Serena Faggiano

Ligand migration through the internal hydrophobic cavities in human neuroglobin

Neuroglobin (Ngb), a member of the globin superfamily, was found in the brain of vertebrates and is suggested to play a neuroprotective function under hypoxic conditions by scavenging nitrogen monoxide (NO) through a dioxygenase activity. In order for such a reaction to efficiently take place and to minimize the release of reactive intermediates in the cytosol, the cosubstrates O2 and NO and other unstable reaction intermediates should bind sequentially to docking sites in the protein matrix. We have characterized the accessibility of these sites by analyzing the geminate CO rebinding kinetics to the heme moiety observed upon nanosecond flash photolysis of the Ngb-CO complex encapsulated in silica gels. The geminate rebinding phase showed a remarkable complexity, revealing the presence of a system of secondary docking sites where ligands are stored for hundreds of microseconds. Most kinetics steps display little temperature dependence, demonstrating that ligands can easily migrate through the cavities, except for the slowest reaction intermediate, possibly reflecting a structural conformational change reshaping the system of cavities. This conformational change is unrelated with distal His E7 binding to the heme, as it persists for the HE7L mutant. Overall, data are consistent with the presence of a discrete system of docking sites, possibly acting as reservoirs for the putative cosubstrates and for other reactive species involved in the physiologically relevant reaction.

Time-resolved methods in Biophysics. 2. Monitoring haem proteins at work with nanosecond laser flash photolysis

Haem proteins have long been the most studied proteins in biophysics, and have become paradigms for the characterization of fundamental biomolecular processes as ligand binding and regulatory conformational transitions. The presence of the haem prosthetic group, the absorbance spectrum of which has a ligation sensitive region conveniently located in the UV-visible range, has offered a powerful and sensitive tool for the investigation of molecular functions. The central Fe atom is capable of reversibly binding diatomic ligands, including O(2), CO, and NO. The Fe-ligand bond is photolabile, and a reactive unligated state can be transiently generated with a pulsed laser. The photodissociated ligands quickly rebind to the haem and the process can be monitored by transient absorbance methods. The ligand rebinding kinetics reflects protein dynamics and ligand migration within the protein inner cavities. The characterization of these processes was done in the past mainly by low temperature experiments. The use of silica gels to trap proteins allows the characterization of internal ligand dynamics at room temperature. In order to show the potential of the laser flash photolysis techniques, combined with modern numerical analysis methods, we report experiments conducted on two non-symbiotic haemoglobins from Arabidopsis thaliana. The comparison between time courses recorded on haemoglobins in solution and encapsulated in silica gels allows for the highlighting of different interplays between protein dynamics and ligand migration.

Haemoglobin-based oxygen carriers: research and reality towards an alternative to blood transfusions.

Blood transfusion is the key life-saving treatment in many traumatic emergencies, chronic or acute pathologies, and during or upon surgical interventions. The primary goal of blood transfusion is the fast recovery of oxygen delivery to organs, especially the brain. Furthermore, circulation volume is restored, thus maintaining the blood pressure at levels that guarantee an efficient blood flux. Whereas this secondary need can be fulfilled to some extent by blood expanders, such as colloid- and crystalloid-based solutions, up to now no approved alternative to red cells is available for oxygen supply. The main transfusion active principle, red blood cells, is derived from the voluntary action of blood donors. Transfusions can be and are considered a very safe and effective oxygen-based therapy, provided that detailed guidelines are followed1. This evaluation has been somewhat challenged in recent years2–5. Presently, clinical studies are underway to provide a more solid ground to the safety and efficacy of blood transfusions (examples available at: http://clinicaltrials.gov/ct2/show/{type:clinical-trial,attrs:{text:NCT01038557,term_id:NCT01038557}}NCT01038557 and http://clinicaltrialsfeeds.org/clinical-trials/show/{type:clinical-trial,attrs:{text:NCT00991341,term_id:NCT00991341}}NCT00991341). Indeed, transfusions are exposed to a series of limitations, listed in table I, that can lead to potential health risks. For example, in stored blood the intracellular levels of the haemoglobin allosteric effector 2–3 bisphosphoglycerate (2,3-BPG), that maintains the p50 (the oxygen pressure at 50% saturation) in vivo at 26 torr, decreases in one week from 5 mM to negligible concentrations, resulting in a drop of the p50 to about 12 torr3. The concentration of potassium ions in red cells increases from 4 mM in fresh blood to about 20 mM after three weeks of aging3. In the same time range, lactate concentration increases from about 1 to 15 mM, and solfohaemoglobin (HbSO2) from 30% to almost 100%. The intracellular pH of red cells drops from 7.4 to 6.9 in a few hours and to a value of 6.7 in three weeks3. Furthermore, free haemoglobin, i.e. haemoglobin released due to red cell haemolysis, increases from 5 μM at 3 hours after blood withdrawal to about 20 μM after three weeks3. Free haemoglobin scavenges nitric oxide (NO), the molecule that controls vessel tone, and undergoes oxidation, leading to pro-oxidative radical-based reactions6. Studies on blood units aging have also pointed to adverse effects associated to the decreased capability of red cell haemoglobin to supply nitric oxide4. However, this is a controversial issue7,8.

The role of interruptions in polyQ in the pathology of SCA1.

At least nine dominant neurodegenerative diseases are caused by expansion of CAG repeats in coding regions of specific genes that result in abnormal elongation of polyglutamine (polyQ) tracts in the corresponding gene products. When above a threshold that is specific for each disease the expanded polyQ repeats promote protein aggregation, misfolding and neuronal cell death. The length of the polyQ tract inversely correlates with the age at disease onset. It has been observed that interruption of the CAG tract by silent (CAA) or missense (CAT) mutations may strongly modulate the effect of the expansion and delay the onset age. We have carried out an extensive study in which we have complemented DNA sequence determination with cellular and biophysical models. By sequencing cloned normal and expanded SCA1 alleles taken from our cohort of ataxia patients we have determined sequence variations not detected by allele sizing and observed for the first time that repeat instability can occur even in the presence of CAG interruptions. We show that histidine interrupted pathogenic alleles occur with relatively high frequency (11%) and that the age at onset inversely correlates linearly with the longer uninterrupted CAG stretch. This could be reproduced in a cellular model to support the hypothesis of a linear behaviour of polyQ. We clarified by in vitro studies the mechanism by which polyQ interruption slows down aggregation. Our study contributes to the understanding of the role of polyQ interruption in the SCA1 phenotype with regards to age at disease onset, prognosis and transmission.

Oxygen binding to heme proteins in solution, encapsulated in silica gels, and in the crystalline state.

The determination of accurate oxygen-binding curves for heme-containing proteins is a demanding task. In fact, great care is required in the (i) preparation of accurate gas mixtures at defined oxygen partial pressures, (ii) precise measurement of changes in protein absorbance, (iii) calculation of the fraction of oxygen-containing sites, and (iv) analysis of the dependence of fractional saturation on oxygen pressure using phenomenological or model-dependent equations. Over the years, methods have been developed for the determination of oxygen-binding curves based either on discrete steps in oxygen partial pressure (static method) or on continuous variations (dynamic method). This work presents a novel, versatile setup that allows one to determine oxygen-binding curves for heme and nonheme proteins in solution, encapsulated in wet, nanoporous silica gels, in the crystalline state, and for hemoglobin within single red blood cells. The apparatus is composed of a tandem of high-precision gas mixture generators and either an equilibration chamber coupled to a spectrophotometer cuvette or a gas-tight flow cell, placed on the stage of a microspectrophotometer, for immobilized samples down to a few micrometers in size.

The Ball and Chain of Polyubiquitin Structures

Ubiquitylation is a post-translational modification implicated in several different cellular pathways. The possibility of forming chains through covalent crosslinking between any of the seven lysines, or the initial methionine, and the C terminus of another moiety provides ubiquitin (Ub) with special flexibility in its function in signalling. Here, we review the knowledge accumulated over the past several years about the functions and structural features of polyUb chains. This analysis reveals the need to understand further the functional role of some of the linkages and the structural code that determines recognition of polyUbs by protein partners.

Structural plasticity and functional implications of internal cavities in distal mutants of type 1 non-symbiotic hemoglobin AHb1 from Arabidopsis thaliana.

The increasing number of nonsymbiotic plant hemoglobins discovered in genomic studies in the past decade raises intriguing questions about their physiological role. Among them, the nonsymbiotic hemoglobin AHb1 from Arabidopsis thaliana deserves particular attention, as it combines an extremely high oxygen affinity with an internal hexacoordination of the distal histidine HisE7 to the heme iron in the absence of exogenous ligands. In order to gain insight into the structure-function relationships of the protein, the ligand binding properties of mutants of two conserved residues of the distal cavity, HisE7 --> Leu and PheB10 --> Leu, were investigated by experimental and computational studies and compared to results determined for the wild type (wt) protein. The Fe(2+)-deoxy HisE7 --> Leu mutant exists, as expected, in the pentacoordinated form, while a mixture of penta- and hexacoordinated forms is found for the PheB10 --> Leu mutant, with an equilibrium shifted toward the pentacoordinated form with respect to the wt protein. Spectroscopic studies of the complexes of CO and CN(-) with AHb1 and its mutants show a subtle interplay of steric and electrostatic effects by distal residues on the ligand binding to the heme. Moreover, stopped-flow and flash photolysis experiments reveal substantial kinetic differences triggered by those mutations, which are particularly manifested in the enhanced geminate rebinding and bimolecular association rate. These findings are discussed in light of the drastic alterations found by molecular dynamics simulations in the nature and distribution of internal cavities in the protein matrix of the mutants, revealing an extremely large sensitivity of the protein structure to changes in distal HisE7 and PheB10 residues. Overall, data are consistent with the putative NO-dioxygenase activity attributed to AHb1.

The missing links to link ubiquitin: Methods for the enzymatic production of polyubiquitin chains

Attachment of ubiquitin (Ub) as monoUb and polyUb chains of different lengths and linkages to proteins plays a dominant role in very different regulatory mechanisms. Therefore, the study of polyUb chains has assumed a central interest in biochemistry and structural biology. An essential step necessary to allow inxa0vitro biochemical and structural studies of polyUbs is the production of their chains in high quantities and purity. This is not always an easy task and can be achieved both enzymatically and chemically. Previous reviews have covered chemical cross-linking exhaustively. In this review, we concentrate on the different approaches developed so far for the enzymatic production of different Ub chains. These strategies permit a certain flexibility in the production of chains with various linkages and lengths. We critically describe the available methods and comment on advantages and limitations. It is clear that the field is mature to study most of the possible links, but some more work needs to be done to complete the picture and to exploit the current methodologies for understanding in full the Ub code.

Histidine E7 dynamics modulates ligand exchange between distal pocket and solvent in AHb1 from Arabidopsis thaliana.

The distal His residue in type 1 nonsymbiotic hemoglobin AHb1 from Arabidopsis thaliana plays a fundamental role in stabilizing the bound ligand. This residue might also be important in regulating the accessibility to the distal cavity. The feasibility of this functional role has been examined using a combination of experimental and computational methods. We show that the exchange of CO between the solvent and the reaction site is modulated by a swinging motion of the distal His, which opens a channel that connects directly the distal heme pocket with the solvent. The nearby PheB10 aids the distal His in the stabilization of the bound ligand by providing additional protection against solvation. Overall, these findings provide evidence supporting the functional implications of the conformational rearrangement found for the distal His in AHb1, which mimics the gating role proposed for the same residue in myoglobin.

Characterization of the Conformational Fluctuations in the Josephin Domain of Ataxin-3

As for a variety of other molecular recognition processes, conformational fluctuations play an important role in the cleavage of polyubiquitin chains by the Josephin domain of ataxin-3. The interaction between Josephin and ubiquitin appears to be mediated by the motions of α-helical hairpin that is unusual among deubiquitinating enzymes. Here, we characterized the conformational fluctuations of the helical hairpin by incorporating NMR measurements as replica-averaged restraints in molecular dynamics simulations, and by validating the results by small-angle x-ray scattering measurements. This approach allowed us to define the extent of the helical hairpin motions and suggest a role of such motions in the recognition of ubiquitin.