An "Onion-like" Model of Protein Unfolding: Collective versus Site Specific Approaches.

Approximating protein unfolding by an all-or-none cooperative event is a convenient assumption that can provide precious global information on protein stability. It is however quickly emerging that the scenario is far more complex and that global denaturation curves often hide a rich heterogeneity of states that are largely probe dependent. In this review, we revisit the importance of gaining site-specific information on the unfolding process. We focus on nuclear magnetic resonance, as this is the main technique able to provide site-specific information. We review historical and most modern approaches that have allowed an appreciable advancement of the field of protein folding. We also demonstrate how unfolding is a reporter dependent event, suggesting the outmost importance of selecting the reporter carefully.

A S-adenosylmethionine methyltransferase-like domain within the essential, Fe-S-containing yeast protein Dre2.

Yeast Dre2 is an essential Fe-S cluster-containing protein that has been implicated in cytosolic Fe-S protein biogenesis and in cell death regulation in response to oxidative stress. Its absence in yeast can be complemented by the human homologous antiapoptotic protein cytokine-induced apoptosis inhibitor 1 (also known as anamorsin), suggesting at least one common function. Using complementary techniques, we have investigated the biochemical and biophysical properties of Dre2. We show that it contains an N-terminal domain whose structure in solution consists of a stable well-structured monomer with an overall typical S-adenosylmethionine methyltransferase fold lacking two α-helices and a ß-strand. The highly conserved C-terminus of Dre2, containing two Fe-S clusters, influences the flexibility of the N-terminal domain. We discuss the hypotheses that the activity of the N-terminal domain could be modulated by the redox activity of Fe-S clusters containing the C-terminus domain in vivo.

Structural bases for the interaction of frataxin with the central components of iron-sulphur cluster assembly.

Reduced levels of frataxin, an essential protein of as yet unknown function, are responsible for causing the neurodegenerative pathology Friedreich's ataxia. Independent reports have linked frataxin to iron-sulphur cluster assembly through interactions with the two central components of this machinery: desulphurase Nfs1/IscS and the scaffold protein Isu/IscU. In this study, we use a combination of biophysical methods to define the structural bases of the interaction of CyaY (the bacterial orthologue of frataxin) with the IscS/IscU complex. We show that CyaY binds IscS as a monomer in a pocket between the active site and the IscS dimer interface. Recognition does not require iron and occurs through electrostatic interactions of complementary charged residues. Mutations at the complex interface affect the rates of enzymatic cluster formation. CyaY binding strengthens the affinity of the IscS/IscU complex. Our data suggest a new paradigm for understanding the role of frataxin as a regulator of IscS functions.

A major IgE epitope-containing grass pollen allergen domain from Phl p 5 folds as a four-helix bundle.

Phl p 5, a 29 kDa major allergen from timothy grass pollen, is one of the most reactive members of group 5 allergens. Its sequence comprises two repeats of a novel alanine-rich motif (AR) whose structure and allergenic response are still mostly unknown. We report here a structural characterization of an immunodominant fragment of Phl p 5, Phl p 5(56-165) which comprises the first AR repeat. Recombinant (r)Phl p 5(56-165) was expressed in Escherichia coli, purified to homogeneity and shown to be sufficient to react with serum IgE from 90% of grass pollen allergic patients. Using NMR spectroscopy, we show conclusively that the fragment forms a compact globular domain which is, however, prone to degradation with time. The rPhl p 5(56-165) fold consists of a four-helix bundle held together by hydrophobic interactions between the aromatic rings and aliphatic side chains. This evidence gives clear indications about the structure of the full-length Phl p 5 and provides a rational basis for finding ways to stabilize the fold and designing therapeutic vaccines against grass pollen allergy.