MAVS regulates the quality of the antibody response to West-Nile Virus.

A key difference that distinguishes viral infections from protein immunizations is the recognition of viral nucleic acids by cytosolic pattern recognition receptors (PRRs). Insights into the functions of cytosolic PRRs such as the RNA-sensing Rig-I-like receptors (RLRs) in the instruction of adaptive immunity are therefore critical to understand protective immunity to infections. West Nile virus (WNV) infection of mice deficent of RLR-signaling adaptor MAVS results in a defective adaptive immune response. While this finding suggests a role for RLRs in the instruction of adaptive immunity to WNV, it is difficult to interpret due to the high WNV viremia, associated exessive antigen loads, and pathology in the absence of a MAVS-dependent innate immune response. To overcome these limitations, we have infected MAVS-deficient (MAVSKO) mice with a single-round-of-infection mutant of West Nile virus. We show that MAVSKO mice failed to produce an effective neutralizing antibody response to WNV despite normal antibody titers against the viral WNV-E protein. This defect occurred independently of antigen loads or overt pathology. The specificity of the antibody response in infected MAVSKO mice remained unchanged and was still dominated by antibodies that bound the neutralizing lateral ridge (LR) epitope in the DIII domain of WNV-E. Instead, MAVSKO mice produced IgM antibodies, the dominant isotype controlling primary WNV infection, with lower affinity for the DIII domain. Our findings suggest that RLR-dependent signals are important for the quality of the humoral immune response to WNV.

ESCRT-Dependent Cell Death in a Caenorhabditis elegans Model of the Lysosomal Storage Disorder Mucolipidosis Type IV.

Mutations in MCOLN1, which encodes the cation channel protein TRPML1, result in the neurodegenerative lysosomal storage disorder Mucolipidosis type IV. Mucolipidosis type IV patients show lysosomal dysfunction in many tissues and neuronal cell death. The ortholog of TRPML1 in Caenorhabditis elegans is CUP-5; loss of CUP-5 results in lysosomal dysfunction in many tissues and death of developing intestinal cells that results in embryonic lethality. We previously showed that a null mutation in the ATP-Binding Cassette transporter MRP-4 rescues the lysosomal defect and embryonic lethality of cup-5(null) worms. Here we show that reducing levels of the Endosomal Sorting Complex Required for Transport (ESCRT)-associated proteins DID-2, USP-50, and ALX-1/EGO-2, which mediate the final de-ubiquitination step of integral membrane proteins being sequestered into late endosomes, also almost fully suppresses cup-5(null) mutant lysosomal defects and embryonic lethality. Indeed, we show that MRP-4 protein is hypo-ubiquitinated in the absence of CUP-5 and that reducing levels of ESCRT-associated proteins suppresses this hypo-ubiquitination. Thus, increased ESCRT-associated de-ubiquitinating activity mediates the lysosomal defects and corresponding cell death phenotypes in the absence of CUP-5.

Analysis of human monoclonal antibodies generated by dengue virus-specific memory B cells.

Dengue, caused by the four serotypes of dengue virus (DENV), represents an expanding global health challenge. The potential for serotype-cross-reactive antibodies to exacerbate disease during a secondary infection with a heterologous DENV serotype has driven efforts to study human DENV-specific antibodies. Most DENV-specific antibodies generated in humans are serotype-cross-reactive, weakly neutralizing, and directed against the immature pre-membrane (prM), envelope (E), and nonstructural 1 (NS1) proteins. To broaden the characterization of human DENV-specific antibodies, we assessed B-cell responses by ELISpot assays and isolated B cells from the peripheral blood of a human subject with previous DENV infection. Forty-eight human IgG monoclonal antibodies (hMAbs) were initially characterized by their potential to bind to an inactivated lysate of DENV-infected cells. Subsequently, most DENV-specific hMAbs were found to bind soluble, recombinant E protein (rE). Two hMAbs were unable to bind rE, despite strongly binding to the DENV-infected cell lysate. Further analyses showed that these two hMAbs bound conformation-dependent, reduction-sensitive epitopes on E protein. These data shed light on the breadth of DENV-specific hMAbs generated within a single immune donor.