TLE1 Expression in Malignant Rhabdoid Tumor and Atypical Teratoid/Rhabdoid Tumor.

Malignant rhabdoid tumors (MRT; atypical teratoid/rhabdoid tumor [ATRT] in the central nervous system) are aggressive tumors in infants and children which can overlap with other sarcomas, such as synovial sarcoma (SS). The gold standard for SS diagnosis is characterization of the t(X;18) chromosomal translocation. However, stratification of cases for molecular analysis is not always straightforward or feasible. Recent literature suggests transducer-like enhancer of split 1 (TLE1) protein expression may distinguish SS from certain histologic mimics; however, this has not been investigated in MRT and ATRT. We stained whole-tissue sections of 18 archived cases of MRT and ATRT with TLE1. Nuclear expression was scored using a 4-tiered (0, 1+, 2+, and 3+) scale describing staining intensity, extent, or combination of both. The majority of MRT and ATRT cases showed some TLE1 immunoreactivity (n = 16; 89% for ≥1 + staining); 14 (78%) of total cases showed ≥2 + positivity using any of the 3 scoring systems. Over half (n = 10; 56%) of cases showed ≥2 + staining; 4 (22%) cases showed 3 + strong and diffuse TLE1 staining measured by all scoring systems in agreement. Although still of potential use, we urge caution in the interpretation of TLE1 when the differential diagnosis includes both SS and MRT or ATRT.

In vitro analysis of MyD88-mediated cellular immune response to West Nile virus mutant strain infection.

An attenuated West Nile virus (WNV), a nonstructural (NS) 4B-P38G mutant, induced higher innate cytokine and T cell responses than the wild-type WNV in mice. Recently, myeloid differentiation factor 88 (MyD88) signaling was shown to be important for initial T cell priming and memory T cell development during WNV NS4B-P38G mutant infection. In this study, two flow cytometry-based methods - an in vitro T cell priming assay and an intracellular cytokine staining (ICS) - were utilized to assess dendritic cells (DCs) and T cell functions. In the T cell priming assay, cell proliferation was analyzed by flow cytometry following co-culture of DCs from both groups of mice with carboxyfluorescein succinimidyl ester (CFSE) - labeled CD4(+) T cells of OTII transgenic mice. This approach provided an accurate determination of the percentage of proliferating CD4(+) T cells with significantly improved overall sensitivity than the traditional assays with radioactive reagents. A microcentrifuge tube system was used in both cell culture and cytokine staining procedures of the ICS protocol. Compared to the traditional tissue culture plate-based system, this modified procedure was easier to perform at biosafety level (BL) 3 facilities. Moreover, WNV- infected cells were treated with paraformaldehyde in both assays, which enabled further analysis outside BL3 facilities. Overall, these in vitro immunological assays can be used to efficiently assess cell-mediated immune responses during WNV infection.

A West Nile virus NS4B-P38G mutant strain induces adaptive immunity via TLR7-MyD88-dependent and independent signaling pathways.

Prior work shows that an attenuated West Nile virus (WNV), the nonstructural (NS)4B-P38G mutant infection in mice induced strong immune responses and protected host from subsequent lethal wild-type WNV infection. Here, we investigated NS4B-P38G mutant infection in myeloid differentiation factor 88-deficient (MyD88(-/-)) and Toll-like receptor 7-deficient (TLR7(-/-)) mice and found they had enhanced susceptibility compared to wild-type mice. Both groups had lower WNV-specific IgM response and reduced effector T cell functions. Dendritic cells (DCs) also exhibited a reduced maturation and impaired antigen-presenting functions compared to wild-type DCs. Moreover, infection with NS4B-P38G mutant in TLR7(-/-) and MyD88(-/-) mice provided full and partial protection respectively from subsequent challenge with lethal wild-type WNV. There were reduced T cell responses in MyD88(-/-) and interleukin-1 receptor deficient (IL-1R(-/-)) mice during secondary challenge with wild-type WNV. In contrast, TLR7(-/-) mice displayed normal T cell functions. Collectively, these results suggest that TLR7-dependent MyD88 signaling is required for T cell priming during NS4B-P38G mutant infection, whereas the TLR7-independent MyD88 signaling pathways are involved in memory T cell development, which may contribute to host protection during secondary challenge with wild-type WNV.

Vertebrate attenuated West Nile virus mutants have differing effects on vector competence in Culex tarsalis mosquitoes.

Previous mutational analyses of naturally occurring West Nile virus (WNV) strains and engineered mutant WNV strains have identified locations in the viral genome that can have profound phenotypic effect on viral infectivity, temperature sensitivity and neuroinvasiveness. We chose six mutant WNV strains to evaluate for vector competence in the natural WNV vector Culex tarsalis, two of which contain multiple ablations of glycosylation sites in the envelope and NS1 proteins; three of which contain mutations in the NS4B protein and an attenuated natural bird isolate (Bird 1153) harbouring an NS4B mutation. Despite vertebrate attenuation, all NS4B mutant viruses displayed enhanced vector competence by Cx. tarsalis. Non-glycosylated mutant viruses displayed decreased vector competence in Cx. tarsalis mosquitoes, particularly when all three NS1 glycosylation sites were abolished. These results indicate the importance of both the NS4B protein and NS1 glycosylation in the transmission of WNV by a significant mosquito vector.

Mutational analysis of the West Nile virus NS4B protein.

West Nile virus NS4B is a small hydrophobic nonstructural protein approximately 27 kDa in size whose function is poorly understood. Amino acid substitutions were introduced into the NS4B protein primarily targeting two distinct regions; the N-terminal domain (residues 35 through 60) and the central hydrophobic domain (residues 95 through 120). Only the NS4B P38G substitution was associated with both temperature-sensitive and small-plaque phenotypes. Importantly, this mutation was found to attenuate neuroinvasiveness greater than 10,000,000-fold and lower viremia titers compared to the wild-type NY99 virus in a mouse model. Full genome sequencing of the NS4B P38G mutant virus revealed two unexpected mutations at NS4B T116I and NS3 N480H (P38G/T116I/N480H), however, neither mutation alone was temperature sensitive or attenuated in mice. Following incubation of P38G/T116I/N480H at 41°C, five mutants encoding compensatory substitutions in the NS4B protein exhibited a reduction in the temperature-sensitive phenotype and reversion to a virulent phenotype in the mouse model.

Multiple amino acid changes at the first glycosylation motif in NS1 protein of West Nile virus are necessary for complete attenuation for mouse neuroinvasiveness.

West Nile virus (WNV), like all members of the Japanese encephalitis (JE) serogroup except JE virus, contains three N-linked glycosylation (N-X-S/T) sites in the NS1 protein at asparagine residues NS1(130), NS1(175) and NS1(207). Previously we showed that the ablation of these glycosylation sites in WNV, by substitution of asparagine for alanine, attenuated mouse neuroinvasiveness; however, full attenuation was not achieved and the virus retained a neurovirulence phenotype. Sequence of viral RNA extracted from mouse brains revealed a reversion at the NS1(130) site in some mice that succumbed to the attenuated NS1(130A/175A/207A) strain. Here, we further attenuated WNV by mutating the asparagine to serine or glutamine in addition to mutating other residues in the NS1(130-132) glycosylation motif. These mutants proved to further attenuate WNV for both neuroinvasiveness and neurovirulence in mice. NS1(130-132QQA/175A/207A), the most attenuated mutant virus, showed modest changes in infectivity titers versus the parental strain, was not temperature sensitive, and did not show reversion in mice. Mutant virus was completely attenuated for neuroinvasiveness after intraperitoneal inoculation with >1,000,000 PFU, and mice were protected against lethal challenge. Overall, we showed that changing the asparagine of the NS1(130) glycosylation motif to a serine or glutamine attenuated WNV further than the asparagine to alanine substitution. Further, mutating all three of the amino acids of the NS1(130-132) glycosylation motif (NTT-QQA) along with NS1(175) and NS1(207) asparagine to alanine mutations gave the most stable and attenuated strain.

Immune responses to an attenuated West Nile virus NS4B-P38G mutant strain.

The nonstructural (NS) proteins of West Nile virus (WNV) have been associated with participation in evasion of host innate immune defenses. In the present study, we characterized immune response to an attenuated WNV strain, which has a P38G substitution in the NS4B protein. The WNV NS4B-P38G mutant induced a lower level of viremia and no lethality in C57BL/6 (B6) mice following a systemic infection. Interestingly, there were higher type 1 IFNs and IL-1ß responses compared to mice infected by wild-type WNV. NS4B-P38G mutant-infected mice also showed stronger effector and memory T cell responses. WNV specific antibody responses were not different between mice infected with these two viruses. As a consequence, all mice were protected from a secondary infection with a lethal dose of wild-type WNV following a primary infection with NS4B-P38G mutant. Moreover, NS4B-P38G mutant infection in cultured bone-marrow derived dendritic cells (DCs) were shown to have a reduced replication rate, but a higher level of innate cytokine production than wild-type WNV, some of which were dependent on Myd88 signaling. In conclusion, the NS4B-P38G mutant strain induces higher protective innate and adaptive immune response in mice, which results in a lower viremia and no lethality in either primary or secondary infection, suggesting a high potential as an attenuating mutation in a vaccine candidate.

Development and characterization of non-glycosylated E and NS1 mutant viruses as a potential candidate vaccine for West Nile virus.

West Nile virus is an arthropod-borne flavivirus that has caused substantial morbidity and mortality to animals as well as humans since its introduction in to the New York area in 1999. Given that there are no antiviral drugs available for treatment of the disease, vaccines provide an efficacious alternative to control this disease. Herein we describe an attenuated WNV strain developed by the ablation of the glycosylation sites in the envelope (E) and non-structural 1 (NS1) proteins. This E(154S)/NS1(130A/175A/207A) strain showed modest reduction in multiplication kinetics in cell culture and small plaque phenotype compared to the parental NY99 strain yet displayed greater than a 200,000-fold attenuation for mouse neuroinvasiveness compared to the parental strain. Mice infected with 1000PFU of E(154S)/NS1(130A/175A/207A) showed undectable viremia at either two or three days post infection; nonetheless, high titer neutralizing antibodies were detected in mice inoculated with low doses of this virus and protected against lethal challenge with a 50% protective dose of 50PFU.

Complex adenovirus-mediated expression of West Nile virus C, PreM, E, and NS1 proteins induces both humoral and cellular immune responses.

West Nile Virus (WNV), a member of the family Flaviviridae, was first identified in Africa in 1937. In recent years, it has spread into Europe and North America. The clinical manifestations of WNV infection range from mild febrile symptoms to fatal encephalitis. Two genetic lineages (lineages I and II) are recognized; lineage II is associated with mild disease, while lineage I has been associated with severe disease, including encephalitis. WNV has now spread across North America, significantly affecting both public and veterinary health. In the efforts to develop an effective vaccine against all genetic variants of WNV, we have studied the feasibility of inducing both neutralizing and cellular immune responses by de novo synthesis of WNV antigens using a complex adenoviral vaccine (CAdVax) vector. By expressing multiple WNV proteins from a single vaccine vector, we were able to induce both humoral and cellular immune responses in vaccinated mice. Neutralization assays demonstrated that the antibodies were broadly neutralizing against both lineages of WNV, with a significant preference for the homologous lineage II virus. The results from this study show that multiple antigens synthesized de novo from a CAdVax vector are capable of inducing both humoral and cellular immune responses against WNV and that a multiantigen approach may provide broad protection against multiple genetic variants of WNV.

A single amino acid substitution in the central portion of the West Nile virus NS4B protein confers a highly attenuated phenotype in mice.

West Nile virus (WNV) NS4B is a small hydrophobic nonstructural protein that is hypothesized to participate both in viral replication and evasion of host innate immune defenses. The protein has four cysteine residues (residues 102, 120, 227, and 237). Since cysteines are often critical for the function of proteins, each of the four cysteine residues found in WNV NS4B was mutated to serine by site-directed mutagenesis. While three of these substitutions had little effect on replication or mouse virulence phenotypes, the C102S mutation was associated with a temperature-sensitive phenotype at 41 degrees C as well as attenuation of the neuroinvasive and neurovirulence phenotypes in mice.

Genome analysis and phylogenetic relationships between east, central and west African isolates of Yellow fever virus.

Yellow fever virus (YFV), a reemerging disease agent in Africa and South America, is the prototype member of the genus Flavivirus. Based on examination of the prM/M, E and 3' non-coding regions of the YFV genome, previous studies have identified seven genotypes of YFV, including the Angolan, east/central African and east African genotypes, which are highly divergent from the prototype strain Asibi. In this study, full genome analysis was used to expand upon these genetic relationships as well as on the very limited full genome database for YFV. This study was the first to investigate genomic sequences of YFV strains from east and central Africa (Angola71, Uganda48a and Ethiopia61b). All three viruses had genomes of 10 823 nt in length. Compared with the prototype strain Asibi (from west Africa) they were approximately 25 % divergent in nucleotide sequence and 7 % divergent in amino acid sequence. Comparison of multiple flaviviruses in the N-terminal region of NS4B showed that amino acid sequences were variable and that west African strains of YFV had an amino acid deletion at residue 21. Additionally, N-linked glycosylation sites were conserved between viral genotypes, while codon usage varied between strains.