Your search keyword '"Alnaji FG"' showing total 11 results

1. Fitness adaptations of Japanese encephalitis virus in pigs following vector-free serial passaging.

Author

Marti A, Nater A, Pego Magalhaes J, Almeida L, Lewandowska M, Liniger M, Ruggli N, Grau-Roma L, Brito F, Alnaji FG, Vignuzzi M, García-Nicolás O, and Summerfield A

Subjects

Animals, Swine, Swine Diseases virology, Swine Diseases transmission, Serial Passage, Genetic Fitness, Adaptation, Physiological, Encephalitis Virus, Japanese genetics, Encephalitis Virus, Japanese physiology, Encephalitis, Japanese transmission, Encephalitis, Japanese virology, Encephalitis, Japanese veterinary, Virus Replication

Abstract

Japanese encephalitis virus (JEV) is a zoonotic mosquito-transmitted Flavivirus circulating in birds and pigs. In humans, JEV can cause severe viral encephalitis with high mortality. Considering that vector-free direct virus transmission was observed in experimentally infected pigs, JEV introduction into an immunologically naïve pig population could result in a series of direct transmissions disrupting the alternating host cycling between vertebrates and mosquitoes. To assess the potential consequences of such a realistic scenario, we passaged JEV ten times in pigs. This resulted in higher in vivo viral replication, increased shedding, and stronger innate immune responses in pigs. Nevertheless, the viral tissue tropism remained similar, and frequency of direct transmission was not enhanced. Next generation sequencing showed single nucleotide deviations in 10% of the genome during passaging. In total, 25 point mutations were selected to reach a frequency of at least 35% in one of the passages. From these, six mutations resulted in amino acid changes located in the precursor of membrane, the envelope, the non-structural 3 and the non-structural 5 proteins. In a competition experiment with two lines of passaging, the mutation M374L in the envelope protein and N275D in the non-structural protein 5 showed a fitness advantage in pigs. Altogether, the interruption of the alternating host cycle of JEV caused a prominent selection of viral quasispecies as well as selection of de novo mutations associated with fitness gains in pigs, albeit without enhancing direct transmission frequency., Competing Interests: The authors have declared that no competing interests exist., (Copyright: © 2024 Marti et al. This is an open access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.)

Published

2024

2. Cryptic proteins translated from deletion-containing viral genomes dramatically expand the influenza virus proteome.

Author

Ranum JN, Ledwith MP, Alnaji FG, Diefenbacher M, Orton R, Sloan E, Güereca M, Feltman EM, Smollett K, da Silva Filipe A, Conley M, Russell AB, Brooke CB, Hutchinson E, and Mehle A

Subjects

Humans, RNA, Viral genetics, RNA, Viral metabolism, Virus Replication genetics, Sequence Deletion genetics, Animals, Dogs, Cell Line, Genome, Viral genetics, Influenza A virus genetics, Proteome genetics, Viral Proteins genetics, Viral Proteins metabolism

Abstract

Productive infections by RNA viruses require faithful replication of the entire genome. Yet many RNA viruses also produce deletion-containing viral genomes (DelVGs), aberrant replication products with large internal deletions. DelVGs interfere with the replication of wild-type virus and their presence in patients is associated with better clinical outcomes. The DelVG RNA itself is hypothesized to confer this interfering activity. DelVGs antagonize replication by out-competing the full-length genome and triggering innate immune responses. Here, we identify an additionally inhibitory mechanism mediated by a new class of viral proteins encoded by DelVGs. We identified hundreds of cryptic viral proteins translated from DelVGs. These DelVG-encoded proteins (DPRs) include canonical viral proteins with large internal deletions, as well as proteins with novel C-termini translated from alternative reading frames. Many DPRs retain functional domains shared with their full-length counterparts, suggesting they may have activity during infection. Mechanistic studies of DPRs derived from the influenza virus protein PB2 showed that they poison replication of wild-type virus by acting as dominant-negative inhibitors of the viral polymerase. These findings reveal that DelVGs have a dual inhibitory mechanism, acting at both the RNA and protein level. They further show that DPRs have the potential to dramatically expand the functional proteomes of diverse RNA viruses., (© The Author(s) 2024. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2024

3. Cryptic proteins translated from deletion-containing viral genomes dramatically expand the influenza virus proteome.

Author

Ranum JN, Ledwith MP, Alnaji FG, Diefenbacher M, Orton R, Sloan E, Guereca M, Feltman EM, Smollett K, da Silva Filipe A, Conley M, Russell AB, Brooke CB, Hutchinson E, and Mehle A

Abstract

Productive infections by RNA viruses require faithful replication of the entire genome. Yet many RNA viruses also produce deletion-containing viral genomes (DelVGs), aberrant replication products with large internal deletions. DelVGs interfere with the replication of wild-type virus and their presence in patients is associated with better clinical outcomes as they. The DelVG RNA itself is hypothesized to confer this interfering activity. DelVGs antagonize replication by out-competing the full-length genome and triggering innate immune responses. Here, we identify an additionally inhibitory mechanism mediated by a new class of viral proteins encoded by DelVGs. We identified hundreds of cryptic viral proteins translated from DelVGs. These DelVG-encoded proteins (DPRs) include canonical viral proteins with large internal deletions, as well as proteins with novel C-termini translated from alternative reading frames. Many DPRs retain functional domains shared with their full-length counterparts, suggesting they may have activity during infection. Mechanistic studies of DPRs derived from the influenza virus protein PB2 showed that they poison replication of wild-type virus by acting as dominant-negative inhibitors of the viral polymerase. These findings reveal that DelVGs have a dual inhibitory mechanism, acting at both the RNA and protein level. They further show that DPRs have the potential to dramatically expand the functional proteomes of diverse RNA viruses., Competing Interests: Conflict of Interest AM, JRM and MPL are inventors on a patent related to this material.

Published

2024

4. Within-host evolutionary dynamics and tissue compartmentalization during acute SARS-CoV-2 infection.

Author

Farjo M, Koelle K, Martin MA, Gibson LL, Walden KKO, Rendon G, Fields CJ, Alnaji FG, Gallagher N, Luo CH, Mostafa HH, Manabe YC, Pekosz A, Smith RL, McManus DD, and Brooke CB

Subjects

Humans, COVID-19 virology, Nose virology, Saliva virology, Male, Female, Adolescent, Young Adult, Adult, Middle Aged, Genetic Drift, SARS-CoV-2 genetics, Evolution, Molecular

Abstract

The global evolution of SARS-CoV-2 depends in part upon the evolutionary dynamics within individual hosts with varying immune histories. To characterize the within-host evolution of acute SARS-CoV-2 infection, we sequenced saliva and nasal samples collected daily from vaccinated and unvaccinated individuals early during infection. We show that longitudinal sampling facilitates high-confidence genetic variant detection and reveals evolutionary dynamics missed by less-frequent sampling strategies. Within-host dynamics in both unvaccinated and vaccinated individuals appeared largely stochastic; however, in rare cases, minor genetic variants emerged to frequencies sufficient for forward transmission. Finally, we detected significant genetic compartmentalization of viral variants between saliva and nasal swab sample sites in many individuals. Altogether, these data provide a high-resolution profile of within-host SARS-CoV-2 evolutionary dynamics.IMPORTANCEWe detail the within-host evolutionary dynamics of SARS-CoV-2 during acute infection in 31 individuals using daily longitudinal sampling. We characterized patterns of mutational accumulation for unvaccinated and vaccinated individuals, and observed that temporal variant dynamics in both groups were largely stochastic. Comparison of paired nasal and saliva samples also revealed significant genetic compartmentalization between tissue environments in multiple individuals. Our results demonstrate how selection, genetic drift, and spatial compartmentalization all play important roles in shaping the within-host evolution of SARS-CoV-2 populations during acute infection., Competing Interests: The authors declare no conflict of interest.

Published

2024

5. Mitigation of SARS-CoV-2 transmission at a large public university.

Author

Ranoa DRE, Holland RL, Alnaji FG, Green KJ, Wang L, Fredrickson RL, Wang T, Wong GN, Uelmen J, Maslov S, Weiner ZJ, Tkachenko AV, Zhang H, Liu Z, Ibrahim A, Patel SJ, Paul JM, Vance NP, Gulick JG, Satheesan SP, Galvan IJ, Miller A, Grohens J, Nelson TJ, Stevens MP, Hennessy PM, Parker RC Jr, Santos E, Brackett C, Steinman JD, Fenner MR Jr, Dohrer K, DeLorenzo M, Wilhelm-Barr L, Brauer BR, Best-Popescu C, Durack G, Wetter N, Kranz DM, Breitbarth J, Simpson C, Pryde JA, Kaler RN, Harris C, Vance AC, Silotto JL, Johnson M, Valera EA, Anton PK, Mwilambwe L, Bryan SP, Stone DS, Young DB, Ward WE, Lantz J, Vozenilek JA, Bashir R, Moore JS, Garg M, Cooper JC, Snyder G, Lore MH, Yocum DL, Cohen NJ, Novakofski JE, Loots MJ, Ballard RL, Band M, Banks KM, Barnes JD, Bentea I, Black J, Busch J, Conte A, Conte M, Curry M, Eardley J, Edwards A, Eggett T, Fleurimont J, Foster D, Fouke BW, Gallagher N, Gastala N, Genung SA, Glueck D, Gray B, Greta A, Healy RM, Hetrick A, Holterman AA, Ismail N, Jasenof I, Kelly P, Kielbasa A, Kiesel T, Kindle LM, Lipking RL, Manabe YC, Mayes J, McGuffin R, McHenry KG, Mirza A, Moseley J, Mostafa HH, Mumford M, Munoz K, Murray AD, Nolan M, Parikh NA, Pekosz A, Pflugmacher J, Phillips JM, Pitts C, Potter MC, Quisenberry J, Rear J, Robinson ML, Rosillo E, Rye LN, Sherwood M, Simon A, Singson JM, Skadden C, Skelton TH, Smith C, Stech M, Thomas R, Tomaszewski MA, Tyburski EA, Vanwingerden S, Vlach E, Watkins RS, Watson K, White KC, Killeen TL, Jones RJ, Cangellaris AC, Martinis SA, Vaid A, Brooke CB, Walsh JT, Elbanna A, Sullivan WC, Smith RL, Goldenfeld N, Fan TM, Hergenrother PJ, and Burke MD

Subjects

COVID-19 Testing, Humans, Sensitivity and Specificity, Universities, COVID-19 epidemiology, COVID-19 prevention & control, SARS-CoV-2 genetics

Abstract

In Fall 2020, universities saw extensive transmission of SARS-CoV-2 among their populations, threatening health of the university and surrounding communities, and viability of in-person instruction. Here we report a case study at the University of Illinois at Urbana-Champaign, where a multimodal "SHIELD: Target, Test, and Tell" program, with other non-pharmaceutical interventions, was employed to keep classrooms and laboratories open. The program included epidemiological modeling and surveillance, fast/frequent testing using a novel low-cost and scalable saliva-based RT-qPCR assay for SARS-CoV-2 that bypasses RNA extraction, called covidSHIELD, and digital tools for communication and compliance. In Fall 2020, we performed >1,000,000 covidSHIELD tests, positivity rates remained low, we had zero COVID-19-related hospitalizations or deaths amongst our university community, and mortality in the surrounding Champaign County was reduced more than 4-fold relative to expected. This case study shows that fast/frequent testing and other interventions mitigated transmission of SARS-CoV-2 at a large public university., (© 2022. The Author(s).)

Published

2022

6. Generated Randomly and Selected Functionally? The Nature of Enterovirus Recombination.

Author

Alnaji FG, Bentley K, Pearson A, Woodman A, Moore J, Fox H, Macadam AJ, and Evans DJ

Subjects

Antigens, Viral, Genome, Viral, Humans, RNA, Recombination, Genetic, Enterovirus genetics, Enterovirus Infections, Poliovirus genetics

Abstract

Genetic recombination in RNA viruses is an important evolutionary mechanism. It contributes to population diversity, host/tissue adaptation, and compromises vaccine efficacy. Both the molecular mechanism and initial products of recombination are relatively poorly understood. We used an established poliovirus-based in vitro recombination assay to investigate the roles of sequence identity and RNA structure, implicated or inferred from an analysis of circulating recombinant viruses, in the process. In addition, we used next-generation sequencing to investigate the early products of recombination after cellular coinfection with different poliovirus serotypes. In independent studies, we find no evidence for a role for RNA identity or structure in determining recombination junctions location. Instead, genome function and fitness are of greater importance in determining the identity of recombinant progeny. These studies provide further insights into this important evolutionary mechanism and emphasize the critical nature of the selection process on a mixed virus population.

Published

2022

7. Influenza A Virus Defective Viral Genomes Are Inefficiently Packaged into Virions Relative to Wild-Type Genomic RNAs.

Author

Alnaji FG, Reiser WK, Rivera-Cardona J, Te Velthuis AJW, and Brooke CB

Subjects

Defective Interfering Viruses genetics, Humans, Influenza A virus genetics, Influenza, Human virology, RNA, Viral genetics, RNA, Viral metabolism, Virion genetics, Virus Replication, Defective Interfering Viruses physiology, Genome, Viral, Influenza A virus physiology, Viral Genome Packaging, Virion physiology

Abstract

Deletion-containing viral genomes (DelVGs) are commonly produced during influenza A virus infection and have been implicated in influencing clinical infection outcomes. Despite their ubiquity, the specific molecular mechanisms that govern DelVG formation and their packaging into defective interfering particles (DIPs) remain poorly understood. Here, we utilized next-generation sequencing to analyze DelVGs that form de novo early during infection, prior to packaging. Analysis of these early DelVGs revealed that deletion formation occurs in clearly defined hot spots and is significantly associated with both direct sequence repeats and enrichment of adenosine and uridine bases. By comparing intracellular DelVGs with those packaged into extracellular virions, we discovered that DelVGs face a significant bottleneck during genome packaging relative to wild-type genomic RNAs. Interestingly, packaged DelVGs exhibited signs of enrichment for larger DelVGs suggesting that size is an important determinant of packaging efficiency. Our data provide the first unbiased, high-resolution portrait of the diversity of DelVGs that are generated by the influenza A virus replication machinery and shed light on the mechanisms that underly DelVG formation and packaging. IMPORTANCE Defective interfering particles (DIPs) are commonly produced by RNA viruses and have been implicated in modulating clinical infection outcomes; hence, there is increasing interest in the potential of DIPs as antiviral therapeutics. For influenza viruses, DIPs are formed by the packaging of genomic RNAs harboring internal deletions. Despite decades of study, the mechanisms that drive the formation of these deletion-containing viral genomes (DelVGs) remain elusive. Here, we used a specialized sequencing pipeline to characterize the first wave of DelVGs that form during influenza virus infection. This data set provides an unbiased profile of the deletion-forming preferences of the influenza virus replicase. In addition, by comparing the early intracellular DelVGs to those that get packaged into extracellular virions, we described a significant segment-specific bottleneck that limits DelVG packaging relative to wild-type viral RNAs. Altogether, these findings reveal factors that govern the production of both DelVGs and DIPs during influenza virus infection.

Published

2021

8. Semi-continuous Propagation of Influenza A Virus and Its Defective Interfering Particles: Analyzing the Dynamic Competition To Select Candidates for Antiviral Therapy.

Author

Pelz L, Rüdiger D, Dogra T, Alnaji FG, Genzel Y, Brooke CB, Kupke SY, and Reichl U

Subjects

Animals, Cell Culture Techniques, Cell Line, Defective Interfering Viruses, Defective Viruses genetics, Dogs, Gene Deletion, Genome, Viral, Humans, Immunity, Innate drug effects, Madin Darby Canine Kidney Cells, Oscillometry, Real-Time Polymerase Chain Reaction, Viral Load drug effects, Virus Replication drug effects, Antiviral Agents pharmacology, Drug Design methods, Influenza A virus, Influenza, Human virology, RNA, Viral

Abstract

Defective interfering particles (DIPs) of influenza A virus (IAV) are naturally occurring mutants that have an internal deletion in one of their eight viral RNA (vRNA) segments, rendering them propagation-incompetent. Upon coinfection with infectious standard virus (STV), DIPs interfere with STV replication through competitive inhibition. Thus, DIPs are proposed as potent antivirals for treatment of the influenza disease. To select corresponding candidates, we studied de novo generation of DIPs and propagation competition between different defective interfering (DI) vRNAs in an STV coinfection scenario in cell culture. A small-scale two-stage cultivation system that allows long-term semi-continuous propagation of IAV and its DIPs was used. Strong periodic oscillations in virus titers were observed due to the dynamic interaction of DIPs and STVs. Using next-generation sequencing, we detected a predominant formation and accumulation of DI vRNAs on the polymerase-encoding segments. Short DI vRNAs accumulated to higher fractions than longer ones, indicating a replication advantage, yet an optimum fragment length was observed. Some DI vRNAs showed breaking points in a specific part of their bundling signal (belonging to the packaging signal), suggesting its dispensability for DI vRNA propagation. Over a total cultivation time of 21 days, several individual DI vRNAs accumulated to high fractions, while others decreased. Using reverse genetics for IAV, purely clonal DIPs derived from highly replicating DI vRNAs were generated. We confirm that these DIPs exhibit a superior in vitro interfering efficacy compared to DIPs derived from lowly accumulated DI vRNAs and suggest promising candidates for efficacious antiviral treatment. IMPORTANCE Defective interfering particles (DIPs) emerge naturally during viral infection and typically show an internal deletion in the viral genome. Thus, DIPs are propagation-incompetent. Previous research suggests DIPs as potent antiviral compounds for many different virus families due to their ability to interfere with virus replication by competitive inhibition. For instance, the administration of influenza A virus (IAV) DIPs resulted in a rescue of mice from an otherwise lethal IAV dose. Moreover, no apparent toxic effects were observed when only DIPs were administered to mice and ferrets. IAV DIPs show antiviral activity against many different IAV strains, including pandemic and highly pathogenic avian strains, and even against nonhomologous viruses, such as SARS-CoV-2, by stimulation of innate immunity. Here, we used a cultivation/infection system, which exerted selection pressure toward accumulation of highly competitive IAV DIPs. These DIPs showed a superior interfering efficacy in vitro , and we suggest them for effective antiviral therapy.

Published

2021

9. Imprecise recombinant viruses evolve via a fitness-driven, iterative process of polymerase template-switching events.

Author

Bentley K, Alnaji FG, Woodford L, Jones S, Woodman A, and Evans DJ

Subjects

HeLa Cells, Humans, Poliovirus growth & development, RNA-Dependent RNA Polymerase genetics, Transcriptome, Biological Evolution, Genetic Fitness, Genome, Viral, Poliovirus genetics, RNA, Viral genetics, RNA-Dependent RNA Polymerase metabolism, Recombination, Genetic

Abstract

Recombination is a common feature of many positive-strand RNA viruses, playing an important role in virus evolution. However, to date, there is limited understanding of the mechanisms behind the process. Utilising in vitro assays, we have previously shown that the template-switching event of recombination is a random and ubiquitous process that often leads to recombinant viruses with imprecise genomes containing sequence duplications. Subsequently, a process termed resolution, that has yet to be mechanistically studied, removes these duplicated sequences resulting in a virus population of wild type length genomes. Using defined imprecise recombinant viruses together with Oxford Nanopore and Illumina high throughput next generation sequencing technologies we have investigated the process of resolution. We show that genome resolution involves subsequent rounds of template-switching recombination with viral fitness resulting in the survival of a small subset of recombinant genomes. This alters our previously held understanding that recombination and resolution are independent steps of the process, and instead demonstrates that viruses undergo frequent and continuous recombination events over a prolonged period until the fittest viruses, predominantly those with wild type length genomes, dominate the population., Competing Interests: The authors have declared that no competing interests exist.

Published

2021

10. Influenza virus DI particles: Defective interfering or delightfully interesting?

Author

Alnaji FG and Brooke CB

Subjects

Animals, Defective Viruses physiology, Humans, Influenza, Human genetics, Orthomyxoviridae genetics, Orthomyxoviridae Infections genetics, RNA, Viral genetics, RNA, Viral metabolism, Virion genetics, Virion metabolism, Virus Replication genetics, Defective Viruses genetics, Defective Viruses metabolism, Orthomyxoviridae metabolism

Abstract

Competing Interests: The authors have declared that no competing interests exist.

Published

2020

11. Sequencing Framework for the Sensitive Detection and Precise Mapping of Defective Interfering Particle-Associated Deletions across Influenza A and B Viruses.

Author

Alnaji FG, Holmes JR, Rendon G, Vera JC, Fields CJ, Martin BE, and Brooke CB

Subjects

Genome, Viral, Humans, Influenza A virus genetics, Influenza B virus genetics, Influenza, Human virology, Orthomyxoviridae genetics, Orthomyxoviridae Infections genetics, Sequence Deletion, Virus Replication, Computational Biology methods, Defective Viruses genetics, High-Throughput Nucleotide Sequencing methods

Abstract

The mechanisms and consequences of defective interfering particle (DIP) formation during influenza virus infection remain poorly understood. The development of next-generation sequencing (NGS) technologies has made it possible to identify large numbers of DIP-associated sequences, providing a powerful tool to better understand their biological relevance. However, NGS approaches pose numerous technical challenges, including the precise identification and mapping of deletion junctions in the presence of frequent mutation and base-calling errors, and the potential for numerous experimental and computational artifacts. Here, we detail an Illumina-based sequencing framework and bioinformatics pipeline capable of generating highly accurate and reproducible profiles of DIP-associated junction sequences. We use a combination of simulated and experimental control data sets to optimize pipeline performance and demonstrate the absence of significant artifacts. Finally, we use this optimized pipeline to reveal how the patterns of DIP-associated junction formation differ between different strains and subtypes of influenza A and B viruses and to demonstrate how these data can provide insight into mechanisms of DIP formation. Overall, this work provides a detailed roadmap for high-resolution profiling and analysis of DIP-associated sequences within influenza virus populations. IMPORTANCE Influenza virus defective interfering particles (DIPs) that harbor internal deletions within their genomes occur naturally during infection in humans and during cell culture. They have been hypothesized to influence the pathogenicity of the virus; however, their specific function remains elusive. The accurate detection of DIP-associated deletion junctions is crucial for understanding DIP biology but is complicated by an array of technical issues that can bias or confound results. Here, we demonstrate a combined experimental and computational framework for detecting DIP-associated deletion junctions using next-generation sequencing (NGS). We detail how to validate pipeline performance and provide the bioinformatics pipeline for groups interested in using it. Using this optimized pipeline, we detect hundreds of distinct deletion junctions generated during infection with a diverse panel of influenza viruses and use these data to test a long-standing hypothesis concerning the molecular details of DIP formation., (Copyright © 2019 American Society for Microbiology.)

Published

2019