Manuel Iglesias-Bexiga scite author profile

WW domains are the smallest naturally independent beta-sheet protein structures available to date and constitute attractive model systems for investigating the determinants of beta-sheet folding and stability. Nonetheless, their small size and low cooperativity pose a difficult challenge for a quantitative analysis of the folding equilibrium. We describe here a comprehensive thermodynamic characterization of the conformational equilibrium of the fourth WW domain from the human ubiquitin ligase Nedd4 (hNedd4-WW4) using a combination of calorimetric and spectroscopic techniques with several denaturing agents (temperature, pH, and chemical denaturants). Our results reveal that even though the experimental data can be described in terms of a two-state equilibrium, spectral data together with anomalous values for some thermodynamic parameters (a strikingly low temperature of maximum stability, a higher than expected native-state heat capacity, and a small specific enthalpy of unfolding) could be indicative of more complex types of equilibria, such as one-state downhill folding or alternative native conformations. Moreover, double-perturbation experiments reveal some features that, in spite of the apparent linear correlation between the thermodynamic parameters, seem to be indicative of a complex conformational equilibrium in the presence of urea. In summary, the data presented here point toward the existence of a low-energy barrier between the different macrostates of hNedd4-WW4, placing it at the frontier of cooperative folding.

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WW Domains of the Yes-Kinase-Associated-Protein (YAP) Transcriptional Regulator Behave as Independent Units with Different Binding Preferences for PPxY Motif-Containing Ligands

Iglesias-Bexiga

Castillo

Cobos

et al. 2015

PLoS ONE

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YAP is a WW domain-containing effector of the Hippo tumor suppressor pathway, and the object of heightened interest as a potent oncogene and stemness factor. YAP has two major isoforms that differ in the number of WW domains they harbor. Elucidating the degree of co-operation between these WW domains is important for a full understanding of the molecular function of YAP. We present here a detailed biophysical study of the structural stability and binding properties of the two YAP WW domains aimed at investigating the relationship between both domains in terms of structural stability and partner recognition. We have carried out a calorimetric study of the structural stability of the two YAP WW domains, both isolated and in a tandem configuration, and their interaction with a set of functionally relevant ligands derived from PTCH1 and LATS kinases. We find that the two YAP WW domains behave as independent units with different binding preferences, suggesting that the presence of the second WW domain might contribute to modulate target recognition between the two YAP isoforms. Analysis of structural models and phage-display studies indicate that electrostatic interactions play a critical role in binding specificity. Together, these results are relevant to understand of YAP function and open the door to the design of highly specific ligands of interest to delineate the functional role of each WW domain in YAP signaling.

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PL3 Amidase, a Tailor-made Lysin Constructed by Domain Shuﬄing with Potent Killing Activity against Pneumococci and Related Species

et al. 2016

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The emergence and spread of antibiotic-resistant bacteria is pushing the need of alternative treatments. In this context, phage therapy is already a reality to successfully fight certain multiresistant bacteria. Among different phage gene products, murein hydrolases responsible of phage progeny liberation (also called lysins or endolysins) are weapons that target specific peptidoglycan bonds, leading to lysis and death of susceptible bacteria when added from the outside. In the pneumococcal system, all but one phage murein hydrolases reported to date share a choline-binding domain that recognizes cell walls containing choline residues in the (lipo)teichoic acids. Some purified pneumococcal or phage murein hydrolases, as well as several chimeric proteins combining natural catalytic and cell wall-binding domains (CBDs) have been used as effective antimicrobials. In this work we have constructed a novel chimeric N-acetylmuramoyl-L-alanine amidase (PL3) by fusing the catalytic domain of the Pal amidase (a phage-coded endolysin) to the CBD of the LytA amidase, the major pneumococcal autolysin. The physicochemical properties of PL3 and the bacteriolytic effect against several pneumococci (including 48 multiresistant representative strain) and related species, like Streptococcus pseudopneumoniae, Streptococcus mitis, and Streptococcus oralis, have been studied. Results have shown that low doses of PL3, in the range of 0.5–5 μg/ml, are enough to practically sterilize all choline-containing strains tested. Moreover, a single 20-μg dose of PL3 fully protected zebrafish embryos from infection by S. pneumoniae D39 strain. Importantly, PL3 keeps 95% enzymatic activity after 4 weeks at 37°C and can be lyophilized without losing activity, demonstrating a remarkable robustness. Such stability, together with a prominent efficacy against a narrow spectrum of human pathogens, confers to PL3 the characteristic to be an effective therapeutic. In addition, our results demonstrate that the structure/function-based domain shuﬄing approach is a successful method to construct tailor-made endolysins with higher bactericidal activities than their parental enzymes.

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