Conserved folding pathways of alpha-lactalbumin and lysozyme revealed by kinetic CD, fluorescence, NMR, and interrupted refolding experiments.

In this report, it is shown by a combination of stopped-flow CD, fluorescence, and time-resolved NMR studies that the Ca(2+)-induced refolding of bovine alpha-lactalbumin (BLA) at constant denaturant concentration (4 M urea) exhibits triple-exponential kinetics. In order to distinguish between parallel folding pathways and a strictly sequential formation of the native state, interrupted refolding experiments were conducted. We show here that the Ca(2+)-induced refolding of BLA involves parallel pathways and the transient formation of a folding intermediate on the millisecond timescale.

Molecular contacts between antibiotics and the 30S ribosomal particle.

Crystal structures of complexes between ribosomal particles and antibiotics have pinned down very precisely the discrete binding sites of several classes of antibiotics inhibiting protein synthesis. The crystal structures of complexes between various antibiotics and ribosomal particles show definitively that ribosomal RNAs (rRNAs), rather than ribosomal proteins, are overwhelmingly targeted. The antibiotics are found at messenger RNA or transfer RNA binding sites and, most importantly, at pivot locations that are key for the structural rearrangements during the molecular mechanical steps in initiation, elongation, or termination of protein synthesis.

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

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.

Characterization of the unfolded state of bovine alpha-lactalbumin and comparison with unfolded states of homologous proteins.

The unfolded states of three homologous proteins with a very similar fold have been investigated by heteronuclear NMR spectroscopy. Secondary structure propensities as derived from interpretation of chemical shifts and motional restrictions as evidenced by heteronuclear (15)N relaxation rates have been analyzed in the reduced unfolded states of hen lysozyme and the calcium-binding proteins bovine alpha-lactalbumin and human alpha-lactalbumin. For all three proteins, significant deviations from random-coil predictions can be identified; in addition, the unfolded states also differ from each other, despite the fact that they possess very similar structures in their native states.

Heterologous expression of hen egg white lysozyme and resonance assignment of tryptophan side chains in its non-native states.

A new protocol is described for the isotope (15N and 13C,15N) enrichment of hen egg white lysozyme. Hen egg white lysozyme and an all-Ala-mutant of this protein have been expressed in E. coli.

Characterisation of disulfide-bond dynamics in non-native states of lysozyme and its disulfide deletion mutants by NMR.

This report describes NMR-spectroscopic investigations of the conformational dynamics of disulfide bonds in hen-egg-white lysozyme substitution mutants. The following four systems have been investigated: 2SS(alpha), a lysozyme variant that contains C64A, C76A, C80A and C94A substitutions, was studied in water at pH 2 and 3.8 and in urea (8 M, pH 2); 2SS(beta) lysozyme, which has C6S, C30A, C115A and C127A substitutions, was studied in water (pH 2) and urea (8 M, pH 2).

Angular dependence of 1J(Ni,Calphai) and 2J(Ni,Calpha(i-1)) coupling constants measured in J-modulated HSQCs.

A new method to measure 1J(Ni,Calphai) and 2J(Ni,Calpha(i-1)) coupling constants in proteins based on a J-modulated sensitivity enhanced HSQC was introduced. Coupling constants were measured in the denatured and in the native state of ubiquitin and found to depend on the conformation of the protein backbone. Using a combined data set of experimental coupling constants from ubiquitin and staphylococcal nuclease (Delaglio et al.

Long-range interactions within a nonnative protein.

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.

Millisecond Time Resolved Photo-CIDNP NMR Reveals a Non-Native Folding Intermediate on the Ion-Induced Refolding Pathway of Bovine α-Lactalbumin.

Aspects of the structure of the intermediate populated after 200 ms in the Ca -induced refolding of α-lactalbumin have been derived by time-resolved photo-CIDNP NMR methods. Refolding at constant denaturant concentration was initiated by laser-induced ion release from photolabile chelators. The NMR data demonstrated that part of the polypeptide chain in the β-domain of α-lactalbumin samples adopt non-native conformations while a hydrophobic core of the α-domain is already formed.