NMR analysis of the conformational properties of the trapped on-pathway folding intermediate of the bacterial immunity protein Im7.

Previous work shows that the transiently populated, on-pathway intermediate in Im7 folding contains three of the four native alpha-helices docked around a core stabilised by native and non-native interactions. To determine the structure and dynamic properties of this species in more detail, we have used protein engineering to trap the intermediate at equilibrium and analysed the resulting proteins using NMR spectroscopy and small angle X-ray scattering. Four variants were created.

Determination of an ensemble of structures representing the intermediate state of the bacterial immunity protein Im7.

We present a detailed structural characterization of the intermediate state populated during the folding and unfolding of the bacterial immunity protein Im7. We achieve this result by incorporating a variety of experimental data available for this species in molecular dynamics simulations. First, we define the structure of the exchange-competent intermediate state of Im7 by using equilibrium hydrogen-exchange protection factors.

Ultraviolet resonance Raman studies reveal the environment of tryptophan and tyrosine residues in the native and partially folded states of the E colicin-binding immunity protein Im7.

Understanding the nature of partially folded proteins is a challenging task that is best accomplished when several techniques are applied in combination. Here we present ultraviolet resonance Raman (UVRR) spectroscopy studies of the E colicin-binding immunity proteins, Im7* and Im9*, together with a series of variants of Im7* that are designed to trap a partially folded state at equilibrium. We show that the environments of the tryptophan and tyrosine residues in native wild-type Im7* and Im9* are indistinguishable, in contrast with models for their structures based on X-ray and NMR methods.

Trapping the on-pathway folding intermediate of Im7 at equilibrium.

The four-helical protein Im7 folds via a rapidly formed on-pathway intermediate (k(UI)=3000 s(-1) at pH 7.0, 10 degrees C) that contains three (helices I, II and IV) of the four native alpha-helices. The relatively slow (k(IN)=300 s(-1)) conversion of this intermediate into the native structure is driven by the folding and docking of the six residue helix III onto the developing hydrophobic core.