Virus Propagation and Plaque Assay for Dengue Virus.

This chapter describes the methods of propagation and titration for DENV-1 to -4, which are required for most of the experiments using live viruses. DENV does not reach titers as high as those of other viruses or as high as desired for their use in biological assays. Although DENV grows in many different cell lines derived from both vertebrate and invertebrate cells, the most common cell lines used for virus isolation and propagation are mosquito cells C6/36 from Aedes albopictus. Amongst several methods for virus quantification, plaque assay stands out as being very practical and inexpensive. This technique is carried out essentially to estimate virion density in a particular material, being extremely important when evaluating the effect of an antiviral treatment or antibody neutralization capacity, for example. In this assay, viral particles are serially diluted and added onto confluent cell monolayers immersed in a semisolid medium, which is responsible for limiting virus spread throughout the culture. Therefore, regarding the medium consistency, once a virion successfully infects a cell, the newly produced particles can only infect neighboring cells, eventually leading them to death. This phenomenon can be observed as round gaps or plaques in the culture after staining live cells with a crystal violet solution. Then, plaques are counted and used to determine plaque-forming units per milliliter. Here, we describe a protocol established by our group for dengue virus (DENV) titration with porcine kidney (PS) cells.

Expression and Purification of Dengue NS1 Protein in Sf9-Baculovirus System.

It is well known that glycosylations of Dengue NS1 protein are important for its structure, oligomerization, and immunogenicity. One of the major challenges in heterologous NS1 protein expression is the difference in glycosylation patterns amongst different organisms. The two major natural hosts for Dengue virus are humans and mosquitoes, which are capable of producing very complex glycosylation motifs. This chapter presents an optimized protocol for heterologous expression and purification of Dengue NS1 protein in Sf9 cells infected with baculovirus. NS1 protein obtained from this protocol is glycosylated and capable of forming soluble hexamers that can be used for structural and functional assays.

Inflammatory signaling in dengue-infected platelets requires translation and secretion of nonstructural protein 1.

Emerging evidence identifies major contributions of platelets to inflammatory amplification in dengue, but the mechanisms of infection-driven platelet activation are not completely understood. Dengue virus nonstructural protein-1 (DENV NS1) is a viral protein secreted by infected cells with recognized roles in dengue pathogenesis, but it remains unknown whether NS1 contributes to the inflammatory phenotype of infected platelets. This study shows that recombinant DENV NS1 activated platelets toward an inflammatory phenotype that partially reproduced DENV infection. NS1 stimulation induced translocation of α-granules and release of stored factors, but not of newly synthesized interleukin-1ß (IL-1ß). Even though both NS1 and DENV were able to induce pro-IL-1ß synthesis, only DENV infection triggered caspase-1 activation and IL-1ß release by platelets. A more complete thromboinflammatory phenotype was achieved by synergistic activation of NS1 with classic platelet agonists, enhancing α-granule translocation and inducing thromboxane A2 synthesis (thrombin and platelet-activating factor), or activating caspase-1 for IL-1ß processing and secretion (adenosine triphosphate). Also, platelet activation by NS1 partially depended on toll-like receptor-4 (TLR-4), but not TLR-2/6. Finally, the platelets sustained viral genome translation and replication, but did not support the release of viral progeny to the extracellular milieu, characterizing an abortive viral infection. Although DENV infection was not productive, translation of the DENV genome led to NS1 expression and release by platelets, contributing to the activation of infected platelets through an autocrine loop. These data reveal distinct, new mechanisms for platelet activation in dengue, involving DENV genome translation and NS1-induced platelet activation via platelet TLR4.

Dengue virus nonstructural 3 protein interacts directly with human glyceraldehyde-3-phosphate dehydrogenase (GAPDH) and reduces its glycolytic activity.

Dengue is an important mosquito-borne disease and a global public health problem. The disease is caused by dengue virus (DENV), which is a member of the Flaviviridae family and contains a positive single-stranded RNA genome that encodes a single precursor polyprotein that is further cleaved into structural and non-structural proteins. Among these proteins, the non-structural 3 (NS3) protein is very important because it forms a non-covalent complex with the NS2B cofactor, thereby forming the functional viral protease. NS3 also contains a C-terminal ATPase/helicase domain that is essential for RNA replication. Here, we identified 47 NS3-interacting partners using the yeast two-hybrid system. Among those partners, we highlight several proteins involved in host energy metabolism, such as apolipoprotein H, aldolase B, cytochrome C oxidase and glyceraldehyde-3-phosphate dehydrogenase (GAPDH). GAPDH directly binds full-length NS3 and its isolated helicase and protease domains. Moreover, we observed an intense colocalization between the GAPDH and NS3 proteins in DENV2-infected Huh7.5.1 cells, in NS3-transfected BHK-21 cells and in hepatic tissue from a fatal dengue case. Taken together, these results suggest that the human GAPDH-DENV NS3 interaction is involved in hepatic metabolic alterations, which may contribute to the appearance of steatosis in dengue-infected patients. The interaction between GAPDH and full-length NS3 or its helicase domain in vitro as well as in NS3-transfected cells resulted in decreased GAPDH glycolytic activity. Reduced GAPDH glycolytic activity may lead to the accumulation of metabolic intermediates, shifting metabolism to alternative, non-glycolytic pathways. This report is the first to identify the interaction of the DENV2 NS3 protein with the GAPDH protein and to demonstrate that this interaction may play an important role in the molecular mechanism that triggers hepatic alterations.