Conformational Exchange in a Membrane Transport Protein Is Altered in Protein Crystals

Successful macromolecular crystallography requires solution conditions that may alter the conformational sampling of a macromolecule. Here, site-directed spin labeling is used to examine a conformational equilibrium within BtuB, the Escherichia coli outer membrane transporter for vitamin B₁₂. Electron paramagnetic resonance (EPR) spectra from a spin label placed within the N-terminal energy coupling motif (Ton box) of BtuB indicate that this segment is in equilibrium between folded and unfolded forms. In bilayers, substrate binding shifts this equilibrium toward the unfolded form; however, EPR spectra from this same spin-labeled mutant indicate that this unfolding transition is blocked in protein crystals. Moreover, crystal structures of this spin-labeled mutant are consistent with the EPR result. When the free energy difference between substates is estimated from the EPR spectra, the crystal environment is found to alter this energy by 3 kcal/mol when compared to the bilayer state. Approximately half of this energy change is due to solutes or osmolytes in the crystallization buffer, and the remainder is contributed by the crystal lattice. These data provide a quantitative measure of how a conformational equilibrium in BtuB is modified in the crystal environment, and suggest that more-compact, less-hydrated substates will be favored in protein crystals.     

Carbonic Anhydrase and Urease Inhibitory Potential of Various Plant Phenolics Using in vitro and in silico Methods

Plant phenolics are known to display many pharmacological activities. In the current study, eight phenolic compounds, e.g., luteolin 5‐O‐β‐glucoside ( 1 ), methyl rosmarinate ( 2 ), apigenin ( 3 ), vicenin 2 ( 4 ), lithospermic acid ( 5 ), soyasaponin II ( 6 ), rubiadin 3‐O‐β‐primeveroside ( 7 ), and 4‐(β‐d ‐glucopyranosyloxy)benzyl 3,4‐dihydroxybenzoate ( 8 ), isolated from various plant species were tested at 0.2 mm against carbonic anhydrase‐II (CA‐II) and urease using microtiter assays. Urease inhibition rate for compounds 1  –  8 ranged between 5.0 – 41.7%, while only compounds 1 , 2 , and 4 showed a considerable inhibition over 50% against CA‐II with the IC₅₀ values of 73.5 ± 1.05, 39.5 ± 1.14, and 104.5 ± 2.50 μm , respectively, where IC₅₀ of the reference (acetazolamide) was 21.0 ± 0.12 μm . In silico experiments were also performed through two docking softwares (Autodock Vina and i‐GEMDOCK) in order to find out interactions between the compounds and CA‐II. Actually, compounds 6 (30.0%) and 7 (42.0%) possessed a better binding capability toward the active site of CA‐II. According to our results obtained in this study, among the phenolic compounds screened, particularly 1 , 2 , and 4 appear to be the promising inhibitors of CA‐II and may be further investigated as possible leads for diuretic, anti‐glaucoma, and antiepileptic agents.     

A Simple Detection Method for Low-Affinity Membrane Protein Interactions by Baculoviral Display

Background

Membrane protein interactions play an important role in cell-to-cell recognition in various biological activities such as in the immune or neural system. Nevertheless, there has remained the major obstacle of expression of the membrane proteins in their active form. Recently, we and other investigators found that functional membrane proteins express on baculovirus particles (budded virus, BV). In this study, we applied this BV display system to detect interaction between membrane proteins important for cell-to-cell interaction in immune system.

Methodology/Principal Findings

We infected Sf9 cells with recombinant baculovirus encoding the T cell membrane protein CD2 or its ligand CD58 and recovered the BV. We detected specific interaction between CD2-displaying BV and CD58-displaying BV by an enzyme-linked immunosorbent assay (ELISA). Using this system, we also detected specific interaction between two other membrane receptor-ligand pairs, CD40-CD40 ligand (CD40L), and glucocorticoid-induced TNFR family-related protein (GITR)-GITR ligand (GITRL). Furthermore, we observed specific binding of BV displaying CD58, CD40L, or GITRL to cells naturally expressing their respective receptors by flowcytometric analysis using anti-baculoviral gp64 antibody. Finally we isolated CD2 cDNA from a cDNA expression library by magnetic separation using CD58-displayng BV and anti-gp64 antibody.

Conclusions

We found the BV display system worked effectively in the detection of the interaction of membrane proteins. Since various membrane proteins and their oligomeric complexes can be displayed on BV in the native form, this BV display system should prove highly useful in the search for natural ligands or to develop screening systems for therapeutic antibodies and/or compounds.     

Prediction of Spontaneous Protein Deamidation from Sequence-Derived Secondary Structure and Intrinsic Disorder

Asparagine residues in proteins undergo spontaneous deamidation, a post-translational modification that may act as a molecular clock for the regulation of protein function and turnover. Asparagine deamidation is modulated by protein local sequence, secondary structure and hydrogen bonding. We present NGOME, an algorithm able to predict non-enzymatic deamidation of internal asparagine residues in proteins in the absence of structural data, using sequence-based predictions of secondary structure and intrinsic disorder. Compared to previous algorithms, NGOME does not require three-dimensional structures yet yields better predictions than available sequence-only methods. Four case studies of specific proteins show how NGOME may help the user identify deamidation-prone asparagine residues, often related to protein gain of function, protein degradation or protein misfolding in pathological processes. A fifth case study applies NGOME at a proteomic scale and unveils a correlation between asparagine deamidation and protein degradation in yeast. NGOME is freely available as a webserver at the National EMBnet node Argentina, URL: http://www.embnet.qb.fcen.uba.ar/ in the subpage “Protein and nucleic acid structure and sequence analysis”.     

Critical Evaluation of Membrane Supports for Use in Quantitative Hybridizations

The quantification of 16S rRNA by oligonucleotide probe hybridization was investigated with MagnaGraph (Micron Separation, Inc. [MSI]), Magna Charge (MSI), Magna (MSI), Immobilon-N (Millipore Corporation), and Nytran (Schleicher & Schuell, Inc.) membranes as supports for nucleic acid immobilization. The levels of detectability provided by the Magna Charge and Immobilon-N membranes were 20 to 50 times better than those obtained with the MagnaGraph, Magna, and Nytran membranes. The variability of the signal response for individual membranes ranged from 10 to 50%, with the Magna Charge and Immobilon-N membranes demonstrating the lowest variability.     

A Critical Role of a Cellular Membrane Traffic Protein in Poliovirus RNA Replication

Replication of many RNA viruses is accompanied by extensive remodeling of intracellular membranes. In poliovirus-infected cells, ER and Golgi stacks disappear, while new clusters of vesicle-like structures form sites for viral RNA synthesis. Virus replication is inhibited by brefeldin A (BFA), implicating some components(s) of the cellular secretory pathway in virus growth. Formation of characteristic vesicles induced by expression of viral proteins was not inhibited by BFA, but they were functionally deficient. GBF1, a guanine nucleotide exchange factor for the small cellular GTPases, Arf, is responsible for the sensitivity of virus infection to BFA, and is required for virus replication. Knockdown of GBF1 expression inhibited virus replication, which was rescued by catalytically active protein with an intact N-terminal sequence. We identified a mutation in GBF1 that allows growth of poliovirus in the presence of BFA. Interaction between GBF1 and viral protein 3A determined the outcome of infection in the presence of BFA.     

Intrinsic Disorder of the Neuronal SNARE Protein SNAP25a in its Pre-fusion Conformation

The neuronal SNARE protein SNAP25a (isoform 2) forms part of the SNARE complex eliciting synaptic vesicle fusion during neuronal exocytosis. While the post-fusion cis-SNARE complex has been studied extensively, little is known about the pre-fusion conformation of SNAP25a. Here we analyze monomeric SNAP25a by NMR spectroscopy, further supported by small-angle X-ray scattering (SAXS) experiments. SAXS data indicate that monomeric SNAP25 is more compact than a Gaussian chain but still a random coil. NMR shows that for monomeric SNAP25a, before SNAP25a interacts with its SNARE partners to drive membrane fusion, only the N-terminal part (region A5 to V36) of the first SNARE motif, SN1 (L11 - L81), is helical, comprising two α-helices (ranging from A5 to Q20 and S25 toV36). From E37 onwards, SNAP25a is mostly disordered and displays high internal flexibility, including the C-terminal part of SN1, almost the entire second SNARE motif (SN2, N144-A199), and the connecting loop region. Apart from the N-terminal helices, only the C-termini of both SN1 (E73 - K79) and SN2 (region T190 - A199), as well as two short regions in the connecting loop (D99 - K102 and E123 - M127) show a weak α-helical propensity (α-helical population < 25%). We speculate that the N-terminal helices (A5 to Q20 and S25 to V36) which constitute the N-terminus of SN1 act as a nucleation site for initiating SNARE zippering.     

Applications of Single-Molecule Methods to Membrane Protein Folding Studies

Protein folding is a fundamental life process with many implications throughout biology and medicine. Consequently, there have been enormous efforts to understand how proteins fold. Almost all of this effort has focused on water-soluble proteins, however, leaving membrane proteins largely wandering in the wilderness. The neglect has occurred not because membrane proteins are unimportant but rather because they present many theoretical and technical complications. Indeed, quantitative membrane protein folding studies are generally restricted to a handful of well-behaved proteins. Single-molecule methods may greatly alter this picture, however, because the ability to work at or near infinite dilution removes aggregation problems, one of the main technical challenges of membrane protein folding studies.     

Characterization of the pace-and-drive capacity of the human sinoatrial node: A 3D in silico study

The sinoatrial node (SAN) is a complex structure that spontaneously depolarizes rhythmically (“pacing”) and excites the surrounding non-automatic cardiac cells (“drive”) to initiate each heart beat. However, the mechanisms by which the SAN cells can activate the large and hyperpolarized surrounding cardiac tissue are incompletely understood. Experimental studies demonstrated the presence of an insulating border that separates the SAN from the hyperpolarizing influence of the surrounding myocardium, except at a discrete number of sinoatrial exit pathways (SEPs). We propose a highly detailed 3D model of the human SAN, including 3D SEPs to study the requirements for successful electrical activation of the primary pacemaking structure of the human heart. A total of 788 simulations investigate the ability of the SAN to pace and drive with different heterogeneous characteristics of the nodal tissue (gradient and mosaic models) and myocyte orientation. A sigmoidal distribution of the tissue conductivity combined with a mosaic model of SAN and atrial cells in the SEP was able to drive the right atrium (RA) at varying rates induced by gradual If block. Additionally, we investigated the influence of the SEPs by varying their number, length, and width. SEPs created a transition zone of transmembrane voltage and ionic currents to enable successful pace and drive. Unsuccessful simulations showed a hyperpolarized transmembrane voltage (?66 mV), which blocked the L-type channels and attenuated the sodium-calcium exchanger. The fiber direction influenced the SEPs that preferentially activated the crista terminalis (CT). The location of the leading pacemaker site (LPS) shifted toward the SEP-free areas. LPSs were located closer to the SEP-free areas (3.46 $\pm$ 1.42 mm), where the hyperpolarizing influence of the CT was reduced, compared with a larger distance from the LPS to the areas where SEPs were located (7.17$\pm$ 0.98 mm). This study identified the geometrical and electrophysiological aspects of the 3D SAN-SEP-CT structure required for successful pace and drive in silico.     

Multiple Nucleic Acid Binding Sites and Intrinsic Disorder of Severe Acute Respiratory Syndrome Coronavirus Nucleocapsid Protein: Implications for Ribonucleocapsid Protein Packaging

The nucleocapsid protein (N) of the severe acute respiratory syndrome coronavirus (SARS-CoV) packages the viral genomic RNA and is crucial for viability. However, the RNA-binding mechanism is poorly understood. We have shown previously that the N protein contains two structural domains—the N-terminal domain (NTD; residues 45 to 181) and the C-terminal dimerization domain (CTD; residues 248 to 365)—flanked by long stretches of disordered regions accounting for almost half of the entire sequence. Small-angle X-ray scattering data show that the protein is in an extended conformation and that the two structural domains of the SARS-CoV N protein are far apart. Both the NTD and the CTD have been shown to bind RNA. Here we show that all disordered regions are also capable of binding to RNA. Constructs containing multiple RNA-binding regions showed Hill coefficients greater than 1, suggesting that the N protein binds to RNA cooperatively. The effect can be explained by the “coupled-allostery” model, devised to explain the allosteric effect in a multidomain regulatory system. Although the N proteins of different coronaviruses share very low sequence homology, the physicochemical features described above may be conserved across different groups of Coronaviridae. The current results underscore the important roles of multisite nucleic acid binding and intrinsic disorder in N protein function and RNP packaging.Severe acute respiratory syndrome (SARS) is the first pandemic of the 21st century that spread to multiple nations, with a fatality rate of ca. 8%. The disease is caused by a novel SARS-associated coronavirus (SARS-CoV) closely related to the group II coronaviruses, which include the human coronavirus OC43 and murine hepatitis virus (6, 18). Traditional antiviral treatments have had little success against SARS during the outbreak, and vaccines have yet to be developed (35).Coronaviruses are positive-sense single-stranded RNA (ssRNA) viruses. The coronavirus genomic RNA is encapsidated into a helical capsid by the nucleocapsid (N) protein, which is one of the most abundant coronavirus proteins (19). The N protein has nonspecific binding activity toward nucleic acids, including ssRNA, single-stranded DNA, and double-stranded DNA (33). It can also act as an RNA chaperone (39). However, the mechanism of binding of the N protein to nucleic acids is poorly understood.The SARS-CoV N protein is a homodimer composed of 422 amino acids (aa) in each chain. The N protein can be divided into two structural domains interspersed with disordered (unstructured) regions (Fig. ​(Fig.1A)1A) (2). The N-terminal domain (NTD; also called RBD) serves as a putative RNA-binding domain, while the C-terminal domain (CTD; also called DD) is a dimerization domain (13, 36). Both the NTD and the CTD bind to nucleic acids through electropositive regions on their surfaces (3, 13, 32). All coronaviruses share similar domain architectures at both the sequence and structure levels. No structure of N protein or any of its domains in complex with nucleic acids is available.Open in a separate windowFIG. 1.(A) Schematic of the domain architecture of the SARS-CoV N protein. Structured domains are shown as balls, and unstructured regions are shown as lines. (B) Protein constructs used in the current study. Numbers represent the amino acid residue range relative to the full-length N protein (NP). Sumo-1-FL contains a Sumo-1 tag (shown as an oval), followed by the flexible linker of the N protein between residues 181 and 246.The functions of the disordered regions in the SARS-CoV N protein have not been clearly defined, although some evidence suggests that they are involved in protein-protein interactions between the N protein and other viral and host proteins (11, 20, 22, 38). A previous report has shown that part of the C-terminal disordered region with a polylysine sequence also binds to RNA (21). Unlike the structural domains, the disordered regions of the different coronaviruses share little sequence homology. However, they share a common physicochemical property: they are highly enriched in basic residues. Intrinsic disorder coupled with an abundance of positive charges leads to the possibility of nonspecific binding to nucleic acids (34). These findings prompted us to investigate the role of intrinsically disordered (ID) regions in the RNA-binding mechanism of the SARS-CoV N protein.Here we tested all three disordered regions of the SARS-CoV N protein and found that they are all involved in RNA binding. The central region, in particular, had a large impact on binding behavior as monitored by electrophoretic mobility shift assays (EMSA). Small-angle X-ray scattering (SAXS) and nuclear magnetic resonance (NMR) results show that this central region is a flexible linker (FL) that connects the two structural domains in an extended conformation. Our results provide new insights into the functional coupling of intrinsic disorder, RNA binding, and oligomerization.     

两种PCR方法对检测A组轮状病毒膜芯片杂交结果的影响

A组轮状病毒(rotavirus,RV)是导致拿世界婴幼儿腹泻的最主要病原,危害巨大。拟用RT-巢式PCR技术对A组RV的保守序列进行高度扩增,通过固本室内制的膜芯片杂交,实现对该病毒的检测。分别采用对称PCR和不对称PCR扩增,均可得到扩增的目的片段．对称式扩增产物杂交结果不理想。而不对称式扩增得到了大量待检单链产物,同膜芯片杂交获得了理想的杂交结果。显著地提高了对A组RV杂交检测的灵敏度。表明不对称式PCR扩增是一种制备用于芯片杂交大量单链产物的理想方法,尤其是针对富含AT的核酸检测区域。     

Evaluation of Protein Dihedral Angle Prediction Methods

Tertiary structure prediction of a protein from its amino acid sequence is one of the major challenges in the field of bioinformatics. Hierarchical approach is one of the persuasive techniques used for predicting protein tertiary structure, especially in the absence of homologous protein structures. In hierarchical approach, intermediate states are predicted like secondary structure, dihedral angles, C^α-C^α distance bounds, etc. These intermediate states are used to restraint the protein backbone and assist its correct folding. In the recent years, several methods have been developed for predicting dihedral angles of a protein, but it is difficult to conclude which method is better than others. In this study, we benchmarked the performance of dihedral prediction methods ANGLOR and SPINE X on various datasets, including independent datasets. TANGLE dihedral prediction method was not benchmarked (due to unavailability of its standalone) and was compared with SPINE X and ANGLOR on only ANGLOR dataset on which TANGLE has reported its results. It was observed that SPINE X performed better than ANGLOR and TANGLE, especially in case of prediction of dihedral angles of glycine and proline residues. The analysis suggested that angle shifting was the foremost reason of better performance of SPINE X. We further evaluated the performance of the methods on independent ccPDB30 dataset and observed that SPINE X performed better than ANGLOR.     

A sensitive GRAB sensor for detecting extracellular ATP in vitro and in vivo

1. Download : Download high-res image (156KB)
2. Download : Download full-size image

     

Vegetative and Seed-Specific Forms of Tonoplast Intrinsic Protein in the Vacuolar Membrane of Arabidopsis thaliana

Reports from a number of laboratories describe the presence of a family of proteins (the major intrinsic protein family) in a variety of organisms. These proteins are postulated to form channels that function in metabolite transport. In plants, this family is represented by the product of NOD26, a nodulation gene in soybean that encodes a protein of the peribacteroid membrane, and tonoplast intrinsic protein (TIP), an abundant protein in the tonoplast of protein storage vacuoles of bean seeds (KD Johnson, H Höfte, MJ Chrispeels [1990] Plant Cell 2: 525-532). Other homologs that are induced by water stress in pea and in Arabidopsis thaliana and that are expressed in the roots of tobacco have been reported, but the location of the proteins they encode is not known. We now report the presence and derived amino acid sequences of two different TIP proteins in A. thaliana. α-TIP is a seed-specific protein that has 68% amino acid sequence identity with bean seed TIP; γ-TIP is expressed in the entire vegetative body of A. thaliana and has 58% amino acid identity with bean seed TIP. Both proteins are associated with the tonoplast. Comparisons of the derived amino acid sequences of the seven known plant proteins in the major intrinsic protein family show that genes with similar expression patterns (e.g. water stress-induced or seed specific) are more closely related to each other than the three A. thaliana homologs are related. We propose that the nonoverlapping gene expression patterns reported here, and the evolutionary relationships indicated by the phylogenetic tree, suggest a functional specialization of these proteins.     

应用不同方法检测食品中大肠菌群结果的比较

评价检测食品中大肠菌群不同方法。比较国家标准、行业标准和显色培养基检测方法检测大肠菌群结果的差别。国家标准和行业标准检测结果基本一致,但有差异,应用显色培养基检测大肠菌群优于目前使用的国家标准和出口食品检验行业标准方法。检测食品中大肠菌群,显色培养基检测方法快速、灵敏、特异。     

A Model for Shaping Membrane Sheets by Protein Scaffolds

Membranes of peripheral endoplasmic reticulum form intricate morphologies consisting of tubules and sheets as basic elements. The physical mechanism of endoplasmic-reticulum shaping has been suggested to originate from the elastic behavior of the sheet edges formed by linear arrays of oligomeric protein scaffolds. The heart of this mechanism, lying in the relationships between the structure of the protein scaffolds and the effective intrinsic shapes and elastic properties of the sheets’ edges, has remained hypothetical. Here we provide a detailed computational analysis of these issues. By minimizing the elastic energy of membrane bending, we determine the effects of a rowlike array of semicircular arclike membrane scaffolds on generation of a membrane fold, which shapes the entire membrane surface into a flat double-membrane sheet. We show, quantitatively, that the sheet’s edge line tends to adopt a positive or negative curvature depending on the scaffold’s geometrical parameters. We compute the effective elastic properties of the sheet edge and analyze the dependence of the equilibrium distance between the scaffolds along the edge line on the scaffold geometry.     

鮰爱德华氏菌外膜微孔蛋白N基因PCR快速检测方法的建立

根据Gen Bank中鮰爱德华氏菌Edwardsiella ictaluri外膜微孔蛋白N(porin N)基因序列(Gen Bank No:NC_012779.2)设计了1对引物,预计目的片段大小为381 bp。通过对反应体系和条件的优化,并进行特异性试验、敏感性试验及人工感染组织样品检测,建立了一种快速检测鮰爱德华氏菌的PCR方法。结果表明,在所检测的鮰爱德华氏菌、迟缓爱德华氏菌、嗜水气单胞菌、温和气单胞菌、杀鲑气单胞菌、豚鼠气单胞菌、嗜麦芽寡养单胞菌、鲁氏耶尔森氏菌、海豚链球菌、不动杆菌、产气肠杆菌、大肠杆菌、拟态弧菌、荧光假单胞菌、弗氏柠檬酸杆菌15种细菌中仅鮰爱德华氏菌扩增出特异性条带;敏感性试验结果显示,该方法最小核酸检出量为9.35×10-3ng·μL-1;同时对人工感染的病料肝脏、细菌基因组DNA、细菌菌液及菌落进行扩增,结果显示4种材料均能检测出大小为381 bp的基因片段。本研究所建立的方法特异强、灵敏度高,适用于鮰爱德华氏菌感染病例的高效、快速检测。