loop of residues (from 113 to 118 in NusB) affected by NusE binding in the ternary complex but not in the binary complex. This difference may be correlated to an increase in binding affinity of RNA for the NusB/NusE complex.

Determination of the structure of the Escherichia coli K100 capsular polysaccharide, cross-reactive with the capsule from type b Haemophilus influenzae

The structure of the Escherichia coli K100 capsular polysaccharide, cross-reactive with that from type b Haemophilus influenzae, was determined by using a combination of chemical and spectroscopic techniques. The structure of the K100 repeating unit was found to be----3)-beta-D-Ribf-(1----2)-D-ribitol-5-(PO4----. The K100 polysaccharide is thus identical in composition to, but different in linkage from, the H. influenzae type b capsular polysaccharide, which has beta-D-Ribf-(1----1)-D-ribitol linkages.

Accuracy and precision in the estimation of peak areas and NOE factors. II. The effects of apodization

Abstract The use of apodization functions in the numerical estimation of peak areas and NOE factors in NMR spectra is investigated. The formalism required in such studies is introduced and the effects of exponential and Gaussian apodization are analyzed. Two effects are found to be important, the bias due to the inability to perform an exact integration over the peak, and the effects of instrumental noise. A generalized variance which combines bias and noise in peak area measurements is used to demonstrate the superiority of the Gaussian apodization function over the exponential.

Solution structure of lysine-free (K0) ubiquitin.

Lysine‐free ubiquitin (K0‐Ub) is commonly used to study the ubiquitin‐signaling pathway, where it is assumed to have the same structure and function as wild‐type ubiquitin (wt‐Ub). However, the K0‐Ub 15N heteronuclear single quantum correlation NMR spectrum differs significantly from wt‐Ub and the melting temperature is depressed by 19°C, raising the question of the structural integrity and equivalence to wt‐Ub. The three‐dimensional structure of K0‐Ub was determined by solution NMR, using chemical shift and residual dipolar coupling data. K0‐Ub adopts the same backbone structure as wt‐Ub, and all significant chemical shifts can be related to interactions impacted by the K to R mutations.