Structural studies on the mechanisms of antibody-mediated neutralization of human rhinovirus

Antibodies represent a major component of the mammalian immunological defense against picornavirus infection. The work reviewed here examines structural details of antibody-mediated neutralization of human rhinovirus 14 (HRV14) using a combination of crystallography, molecular biology and electron microscopy. The atomic structures of the Fab fragment from a neutralizing monoclonal antibody (Fab17-IA) and HRV14 were used to interpret the ∼25Å resolution cryo-electron microscopy structure of the Fab17-IA/HRV14 complex. While there were not any observable antibody-induced conformational changes in the HRV14 upon antibody binding, there was evidence that charge interactions dominate the paratope-epitope interface and that the intact antibody might bind bivalently across icosahedral two-fold axes. Site-directed mutagenesis results confirmed that charge interactions dominate antibody binding and electron microscopy studies on the mAb17-IA/HRV14 complex confirmed that this neutralizing antibody binds bivalently across icosahedral two-fold axes.     

Structural insights into the gating mechanisms of TRPV channels

Transient Receptor Potential channels from the vanilloid subfamily (TRPV) are a group of cation channels modulated by a variety of endogenous stimuli as well as a range of natural and synthetic compounds. Their roles in human health make them of keen interest, particularly from a pharmacological perspective. However, despite this interest, the complexity of these channels has made it difficult to obtain high resolution structures until recently. With the cryo-EM resolution revolution, TRPV channel structural biology has blossomed to produce dozens of structures, covering every TRPV family member and a variety of approaches to examining channel modulation. Here, we review all currently available TRPV structures and the mechanistic insights into gating that they reveal.     

Structural insights into the neutralization mechanism of a higher primate antibody against dengue virus

The four serotypes of dengue virus (DENV-1 to -4) cause the most important emerging viral disease. Protein E, the principal viral envelope glycoprotein, mediates fusion of the viral and endosomal membranes during virus entry and is the target of neutralizing antibodies. However, the epitopes of strongly neutralizing human antibodies have not been described despite their importance to vaccine development. The chimpanzee Mab 5H2 potently neutralizes DENV-4 by binding to domain I of E. The crystal structure of Fab 5H2 bound to E from DENV-4 shows that antibody binding prevents formation of the fusogenic hairpin conformation of E, which together with in-vitro assays, demonstrates that 5H2 neutralizes by blocking membrane fusion in the endosome. Furthermore, we show that human sera from patients recovering from DENV-4 infection contain antibodies that bind to the 5H2 epitope region on domain I. This study, thus, provides new information and tools for effective vaccine design to prevent dengue disease.     

Translating innate immunity into immunological memory: implications for vaccine development

Vaccination is the most effective means of preventing infectious diseases. Despite the success of many vaccines, there is presently little knowledge of the immunological mechanisms that mediate their efficacy. Such information will be critical in the design of future vaccines against old and new infectious diseases. Recent advances in immunology are beginning to provide an intellectual framework with which to address fundamental questions about how the innate immune system shapes adaptive immunity. In this review, we summarize current knowledge about how the innate immune system modulates the quantity and quality of long-term T and B cell memory and protective immune responses to pathogens. In addition, we point out unanswered questions and identify critical challenges, the solution of which, we believe, will greatly facilitate the rational design of novel vaccines against a multitude of emerging infections.     

Trypanosoma brucei ATG8: Structural insights into autophagic-like mechanisms in protozoa

Bioinformatic searches of genome databases revealed that the number of autophagy-related genes (ATG) is considerably lower in trypanosomes than in higher eukaryotes and even in yeast. This raises the question of whether autophagy in this protozoan parasite is more primitive and represents a rudimentary paradigm due to its early branching off the evolutionary tree. We here present the crystal structure of TbATG8B. This molecule (MW 13.7 kDa) belongs to the ubiquitin-like proteins showing the typical ubiquitin fold and strong sequence homology to LC3, the human homologue. Due to its characteristic folding, it should readily bind to TbATG4.1 for being processed. This presumption was tested by molecular modeling approaches, docking TbATG8B to a homology model of TbATG4.1. Although exchanges of several amino acids are evident from sequence comparisons, the overall structure seems very much alike and the necessary catalytic triad (C-D-H) is well conserved in TbATG4.1. Thus membrane formation during appearance of the autophagic bodies seems very similar in trypanosomes and their higher eukaryotic counterpart.     

The stoichiometry of antibody-mediated neutralization and enhancement of West Nile virus infection

Antibody binding to the icosahedral arrangement of envelope proteins on the surface of flaviviruses can result in neutralization or enhancement of infection. We evaluated how many antibodies must bind to a given epitope on West Nile virus (WNV) to achieve neutralization. The most potent monoclonal antibodies (mAbs) block infection at concentrations that result in low occupancy of accessible sites on the virion, with neutralization occurring when as few as 30 of 180 envelope proteins are bound. In contrast, weakly neutralizing mAbs recognize fewer sites on the virion and require almost complete occupancy to inhibit WNV infection. For all mAbs studied, enhancement of infection is possible in cells bearing activating Fc-gamma receptors when the number of mAbs docked to the virion is not sufficient for neutralization. Thus, neutralization is best described by a model requiring "multiple hits" with the cumulative functional outcome determined by interplay between antibody affinity and epitope accessibility.     

Advances in antibody-mediated immunity against Mycobacterium tuberculosis: implications for a novel vaccine strategy

Cell-mediated immunity is considered to be the major component of the host response against Mycobacterium tuberculosis, whereas antibody-mediated immunity historically has been considered inconsequential. In recent years, studies from several groups have challenged the traditional dogma and demonstrated that monoclonal antibodies can modify various aspects of mycobacterial infections. This review describes the experimental evidence supporting a role for antibodies in defense against mycobacterial infections and outlines future challenges to the field of antibody-mediated immunity against M. tuberculosis, with particular emphasis on the implications of these findings for a novel vaccine strategy.     

Structural characterization of the O-GlcNAc cycling enzymes: insights into substrate recognition and catalytic mechanisms

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Worldwide genetic variability of the Duffy binding protein: insights into Plasmodium vivax vaccine development

The dependence of Plasmodium vivax on invasion mediated by Duffy binding protein (DBP) makes this protein a prime candidate for development of a vaccine. However, the development of a DBP-based vaccine might be hampered by the high variability of the protein ligand (DBP(II)), known to bias the immune response toward a specific DBP variant. Here, the hypothesis being investigated is that the analysis of the worldwide DBP(II) sequences will allow us to determine the minimum number of haplotypes (MNH) to be included in a DBP-based vaccine of broad coverage. For that, all DBP(II) sequences available were compiled and MNH was based on the most frequent nonsynonymous single nucleotide polymorphisms, the majority mapped on B and T cell epitopes. A preliminary analysis of DBP(II) genetic diversity from eight malaria-endemic countries estimated that a number between two to six DBP haplotypes (17 in total) would target at least 50% of parasite population circulating in each endemic region. Aiming to avoid region-specific haplotypes, we next analyzed the MNH that broadly cover worldwide parasite population. The results demonstrated that seven haplotypes would be required to cover around 60% of DBP(II) sequences available. Trying to validate these selected haplotypes per country, we found that five out of the eight countries will be covered by the MNH (67% of parasite populations, range 48-84%). In addition, to identify related subgroups of DBP(II) sequences we used a Bayesian clustering algorithm. The algorithm grouped all DBP(II) sequences in six populations that were independent of geographic origin, with ancestral populations present in different proportions in each country. In conclusion, in this first attempt to undertake a global analysis about DBP(II) variability, the results suggest that the development of DBP-based vaccine should consider multi-haplotype strategies; otherwise a putative P. vivax vaccine may not target some parasite populations.     

Structural insights into mechanisms of catalysis and inhibition in Norwalk virus polymerase

Crystal structures of Norwalk virus polymerase bound to an RNA primer-template duplex and either the natural substrate CTP or the inhibitor 5-nitrocytidine triphosphate have been determined to 1.8A resolution. These structures reveal a closed conformation of the polymerase that differs significantly from previously determined open structures of calicivirus and picornavirus polymerases. These closed complexes are trapped immediately prior to the nucleotidyl transfer reaction, with the triphosphate group of the nucleotide bound to two manganese ions at the active site, poised for reaction to the 3'-hydroxyl group of the RNA primer. The positioning of the 5-nitrocytidine triphosphate nitro group between the alpha-phosphate and the 3'-hydroxyl group of the primer suggests a novel, general approach for the design of antiviral compounds mimicking natural nucleosides and nucleotides.     

幽门螺杆菌感染引起的免疫应答及其对疫苗研制的启示

幽门螺杆菌是一种全世界范围的人类感染病原菌,人感染该菌后可以被诱导产生较强的体液免疫应答和一定程度的细胞免疫应答反应;但是,自然感染往往不能使机体产生有效的免疫保护,相反可引起对机体的免疫病理损伤,有效的疫苗应该被设计为能够诱导机体产生非病理损伤的特异的免疫保护反应,以此来预防和治疗幽门螺杆菌相关性疾病。本综述了这些方面的研究进展。     

Exosomes: New insights into cancer mechanisms

Exosomes are mobile extracellular vesicles with a diameter 40 to 150 nm. They play a critical role in several processes such as the development of cancers, intercellular signaling, drug resistance mechanisms, and cell-to-cell communication by fusion onto the cell membrane of recipient cells. These vesicles contain endogenous proteins and both noncoding and coding RNAs (microRNA and messenger RNAs) that can be delivered to various types of cells. Furthermore, exosomes exist in body fluids such as plasma, cerebrospinal fluid, and urine. Therefore, they could be used as a novel carrier to deliver therapeutic nucleic-acid drugs for cancer therapy. It was recently documented that, hypoxia promotes exosomes secretion in different tumor types leading to the activation of vascular cells and angiogenesis. Cancer cell-derived exosomes (CCEs) have been used as prognostic and diagnostic markers in many types of cancers because exosomes are stable at 4°C and −70°C. CCEs have many functional roles in tumorigenesis, metastasis, and invasion. Consequently, this review presents the data about the therapeutic application of exosomes and the role of CCEs in cancer invasion, drug resistance, and metastasis.     

Structural and functional insights into the molecular mechanisms responsible for the regulation of pyruvate dehydrogenase kinase 2

PDHK2 is a mitochondrial protein kinase that phosphorylates pyruvate dehydrogenase complex, thereby down-regulating the oxidation of pyruvate. Here, we present the crystal structure of PDHK2 bound to the inner lipoyl-bearing domain of dihydrolipoamide transacetylase (L2) determined with or without bound adenylyl imidodiphosphate. Both structures reveal a PDHK2 dimer complexed with two L2 domains. Comparison with apo-PDHK2 shows that L2 binding causes rearrangements in PDHK2 structure that affect the L2- and E1-binding sites. Significant differences are found between PDHK2 and PDHK3 with respect to the structure of their lipoyllysine-binding cavities, providing the first structural support to a number of studies showing that these isozymes are markedly different with respect to their affinity for the L2 domain. Both structures display a novel type II potassium-binding site located on the PDHK2 interface with the L2 domain. Binding of potassium ion at this site rigidifies the interface and appears to be critical in determining the strength of L2 binding. Evidence is also presented that potassium ions are indispensable for the cross-talk between the nucleotide- and L2-binding sites of PDHK2. The latter is believed to be essential for the movement of PDHK2 along the surface of the transacetylase scaffold.     

Structural insights into the clathrin coat

Clathrin is a cytoplasmic protein best known for its role in endocytosis and intracellular trafficking. The diverse nature of clathrin has recently become apparent, with strong evidence available suggesting roles in both chromosome segregation and reassembly of the Golgi apparatus during mitosis. Clathrin functions as a heterohexamer, adopting a three-legged triskelion structure of three clathrin light chains and three heavy chains. During endocytosis clathrin forms a supportive network about the invaginating membrane, interacting with itself and numerous adapter proteins. Advances in the field of structural biology have led us to a greater understanding of clathrin in its assembled state, the clathrin lattice. Combining techniques such as X-ray crystallography, NMR, and cryo-electron microscopy has allowed us to piece together the intricate nature of clathrin-coated vesicles and the interactions of clathrin with its many binding partners. In this review I outline the roles of clathrin within the cell and the recent structural advances that have improved our understanding of clathrin-clathrin and clathrin-protein interactions.     

Structural insights into the SNARE mechanism

Eukaryotic cells distribute materials among intracellular organelles and secrete into the extracellular space through cargo-loaded vesicles. A concluding step during vesicular transport is the fusion of a transport vesicle with a target membrane. SNARE proteins are essential for all vesicular fusion steps, thus they possibly comprise a conserved membrane fusion machinery. According to the "zipper" model, they assemble into stable membrane-bridging complexes that gradually bring membranes in juxtaposition. Hence, complex formation may provide the necessary energy for overcoming the repulsive forces between two membranes. During the last years, detailed structural and functional studies have extended the evidence that SNAREs are mostly in accord with the zipper model. Nevertheless, it remains unclear whether SNARE assembly between membranes directly leads to the merger of lipid bilayers.     

Structural insights into the Notch-modifying glycosyltransferase Fringe

Fringe proteins are beta1,3-N-acetylglucosaminyltransferases that modify Notch receptors, altering their ligand-binding specificity to regulate Notch signaling in development. We present the crystal structure of mouse Manic Fringe bound to UDP and manganese. The structure reveals amino acid residues involved in recognition of donor substrates and catalysis, and a putative binding pocket for acceptor substrates. Mutations of several invariant residues in this pocket impair Fringe activity in vivo.     

Virulence factors of Helicobacter pylori: implications for vaccine development

Helicobacter pylori is one of the most common infectious diseases in humans and causes gastritis, peptic ulcer disease and malignant tumours of the stomach. This review discusses how H. pylori can colonize the human stomach, an ecological niche that is protected against all other bacteria. Knowledge about the virulence factors of H. pylori has accumulated rapidly over the last decade. Together with the information contained in the complete H. pylori genome sequence, this knowledge is now being applied in the search for a vaccine against this global pathogen.