Signaling from multiple receptor tyrosine kinases (RTK) contributes to therapeutic resistance in glioblastoma (GBM). Heparan sulfate (HS), present on cell surfaces and in the extracellular matrix, regulates cell signaling via several mechanisms. To investigate the role for HS in promoting RTK signaling in GBM, we generated neural progenitor cells deficient for HS by knockout of the essential HS-biosynthetic enzyme
Heparan sulfate proteoglycans (HSPGs) play crucial roles in a number of signaling pathways during development through binding to various secreted molecules such as FGF, WNT, SHH and BMP. Most of the studies examined the interactions between these secreted proteins with monomeric heparin sequences. However, almost all endogenous proteoglycans (PGs) possess two or more glycosaminoglycan (GAG) chains. This study is the first attempt to stimulate the expressions of endogenous PG mimetics with two or more HS chains connected covalently in an animal model to investigate the roles of these molecules in various signaling events. A library of monomeric and multimeric xylosides, which prime GAG chains, was examined in zebrafish embryos. We found that only clustered HS chains primed by multimeric xylosides hyperactivated the FGF/FGFR mediated signaling pathways leading to elongation of zebrafish embryos. Based on our findings, we propose that multimeric HS is required for the formation of biologically relevant HS/FGF/FGFR ternary complexes, leading to receptor dimerization in vivo and subsequent cell signaling events.
Heparan sulfate (HS) glucosaminyl 3-O-sulfotranferases sulfate the C3-hydroxyl group of certain glucosamine residues on heparan sulfate. Six different 3-OST isoforms exist, each of which can sulfate very distinct glucosamine residues within the HS chain. Among these isoforms, 3-OST1 has been shown to play a role in generating ATIII-binding HS anticoagulants whereas 3-OST2, 3-OST3, 3-OST4 and 3OST-6 have been shown to play a vital role in generating gD-binding HS chains that permit the entry of herpes simplex virus type 1 into cells. 3-OST5 has been found to generate both ATIII- and gD-binding HS motifs. Previous studies have examined the substrate specificities of all the 3-OST isoforms using HS polysaccharides. However, very few studies have examined the contribution of the epimer configuration of neighboring uronic acid residues next to the target site to 3-OST action. In this study, we utilized a well-defined synthetic oligosaccharide library to examine the substrate specificity of 3-OST3a and compared it to 3-OST1. We found that both 3-OST1 and 3-OST3a preferentially sulfate the 6-O-sulfated, N-sulfoglucosamine when an adjacent iduronyl residue is located to its reducing side. On the other hand, 2-O-sulfation of this uronyl residue can inhibit the action of 3-OST3a on the target residue. The results reveal novel substrate sites for the enzyme actions of 3-OST3a. It is also evident that both these enzymes have promiscuous and overlapping actions that are differentially regulated by iduronyl 2-O-sulfation.
ABSTRACT The continual public health threat posed by the emergence of novel influenza viruses necessitates the ability to rapidly monitor infection and spread in experimental systems. To analyze real-time infection dynamics, we have created a replication-competent influenza reporter virus suitable for in vivo imaging. The reporter virus encodes the small and bright NanoLuc luciferase whose activity serves as an extremely sensitive readout of viral infection. This virus stably maintains the reporter construct and replicates in culture and in mice with near-native properties. Bioluminescent imaging of the reporter virus permits serial observations of viral load and dissemination in infected animals, even following clearance of a sublethal challenge. We further show that the reporter virus recapitulates known restrictions due to host range and antiviral treatment, suggesting that this technology can be applied to studying emerging influenza viruses and the impact of antiviral interventions on infections in vivo . These results describe a generalizable method to quickly determine the replication and pathogenicity potential of diverse influenza strains in animals.
