Circular dichroism (CD) spectroscopy is a widely used technique for the study of protein structure. Numerous algorithms have been developed for the estimation of the secondary structure composition from the CD spectra. These methods often fail to provide acceptable results on α/β-mixed or β-structure-rich proteins. The problem arises from the spectral diversity of β-structures, which has hitherto been considered as an intrinsic limitation of the technique. The predictions are less reliable for proteins of unusual β-structures such as membrane proteins, protein aggregates, and amyloid fibrils. Here, we show that the parallel/antiparallel orientation and the twisting of the β-sheets account for the observed spectral diversity. We have developed a method called β-structure selection (BeStSel) for the secondary structure estimation that takes into account the twist of β-structures. This method can reliably distinguish parallel and antiparallel β-sheets and accurately estimates the secondary structure for a broad range of proteins. Moreover, the secondary structure components applied by the method are characteristic to the protein fold, and thus the fold can be predicted to the level of topology in the CATH classification from a single CD spectrum. By constructing a web server, we offer a general tool for a quick and reliable structure analysis using conventional CD or synchrotron radiation CD (SRCD) spectroscopy for the protein science research community. The method is especially useful when X-ray or NMR techniques fail. Using BeStSel on data collected by SRCD spectroscopy, we investigated the structure of amyloid fibrils of various disease-related proteins and peptides. circular dichroism | secondary structure determination | protein fold | protein aggregation | amyloid O ptically active macromolecules, such as proteins, exhibit differential absorption of circular polarized light. The far-UV circular dichroism (CD) spectroscopy of proteins and peptides (180-250 nm) is predominantly based on the excitation of electronic transitions in amide groups. The peptide backbone forms characteristic secondary structures such as α-helices, β-pleated sheets, turns, and disordered sections with specific Φ, Ψ dihedral angles and H-bond patterns affecting the CD spectrum (1). CD has been exploited for protein folding and stability assays, intermolecular interactions, and ligand binding studies, and has recently been applied in the investigations of protein disorder (2, 3). Synchrotron radiation CD (SRCD) spectroscopy is an emerging technique complementary to small-angle X-ray scattering or infrared spectroscopy, synergistic to biochemical and biophysical assays characterizing the protein folding state. SRCD extends the limits of conventional CD spectroscopy by broadening the spectral range, increasing the signal-to-noise ratio, and accelerating the data acquisition, in the presence of absorbing components (buffers, salts, etc.) (4). Additionally, SRCD has the capability of time-resolved and stopped-flow measurements as well as hig...
Circular dichroism (CD) spectroscopy is a widely used method to study the protein secondary structure. However, for decades, the general opinion was that the correct estimation of β-sheet content is challenging because of the large spectral and structural diversity of β-sheets. Recently, we showed that the orientation and twisting of β-sheets account for the observed spectral diversity, and developed a new method to estimate accurately the secondary structure (PNAS, 112, E3095). BeStSel web server provides the Beta Structure Selection method to analyze the CD spectra recorded by conventional or synchrotron radiation CD equipment. Both normalized and measured data can be uploaded to the server either as a single spectrum or series of spectra. The originality of BeStSel is that it carries out a detailed secondary structure analysis providing information on eight secondary structure components including parallel-β structure and antiparallel β-sheets with three different groups of twist. Based on these, it predicts the protein fold down to the topology/homology level of the CATH protein fold classification. The server also provides a module to analyze the structures deposited in the PDB for BeStSel secondary structure contents in relation to Dictionary of Secondary Structure of Proteins data. The BeStSel server is freely accessible at http://bestsel.elte.hu.
Food-grade titanium dioxide (TiO2) containing a nanoscale particle fraction (TiO2-NPs) is approved as a white pigment (E171 in Europe) in common foodstuffs, including confectionary. There are growing concerns that daily oral TiO2-NP intake is associated with an increased risk of chronic intestinal inflammation and carcinogenesis. In rats orally exposed for one week to E171 at human relevant levels, titanium was detected in the immune cells of Peyer’s patches (PP) as observed with the TiO2-NP model NM-105. Dendritic cell frequency increased in PP regardless of the TiO2 treatment, while regulatory T cells involved in dampening inflammatory responses decreased with E171 only, an effect still observed after 100 days of treatment. In all TiO2-treated rats, stimulation of immune cells isolated from PP showed a decrease in Thelper (Th)-1 IFN-γ secretion, while splenic Th1/Th17 inflammatory responses sharply increased. E171 or NM-105 for one week did not initiate intestinal inflammation, while a 100-day E171 treatment promoted colon microinflammation and initiated preneoplastic lesions while also fostering the growth of aberrant crypt foci in a chemically induced carcinogenesis model. These data should be considered for risk assessments of the susceptibility to Th17-driven autoimmune diseases and to colorectal cancer in humans exposed to TiO2 from dietary sources.
International audienceResearchers, clinicians and governments all recognize antimicrobial resistance as a serious and growing threat worldwide. New antimicrobials are urgently needed, especially for infections caused by Gram-negative bacteria, whose cell envelopes are char- acterized by low permeability and often contain drug e ux systems. Individual bacteria and populations control their internal concentrations of antibiotics by regulating proteins involved in membrane permeability, such as porins or e ux pumps. Robust methods to quantify and visualize intrabacterial antibiotic concentrations have identi ed clear correlations between e ux activ- ity and drug di usion and accumulation in both susceptible and resistant strains, and have also clari ed how certain chemical structures can a ect drug entry and residence time within the cell. In this Perspective, we discuss the biological underpinnings of drug permeability and export using several prototypical in ux and e ux systems. We also highlight how new methods for the determination of antibacterial activities enable more careful quantitation and may provide us with a way forward for capturing and correlating the modes of action and kinetics of antibiotic uptake inside bacterial cells. Together, these advances will aid e orts to generate structurally improved molecules with better access and retention within bacteria, thereby reducing the emergence and spread of resistant strains and extending the clinical use of current antibiotics
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