Waltho Jp scite author profile

Myoglobin has been extensively studied as a model system for protein folding in vitro. As part of an ongoing study of myoglobin folding, we have synthesized a series of peptide fragments corresponding to portions of the sequence of the sperm whale protein. The conformational preferences of these peptides have been investigated by circular dichroism and nuclear magnetic resonance spectroscopy in aqueous solution. In this paper we describe the folding propensities of two peptides (Mb-G and Mb-H), corresponding to the G- and H-helix segments of the myoglobin sequence. The Mb-G peptide shows evidence of a very small population of helical conformations in aqueous solution, both by CD and NMR. By contrast, the monomeric Mb-H peptide is found by CD to adopt a significant population (ca. 30%) of ordered helix and by NMR to populate helical conformations in rapid dynamic equilibrium with unfolded states. The Mb-H peptide undergoes a well-characterized, concentration-dependent monomer-tetramer equilibrium. At peptide concentrations greater than 1 mM there is an increase in the population of helix, to approximately 85% according to the CD spectrum, through self-association to form a tetramer. Both medium-range NOE connectivities and a CD spectrum characteristic of ordered helix are observed at low peptide concentrations, establishing that helical conformations are present in the monomeric state of Mb-H. The relative helicity at various sites throughout the Mb-H peptide has been estimated using a novel method for assessing the distribution of helical populations based on the relative magnitudes of medium-range d alpha beta (i,i+3) NOE connectivities. The population of ordered helix is seen to be highest in the center of the peptide sequence; the ends of the peptide show evidence of pronounced fraying.

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Peptide models of protein folding initiation sites. 3. The G-H helical hairpin of myoglobin

Hc¹,

Merutka²,

Jp³

et al. 1993

Biochemistry

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As part of an extensive dissection of the folding pathway of myoglobin, a series of peptides corresponding to fragments of sperm whale myoglobin have been synthesized, and their conformational preferences investigated using circular dichroism and nuclear magnetic resonance spectroscopy in aqueous solution and in solvent mixtures containing water and trifluoroethanol. The behavior of short fragments corresponding to the sequences of the G- and H-helices of myoglobin and to the turn region between these helices has been described in accompanying papers. At the next level of complexity, peptide model compounds have been synthesized to explore the longer-range interactions which may take place in protein folding after initial secondary structure formation has occurred. A series of disulfide-bridged dimeric peptides containing the complete sequences of the G- and H-helices of myoglobin were synthesized and their conformational preferences examined. CD spectra indicate that disulfide-bridged peptides consisting of two H-helix sequences (Mb-HssH) and of one G- and one H-helix (Mb-GssH) are highly helical in water solution, as a result of intermolecular association. A 51-residue peptide, Mb-GH51, encompassing the entire G-H helical hairpin of myoglobin, including the turn sequence between the two helices, has been successfully synthesized by standard methods. This peptide was designed to be monomeric in aqueous solution. Mb-GH51 does not appear from CD spectra to contain any additional helix in water solution above what would be expected from an equimolar mixture of the G- and H-helix peptides. NMR spectra indicate that the turn conformation observed in shorter peptide fragments is retained in Mb-GH51 in high population.(ABSTRACT TRUNCATED AT 250 WORDS)

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The Role of Gly-4 of Human Cystatin A (Stefin A) in the Binding of Target Proteinases. Characterization by Kinetic and Equilibrium Methods of the Interactions of Cystatin A Gly-4 Mutants with Papain, Cathepsin B, and Cathepsin L

Estrada

Nycander

et al. 1998

Biochemistry

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The importance of the evolutionarily conserved Gly-4 residue for the affinity and kinetics of interaction of cystatin A with several cysteine proteinases was assessed by site-directed mutagenesis. Even the smallest replacement, by Ala, resulted in approximately 1000-, approximately 10- and approximately 6000-fold decreased affinities for papain, cathepsin L, and cathepsin B, respectively. Substitution by Ser gave further 3-8-fold reductions in affinity, whereas the largest decreases, >10(5)-fold, were observed for mutations to Arg and Glu. The kinetics of inhibition of papain by the mutants with small side chains, Ala and Ser, were compatible with a one-step bimolecular reaction similar to that with wild-type cystatin A. The decreased affinities of these mutants for papain and cathepsin L were due exclusively to increased dissociation rate constants, but the reduced affinities for cathepsin B were due also to decreased association rate constants. The latter finding indicates that the intact N-terminal region serves as a guide directing cystatin A to the active site of cathepsin B, as has been proposed for cystatin C. The kinetics of binding of the mutants with charged side chains, Arg and Glu, to papain were consistent with a two-step binding mechanism, in which the mutant side chains are accommodated in the complex by a conformational change. The NMR solution structure of the Ala and Trp mutants showed only minor changes compared with wild-type cystatin A, indicating that the large reductions in affinity for proteinases are not due to altered structures of the mutants. Instead, a side chain larger than a hydrogen atom at position 4 affects the interaction with the proteinase most likely by interfering with the binding of the N-terminal region.

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Structure of a kinetic protein folding intermediate by equilibrium amide exchange

Hosszu

Craven

Parker

et al. 1997

Nat Struct Mol Biol

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Waltho Jp

Peptide models of protein folding initiation sites. 1. Secondary structure formation by peptides corresponding to the G- and H-helixes of myoglobin

Peptide models of protein folding initiation sites. 3. The G-H helical hairpin of myoglobin

The Role of Gly-4 of Human Cystatin A (Stefin A) in the Binding of Target Proteinases. Characterization by Kinetic and Equilibrium Methods of the Interactions of Cystatin A Gly-4 Mutants with Papain, Cathepsin B, and Cathepsin L

Structure of a kinetic protein folding intermediate by equilibrium amide exchange

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