Barbara Pioselli

PEGylation Promotes Hemoglobin Tetramer Dissociation

Hemoglobin conjugated with poly(ethylene glycol) (PEG) acts as an oxygen carrier free in plasma, substituting red blood cells in supplementing oxygen in hypo-oxygenation pathologies. Given the complexity of oxygen delivery controls, subtle structural and functional differences in PEGylated hemoglobins might be associated with distinct physiological responses and, potentially, adverse effects. We have compared hemoglobin PEGylated under anaerobic conditions, called PEG-Hb(deoxy), with hemoglobin PEGylated under aerobic conditions, called PEG-Hb(oxy), a product that mimics Hemospan, produced by Sangart, Inc. SDS PAGE and MALDI-TOF analyses demonstrated that PEG conjugation yields products characterized by a broad distribution of PEG/hemoglobin ratios. The elution profiles in size-exclusion chromatography indicate that both products exhibit a more homogeneous distribution of molecular weight/hydrodynamic volume under deoxy conditions and at higher concentrations. PEG-Hb(oxy) shows high oxygen affinity, low modulation of allosteric effectors, almost no cooperativity, a fast and monophasic CO binding, and a limited dependence of functional properties on concentration, whereas PEG-Hb(deoxy) exhibits oxygen binding curves that significantly depend on protein concentration, and a slow CO binding, similar to native hemoglobin. PEGylated CO-hemoglobins, probed by flash photolysis, exhibited a lower amplitude for the geminate rebinding phase with respect to native hemoglobin and a negligible T state bimolecular CO rebinding phase. These findings are explained by an increased dissociation of PEGylated hemoglobins into dimers and perturbed T and R states with decreased quaternary transition rates. These features are more pronounced for PEG-Hb(oxy) than PEG-Hb(deoxy). The detected heterogeneity might be a source of adverse effects when PEGylated Hbs are used as blood substitutes.

Tyrosine phenol-lyase and tryptophan indole-lyase encapsulated in wet nanoporous silica gels: Selective stabilization of tertiary conformations.

The pyridoxal 5′‐phosphate‐dependent enzymes tyrosine phenol‐lyase and tryptophan indole‐lyase were encapsulated in wet nanoporous silica gels, a powerful method to selectively stabilize tertiary and quaternary protein conformations and to develop bioreactors and biosensors. A comparison of the enzyme reactivity in silica gels and in solution was carried out by determining equilibrium and kinetic parameters, exploiting the distinct spectral properties of catalytic intermediates and reaction products. The encapsulated enzymes exhibit altered distributions of ketoenamine and enolimine tautomers, increased values of inhibitors dissociation constants, slow attaining of steady‐state in the presence of substrate and substrate analogs, modified steady‐state distribution of catalytic intermediates, and a sixfold–eightfold decrease of specific activities. This behavior can be rationalized by a reduced conformational flexibility for the encapsulated enzymes and a selective stabilization of either the open (inactive) or the closed (active) form of the enzymes. Despite very similar structures and catalytic mechanisms, the influence of encapsulation is more pronounced for tyrosine phenol‐lyase than tryptophan indole‐lyase. This finding indicates that subtle structural and dynamic differences can lead to distinct interactions of the protein with the gel matrix.

Confinement and crowding effects on tryptophan synthase α2β2 complex

Biological molecules experience in vivo a highly crowded environment. The investigation of the functional properties of the tryptophan synthase α2β2 complex either entrapped in wet nanoporous silica gels or in the presence of the crowding agents dextran 70 and ficoll 70 indicates that the rates of the conformational transitions associated to catalysis and regulation are reduced, and an open and less catalytically active conformation is stabilized.

X-Ray Crystallography, Mass Spectrometry and Single Crystal Microspectrophotometry: A Multidisciplinary Characterization of Catechol 1,2 Dioxygenase.

Intradiol-cleaving catechol 1,2 dioxygenases are Fe(III) dependent enzymes that act on catechol and substituted catechols, including chlorocatechols pollutants, by inserting molecular oxygen in the aromatic ring. Members of this class are the object of intense biochemical investigations aimed at the understanding of their catalytic mechanism, particularly for designing mutants with selected catalytic properties. We report here an in depth investigation of catechol 1,2 dioxygenase IsoB from Acinetobacter radioresistens LMG S13 and its A72G and L69A mutants. By applying a multidisciplinary approach that includes high resolution X-rays crystallography, mass spectrometry and single crystal microspectrophotometry, we characterised the phospholipid bound to the enzyme and provided a structural framework to understand the inversion of substrate specificity showed by the mutants. Our results might be of help for the rational design of enzyme mutants showing a biotechnologically relevant substrate specificity, particularly to be used in bioremediation. This article is part of a Special Issue entitled: Protein Structure and Function in the Crystalline State.

Modulation of expression and polymerization of hemoglobin Polytaur, a potential blood substitute.

Chemically or genetically modified hemoglobins are a therapeutic class indicated for the treatment of a variety of hypo-oxygenation pathologies, severe trauma-related hemorrhages or elective surgery when blood transfusions are refused or not available. Recombinant heterologous hemoglobins offer the possibility of a potentially unlimited production and genetically optimized properties in terms of oxygen affinity, NO reactivity and resistance to autoxidation. Hemoglobin Polytaur is an autopolymerizing human-bovine hybrid mutant, previously obtained as a 500kDa polymer, shown to reduce the infarct volume from focal cerebral ischemia in in vivo animal models. In this work, hemoglobin Polytaur polymerization, carried out under conditions to minimize heme oxidation and modification, resulted in a 180kDa cyclic homogeneous trimer of hemoglobin tetramers. This novel oligomer was characterized by electrophoresis, MALDI-TOF mass spectrometry and gel filtration. The size and the oxygen binding properties were shown to be ideally suited for its use as a blood substitute. Co-expression with the human α hemoglobin-stabilizing protein (AHSP), a chaperone that assists hemoglobin folding in vivo, resulted in an unexpected decrease in yield and in unusual spectroscopic and functional properties, suggesting the formation of strong protein-protein interactions that reduce the expression, hinder the tetramer assembly and prevent purification.

Electrophoretic analysis of PEGylated hemoglobin-based blood substitutes.

Polyethylene glycol (PEG)-conjugated hemoglobins, a novel class of blood substitutes, were investigated by a combination of native and denaturing one- and two-dimensional polyacrylamide gel electrophoresis (PAGE) coupled with the microspectrophotometric characterization of single bands and the functional analysis of electrophoretically separated fractions. For these intrinsically heterogeneous products, the molecular mass, the size distribution, and the degree of PEGylation are strictly correlated to their side effects and, therefore, are crucial pieces of information to evaluate their safety and efficacy. The PEGylation pattern was shown to strongly depend on the quaternary conformation of hemoglobin during the reaction, and the degree of conjugation was shown to correlate with the oxygen binding properties of the individual electrophoretically separated fractions. Moreover, small but not negligible fractions of underivatized tetramers, known to be responsible for serious side effects, were detected even in preparations with a high average degree of PEGylation. Overall, this approach might be exploited to characterize other products of protein PEGylation, an increasingly relevant technology for the optimization of the pharmacokinetic properties of protein-based drugs.

Role of histidine 148 in stability and dynamics of a highly fluorescent GFP variant

The armory of GFP mutants available to biochemists and molecular biologists is huge. Design and selection of mutants are usually driven by tailored spectroscopic properties, but some key aspects of stability, folding and dynamics of selected GFP variants still need to be elucidated. We have prepared, expressed and characterized three H148 mutants of the highly fluorescent variant GFPmut2. H148 is known to be involved in the H-bonding network surrounding the chromophore, and all the three mutants, H148G, H148R and H148K, show increased pKa values of the chromophore. Only H148G GFPmut2 (Mut2G) gave good expression and purification yields, indicating that position 148 is critical for efficient folding in vivo. The chemical denaturation of Mut2G was monitored by fluorescence emission, absorbance and far-UV circular dichroism spectroscopy. The mutation has little effect on the spectroscopic properties of the protein and on its stability in solution. However, the unfolding kinetics of the protein encapsulated in wet nanoporous silica gels, a system that allows to stabilize conformations that are poorly or only transiently populated in solution, indicate that the unfolding pathway of Mut2G is markedly different from the parent molecule. In particular, encapsulation allowed to identify an unfolding intermediate that retains a native-like secondary structure despite a destructured chromophore environment. Thus, H148 is a critical residue not only for the chromophoric and photodynamic properties, but also for the correct folding of GFP, and its substitution has great impact on expression yields and stability of the mature protein.

From meat to food: the proteomics assessment

Farm animal meat is a worldwide food with poultry, pork and bovine meat supplying a large portion of proteins to human diet. Because animal muscles cannot be consumed immediately after slaughtering, aging is required to achieve the transformation of muscles to meat. This process is associated with a complex pattern of molecular events that depends on many variables, including animal genetic profile, diet, slaughtering procedures and temperatures. Correlations between such variables and protein pattern have been and are still being thoroughly studied applying proteomic methods [1–4].

Quenching of tryptophan fluorescence in a highly scattering solution: Insights on protein localization in a lung surfactant formulation

CHF5633 (Chiesi Farmaceutici, Italy) is a synthetic surfactant developed for respiratory distress syndrome replacement therapy in pre-term newborn infants. CHF5633 contains two phospholipids (dipalmitoylphosphatidylcholine and 1-palmitoyl-2oleoyl-sn-glycero-3-phosphoglycerol sodium salt), and peptide analogues of surfactant protein C (SP-C analogue) and surfactant protein B (SP-B analogue). Both proteins are fundamental for an optimal surfactant activity in vivo and SP-B genetic deficiency causes lethal respiratory failure after birth. Fluorescence emission of the only tryptophan residue present in SP-B analogue (SP-C analogue has none) could in principle be exploited to probe SP-B analogue conformation, localization and interaction with other components of the pharmaceutical formulation. However, the high light scattering activity of the multi-lamellar vesicles suspension characterizing the pharmaceutical surfactant formulation represents a challenge for such studies. We show here that quenching of tryptophan fluorescence and Singular Value Decomposition analysis can be used to accurately calculate and subtract background scattering. The results indicate, with respect to Trp microenvironment, a conformationally homogeneous population of SP-B. Trp is highly accessible to the water phase, suggesting a surficial localization on the membrane of phospholipid vesicles, similarly to what observed for full length SP-B in natural lung surfactant, and supporting an analogous role in protein anchoring to the lipid phase.