947 research outputs found
The Sam domain of the lipid phosphatase Ship2 adopts a common model to interact with Arap3-Sam and EphA2-Sam
<p>Abstract</p> <p>Background</p> <p>Sterile alpha motif (Sam) domains are small protein modules that can be involved in homotypic or heterotypic associations and exhibit different functions. Previous studies have demonstrated that the Sam domain of the lipid phosphatase Ship2 can hetero-dimerize with the Sam domain of the PI3K effector protein Arap3.</p> <p>Results</p> <p>Here, we determine the NMR solution structure of Arap3-Sam and implement a multidisciplinary approach consisting of NMR spectroscopy, ITC (Isothermal Titration Calorimetry), mutagenesis and molecular modeling studies to analyze the interaction between Ship2-Sam and Arap3-Sam. This work reveals that Arap3-Sam may associate with Ship2-Sam by adopting a binding mode common to other Sam domains. This binding mode is identical to what we have very recently observed for the association between Ship2-Sam and the Sam domain from the Ephrin A2 receptor.</p> <p>Conclusion</p> <p>Our studies further clarify the structural features that are relevant for Sam-Sam interactions involving Ship2 and give additional hints that could be used for the identification of new molecules able to selectively inhibit Sam-Sam associations.</p
Optimizing the relaxivity of MRI probes at high magnetic field strengths with binuclear GdIIIComplexes
The key criteria to optimize the relaxivity of a Gd(III) contrast agent at high fields (defined
as the region 65 1.5 T) can be summarized as follows: (i) the occurrence of a rotational
correlation time \u3c4R in the range of ca. 0.2\u20130.5 ns; (ii) the rate of water exchange is
not critical, but a \u3c4M < 100 ns is preferred; (iii) a relevant contribution from water
molecules in the second sphere of hydration. In addition, the use of macrocycle-based
systems ensures the formation of thermodynamically and kinetically stable Gd(III)
complexes. Binuclear Gd(III) complexes could potentially meet these requirements. Their
efficiency depends primarily on the degree of flexibility of the linker connecting the two
monomeric units, the absence of local motions and the presence of contribution from
the second sphere water molecules. With the aim to maximize relaxivity (per Gd) over
a wide range of magnetic field strengths, two binuclear Gd(III) chelates derived from
the well-known macrocyclic systems DOTA-monopropionamide and HPDO3A (Gd2L1
and Gd2L2, respectively) were synthesized through a multistep synthesis. Chemical
Exchange Saturation Transfer (CEST) experiments carried out on Eu2L2 at different pH
showed the occurrence of a CEST effect at acidic pH that disappears at neutral pH,
associated with the deprotonation of the hydroxyl groups. Then, a complete 1H and 17O
NMR relaxometric study was carried out in order to evaluate the parameters that govern
the relaxivity associated with these complexes. The relaxivities of Gd2L1 and Gd2L2 (20
MHz, 298 K) are 8.7 and 9.5 mM 121 s 121, respectively, +77% and +106% higher than the
relaxivity values of the corresponding mononuclear GdDOTAMAP-En and GdHPDO3A
complexes. A significant contribution of second sphere water molecules was accounted
for the strong relaxivity enhancement of Gd2L2. MR phantom images of the dinuclear
complexes compared to GdHPDO3A, recorded at 7 T, confirmed the superiority of
Gd2L2. Finally, ab initio (DFT) calculations were performed to obtain information about
the solution structure of the dinuclear complexes
A Long Journey into the Investigation of the Structure–Dynamics–Function Paradigm in Proteins through the Activities of the Palermo Biophysics Group
An overview of the biophysics activity at the Department of Physics and Chemistry Emilio Segrè of the University of Palermo is given. For forty years, the focus of the research has been on the protein structure–dynamics–function paradigm, with the aim of understanding the molecular basis of the relevant mechanisms and the key role of solvent. At least three research lines are identified; the main results obtained in collaboration with other groups in Italy and abroad are presented. This review is dedicated to the memory of Professors Massimo Ugo Palma, Maria Beatrice Palma Vittorelli, and Lorenzo Cordone, which were the founders of the Palermo School of Biophysics. We all have been, directly or indirectly, their pupils; we miss their enthusiasm for scientific research, their deep physical insights, their suggestions, their strict but always constructive criticisms, and, most of all, their friendship. This paper is dedicated also to the memory of Prof. Hans Frauenfelder, whose pioneering works on nonexponential rebinding kinetics, protein substates, and energy landscape have inspired a large part of our work in the field of protein dynamics
Photoluminescence dispersion as a probe of structural inhomogeneity in silica
We report time-resolved photoluminescence spectra of point defects in
amorphous silicon dioxide (silica), in particular the decay kinetics of the
emission signals of extrinsic Oxygen Deficient Centres of the second type from
singlet and directly-excited triplet states are measured and used as a probe of
structural inhomogeneity. Luminescence activity in sapphire
(-AlO) is studied as well and used as a model system to compare
the optical properties of defects in silica with those of defects embedded in a
crystalline matrix. Only for defects in silica, we observe a variation of the
decay lifetimes with emission energy and a time dependence of the first moment
of the emission bands. These features are analyzed within a theoretical model
with explicit hypothesis about the effect introduced by the disorder of
vitreous systems. Separate estimations of the homogenous and inhomogeneous
contributions to the measured emission linewidth are obtained: it is found that
inhomogeneous effects strongly condition both the triplet and singlet
luminescence activities of oxygen deficient centres in silica, although the
degree of inhomogeneity of the triplet emission turns out to be lower than that
of the singlet emission. Inhomogeneous effects appear to be negligible in
sapphire
Low-frequency, high-power ultrasound treatment at different pressures for olive paste: Effects on olive oil yield and quality.
Abstract Ultrasound technology was employed to test its action on the extraction of olive oil at the industrial scale. Because of its mechanical effects, ultrasound waves were applied to the olive paste, between the crushing and malaxing operations. Comparative experiments were performed between traditional extraction processes and the innovative extraction process, with the addition of the ultrasound treatment. Different levels of pressure were tested on olive paste, using four different olive cultivars. Pressure level played an important role in olive oil extractability. When ultrasound was subjected to olive paste with a pressure of about 3.5 bar, there was a significant increase of extractability compared to the traditional process. On the other hand, there was no significant effect between ultrasound treatment and traditional technology on extractability when ultrasound at a pressure level of 1.7 bar was used
Deciphering metal-induced oxidative damages on glycated albumin structure and function
Background: Metal ions such as copper or zinc are involved in the development of neurodegenerative pathologies and metabolic diseases such as diabetes mellitus. Albumin structure and functions are impaired following metal- and glucose-mediated oxidative alterations. The aim of this study was to elucidate effects of Cu(II) and Zn(II) ions on glucose-induced modifications in albumin by focusing on glycation, aggregation, oxidation and functional aspects. Methods: Aggregation and conformational changes in albumin were monitored by spectroscopy, fluorescence and microscopy techniques. Biochemical assays such as carbonyl, thiol groups, albumin-bound Cu, fructosamine and amine group measurements were used. Cellular assays were used to gain functional information concerning antioxidant activity of oxidized albumins. Results: Both metals promoted inhibition of albumin glycation associated with an enhanced aggregation and oxidation process. Metal ions gave rise to the formation of β-amyloid type aggregates in albumin exhibiting impaired antioxidant properties and toxic activity to murine microglia cells (BV2). The differential efficiency of both metal ions to inhibit albumin glycation, to promote aggregation and to affect cellular physiology is compared. Conclusions and general significance: Considering the key role of oxidized protein in pathology complications, glycation-mediated and metal ion-induced impairment of albumin properties might be important parameters to be followed and fought. © 2013 Elsevier B.V
Overdentures on implants placed in bone augmented with fresh frozen bone
Introduction In the last decade several studies have been performed to evaluate the clinical outcome of one or two stage loaded implants supporting overdentures. Aim Since fresh frozen bone (FFB) has an ever-increasing number of clinical applications and few reports are available on implants inserted into FFB, we performed a retrospective study on fixtures inserted in FFB and bearing overdentures. Methods In the period between December 2003 and December 2006, 17 patients (14 females and 3 males with a median age of about 56 years) were grafted and 60 implants inserted thereafter. A total of 17 overdentures were delivered: 8 in the mandible and 9 in the maxilla. Multiple implant systems were used: 22 Double etched, 7 SLA, 9 Anodic oxidized, and 22 CaPo4 ceramic-blasted. Implant diameter ranged from 3.25 to 4.3 mm and length from 11.5 to 16.0 mm. Implants were inserted to replace 23 incisors, 9 cuspids, 20 premolars and 8 molars. Results No implants were lost (i.e. survival rate = 100%) and no differences were detected among the studied variables. Kaplan Meier algorithm and Cox regression did not reveal any statistical differences among the studied variables also as regards the success rate. Conclusion Implants inserted FFB and bearing overdentures have a high survival rate and success rates, which are comparable to those of implants inserted in non-grafted bone. FFB bone is a reliable material for alveolar ridge augmentation. No difference was detected among removable prostheses supported by 2 or more implants
On the Effect of Downscaling in Inkjet Printed Life-Inspired Compartments
The fabrication of size-scalable liquid compartments is a topic of fundamental importance in synthetic
biology, aiming to mimic the structures and the functions of cellular compartments. Here, inkjet
printing is demonstrated as a customizable approach to fabricate aqueous compartments at different
size regimes (from nanoliter to femtoliter scale) revealing the crucial role of size in governing the
emerging of new properties. At first, inkjet printing is shown to produce homogenous aqueous
compartments stabilized by oil-confinement with mild surfactants down to the hundreds of picoliter
scale [1]. Raster Image Correlation Spectroscopy allows to monitor few intermolecular events by the
involvement of protein-binding assays within these compartments [2]. Subsequently, in order to
reduce droplet size at values below the nozzle size, a theoretical model from Eggers et al. [3] is
experimentally reproduced permitting to obtain femtoliter-scale aqueous droplets from picoliter-scale
microchannels [4]. As a remarkable difference to picoliter scale droplets, downscaling at the
femtoliter-size triggers the spontaneous formation of molecularly crowded shell structures at the
water/oil interface stabilized by a mixture of biocompatible surfactants. The shells have typical
thickness in order of hundreds of nanometers, in accordance with theoretical models [5]. Molecular
crowding effects in these systems are tested by using fluorescence lifetime imaging under the phasor
plot approach [6], revealing different characteristic lifetimes of specific probe molecules in the
confined volumes with respect to bulk solutions. The femtoliter-scale compartments autonomously
trigger the formation of unique features (e.g., up-concentration, spatial heterogeneity, molecular proximity) that are mediated by the intermolecular interactions in these novel environments, ultimately permitting to mimic the native conditions of sub-cellular scale compartments. The crowding conditions in femtoliter-scale droplets do not to affect the conformation variation of a model DNA hairpin in presence of molecular triggers and of a CYP2E1-catalyzed enzymatic reaction. Our results can be a first step towards the fabrication of size-scalable lab-on-a-chip compartments mimicking sub-cellular environments.
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