Isolation and Characterization of Distinct Rotavirus A in Bat and Rodent Hosts.

Rotavirus A (RVA) causes diarrheal disease in humans and various animals. Recent studies have identified bat and rodent RVAs with evidence of zoonotic transmission and genome reassortment. However, the virological properties of bat and rodent RVAs with currently identified genotypes still need to be better clarified. Here, we performed virus isolation-based screening for RVA in animal specimens and isolated RVAs (representative strains: 16-06 and MpR12) from Egyptian fruit bat and Natal multimammate mouse collected in Zambia. Whole-genome sequencing and phylogenetic analysis revealed that the genotypes of bat RVA 16-06 were identical to that of RVA BATp39 strain from the Kenyan fruit bat, which has not yet been characterized. Moreover, all segments of rodent RVA MpR12 were highly divergent and assigned to novel genotypes, but RVA MpR12 was phylogenetically closer to bat RVAs than to other rodent RVAs, indicating a unique evolutionary history. We further investigated the virological properties of the isolated RVAs. In brief, we found that 16-06 entered cells by binding to sialic acids on the cell surface, while MpR12 entered in a sialic acid-independent manner. Experimental inoculation of suckling mice with 16-06 and MpR12 revealed that these RVAs are causative agents of diarrhea. Moreover, 16-06 and MpR12 demonstrated an ability to infect and replicate in a 3D-reconstructed primary human intestinal epithelium with comparable efficiency to the human RVA. Taken together, our results detail the unique genetic and virological features of bat and rodent RVAs and demonstrate the need for further investigation of their zoonotic potential. IMPORTANCE Recent advances in nucleotide sequence detection methods have enabled the detection of RVA genomes from various animals. These studies have discovered multiple divergent RVAs and have resulted in proposals for the genetic classification of novel genotypes. However, most of these RVAs have been identified via dsRNA viral genomes and not from infectious viruses, and their virological properties, such as cell/host tropisms, transmissibility, and pathogenicity, are unclear and remain to be clarified. Here, we successfully isolated RVAs with novel genome constellations from three bats and one rodent in Zambia. In addition to whole-genome sequencing, the isolated RVAs were characterized by glycan-binding affinity, pathogenicity in mice, and infectivity to the human gut using a 3D culture of primary intestinal epithelium. Our study reveals the first virological properties of bat and rodent RVAs with high genetic diversity and unique evolutional history and provides basic knowledge to begin estimating the potential of zoonotic transmission.

Full-length galectin-8 and separate carbohydrate recognition domains: the whole is greater than the sum of its parts?

Galectin-8 (Gal-8) is a tandem-repeat type galectin with affinity for ß-galactosides, bearing two carbohydrate recognition domains (CRD) connected by a linker peptide. The N- and C-terminal domains (Gal-8N and Gal-8C) share 35% homology, and their glycan ligand specificity is notably dissimilar: while Gal-8N shows strong affinity for α(2-3)-sialylated oligosaccharides, Gal-8C has higher affinity for non-sialylated oligosaccharides, including poly-N-acetyllactosamine and/ or A and B blood group structures. Particularly relevant for understanding the biological role of this lectin, full-length Gal-8 can bind cell surface glycoconjugates with broader affinity than the isolated Gal-8N and Gal-8C domains, a trait also described for other tandem-repeat galectins. Herein, we aim to discuss the potential use of separate CRDs in modelling tandem-repeat galectin-8 and its biological functions. For this purpose, we will cover several aspects of the structure-function relationship of this protein including crystallographic structures, glycan specificity, cell function and biological roles, with the ultimate goal of understanding the potential role of each CRD in predicting full-length Gal-8 involvement in relevant biological processes.

An overview of lectin-glycan interactions: a key event in initiating fungal infection and pathogenesis.

Infections due to microfungi are of serious concern in many parts of the world. Many species of microfungi are known to cause systemic infection in human beings. Pathogenic microorganisms employ various molecular strategies for colonizing a susceptible host. Recent studies have shown the importance of lectins from microfungi that enable the pathogen to interact with the host, resulting in host immune response. These fungal lectins or adhesins show specific affinities to the glycans present on the membrane proteins or lipids. Binding of the pathogen to the receptors, probably toll-like receptors or dectins, present on the host cell surface triggers/initiates a cascade of signalling pathways, leading to the activation of transcription factors such as NF-κB resulting in the release of proinflammatory cytokines which in turn recruit cells of the immune system to the site of microbial insult to combat the pathogen or resulting in pathogenesis. In this review, we will focus on the interaction between fungal lectins and the host glycans initiating pathogenesis and how the host immune system tries to suppress the pathogenesis.

Mosquito-larvicidal BinA toxin displays affinity for glycoconjugates: Proposal for BinA mediated cytotoxicity.

Lysinibacillus sphaericus parasporal BinAB toxin displays mosquito larvicidal activity against Culex and Anopheles, but several Aedes species are refractory. Recently reported crystal structure of BinAB revealed the presence of N-terminal lectin-like domain in BinA. Hemagglutination and hemolytic activities were not observed for BinA in the present studies. We attempted to characterize carbohydrate specificity of BinA by high-throughput approaches using extrinsic fluorescence and thermofluor shift assay. A total of 34 saccharides (mono-, di- and polysaccharides, and glycoproteins) were used for initial high-throughput screening. The promising glycans were identified based on significant change in the fluorescence intensity. Surface plasmon resonance revealed differential binding of BinA with glycoproteins (fetuin, asialofetuin and thyroglobulin) and affinity for simple sugars, l-fucose and l-arabinose. In the limited carbohydrate competition assay, arabinose, fucose and fetuin inhibited BinA toxicity towards Culex larvae. This study for the first time provides direct evidence that BinA is competent to bind diverse and structurally different glycosylated proteins. This activity may be linked to its intracellular cytotoxicity, as protein N-glycosylation is thought to be critical for development and survival of insect larvae. The glycoproteins do not form stable complexes with BinA, however, as observed in the pull-down assay using affinity immobilized BinA and in native-PAGE analysis. As BinA displays only mild affinity with receptor polypeptide, we hypothesize that toxin-receptor specificity of BinA in Culex may be mediated by dual interaction of BinA with glycan core of GPI anchor and receptor polypeptide. The study shall be useful for refining strategies for improving larvicidal activity and for broadening target specificity of BinAB toxin.

Presentation, presentation, presentation! Molecular-level insight into linker effects on glycan array screening data.

Changes in cell-surface glycan patterns are markers of the presence of many different disease and cancer types, offering a relatively untapped niche for glycan-targeting reagents and therapeutics in diagnosis and treatment. Of paramount importance for the success of any glycan-targeting reagent is the ability to specifically recognize the target among the plethora of different glycans that exist in the human body. The preeminent technique for defining specificity is glycan array screening, in which a glycan-binding protein (GBP) can be simultaneously screened against multiple glycans. Glycan array screening has provided unparalleled insight into GBP specificity, but data interpretation suffers from difficulties in identifying false-negative binding arising from altered glycan presentation, associated with the linker used to conjugate the glycan to the surface. In this work, we model the structure and dynamics of the linkers employed in the glycan arrays developed by the Consortium for Functional Glycomics. The modeling takes into account the physical presence and surface polarity of the array, and provides a structure-based rationalization of false-negative results arising from the so-called "linker effect." The results also serve as a guide for interpreting glycan array screening data in a biological context; in particular, we show that attempts to employ natural amino acids as linkers may be prone to unexpected artifacts compromising glycan recognition.

Structural and Functional Characterization of PA14/Flo5-Like Adhesins From Komagataella pastoris.

Cell-cell and cell-substrate based adhesion of yeasts are major determinants of their adoption of different life styles. Genome-mining of ascomycetous GPI-anchored cell wall proteins with lectin-like PA14 domains identified a unique class of putative adhesins in the clade of methylotrophic Komagataella yeasts, many of which are known to colonize plants and insects involving yet unknown adhesion mechanisms. Here, we report the functional and structural analysis of two of its members: KpFlo1 (=Cea1), that is highly specific for terminal N-acetylglucosamine moieties, and KpFlo2, which represents an orphan lectin with intact binding site but unknown specificity. Crystal structures of the Cea1 adhesion domain complexed to N-acetylglucosamine and N,N'-diacetylchitobiose reveal a Ca2+-dependent binding mode that differs from other members of the PA14/Flo5 adhesin family. Heterologous expression of Cea1A in Saccharomyces cerevisiae promotes cellular adhesion to non-reducing ends of non-crystalline chitin. Overall, our data suggest that high-affinity recognition of ß-GlcNAc-capped glycans by Cea1 enable Komagataella species to interact with surface cues present in fungi and insects.

A Portrait of the Sialyl Glycan Receptor Specificity of the H10 Influenza Virus Hemagglutinin-A Picture of an Avian Virus on the Verge of Becoming a Pandemic?

Pandemic influenza is a constant global threat to human health. In particular, the pandemic potential of novel avian influenza viruses such as the H10N7 and H10N8 avian strains, which recently managed to cross the species barrier from birds to humans, are always of great concern as we are unlikely to have any prior immunity. Human and avian isolates of H10 influenza display the ability to rapidly adapt to replication in mammalian hosts. Fortunately, so far there is no evidence of efficient human-to-human transmission of any avian influenza virus. This review examines all of the available clinical and biological data for H10 influenza viruses with an emphasis on hemagglutinin as it is a major viral antigen that determines host range and immunity. The available glycan binding data on the influenza H10 hemagglutinin are discussed in a structure-recognition perspective. Importantly, this review raises the question of whether the emerging novel avian H10 influenza viruses truly represents a threat to global health that warrants close monitoring.

BacterialLectinDb: An integrated bacterial lectin database.

UNLABELLED: Studies of various diversified bacterial lectins/ lectin data may serve as a tool with enormous promise to help biotechnologists/ geneticists in their innovative technology to explore a deeper understanding in proteomics/ genomics research for finding the molecular basis of infectious diseases and also to new approaches for their prevention and in development of new bacterial vaccines. Hence we developed a bacterial lectin database named 'BacterialLectinDb'. An organized database schema for BacterialLectinDb was designed to collate all the available information about all bacterial lectins as a central repository. The database was designed using HTML, XML. AVAILABILITY: The database is available for free at http://www.research-bioinformatics.in.