Your search keyword '"Jill K. Thompson"' showing total 6 results

1. Author response: Tiled-ClickSeq for targeted sequencing of complete coronavirus genomes with simultaneous capture of RNA recombination and minority variants

Author

Jill K. Thompson, Allan McConnell, Thomas G. Ksiazek, Vineet D. Menachery, Rose M. Langsjoen, Patrick C. Newman, Rick B. Pyles, Victoria Morris, Stephanea Sotcheff, Daniele M. Swetnam, Yiyang Zhou, Scott C. Weaver, Brooke Mitchell, Rafael R. G. Machado, Steven G. Widen, Andrew Routh, Aaron L. Miller, Barbara M. Judy, Nehad Saada, Jessica A. Plante, Jianli Dong, Kenneth S. Plante, Elizabeth Jaworski, and Ping Ren

Subjects

medicine, RNA, Computational biology, Biology, medicine.disease_cause, Genome, Recombination, Coronavirus

Published

2021

2. Tiled-ClickSeq for targeted sequencing of complete coronavirus genomes with simultaneous capture of RNA recombination and minority variants

Author

Victoria Morris, Stephanea Sotcheff, Vineet D. Menachery, Yiyang Zhou, Rick B. Pyles, Jessica A. Plante, Thomas G. Ksiazek, Steven G. Widen, Andrew Routh, Scott C. Weaver, Brooke Mitchell, Allan McConnell, Daniele M. Swetnam, Rafael R. G. Machado, Jianli Dong, Kenneth S. Plante, Elizabeth Jaworski, Rose M. Langsjoen, Ping Ren, Barbara M. Judy, Nehad Saada, Patrick C. Newman, Aaron L. Miller, and Jill K. Thompson

Subjects

Polymerase Chain Reaction, Genome, Insert (molecular biology), Nanopores, Genomic library, Biology (General), Recombination, Genetic, Microbiology and Infectious Disease, General Neuroscience, Defective RNAs, High-Throughput Nucleotide Sequencing, General Medicine, Genomics, Amplicon, Tools and Resources, Viruses, Medicine, RNA, Viral, Next-Generation Sequencing, DNA, Complementary, QH301-705.5, Science, Genome, Viral, Computational biology, Biology, General Biochemistry, Genetics and Molecular Biology, DNA sequencing, Article, Complementary DNA, Humans, RNA, Messenger, Gene Library, Whole genome sequencing, General Immunology and Microbiology, Base Sequence, Whole Genome Sequencing, SARS-CoV-2, COVID-19, RNA, Genetics and Genomics, Coronavirus, Nanopore Sequencing, ClickSeq, Nucleic acid, Nanopore sequencing, Primer (molecular biology)

Abstract

High-throughput genomics of SARS-CoV-2 is essential to characterize virus evolution and to identify adaptations that affect pathogenicity or transmission. While single-nucleotide variations (SNVs) are commonly considered as driving virus adaption, RNA recombination events that delete or insert nucleic acid sequences are also critical. Whole genome targeting sequencing of SARS-CoV-2 is typically achieved using pairs of primers to generate cDNA amplicons suitable for Next-Generation Sequencing (NGS). However, paired-primer approaches impose constraints on where primers can be designed, how many amplicons are synthesized and requires multiple PCR reactions with non-overlapping primer pools. This imparts sensitivity to underlying SNVs and fails to resolve RNA recombination junctions that are not flanked by primer pairs. To address these limitations, we have designed an approach called ‘Tiled-ClickSeq’, which uses hundreds of tiled-primers spaced evenly along the virus genome in a single reverse-transcription reaction. The other end of the cDNA amplicon is generated by azido-nucleotides that stochastically terminate cDNA synthesis, removing the need for a paired-primer. A sequencing adaptor containing a Unique Molecular Identifier (UMI) is appended to the cDNA fragment using click-chemistry and a PCR reaction generates a final NGS library. Tiled-ClickSeq provides complete genome coverage, including the 5’UTR, at high depth and specificity to the virus on both Illumina and Nanopore NGS platforms. Here, we analyze multiple SARS-CoV-2 isolates and clinical samples to simultaneously characterize minority variants, sub-genomic mRNAs (sgmRNAs), structural variants (SVs) and D-RNAs. Tiled-ClickSeq therefore provides a convenient and robust platform for SARS-CoV-2 genomics that captures the full range of RNA species in a single, simple assay.

Published

2021

3. Japanese encephalitis virus live attenuated vaccine strains display altered immunogenicity, virulence and genetic diversity

Author

Alan D.T. Barrett, Emily H. Davis, Mellodee White, Steven G. Widen, Jill K. Thompson, Marianne Banks Greenberg, Andrew S. Beck, Nigel Bourne, and Li Li

Subjects

Pharmacology, Genetic diversity, Attenuated vaccine, Live attenuated vaccines, Immunogenicity, Strain (biology), Immunology, Neoplasms. Tumors. Oncology. Including cancer and carcinogens, Virulence, RC581-607, Biology, Japanese encephalitis, medicine.disease, Virology, Virus, Article, Infectious Diseases, Serial passage, medicine, Pharmacology (medical), Immunologic diseases. Allergy, human activities, RC254-282

Abstract

Japanese encephalitis virus (JEV) is the etiological agent of Japanese encephalitis (JE). The most commonly used vaccine used to prevent JE is the live-attenuated strain SA14-14-2, which was generated by serial passage of the wild-type (WT) JEV strain SA14. Two other vaccine candidates, SA14-5-3 and SA14-2-8 were derived from SA14. Both were shown to be attenuated but lacked sufficient immunogenicity to be considered effective vaccines. To better contrast the SA14-14-2 vaccine with its less-immunogenic counterparts, genetic diversity, ribavirin sensitivity, mouse virulence and mouse immunogenicity of the three vaccines were investigated. Next generation sequencing demonstrated that SA14-14-2 was significantly more diverse than both SA14-5-3 and SA14-2-8, and was slightly less diverse than WT SA14. Notably, WT SA14 had unpredictable levels of diversity across its genome whereas SA14-14-2 is highly diverse, but genetic diversity is not random, rather the virus only tolerates variability at certain residues. Using Ribavirin sensitivity in vitro, it was found that SA14-14-2 has a lower fidelity replication complex compared to SA14-5-3 and SA14-2-8. Mouse virulence studies showed that SA14-2-8 was the most virulent of the three vaccine strains while SA14-14-2 had the most favorable combination of safety (virulence) and immunogenicity for all vaccines tested. SA14-14-2 contains genetic diversity and sensitivity to the antiviral Ribavirin similar to WT parent SA14, and this genetic diversity likely explains the (1) differences in genomic sequences reported for SA14-14-2 and (2) the encoding of major attenuation determinants by the viral E protein.

Published

2020

4. Analysis By Deep Sequencing of Discontinued Neurotropic Yellow Fever Vaccine Strains

Author

Alan D.T. Barrett, Thomas G. Wood, Andrew S. Beck, Steven G. Widen, and Jill K. Thompson

Subjects

0301 basic medicine, 030106 microbiology, Reversion, Yellow fever vaccine, lcsh:Medicine, Biology, Article, Deep sequencing, Virus, Mice, 03 medical and health sciences, Yellow Fever, medicine, Animals, Humans, Child, lcsh:Science, Polymorphism, Genetic, Multidisciplinary, Viral Vaccine, Strain (biology), Encephalomyelitis, Acute Disseminated, Yellow Fever Vaccine, Yellow fever, lcsh:R, High-Throughput Nucleotide Sequencing, Sequence Analysis, DNA, medicine.disease, Virology, 3. Good health, Viral Tropism, 030104 developmental biology, Child, Preschool, Africa, lcsh:Q, Yellow fever virus, Encephalitis, medicine.drug

Abstract

Deep sequencing of live-attenuated viral vaccines has focused on vaccines in current use. Here we report characterization of a discontinued live yellow fever (YF) vaccine associated with severe adverse events. The French neurotropic vaccine (FNV) strain of YF virus was derived empirically in 1930 by 260 passages of wild-type French viscerotropic virus (FVV) in mouse brain. The vaccine was administered extensively in French-speaking Africa until discontinuation in 1982, due to high rates of post-vaccination encephalitis in children. Using rare archive strains of FNV, viral RNAs were sequenced and analyzed by massively parallel, in silico methods. Diversity and specific population structures were compared in reference to the wild-type parental strain FVV, and between the vaccine strains themselves. Lower abundance of polymorphism content was observed for FNV strains relative to FVV. Although the vaccines were of lower diversity than FVV, heterogeneity between the vaccines was observed. Reversion to wild-type identity was variably observed in the FNV strains. Specific population structures were recovered from vaccines with neurotropic properties; loss of neurotropism in mice was associated with abundance of wild-type RNA populations. The analysis provides novel sequence evidence that FNV is genetically unstable, and that adaptation of FNV contributed to the neurotropic adverse phenotype.

Published

2018

5. Attenuation of Live-Attenuated Yellow Fever 17D Vaccine Virus Is Localized to a High-Fidelity Replication Complex

Author

Jill K. Thompson, Ashley E. Strother, Steven G. Widen, Andrew S. Beck, Thomas G. Wood, Stephen Higgs, Alan D.T. Barrett, and Emily H. Davis

Subjects

ribavirin, viruses, Viral quasispecies, Vaccines, Attenuated, Antiviral Agents, Polymorphism, Single Nucleotide, Microbiology, Virus, yellow fever, 03 medical and health sciences, chemistry.chemical_compound, Serial passage, Virology, vaccine, medicine, Animals, Humans, attenuation, 030304 developmental biology, Infectivity, 0303 health sciences, biology, 030306 microbiology, Ribavirin, Viral Vaccine, Yellow fever, Yellow Fever Vaccine, Genetic Variation, RNA virus, quasispecies, live virus vaccine, Therapeutics and Prevention, biology.organism_classification, medicine.disease, QR1-502, 3. Good health, chemistry, Yellow fever virus, Research Article

Abstract

Live-attenuated viral vaccines are highly safe and efficacious but represent complex and often multigenic attenuation mechanisms. Most of these vaccines have been generated empirically by serial passaging of a wild-type (WT) virus in cell culture. One of the safest and most effective live-attenuated vaccines is yellow fever (YF) virus strain 17D, which has been used for over 80 years to control YF disease. The availability of the WT parental strain of 17D, Asibi virus, and large quantities of clinical data showing the effectiveness of the 17D vaccine make this WT parent/vaccine pair an excellent model for investigating RNA virus attenuation. Here, we investigate a mechanism of 17D attenuation and show that the vaccine virus is resistant to the antiviral compound ribavirin. The findings suggest that attenuation is in part due to a low probability of reversion or mutation of the vaccine virus genome to WT, thus maintaining a stable genotype despite external pressures., The molecular basis of attenuation for live-attenuated vaccines is poorly understood. The yellow fever (YF) 17D vaccine virus was derived from the wild-type, parental strain Asibi virus by serial passage in chicken tissue and has proven to be a very safe and efficacious vaccine. We have previously shown that wild-type Asibi is a typical RNA virus with high genetic diversity, while the 17D vaccine virus has very little genetic diversity. To investigate this further, we treated Asibi and 17D viruses with ribavirin, a GTP analog with strong antiviral activity that increases levels of mutations in the viral genome. As expected, ribavirin treatment introduced mutations into the Asibi virus genome at a very high frequency and decreased viral infectivity while, in contrast, the 17D vaccine virus was resistant to ribavirin, as treatment with the antiviral introduced very few mutations into the genome, and viral infectivity was not lost. The results were confirmed for another YF wild-type parental and vaccine pair, a wild-type French viscerotropic virus and French neurotropic vaccine. Using recombinant Asibi and 17D viruses, ribavirin sensitivity was located to viral nonstructural genes. Thus, two live-attenuated YF vaccine viruses are genetically stable even under intense mutagenic pressure, suggesting that attenuation of live-attenuated YF vaccines is due, at least in part, to fidelity of the replication complex resulting in high genetic stability.

Published

2019

6. Genome Characterization of Yellow Fever Virus Wild-Type Strain Asibi, Parent to Live-Attenuated 17D Vaccine, from Three Different Sources

Author

Alan D.T. Barrett, Emily H. Davis, Steven G. Widen, and Jill K. Thompson

Subjects

0301 basic medicine, viruses, 030106 microbiology, Genome, Viral, Biology, Vaccines, Attenuated, Asibi, Microbiology, Genome, Virus, yellow fever, 03 medical and health sciences, Viral Envelope Proteins, Virus vaccine, Serial passage, Virology, 17D vaccine, medicine, wild-type virus, Antigens, Viral, Whole Genome Sequencing, Brief Report, Strain (biology), Yellow Fever Vaccine, Yellow fever, Genetic Variation, Vaccine virus, sequencing, medicine.disease, QR1-502, 030104 developmental biology, Infectious Diseases, consensus compare, Yellow fever virus, Wild type strain

Abstract

The yellow fever virus vaccine, 17D, was derived through the serial passage of the wild-type (WT) strain Asibi virus in mouse and chicken tissue. Since its derivation, the mechanism of attenuation of 17D virus has been investigated using three 17D substrains and WT Asibi virus. Although all three substrains of 17D have been sequenced, only one isolate of Asibi has been examined genetically and all interpretation of attenuation is based on this one isolate. Here, we sequenced the genome of Asibi virus from three different laboratories and show that the WT strain is genetically homogenous at the amino acids that distinguish Asibi from 17D vaccine virus.

Published

2021