Protein and Peptide Letters - Volume 22, Issue 7, 2015

Interleukin-17A (IL-17A) and its receptor (IL-17RA) are prototype members of IL-17 ligand/receptor family firstly identified in CD4+ T cells, which comprises six ligands (IL-17A to IL- 17F) and five receptors (IL-17RA to IL-17RE). IL-17A is predominantly secreted by T helper 17 (Th17) cells, and plays important roles in the development of autoimmune and inflammatory diseases. IL-17RA is widely expressed, and forms a complex with IL-17RC. Binding of IL-17A to this receptor complex triggers the activation of several intracellular signaling pathways. In this review, we aimed to summarize literature data about molecular features of IL-17A and IL-17RA from gene to mature protein. We are also providing insight into regulatory mechanisms, protein structural conformation, including ligand-receptor interaction, and an overview of signaling pathways. Our aim was to compile the data on molecular characteristics of IL-17A and IL-17RA which may help in the understanding of their functions in health and disease.

This study aims to explore the structure characteristic of random polypeptides constructed by origin early amino acid alphabet, as well as the effects of cofactors on conformation transition of random peptides. DNA library R8-4 encoding VNM random peptides were constructed by small cassette strategy. Subsequently, a random polypeptide library was constructed using in vitro translation. Expression and purification of VNM random peptides were also performed by a conventional method of recombinant. CD spectrum analysis indicated that VNM random polypeptides have a secondary structure characteristic of protein, such as the content of α-helix is greater than 60%, random coil is about 20% β sheet, and β turn is less than 10%. CD spectrum changed with the addition of 10–40 µM ATP and NADP, but slightly changed by NAD; no influence was observed with MgSO4. Bis-ANS binding assay indicated that fluorescent intensity of bis-ANS was strengthened slightly by 10 µM random peptides. Fluorescent intensity was strengthened fourfold by adding 10–40 µM ATP, NAD, and NADH, whereas the inducing effect of NADPH and MgSO4 were negligible. VNM random peptides have a classic secondary structure and hydrophobic domain in water solution. Moreover, conformation transition and hydrophobic domain could be induced by cofactor, indicating the preliminary evidence for the hypothesis that “the origin of primitive protein was induced by small molecule.”

Most computational protein structure prediction methods are designed for either templatebased or template-free (ab initio) structure prediction. The approaches that integrate the prediction capabilities of both template-based modeling and template-free modeling are needed to synergistically combine the two kinds of methods to improve protein structure prediction. In this work, we develop a new method to integrate several protein structure prediction methods including our template-based MULTICOM server, our ab initio contact-based protein structure prediction method CONFOLD, our multi-template-based model generation tool MTMG, and locally installed external Rosetta, I-TASSER and RaptorX protein structure prediction tools to improve protein structure prediction of a fullspectrum difficulty ranging from easy, to medium and to hard. Our method participated in the 11th community-wide Critical Assessment of Techniques for Protein Structure Prediction (CASP11) in 2014 as MULTICOM-NOVEL server. It was ranked among top 10 methods for protein tertiary structure prediction according to the official CASP11 assessment, which demonstrates that integrating complementary modeling methods is useful for advancing protein structure prediction.

Nowadays, glycation induced protein aggregation and related opposing strategies have received much attention. We present the effect of functionalized magnetic core–shell nanoparticles of Fe3O4 (MNPs) with β-cyclodextrin (β-CD) on the aggregation/fibrillation of bovine serum albumin (BSA) under diabetic condition known as amyloidogenesis. To confirm the β-CD conjugation on MNP, Fourier transform infrared spectroscopy (FTIR), X-ray diffraction (XRD), thermogravimetric analysis (TGA), transmission electron microscopy (TEM) and vibrating sample magnetometer (VSM) methods were applied. Moreover, spectrofluorimetry and spectropolarimetry were utilized to analyze the effect of β-CD/Fe3O4 MNPs on the aggregation and amyloidogenesis of BSA through glycation. The BSA amyloidogenesis was significantly inhibited by interfering β-CD-MNPs that may present the possible diagnostic and preventive applications against the degenerative effects of protein glycation/fibrillation under diabetes.

In our present investigation, the unfolding and refolding of β-glucosidase (BGL-Al) from sweet almond was investigated using tryptophan (Trp) fluorescence spectroscopy. When the unfolding of BGL-Al was induced by guanidium chloride (GdnHCl) and monitored using biological activity as well as Trp fluorescence spectroscopic measurement, we observed that the denaturation of BGL-Al could be easily induced by low concentration of GdnHCl and the enzyme was completely inactivated at 1.0 M GdnHCl. Higher unfolding in the presence of reducing agent revealed that the protein perhaps containing multiple di-sulfide bonds indicating a reason of high stability against unfolding by GdnHCl. Refolding results suggested that the protein refolded with high yield from 1 M GdnHCl denatured state, however, refolded with negligible yield from completely unfolded state. The kinetic studies of BGL-Al refolding unravel a two phase refolding process with calculated t1/2 (refolding half time) of 1.8 and 33 min, respectively. When 8-Anilino-1-naphthalenesulfonic acid (ANS) was used as extrinsic fluorophore, we found that the surface hydrophobicity of BGL-Al was continuously decreased during GdnHCl-mediated unfolding. The surface hydrophobicity of the protein was calculated to be as high as 128.32. Acrylamide quenching study demonstrated that Trp residues of BGL-Al are mostly and hence they must be located either on the surface or in the crevices accessible by quenchers.

Stabilizing effect of diazepam and ketoprofen, Sudlow’s site II markers on human serum albumin (HSA) against urea denaturation was studied using fluorescence spectroscopy. The two-step, three-state urea transition of HSA was transformed into a single-step, two-state transition with the abolishment of the intermediate state along with a shift of the transition curve towards higher urea concentrations in the presence of diazepam or ketoprofen. Interestingly, a greater shift in the transition curve of HSA was observed in the presence of ketoprofen compared to diazepam. A comparison of the intrinsic fluorescence and three-dimensional fluorescence spectra of HSA and partially-denatured HSAs, obtained in the absence and the presence of diazepam or ketoprofen suggested significant retention of native-like conformation in the partially-denatured states of HSA in the presence of Sudlow’s site II markers. Taken together, all these results suggested stabilization of HSA in the presence of diazepam or ketoprofen, being greater in the presence of ketoprofen.

Peptide-mediated immunity against pathogens in plants can provide information on proteinpeptide interactions and drug discovery in general. The molecular structure of AtPep1, a 23-amino acid signaling peptide isolated from Arabidopsis thaliana leaves and implicated in innate immunity, has evaded structural determination by biophysical methods. The details of molecular interaction of AtPep1 peptide with its receptor (PEPR1), a 170 kDa leucine-rich repeat (LRR) kinase is also unknown. We report a computational approach to the modeling AtPep1 by conformational sampling and its interaction with the receptor PEPR1. Molecular dynamics simulations were employed to sample and cluster energetically favorable conformations of AtPep1 and modeling of PEPR1 through homology. Docking of AtPep1 to PEPR1 and filtering of the biologically relevant poses were facilitated by the computational Ala-scanning mutations and binding energy analysis of the peptide-protein complex. This study provides the first independent in silico validation of the Structure-Activity- Relationship studies carried out on the AtPep1 and provides a molecular mechanism of the peptide-protein complex system.

UDP-glucose dehydrogenases (EC 1.1.1.22) are responsible for the conversion of UDP-glucose to UDP-glucuronic acid, a key precursor in the biosynthesis of glycoconjugates. Herein we report the discovery and characterization of a UDPglucose dehydrogenase (GbUGD) from Granulibacter bethesdensis, a bacterium originally isolated from the lymph nodes of patients with chronic granulomatous disease (CGD). The recombinant form of the protein was expressed in high yield and the purified enzyme showed highest activity at 37°C/pH 9.0 and was strongly inhibited by Zn2+ ions, sodium dodecyl sulfate (SDS) and urea. UDP-xylose, an allosteric feedback inhibitor, reduced significantly the activity of the enzyme. High activities were observed using the co-substrates UDP-glucose and NAD+, whereas no activity could be detected using other nucleotide sugars or NADP+ as potential alternative substrates. The high activity combined with the simple purification procedure used make GbUGD a valuable new alternative biocatalyst for the synthesis of UDP-glucuronic acid or the development of NAD+ regeneration systems.

Molecular modeling deciphered the site of interaction of rifampicin in the structure of ovalbumin at a site which is surrounded by residues Glu-214, Asp-98, Pro-85, Asp-91 and Asp-47. Isothermal calorimetric analysis determined the thermodynamic parameters i.e. ΔH and ΔS which came out be -8.086 cal/mol and -131 cal/mol/deg. respectively. Ovalbumin is a secretory protein of hen oviduct, present in the human blood serum and interacts with the drug rifampicin in vivo, when administered. Simulating these conditions in vitro revealed that rifampicin induced the aggregated state at 6 µM concentration which was featured by a decrease in the ANS fluorescence intensity relative to the native state while as the pre-molten and molten globule state were obtained at 3 µM and 5 µM concentration of rifampicin respectively displaying a hike in the ANS fluorescence intensity. Far-UV CD analysis suggested β-sheet rich structure with negative ellipticity peak at 217 nm for native ovalbumin incubated with 6 µM rifampicin. Increase in absorbance at 450 nm, red shift of 50 nm in the congo red binding assay and a hike of 10 fold in the ThT fluorescence intensity compared to the native state further confirmed aggregate formation. Moreover, TEM images displayed aggregates to be spherical morphologically. Aggregates formed at 6 µM rifampicin concentration were found to be cytotoxic as there was a reduction of cell viability to 28%. Thus, protein-drug interaction primarily facilitates a structural alteration in the native structure of proteins leading to their aggregation which were proved to be cytotoxic in nature.

Long-range interactions and allostery are important for many biological processes. Increasing numbers of studies, both experimental and computational, show that internal dynamics may play an important role in such behaviors. Investigating the dynamical effects of proteins, how- ever, is a challenging problem using all-atom molecular dynamics because of the length-scales and timescales involved. As a result, coarse-grained models are often implemented. Herein, we use three well-defined coarse-grained models: Go, Martini and Cafemol, and a small model protein Eglin C, which is readily studied via all-atom molecular dynamics, to examine if these coarse grained models can explore the dynamics of Eglin C accurately as well as to see how these models respond to mutations. We found that all three models can recapture the dynamics of Eglin C to a significant extent – where we focus on root-mean square fluctuations and correlated motions as dynamical measures – but that the Cafemol and Go models are superior. The best agreement with all-atom simulations is for structured regions of Eglin C.

Previous theoretical studies have determined the intermolecular interactions between Mucor pusillus pepsin (MPP) and the key domain of κ-casein, with the aim to understand the mechanism of milk clotting in the specific hydrolysis of κ-casein by MPP for cheese making. Here, we combined the docking model with site-directed mutagenesis to further investigate the functional roles of amino acid residues in the active site of MPP. T218S replacement caused a low thermostability and moderate increase in the clotting activity. Mutations of three amino acid residues, T218A and T218S in S2 region and L287G in S4 region, led to a significant decrease in proteolytic activity. For T218S and L287G, an increase in the ratio of clotting activity to proteolytic activity (C/P) was observed, in particular 3.34-fold increase was found for T218S mutants. Structural analysis of the binding mode of MPP and chymosin splitting domain (CSD) of κ-casein indicated that T218S plays a critical role in forming a hydrogen bond with the hydroxyl group of Ser104 around the MPP-sensitive Phe105-Met106 peptide bond of κ- casein and L287G is partially responsible for CSD accommodation in a suitable hydrophobic environment. These data suggested that T218S mutant could serve as a promising milk coagulant that contributes to an optimal flavor development in mature cheese.