Structural analysis of a highly glycosylated and unliganded gp120-based antigen using mass spectrometry.

Structural characterization of the HIV-1 envelope protein gp120 is very important for providing an understanding of the protein's immunogenicity and its binding to cell receptors. So far, the crystallographic structure of gp120 with an intact V3 loop (in the absence of a CD4 coreceptor or antibody) has not been determined. The third variable region (V3) of the gp120 is immunodominant and contains glycosylation signatures that are essential for coreceptor binding and entry of the virus into T-cells.

Three-dimensional structure of cofilin bound to monomeric actin derived by structural mass spectrometry data.

The cytoskeletal protein, actin, has its structure and function regulated by cofilin. In the absence of an atomic resolution structure for the actin/cofilin complex, the mechanism of cofilin regulation is poorly understood. Theoretical studies based on the similarities of cofilin and gelsolin segment 1 proposed the cleft between subdomains 1 and 3 in actin as the cofilin binding site.

Biochemical implications of a three-dimensional model of monomeric actin bound to magnesium-chelated ATP.

Actin structure is of intense interest in biology due to its importance in cell function and motility mediated by the spatial and temporal regulation of actin monomer-filament interconversions in a wide range of developmental and disease states. Despite this interest, the structure of many functionally important actin forms has eluded high-resolution analysis. Due to the propensity of actin monomers to assemble into filaments structural analysis of Mg-bound actin monomers has proven difficult, whereas high-resolution structures of actin with a diverse array of ligands that preclude polymerization have been quite successful.

Radiolytic protein footprinting with mass spectrometry to probe the structure of macromolecular complexes.

Structural proteomics approaches using mass spectrometry are increasingly used in biology to examine the composition and structure of macromolecules. Hydroxyl radical-mediated protein footprinting using mass spectrometry has recently been developed to define structure, assembly, and conformational changes of macromolecules in solution based on measurements of reactivity of amino acid side chain groups with covalent modification reagents. Accurate measurements of side chain reactivity are achieved using quantitative liquid-chromatography-coupled mass spectrometry, whereas the side chain modification sites are identified using tandem mass spectrometry.

Structure and dynamics of the actin filament.

The structures of filamentous Mg-ATP-actin (F actin) in the presence and absence of KCl have been mapped with hydroxyl radicals (*OH) generated by synchrotron X-ray radiolysis. Proteolysis and mass spectrometry (MS) analysis revealed 52 reactive side-chain sites from 27 distinct peptides within actin. The reactivities of these probe sites with *OH in the F-actin states are compared with those of Mg-ATP-G-actin (monomers) analyzed previously [Guan, J.

Principles of RNA compaction: insights from the equilibrium folding pathway of the P4-P6 RNA domain in monovalent cations.

Counterions are required for RNA folding, and divalent metal ions such as Mg(2+) are often critical. To dissect the role of counterions, we have compared global and local folding of wild-type and mutant variants of P4-P6 RNA derived from the Tetrahymena group I ribozyme in monovalent and in divalent metal ions. A remarkably simple picture of the folding thermodynamics emerges.

Semi-automated, single-band peak-fitting analysis of hydroxyl radical nucleic acid footprint autoradiograms for the quantitative analysis of transitions.

Hydroxyl radical footprinting can probe the solvent accessibility of the ribose moiety of the individual nucleotides of DNA and RNA. Semi-automated analytical tools are presented for the quantitative analyses of nucleic acid footprint transitions in which processes such as folding or ligand binding are followed as a function of time or ligand concentration. Efficient quantitation of the intensities of the electrophoretic bands comprising the footprinting reaction products is achieved by fitting a series of Lorentzian curves to line profiles obtained from gels utilizing sequentially relaxed constraints consistent with electrophoretic mobility.

DNA binding provides a molecular strap activating the adenovirus proteinase.

Human adenovirus proteinase (AVP) requires two cofactors for maximal activity: pVIc, a peptide derived from the C terminus of adenovirus precursor protein pVI, and the viral DNA. Synchrotron protein footprinting was used to map the solvent accessible cofactor binding sites and to identify conformational changes associated with the binding of cofactors to AVP. The binding of pVIc alone or pVIc and DNA together to AVP triggered significant conformational changes adjacent to the active site cleft sandwiched between the two AVP subdomains.

Radiolytic modification of basic amino acid residues in peptides: probes for examining protein-protein interactions.

Protein footprinting utilizing hydroxyl radicals coupled with mass spectrometry has become a powerful technique for mapping the solvent accessible surface of proteins and examining protein-protein interactions in solution. Hydroxyl radicals generated by radiolysis or chemical methods efficiently react with many amino acid residue side chains, including the aromatic and sulfur-containing residues along with proline and leucine, generating stable oxidation products that are valuable probes for examining protein structure. In this study, we examine the radiolytic oxidation chemistry of histidine, lysine, and arginine for comparison with their metal-catalyzed oxidation products.

Multiple monovalent ion-dependent pathways for the folding of the L-21 Tetrahymena thermophila ribozyme.

Synchrotron hydroxyl radical (*OH) footprinting is a technique that monitors the local changes in solvent accessibility of the RNA backbone on milliseconds to minutes time-scales. The Mg(2+)-dependent folding of the L-21 Sca 1 Tetrahymena thermophila ribozyme has been followed using this technique at an elevated concentration of monovalent ion (200 mM NaCl) and as a function of the initial annealing conditions and substrate. Previous studies conducted at low concentrations of monovalent ion displayed sequential folding of the P4-P6 domain, the peripheral helices and the catalytic core, with each protection displaying monophasic kinetics.

Probing the structural dynamics of nucleic acids by quantitative time-resolved and equilibrium hydroxyl radical "footprinting".

For many years, hydroxyl radical footprinting has been an insightful probe of the solvent accessibility of local regions of nucleic acid structure. Recently, quantitative applications of this technique have been developed that allow time-resolved and equilibrium analysis of transitions involving nucleic acid ligand binding and conformation change to be analyzed incisively.

Monovalent cations mediate formation of native tertiary structure of the Tetrahymena thermophila ribozyme.

The formation of individual tertiary contacts of the Tetrahymena L-21 Sca I ribozyme has been monitored by hydroxyl radical footprinting and its global conformation by analytical ultracentrifugation as a function of monovalent ion concentration in the absence of divalent ions. Advanced methods of data analysis, which allow the hydroxyl radical reactivity of every nucleotide to be quantified, permit monitoring of each and every structural element of the RNA. Monovalent ion-mediated global compaction of the ribozyme is accompanied by the formation of native tertiary contacts; most native tertiary contacts are evident except several that are located near where divalent ions are observed in crystallographic structures.