Spin-echo EPR of Na,K-ATPase unfolding by urea

AbstractDenaturant-perturbation and pulsed EPR spectroscopy are combined to probe the folding of the membrane-bound Na,K-ATPase active transport system. The Na,K-ATPase enzymes from shark salt gland and pig kidney are covalently spin labelled on cysteine residues that either do not perturb or are essential to hydrolytic activity (Class I and Class II –SH groups, respectively). Urea increases the accessibility of water to the spin-labelled groups and increases their mutual separations, as recorded by D2O interactions from ESEEM spectroscopy and instantaneous spin diffusion from echo-detected EPR spectra, respectively. The greater effects of urea are experienced by Class I groups, which indicates preferential unfolding of the extramembrane domains. Conformational heterogeneity induced by urea causes dispersion in spin-echo phase-memory times to persist to higher temperatures. Analysis of lineshapes from partially relaxed echo-detected EPR spectra indicates that perturbation by urea enhances the amplitude and rate of fluctuations between conformational substates, in the higher temperature regime, and also depresses the glasslike transition in the protein. These non-native substates that are promoted by urea lie off the enzymatic pathway and contribute to the loss of function

Proteomics Reveals Novel Oxidative and Glycolytic Mechanisms in Type 1 Diabetic Patients' Skin Which Are Normalized by Kidney-Pancreas Transplantation

Background: In type 1 diabetes (T1D) vascular complications such as accelerated atherosclerosis and diffused macro-/microangiopathy are linked to chronic hyperglycemia with a mechanism that is not yet well understood. End-stage renal disease (ESRD) worsens most diabetic complications, particularly, the risk of morbidity and mortality from cardiovascular disease is increased several fold. Methods and Findings: We evaluated protein regulation and expression in skin biopsies obtained from T1D patients with and without ESRD, to identify pathways of persistent cellular changes linked to diabetic vascular disease. We therefore examined pathways that may be normalized by restoration of normoglycemia with kidney-pancreas (KP) transplantation. Using proteomic and ultrastructural approaches, multiple alterations in the expression of proteins involved in oxidative stress (catalase, superoxide dismutase 1, Hsp27, Hsp60, ATP synthase δ chain, and flavin reductase), aerobic and anaerobic glycolysis (ACBP, pyruvate kinase muscle isozyme, and phosphoglycerate kinase 1), and intracellular signaling (stratifin-14-3-3, S100-calcyclin, cathepsin, and PPI rotamase) as well as endothelial vascular abnormalities were identified in T1D and T1D+ESRD patients. These abnormalities were reversed after KP transplant. Increased plasma levels of malondialdehyde were observed in T1D and T1D+ESRD patients, confirming increased oxidative stress which was normalized after KP transplant. Conclusions: Our data suggests persistent cellular changes of anti-oxidative machinery and of aerobic/anaerobic glycolysis are present in T1D and T1D+ESRD patients, and these abnormalities may play a key role in the pathogenesis of hyperglycemia-related vascular complications. Restoration of normoglycemia and removal of uremia with KP transplant can correct these abnormalities. Some of these identified pathways may become potential therapeutic targets for a new generation of drugs

Thermal Liquid Biopsy (TLB) of Blood Plasma as a Potential Tool to Help in the Early Diagnosis of Multiple Sclerosis

16 pags., 8 figs., 4 tabs. -- This article belongs to the Special Issue Personalized Medicine for Multiple SclerosisBackground: Multiple sclerosis (MS) is frequently characterized by a variety of clinical signs, often exhibiting little specificity. The diagnosis requires a combination of medical observations and instrumental tests, and any support for its objective assessment is helpful. Objective: Herein, we describe the application of thermal liquid biopsy (TLB) of blood plasma samples, a methodology for predicting the occurrence of MS with a noninvasive, quick blood test. Methods: TLB allows one to define an index (TLB score), which provides information about overall real-time alterations in plasma proteome that may be indicative of MS. Results: This pilot study, based on 85 subjects (45 MS patients and 40 controls), showed good performance indexes (sensitivity and specificity both around 70%). The diagnostic methods better discriminate between early stage and low-burden MS patients, and it is not influenced by gender, age, or assumption of therapeutic drugs. TLB is more accurate for patients having low disability level (≤ 3.0, measured by the expanded disability status scale, EDSS) and a relapsing–remitting diagnosis. Conclusion: Our results suggest that TLB can be applied to MS, especially in an initial phase of the disease when diagnosis is difficult and yet more important (in such cases, accuracy of prediction is close to 80%), as well as in personalized patient periodic monitoring. The next step will be determining its utility in differentiating between MS and other disorders, in particular in inflammatory diseases.This research was funded by the Spanish Ministry of Economy and Competitiveness and European ERDF Funds (MCIU/AEI/FEDER, EU) (BFU2016-78232-P to A.V.C.); Projects funded by Instituto de Salud Carlos III and co-funded by European Union (ESF, “Investing in your future”): “PI15/00663 (FIS project to O.A)”, “PI18/00349 (FIS project to O.A.)”, “FI19/00146 (PFIS contract for SHD)”; Diputación General de Aragón (Protein Targets and Bioactive Compounds Group E45_20R to A.V.C. and Digestive Pathology Group B25_20R to O.A.); and the Centro de Investigación Biomédica en Red en Enfermedades Hepáticas y Digestivas (CIBERehd).Peer reviewe

Intramembrane Polarity by Electron Spin Echo Spectroscopy of Labeled Lipids

The association of water (D(2)O) with phospholipid membranes was studied by using pulsed-electron spin resonance techniques. We measured the deuterium electron spin echo modulation of spin-labeled phospholipids by D(2)O in membranes of dipalmitoyl phosphatidylcholine with and without 50 mol% of cholesterol. The Fourier transform of the relaxation-corrected two-pulse echo decay curve reveals peaks, at one and two times the deuterium NMR frequency, that arise from the dipolar hyperfine interaction of the deuterium nucleus with the unpaired electron spin of the nitroxide-labeled lipid. For phosphatidylcholine spin-labeled at different positions down the sn-2 chain, the amplitude of the deuterium signal decreases toward the center of the membrane, and is reduced to zero from the C-12 atom position onward. At chain positions C-5 and C-7 closer to the phospholipid headgroups, the amplitude of the deuterium signal is greater in the presence of cholesterol than in its absence. These results are in good agreement with more indirect measurements of the transmembrane polarity profile that are based on the (14)N-hyperfine splittings in the conventional continuous-wave electron spin resonance spectrum

Multiple binding modes of ibuprofen in human serum albumin identified by absolute binding free energy calculations.

Human serum albumin possesses multiple binding sites and transports a wide range of ligands that include the anti-inflammatory drug ibuprofen. A complete map of the binding sites of ibuprofen in albumin is difficult to obtain in traditional experiments, because of the structural adaptability of this protein in accommodating small ligands. In this work, we provide a set of predictions covering the geometry, affinity of binding and protonation state for the pharmaceutically most active form (S-isomer) of ibuprofen to albumin, by using absolute binding free energy calculations in combination with classical molecular dynamics (MD) simulations and molecular docking. The most favorable binding modes correctly reproduce several experimentally identified binding locations, which include the two Sudlow's drug sites (DS2 and DS1) and the fatty acid binding sites 6 and 2 (FA6 and FA2). Previously unknown details of the binding conformations were revealed for some of them, and formerly undetected binding modes were found in other protein sites. The calculated binding affinities exhibit trends which seem to agree with the available experimental data, and drastically degrade when the ligand is modeled in a protonated (neutral) state, indicating that ibuprofen associates with albumin preferentially in its charged form. These findings provide a detailed description of the binding of ibuprofen, help to explain a wide range of results reported in the literature in the last decades, and demonstrate the possibility of using simulation methods to predict ligand binding to albumin

Molecular simulation of transport proteins in interaction with physiological and pharmacological ligands

School of Science and Technique "Bernardino Telesio", Doctor in Physics of Complex Systems, Ciclo XXVII, a.a. 2014Molecular complexes of transport proteins with small compounds have been studied by using docking techniques and molecular dynamics simulations. The macromolecules considered are β- lactoglobulin and albumin, i.e. the most abundant proteins in bovine milk and human blood serum, respectively. The ligands are long-chain fatty acids of different length and ibuprofen, a molecule of pharmaceutical interest. Simulations of β-lactoglobulin with fatty acids, ranging from caprylic to stearic acid, revealed the key protein residues that contribute to the binding process. In particular, a rationale was found for the high binding affinity of both stearic and palmitic acid compared to shorter lipids. Moreover, the location of two low-affinity external binding sites was predicted for palmitic acid, by comparing docking results with those obtained for vitamin D3, for which an external site has already been identified in crystallography. For human serum albumin, docking results suggest different candidate binding locations for both charged and neutral ibuprofen. An alchemical free energy approach has been used to estimate the binding affinity for each pose. The results show that charged ibuprofen has a greater affinity for albumin compared to the ligand in the neutral form, suggesting that the former corresponds to the physiological binding state. The simulation findings were compared to experimental results and show an overall good agreement, predicting details of the protein-ligand interaction that include binding geometries and contacts with specific amino acid residues. The overall findings reveal significant features of the binding of well-known ligands to two extensively investigated transport proteins, and show how computational tools can be used to support experimental techniques in a variety of cases.Università della Calabri

Thermal stability effects of removing the type-2 copper ligand His306 at the interface of nitrite reductase subunits

Nitrite reductase (NiR) is a highly stable trimeric protein, which denatures via an intermediate, N-3 (k) U-3 -> (k) F (N - native, U - unfolded and F - final). To understand the role of interfacial residues on protein stability, a type-2 copper site ligand, His306, has been mutated to an alanine. The characterization of the native state of the mutated protein highlights that this mutation prevents copper ions from binding to the type-2 site and eliminates catalytic activity. No significant alteration of the geometry of the type-1 site is observed. Study of the thermal denaturation of this His306Ala NiR variant by differential scanning calorimetry shows an endothermic irreversible profile, with maximum heat absorption at T-max approximate to 85 degrees C, i. e., 15 degrees C lower than the corresponding value found for wild-type protein. The reduction of the protein thermal stability induced by the His306Ala replacement was also shown by optical spectroscopy. The denaturation pathway of the variant is compatible with the kinetic model N3 ->(k) F-3, where the protein irreversibly passes from the native to the final state. No evidence of subunits' dissociation has been found within the unfolding process. The results show that the type-2 copper sites, situated at the interface of two monomers, significantly contribute to both the stability and the denaturation mechanism of NiR