H. Jane Dyson

Folding of immunogenic peptide fragments of proteins in water solution: I. Sequence requirements for the formation of a reverse turn

A systematic examination by 1H nuclear magnetic resonance of the population of beta-turn-containing conformers in several series of short linear peptides in water solution has demonstrated a dependence on amino acid sequence which has important implications for initiation of protein folding. The peptides consist of a number of variants of the sequence Tyr-Pro-Tyr-Asp, the trans isomer of which was previously shown to contain a reverse turn in water. Two-dimensional rotating-frame nuclear Overhauser effect spectroscopy provides unequivocal evidence that substantial populations of reverse turn conformations occur in water solutions of certain of these peptides. In the unfolded state, the peptides adopt predominantly extended chain (beta) conformations in water. It appears probable from the nuclear Overhauser effect connectivities observed that the reverse turns in the trans isomers are predominantly type II. The low temperature coefficient of the amide proton resonance of the residue at position 4 of the turn suggests the presence of an intramolecular hydrogen bond. The presence of the beta-turn conformation has been confirmed for certain peptides by circular dichroism measurements. Substitutions at positions 3 and 4 in the sequence Tyr-Pro-Tyr-Asp-Val can enhance or abolish the beta-turn population in the trans peptide isomers. The residue at position 3 of the turn is the primary determinant of its stability. A small amount of additional stabilization appears to result from an electrostatic interaction between the side-chain of residue 4 and the unblocked amino terminus. For peptides of the series Tyr-Pro-X-Asp-Val, where X represents all L-amino acid except Trp and Pro, the temperature coefficient of the Asp4 amide proton resonance provides a measure of the beta-turn population. The beta-turn populations in water solution measured in this way correlate with the beta-turn probabilities determined from protein crystal structures. This indicates that it is frequently the local amino acid sequence, rather than medium- to long-range interactions in the folded protein, that determines the beta-turn conformation in the folded state. Such sequences are excellent candidates for protein folding initiation sites. A high population of structured forms appears to be present in the cis isomer of certain of the peptides, as shown by a considerable increase in the proportion of the cis isomer and by measurement of nuclear Overhauser effects and 3JN alpha coupling constants.(ABSTRACT TRUNCATED AT 400 WORDS)

Equilibrium NMR studies of unfolded and partially folded proteins.

Multidimensional NMR studies of proteins in unfolded and partially folded states give unique insights into their structures and dynamics and provide new understanding of protein folding and function.

Structural differences between oxidized and reduced thioredoxin monitored by two-dimensional 1H NMR spectroscopy

Two‐dimensional high resolution NMR techniques have been applied to study the structural differences between the oxidized and reduced forms of Escherichia coli thioredoxin in solution. Sequential proton resonance assignments indicate only limited conformational changes; major chemical shift differences are found for a few residues in a β‐strand immediately preceding the active site S◀S bridge and the active site itself. Additional resonance shifts are observed for several residues distant in the primary sequence. The X‐ray structure of oxidized thioredoxin shows that these residues form a flat hydrophobic surface, close to the active site S◀S bridge, which is probably involved in interactions with other protein molecules.

Assignment of the 15N NMR spectra of reduced and oxidized Escherichia coli thioredoxin

As a necessary first step in the use of heteronuclear correlated spectra to obtain high resolution solution structures of the protein, assignment of the 15N NMR spectra of reduced and oxidized Escherichia coli thioredoxin (M r 12 000) uniformly labeled with 15N has been performed. The 15N chemical shifts of backbone amide nitrogen atoms have been determined for both oxidation states of thioredoxin using 15N‐1H correlated and two‐dimensional heteronuclear single‐quantum coherence (HSQC) TOCSY and NOESY spectra. The backbone assignments are complete, except for the proline imide nitrogen resonances and include Gly33, whose amide proton resonance is difficult to observe in homonuclear 1H spectra. The differences in the 15N chemical shift between oxidized and reduced thioredoxin, which occur mainly in the vicinity of the two active site cysteines, including residues distant in the amino acid sequence which form a hydrophobic surface close to the active site, are consistent with the differences observed for proton chemical shifts in earlier work on thioredoxin.

Antigen-antibody interactions: an NMR approach.

With recent advances in methodology, it now appears that NMR can be used at an unprecedented level of sophistication to obtain new insights into the solution structure and dynamics of the antibody combining site, both free and in its complex with antigen. Most promising in this regard is the Fv fragment (molecular weight approximately 25 kD) which can be produced by genetic engineering in a form suitable for NMR studies. Isotopic labeling is required to make specific resonance assignments. NMR can also provide information on the conformational preferences of immunogenic peptides and can be used to probe the conformation and dynamics of peptides (appropriately labeled with 13C or 15N) bound to the Fab fragment (molecular weight approximately 50 kD) of antipeptide antibodies.

Selection by Site‐Directed Antibodies of Small Regions of Peptides which are Ordered in Water

High resolution nuclear magnetic resonance has been used to study a short peptide which corresponds to the antigenic region of a larger peptide immunogen. This work shows that there is a strong conformational preference for a Type II beta-turn in solution. This observation has implications for the nature of the immunogenicity and antigenicity of peptide antigens as well as for the more general question of protein-folding mechanisms.