Julia Wirmer scite author profile

Protein folding and unfolding are coupled to a range of biological phenomena, from the regulation of cellular activity to the onset of neurodegenerative diseases. Defining the nature of the conformations sampled in nonnative proteins is crucial for understanding the origins of such phenomena. We have used a combination of nuclear magnetic resonance (NMR) spectroscopy and site-directed mutagenesis to study unfolded states of the protein lysozyme. Extensive clusters of hydrophobic structure exist within the wild-type protein even under strongly denaturing conditions. These clusters involve distinct regions of the sequence but are all disrupted by a single point mutation that replaced residue Trp62 with Gly located at the interface of the two major structural domains in the native state. Thus, nativelike structure in the denatured protein is stabilized by the involvement of Trp62 in nonnative and long-range interactions.

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Modulation of Compactness and Long‐Range Interactions of Unfolded Lysozyme by Single Point Mutations

Wirmer

Schlörb

Klein‐Seetharaman

et al. 2004

Angew Chem Int Ed

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The non‐native states of the model protein hen lysozyme (native state shown in picture) were investigated by using site‐directed mutagenesis in combination with high‐resolution NMR spectroscopy. The disruptions of the interactions between hydrophobic clusters by single point mutations dramatically alter the overall compactness of the unfolded state: single point mutations can turn a compact unfolded state into an extended state.

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Motional properties of unfolded ubiquitin: a model for a random coil protein

2006

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The characterization of unfolded states of proteins has recently attracted considerable interest, as the residual structure present in these states may play a crucial role in determining their folding and misfolding behavior. Here, we investigated the dynamics in the denatured state of ubiquitin in 8 M urea at pH2. Under these conditions, ubiquitin does not have any detectable local residual structure, and uniform 15N relaxation rates along the sequence indicate the absence of motional restrictions caused by residual secondary structure and/or long-range interactions. A comparison of different models to predict relaxation data in unfolded proteins suggests that the subnanosecond dynamics in unfolded states depend on segmental motions only and do not show a dependence on the residue type but for proline and glycine residues.

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Julia Wirmer

Long-Range Interactions Within a Nonnative Protein

Modulation of Compactness and Long‐Range Interactions of Unfolded Lysozyme by Single Point Mutations

Motional properties of unfolded ubiquitin: a model for a random coil protein

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