Project description:Yellow fever virus, a prototypical member of the Flaviviridae family, is a small single-stranded, positive sense enveloped RNA virus causing viscerotropic, frequently fatal disease. Serial passaging of the virulent YFV Asibi strain in the 1930s yielded the YFV17D strain which remains one of the most effective vaccines ever developed. Remarkably, YFV17D and the virulent parental genome differ only by 68 nucleotides leading to 32 amino acid changes. However, it remains largely unknown which of these sequence differences are responsible for attenuation. Here, we demonstrate that while synonymous mutations are highly conserved across pathogenic YFVs they do not contribute to the characteristic host responses elicited by 17D or virulent viruses. Using a highly modular combinatorial genetic approach we identified key genetic elements in the YFV envelope and non-structural 2A (NS2A) proteins that govern the virus’ ability to spread and suppress host responses.. Introducing these mutations into infectious clones of other YFV genomes results in viral attenuation in vitro and in vivo. Collectively, our results define the genetic basis for YFV17D attenuation and highlight a general approach for creating live-attenuated vaccines for other pathogenic viruses.

Project description:Yellow fever virus, a prototypical member of the Flaviviridae family, is a small single-stranded, positive sense enveloped RNA virus causing viscerotropic, frequently fatal disease. Serial passaging of the virulent YFV Asibi strain in the 1930s yielded the YFV17D strain which remains one of the most effective vaccines ever developed. Remarkably, YFV17D and the virulent parental genome differ only by 68 nucleotides leading to 32 amino acid changes. However, it remains largely unknown which of these sequence differences are responsible for attenuation. Here, we demonstrate that while synonymous mutations are highly conserved across pathogenic YFVs they do not contribute to the characteristic host responses elicited by 17D or virulent viruses. Using a highly modular combinatorial genetic approach we identified key genetic elements in the YFV envelope and non-structural 2A (NS2A) proteins that govern the virus’ ability to spread and suppress host responses.. Introducing these mutations into infectious clones of other YFV genomes results in viral attenuation in vitro and in vivo. Collectively, our results define the genetic basis for YFV17D attenuation and highlight a general approach for creating live-attenuated vaccines for other pathogenic viruses.

Project description:Live-attenuated viral vaccines have been successfully used to combat infectious disease for decades but due to their empirical derivation, little is known about their mechanisms of attenuation. This lack of understanding makes the development of next generation live attenuated vaccines difficult. The success of the 17D vaccine and availability of the parent virus, Asibi, makes it an excellent model to understand the molecular basis of attenuation of a live attenuated vaccine and the effects of viral diversity on vaccine function. Due to the differences in genetic diversity between WT Asibi virus and its 17D vaccine derivative, we investigated the changes in genetic diversity of 17D and Asibi viruses following treatment with ribavirin.

Project description:With the advent of advanced sequencing technology, studies of RNA viruses have shown that genetic diversity contribute to both attenuation and virulence. The differences in genetic diversity of wild-type Asibi virus and 17D-204 vaccine provides an unique opportunity to investigate RNA population theory in the context of a well described live attenuated vaccine. Utilizing infectious clone-derived viruses containing some of the amino acid substitutions that differentiate yellow fever wild-type Asibi strain from 17D vaccine and recovered in a controlled experiment, establishes that the genetic diversity differences that exist between wild-type Asibi and 17D-204 vaccine viruses are not influenced by either different passage history or source of samples, but rather resulted from the attenuation of wild-type Asibi virus to yield the 17D vaccine sub-strains.

Project description:The yellow fever virus 17D (YFV-17D) live attenuated vaccine is considered one of the successful vaccines ever generated associated with high antiviral immunity, yet the signaling mechanisms that drive the response in infected cells are not understood. Here, we provide a molecular understanding of how metabolic stress and innate immune responses are linked to drive type I IFN expression in response to YFV-17D infection. Comparison of YFV-17D replication with its parental virus, YFV-Asibi, and a related dengue virus revealed that IFN expression requires RIG-I-like Receptor signaling through MAVS, as expected. However, YFV-17D uniquely induces mitochondrial respiration and major metabolic perturbations, including hyperactivation of electron transport to fuel ATP synthase. Mitochondrial hyperactivity generates reactive oxygen species (ROS) including peroxynitrite, blocking of which abrogated MAVS oligomerization and IFN expression in non-immune cells without reducing YFV-17D replication. Scavenging ROS in YFV-17D-infected human dendritic cells increased cell viability yet globally prevented expression of IFN signaling pathways. Thus, adaptation of YFV-17D for high growth imparts mitochondrial hyperactivity to meet energy demands, resulting in generation of ROS as the critical messengers that convert a blunted IFN response into maximal activation of innate immunity essential for vaccine effectiveness.

Project description:Zika virus (ZIKV) is a mosquito-transmitted positive-sense RNA virus in the family Flaviviridae. Live attenuated vaccines have been successfully used to combat infection by flaviviruses, such as yellow fever and Japanese encephalitis viruses. A Zika virus harboring combined mutations in the envelope protein glycosylation site and in the nonstructural 4B protein amino acid 36 (ZE4B-36) was generated and assessed for stability, attenuation, and protection against infection. To determine the genetic stability of its RNA genome, ZE4B-36 was serially passaged in vitro in Vero cells. Virus harvested from passages (P)1 to P6 was subjected to next generation sequencing and downstream analysis to determine its nucleotide sequence variability. Specifically, single nucleotide variant analysis showed that the ZE4B-36 genome decreased its genetic diversity and resulted in a more stable nucleotide sequence. Thus, in addition to showing attenuation and protection, ZE4B-36 is a stable live attenuated virus that possesses characteristics important for a vaccine to combat Zika disease.

Project description:Yellow fever (YF) is a life-threatening mosquito-borne disease prevalent in South America and Africa, accounting for up to 60,000 annual deaths. Between December 2016 and May 2018, Brazil reported its worst YF outbreak this century with a fatality rate of 33.6%. While YF vaccines have shown protective capabilities, the genetic profile of those infected with the wild-type YF virus (YFV) remains uncharacterized. Building on recent findings by Kallas et al. (2019), which discerned clinical and immunological determinants of YF mortality, we conducted a comprehensive transcriptional profiling of blood samples from YFV-infected patients. Our investigation integrated omics data with clinical and immunological metrics, contrasting the wild-type YFV acute infection signature against the response triggered by the YF17D vaccine strain and the signature linked to severe COVID-19. Our analyses revealed key molecular mechanisms of YFV infection and determinants of disease severity. Notably, a comparative assessment elucidated distinct gene expression patterns between wild-type YFV infections, YF17D vaccination, and severe COVID-19. This study offers pivotal insights into the molecular underpinnings of YFV infection and its severity, potentially enhancing our comprehension of viral infections at large.

Project description:Changes in transcription in bovine dendritic cells after infection with virulent or avirulent <br>rinderpest viruses., measles virus or mock infection.

Project description:Highly pathogenic influenza virus inhibit Inflammatory Responses in Monocytes via Activation of the Rar-Related Orphan Receptor Alpha (RORalpha). Low (PR8) and high pathogenic influenza viruses (FPV and H5N1) were used. Monocytes were infected with low (PR8) and high pathogenic influenza viruses (FPV and H5N1)

Project description:Ducks and wild aquatic birds are the natural reservoirs of avian influenza viruses. However, the host proteome response that causes disease in vivo during infection by the highly pathogenic avian influenza (HPAI) H5N1 virus is still not well understood. In the present study, we compared the proteome response in Muscovy duck lung tissue during 3 day of infection with either a highly virulent or an avirulent H5N1 virus. During infection, proteins involved in immune response of neutrophils and size of cells were increased markedly in the lung by the virulent strain, while the avirulent strain evoked a distinct response, characterized by an increase in proteins involved in cell movement, maturation of dendritic cells, adhesion of phagocytes, and immune response of macrophages.