J S Milne

Bio: J S Milne is an academic researcher from University of Pennsylvania. The author has contributed to research in topics: Peptide sequence & Steric effects. The author has an hindex of 6, co-authored 6 publications receiving 2350 citations.

Primary Structure Effects on Peptide Group Hydrogen Exchange

Abstract: The rate of exchange of peptide group NH hydrogens with the hydrogens of aqueous solvent is sensitive to neighboring side chains. To evaluate the effects of protein side chains, all 20 naturally occurring amino acids were studied using dipeptide models. Both inductive and steric blocking effects are apparent. The additivity of nearest-neighbor blocking and inductive effects was tested in oligo- and polypeptides and, surprisingly, confirmed. Reference rates for alanine-containing peptides were determined and effects of temperature considered. These results provide the information necessary to evaluate measured protein NH to ND exchange rates by comparing them with rates to be expected for the same amino acid sequence is unstructured oligo- and polypeptides. The application of this approach to protein studies is discussed.

Protein stability parameters measured by hydrogen exchange

Abstract: The hydrogen exchange (HX) rates of the slowest peptide group NH hydro- gens in oxidized cytochrome c (equine) are con- trolled by the transient global unfolding equi- librium. These rates can be measured by one- dimensional nuclear magnetic resonance and used to determine the thermodynamic parame- ters of global unfolding at mild solution condi- tions well below the melting transition. The free energy for global unfolding measured by hy- drogen exchange can differ from values found by standard denaturation methods, most nota- bly due to the slow cis-trans isomerization of the prolyl peptide bond. This difference can be quantitatively calculated from basic principles. Even with these corrections, HX experiments at low denaturant concentration measure a free energy of protein stability that rises above the usual linear extrapolation from denaturation data, as predicted by the denaturant binding model of Tanford. o 1994 Wiley-Liss, Inc.

Determinants of protein hydrogen exchange studied in equine cytochrome c.

Abstract: The exchange of a large number of amide hydrogens in oxidized equine cytochrome c was measured by NMR and compared with structural parameters. Hydrogens known to exchange through local structural fluctuations and through larger unfolding reactions were separately considered. All hydrogens protected from exchange by factors greater than 10(3) are in defined H-bonds, and almost all H-bonded hydrogens including those at the protein surface were measured to exchange slowly. H-exchange rates do not correlate with H-bond strength (length) or crystallographic B factors. It appears that the transient structural fluctuation necessary to bring an exchangeable hydrogen into H-bonding contact with the H-exchange catalyst (OH(-)-ion) involves a fairly large separation of the H-bond donor and acceptor, several angstroms at least, and therefore depends on the relative resistance to distortion of immediately neighboring structure. Accordingly, H-exchange by way of local fluctuational pathways tends to be very slow for hydrogens that are neighbored by tightly anchored structure and for hydrogens that are well buried. The slowing of buried hydrogens may also reflect the need for additional motions that allow solvent access once the protecting H-bond is separated, although it is noteworthy that burial in a protein like cytochrome c does not exceed 4 angstroms. When local fluctuational pathways are very slow, exchange can become dominated by a different category of larger, cooperative, segmental unfolding reactions reaching up to global unfolding.

Thermodynamic parameters from hydrogen exchange measurements.

Abstract: Just as exchangeable hydrogens that are controlled by global unfolding can be used to measure thermodynamic parameters at a global level, hydrogens that are exposed to exchange by local unfolding reactions may be used to obtain locally resolved energy parameters. Results with the hemoglobin system demonstrate the ability of HX methods to locate functionally important changes in a protein and to measure the energetic contribution of each. These results offer the promise that HX measurements may be used to delineate, in terms of definable bonds and their energies and interactions, the network of interactions that Hb and other proteins use to produce their various functions.

Molten globule and protein folding.

Abstract: Publisher Summary This chapter describes the present state of the studies of the molten globule state and its role in protein folding and physiological processes Recent data on the intermediates (equilibrium and kinetic), focusing attention on the molten globule state are discussed in the chapter The molten globule has a native-like overall architecture (folding pattern) without including the rigid packing of side chains It is separated by first-order phase transitions from both the native and the unfolded states and represents a third thermodynamic state of protein molecules It is a universal kinetic intermediate in protein folding; the structure of this intermediate is similar to the structure of the equilibrium molten globule It is predicted and confirmed experimentally that the molten globule state can exist in a living cell and plays an important role in a number of physiological processes

NMR Solution Structure of the Human Prion Protein

Abstract: The NMR structures of the recombinant human prion protein, hPrP(23–230), and two C-terminal fragments, hPrP(90–230) and hPrP(121–230), include a globular domain extending from residues 125–228, for which a detailed structure was obtained, and an N-terminal flexibly disordered “tail.” The globular domain contains three α-helices comprising the residues 144–154, 173–194, and 200–228 and a short anti-parallel β-sheet comprising the residues 128–131 and 161–164. Within the globular domain, three polypeptide segments show increased structural disorder: i.e., a loop of residues 167–171, the residues 187–194 at the end of helix 2, and the residues 219–228 in the C-terminal part of helix 3. The local conformational state of the polypeptide segments 187–193 in helix 2 and 219–226 in helix 3 is measurably influenced by the length of the N-terminal tail, with the helical states being most highly populated in hPrP(23–230). When compared with the previously reported structures of the murine and Syrian hamster prion proteins, the length of helix 3 coincides more closely with that in the Syrian hamster protein whereas the disordered loop 167–171 is shared with murine PrP. These species variations of local structure are in a surface area of the cellular form of PrP that has previously been implicated in intermolecular interactions related both to the species barrier for infectious transmission of prion disease and to immune reactions.

Instability, unfolding and aggregation of human lysozyme variants underlying amyloid fibrillogenesis

Abstract: Tissue deposition of soluble proteins as amyloid fibrils underlies a range of fatal diseases. The two naturally occurring human lysozyme variants are both amyloidogenic, and are shown here to be unstable. They aggregate to form amyloid fibrils with transformation of the mainly helical native fold, observed in crystal structures, to the amyloid fibril cross-beta fold. Biophysical studies suggest that partly folded intermediates are involved in fibrillogenesis, and this may be relevant to amyloidosis generally.

Protein Folding Intermediates: Native-State Hydrogen Exchange

Abstract: The hydrogen exchange behavior of native cytochrome c in low concentrations of denaturant reveals a sequence of metastable, partially unfolded forms that occupy free energy levels reaching up to the fully unfolded state. The step from one form to another is accomplished by the unfolding of one or more cooperative units of structure. The cooperative units are entire omega loops or mutually stabilizing pairs of whole helices and loops. The partially unfolded forms detected by hydrogen exchange appear to represent the major intermediates in the reversible, dynamic unfolding reactions that occur even at native conditions and thus may define the major pathway for cytochrome c folding.