Emergence of biased hypermutation in a heterologous additional transcription unit in recombinant lentogenic Newcastle disease virus.

Recombinant Newcastle disease virus (rNDV) strains engineered to express foreign genes from an additional transcription unit (ATU) are considered as candidate live-attenuated vector vaccines for human and veterinary use. Early during the COVID-19 pandemic we and others generated COVID-19 vaccine candidates based on rNDV expressing a partial or complete SARS-CoV-2 spike (S) protein. In our studies, a number of the rNDV constructs did not show high S expression levels in cell culture or seroconversion in immunized hamsters. Sanger sequencing showed the presence of frequent A-to-G transitions characteristic of adenosine deaminase acting on RNA (ADAR). Subsequent whole genome rNDV sequencing revealed that this biased hypermutation was exclusively localized in the ATU expressing the spike gene, and was related to deamination of adenosines in the negative strand viral genome RNA. The biased hypermutation was found both after virus rescue in chicken cell line DF-1 followed by passaging in embryonated chicken eggs, and after direct virus rescue and subsequent passaging in Vero E6 cells. Levels of biased hypermutation were higher in constructs containing codon-optimized as compared to native S gene sequences, suggesting potential association with increased GC content. These data show that deep sequencing of candidate recombinant vector vaccine constructs in different phases of development is of crucial importance in the development of NDV-based vaccines.

A Flow Cytometry-Based Approach to Unravel Viral Interference with the MHC Class I Antigen Processing and Presentation Pathway.

MHC class I molecules are an important component of the cell-mediated immune defense, presenting peptides to surveilling CD8+ cytotoxic T cells. During viral infection, MHC class I molecules carry and display viral peptides at the cell surface. CD8+ T cells that recognize these peptides will eliminate the virus-infected cells. Viruses counteract this highly sophisticated host detection system by downregulating cell surface expression of MHC class I molecules.In this chapter, we describe a flow cytometry-based method that can be used for the identification of viral gene products potentially responsible for evasion from MHC class I-restricted antigen presentation. The gene(s) of interest are expressed constitutively through lentiviral transduction of cells. Subsequently, MHC I surface expression is monitored using MHC class I-specific antibodies. Once the viral gene product responsible for MHC I downregulation has been identified, the same cells can be used to elucidate the mechanism of action. The stage at which interference with antigen processing occurs can be identified using specific assays. An essential step frequently targeted by viruses is the translocation of peptides into the ER by the transporter associated with antigen processing, TAP. TAP function can be measured using a highly specific in vitro assay involving flow cytometric evaluation of the import of a fluorescent peptide substrate.The protocol described in this chapter enables the identification of virus-encoded MHC class I inhibitors that hinder antigen processing and presentation. Subsequently, their mechanism of action can be unraveled; this knowledge may help to rectify their actions.

RNA accessibility impacts potency of Tough Decoy microRNA inhibitors.

MicroRNAs (miRNAs) are small RNA molecules that post-transcriptionally regulate gene expression through silencing of complementary target mRNAs. miRNAs are involved in many biological processes, including cell proliferation, differentiation, cell signaling and cellular defense responses to infection. Strategies that allow for strong and stable suppression of specific microRNA activity are needed to study miRNA functions and to develop therapeutic intervention strategies aimed at interfering with miRNA activity in vivo. One of these classes of miRNA inhibitors are Tough Decoys (TuD) RNAs, which comprise of an imperfect RNA hairpin structure that harbors two opposing miRNA binding sites. Upon developing TuDs targeting Epstein-Barr virus miRNAs, we observed a strong variation in inhibitory potential between different TuD RNAs targeting the same miRNA. We show that the composition of the 'bulge' sequence in the miRNA binding sites has a strong impact on the inhibitory potency of the TuD. Our data implies that miRNA inhibition correlates with the thermodynamic properties of the TuD and that design aimed at lowering the TuD opening energy increases TuD potency. Our study provides specific guidelines for the design and construction of potent decoy-based miRNA inhibitors, which may be used for future therapeutic intervention strategies.

Harnessing CRISPR to combat human viral infections.

CRISPR/Cas9 is a technology that allows for targeted and precise genome editing in eukaryotic cells. The technique has changed the landscape of molecular biology and may be applied to repair genetic disorders in future therapies. Besides targeting the human genome, it can be used to cleave and edit viral DNA present in infected cells, and as such provides a promising new strategy for anti-viral therapy. Here, we discuss recent studies on the use of anti-viral CRISPRs to target pathogenic human viruses, with a focus on in vivo studies, challenges, and potential for future clinical applications.

COMADRE: a global data base of animal demography.

UNLABELLED: The open-data scientific philosophy is being widely adopted and proving to promote considerable progress in ecology and evolution. Open-data global data bases now exist on animal migration, species distribution, conservation status, etc. However, a gap exists for data on population dynamics spanning the rich diversity of the animal kingdom world-wide. This information is fundamental to our understanding of the conditions that have shaped variation in animal life histories and their relationships with the environment, as well as the determinants of invasion and extinction. Matrix population models (MPMs) are among the most widely used demographic tools by animal ecologists. MPMs project population dynamics based on the reproduction, survival and development of individuals in a population over their life cycle. The outputs from MPMs have direct biological interpretations, facilitating comparisons among animal species as different as Caenorhabditis elegans, Loxodonta africana and Homo sapiens. Thousands of animal demographic records exist in the form of MPMs, but they are dispersed throughout the literature, rendering comparative analyses difficult. Here, we introduce the COMADRE Animal Matrix Database, an open-data online repository, which in its version 1.0.0 contains data on 345 species world-wide, from 402 studies with a total of 1625 population projection matrices. COMADRE also contains ancillary information (e.g. ecoregion, taxonomy, biogeography, etc.) that facilitates interpretation of the numerous demographic metrics that can be derived from its MPMs. We provide R code to some of these examples. SYNTHESIS: We introduce the COMADRE Animal Matrix Database, a resource for animal demography. Its open-data nature, together with its ancillary information, will facilitate comparative analysis, as will the growing availability of databases focusing on other aspects of the rich animal diversity, and tools to query and combine them. Through future frequent updates of COMADRE, and its integration with other online resources, we encourage animal ecologists to tackle global ecological and evolutionary questions with unprecedented sample size.