Your search keyword '"Danzy S"' showing total 7 results

1. Influenza virus infection and aerosol shedding kinetics in a controlled human infection model.

Author

Shetty N, Shephard MJ, Rockey NC, Macenczak H, Traenkner J, Danzy S, Vargas-Maldonado N, Arts PJ, Le Sage V, Anderson EJ, Lyon GM, Fitts EC, Gulick DA, Mehta AK, El-Chami MF, Kraft CS, Wigginton KR, Lowen AC, Marr LC, Rouphael NG, and Lakdawala SS

Abstract

Establishing effective mitigation strategies to reduce the spread of influenza virus requires an improved understanding of the mechanisms of transmission. We evaluated the use of a controlled human infection model using an H3N2 seasonal influenza virus to study critical aspects of transmission, including symptom progression and the dynamics of virus shedding. Eight volunteers were challenged with influenza A/Perth/16/2009 (H3N2) virus between July and September 2022 at Emory University Hospital. Viral shedding in the nasopharynx, saliva, stool, urine, and respiratory aerosols was monitored over the quarantine period, and symptoms were tracked until day 15. In addition, environmental swabs were collected from participant rooms to examine fomite contamination, and participant sera were collected to assess seroconversion by hemagglutination inhibition or microneutralization assays. Among the eight participants, influenza virus infection was confirmed in six (75%). Infectious virus or viral RNA was found in multiple physiological compartments, fecal samples, aerosol particles, and on surfaces in the immediate environment. Illness was moderate, with upper respiratory symptoms dominating. In participants with the highest viral loads, antibody titers rose by day 15 post-inoculation, while in participants with low or undetectable viral loads, there was little or no increase in functional antibody titers. These data demonstrate the safety and utility of the human infection model to study features critical to influenza virus transmission dynamics in a controlled manner and will inform the design of future challenge studies focused on modeling and limiting transmission.CLINICAL TRIALSThis study is registered with ClinicalTrials.gov as NCT05332899., Importance: We use a controlled human infection model to assess respiratory and aerosol shedding kinetics to expand our knowledge of influenza infection dynamics and help inform future studies aimed at understanding human-to-human transmission.

Published

2024

2. Both Humoral and Cellular Immunity Limit the Ability of Live Attenuated Influenza Vaccines to Promote T Cell Responses.

Author

Lobby JL, Danzy S, Holmes KE, Lowen AC, and Kohlmeier JE

Subjects

Animals, Mice, Humans, Antibodies, Viral, Immunity, Cellular, CD8-Positive T-Lymphocytes, Vaccines, Attenuated, Influenza, Human, Influenza Vaccines

Abstract

One potential advantage of live attenuated influenza vaccines (LAIVs) is their ability to establish both virus-specific Ab and tissue-resident memory T cells (TRM) in the respiratory mucosa. However, it is hypothesized that pre-existing immunity from past infections and/or immunizations prevents LAIV from boosting or generating de novo CD8+ T cell responses. To determine whether we can overcome this limitation, we generated a series of drifted influenza A/PR8 LAIVs with successive mutations in the hemagglutinin protein, allowing for increasing levels of escape from pre-existing Ab. We also inserted a CD8+ T cell epitope from the Sendai virus nucleoprotein (NP) to assess both generation of a de novo T cell response and boosting of pre-existing influenza-specific CD8+ T cells following LAIV immunization. Increasing the level of escape from Ab enabled boosting of pre-existing TRM, but we were unable to generate de novo Sendai virus NP+ CD8+ TRM following LAIV immunization in PR8 influenza-immune mice, even with LAIV strains that can fully escape pre-existing Ab. As these data suggested a role for cell-mediated immunity in limiting LAIV efficacy, we investigated several scenarios to assess the impact of pre-existing LAIV-specific TRM in the upper and lower respiratory tract. Ultimately, we found that deletion of the immunodominant influenza NP366-374 epitope allowed for sufficient escape from cellular immunity to establish de novo CD8+ TRM. When combined, these studies demonstrate that both pre-existing humoral and cellular immunity can limit the effectiveness of LAIV, which is an important consideration for future design of vaccine vectors against respiratory pathogens., (Copyright © 2023 by The American Association of Immunologists, Inc.)

Published

2024

3. A quantitative approach to assess influenza A virus fitness and transmission in guinea pigs.

Author

Danzy S, Lowen AC, and Steel J

Abstract

Efforts to estimate the risk posed by potentially pandemic influenza A viruses (IAV), and to understand the mechanisms governing interspecies transmission, have been hampered by a lack of animal models that yield relevant and statistically robust measures of viral fitness. To address this gap, we monitored several quantitative measures of fitness in a guinea pig model: infectivity, magnitude of replication, kinetics of replication, efficiency of transmission, and kinetics of transmission. With the goal of identifying metrics that distinguish human- and non-human-adapted IAV we compared strains derived from humans to those circulating in swine and canine populations. Influenza A/Panama/2007/99 (H3N2), A/Netherlands/602/2009 (H1N1), A/swine/Kansas/77778/2007 (H1N1), A/swine/Spain/53207/2004 [M1 P41A] (H1N1), and A/canine/Illinois/41915/2015 (H3N2) viruses were evaluated. Our results revealed higher infectivity and faster kinetics of viral replication and transmission for human and canine strains compared to the swine viruses. Conversely, peak viral titers and efficiency of transmission were higher for human strains relative to both swine and canine IAVs. Total viral loads were comparable among all strains tested. When analyzed together, data from all strains point to peak viral load as a key driver of transmission efficiency and replication kinetics as a key driver of transmission kinetics. While the dose initiating infection did not strongly impact peak viral load, dose was found to modulate kinetics of viral replication and, in turn, timing of transmission. Taken together, our results point to peak viral load and transmission efficiency as key metrics differentiating human and non-human IAVs and suggest that high peak viral load precipitates robust transmission. Importance Influenza pandemics occur when an IAV from non-human hosts enters the human population and adapts to give rise to a lineage capable of sustained transmission among humans. Despite recurring zoonotic infections involving avian or swine adapted IAVs, influenza pandemics occur infrequently because IAVs typically exhibit low fitness in a new host species. Anticipating when a zoonosis might lead to a pandemic is both critical for public health preparedness and extremely challenging. The approach to characterizing IAVs reported here is designed to aid risk assessment efforts by generating rigorous and quantitative data on viral phenotypes relevant for emergence. Our data suggest that the ability to replicate to high titers and transmit efficiently irrespective of initial dose are key characteristics distinguishing IAVs that have established sustained circulation in the human population from IAVs that circulate in non-human mammalian hosts., (Copyright © 2021 American Society for Microbiology.)

Published

2021

4. Human OAS1 activation is highly dependent on both RNA sequence and context of activating RNA motifs.

Author

Schwartz SL, Park EN, Vachon VK, Danzy S, Lowen AC, and Conn GL

Subjects

2',5'-Oligoadenylate Synthetase chemistry, A549 Cells, Allosteric Regulation, Allosteric Site, Catalytic Domain, Humans, Molecular Docking Simulation, Protein Binding, RNA metabolism, 2',5'-Oligoadenylate Synthetase metabolism, Consensus Sequence, RNA chemistry

Abstract

2'-5'-Oligoadenylate synthetases (OAS) are innate immune sensors of cytosolic double-stranded RNA (dsRNA) and play a critical role in limiting viral infection. dsRNA binding induces allosteric structural changes in OAS1 that reorganize its catalytic center to promote synthesis of 2'-5'-oligoadenylate and thus activation of endoribonuclease L. Specific RNA sequences and structural motifs can also enhance activation of OAS1 through currently undefined mechanisms. To better understand these drivers of OAS activation, we tested the impact of defined sequence changes within a short dsRNA that strongly activates OAS1. Both in vitro and in human A549 cells, appending a 3'-end single-stranded pyrimidine (3'-ssPy) can strongly enhance OAS1 activation or have no effect depending on its location, suggesting that other dsRNA features are necessary for correct presentation of the motif to OAS1. Consistent with this idea, we also find that the dsRNA binding position is dictated by an established consensus sequence (WWN9WG). Unexpectedly, however, not all sequences fitting this consensus activate OAS1 equivalently, with strong dependence on the identity of both partially conserved (W) and non-conserved (N9) residues. A picture thus emerges in which both specific RNA features and the context in which they are presented dictate the ability of short dsRNAs to activate OAS1., (© The Author(s) 2020. Published by Oxford University Press on behalf of Nucleic Acids Research.)

Published

2020

5. Characterizing Emerging Canine H3 Influenza Viruses.

Author

Martinez-Sobrido L, Blanco-Lobo P, Rodriguez L, Fitzgerald T, Zhang H, Nguyen P, Anderson CS, Holden-Wiltse J, Bandyopadhyay S, Nogales A, DeDiego ML, Wasik BR, Miller BL, Henry C, Wilson PC, Sangster MY, Treanor JJ, Topham DJ, Byrd-Leotis L, Steinhauer DA, Cummings RD, Luczo JM, Tompkins SM, Sakamoto K, Jones CA, Steel J, Lowen AC, Danzy S, Tao H, Fink AL, Klein SL, Wohlgemuth N, Fenstermacher KJ, El Najjar F, Pekosz A, Sauer L, Lewis MK, Shaw-Saliba K, Rothman RE, Liu ZY, Chen KF, Parrish CR, Voorhees IEH, Kawaoka Y, Neumann G, Chiba S, Fan S, Hatta M, Kong H, Zhong G, Wang G, Uccellini MB, García-Sastre A, Perez DR, Ferreri LM, Herfst S, Richard M, Fouchier R, Burke D, Pattinson D, Smith DJ, Meliopoulos V, Freiden P, Livingston B, Sharp B, Cherry S, Dib JC, Yang G, Russell CJ, Barman S, Webby RJ, Krauss S, Danner A, Woodard K, Peiris M, Perera RAPM, Chan MCW, Govorkova EA, Marathe BM, Pascua PNQ, Smith G, Li YT, Thomas PG, and Schultz-Cherry S

Subjects

Animals, Communicable Diseases, Emerging transmission, Communicable Diseases, Emerging virology, Dog Diseases transmission, Dogs, Ferrets, Guinea Pigs, Humans, Influenza A Virus, H3N2 Subtype classification, Influenza A Virus, H3N2 Subtype genetics, Influenza A Virus, H3N8 Subtype classification, Influenza A Virus, H3N8 Subtype genetics, Influenza A virus classification, Influenza A virus genetics, Influenza, Human transmission, Influenza, Human virology, Mice, Inbred BALB C, Mice, Inbred C57BL, Mice, Inbred DBA, United States, Zoonoses transmission, Communicable Diseases, Emerging veterinary, Dog Diseases virology, Influenza A Virus, H3N2 Subtype isolation & purification, Influenza A Virus, H3N8 Subtype isolation & purification, Influenza A virus isolation & purification, Zoonoses virology

Abstract

The continual emergence of novel influenza A strains from non-human hosts requires constant vigilance and the need for ongoing research to identify strains that may pose a human public health risk. Since 1999, canine H3 influenza A viruses (CIVs) have caused many thousands or millions of respiratory infections in dogs in the United States. While no human infections with CIVs have been reported to date, these viruses could pose a zoonotic risk. In these studies, the National Institutes of Allergy and Infectious Diseases (NIAID) Centers of Excellence for Influenza Research and Surveillance (CEIRS) network collaboratively demonstrated that CIVs replicated in some primary human cells and transmitted effectively in mammalian models. While people born after 1970 had little or no pre-existing humoral immunity against CIVs, the viruses were sensitive to existing antivirals and we identified a panel of H3 cross-reactive human monoclonal antibodies (hmAbs) that could have prophylactic and/or therapeutic value. Our data predict these CIVs posed a low risk to humans. Importantly, we showed that the CEIRS network could work together to provide basic research information important for characterizing emerging influenza viruses, although there were valuable lessons learned., Competing Interests: AG-S. is inventor of patents on influenza virus vaccines owned by the Icahn School for Medicine at Mount Sinai and licensed to Medimmune, BI Vetmedica, Vivaldi Biosciences, Zoetis and Avimex.

Published

2020

6. Dysregulation of M segment gene expression contributes to influenza A virus host restriction.

Author

Calderon BM, Danzy S, Delima GK, Jacobs NT, Ganti K, Hockman MR, Conn GL, Lowen AC, and Steel J

Subjects

A549 Cells, Animals, Dogs, Female, Guinea Pigs, Humans, Influenza, Human genetics, Influenza, Human metabolism, Madin Darby Canine Kidney Cells, Orthomyxoviridae Infections genetics, Orthomyxoviridae Infections metabolism, Species Specificity, Viral Matrix Proteins genetics, Birds virology, Influenza A virus genetics, Influenza A virus pathogenicity, Influenza, Human virology, Orthomyxoviridae Infections virology, Viral Matrix Proteins metabolism, Virus Replication

Abstract

The M segment of the 2009 pandemic influenza A virus (IAV) has been implicated in its emergence into human populations. To elucidate the genetic contributions of the M segment to host adaptation, and the underlying mechanisms, we examined a panel of isogenic viruses that carry avian- or human-derived M segments. Avian, but not human, M segments restricted viral growth and transmission in mammalian model systems, and the restricted growth correlated with increased expression of M2 relative to M1. M2 overexpression was associated with intracellular accumulation of autophagosomes, which was alleviated by interference of the viral proton channel activity by amantadine treatment. As M1 and M2 are expressed from the M mRNA through alternative splicing, we separated synonymous and non-synonymous changes that differentiate human and avian M segments and found that dysregulation of gene expression leading to M2 overexpression diminished replication, irrespective of amino acid composition of M1 or M2. Moreover, in spite of efficient replication, virus possessing a human M segment that expressed avian M2 protein at low level did not transmit efficiently. We conclude that (i) determinants of transmission reside in the IAV M2 protein, and that (ii) control of M segment gene expression is a critical aspect of IAV host adaptation needed to prevent M2-mediated dysregulation of vesicular homeostasis., Competing Interests: The authors have declared that no competing interests exist.

Published

2019

7. Seasonal H3N2 and 2009 Pandemic H1N1 Influenza A Viruses Reassort Efficiently but Produce Attenuated Progeny.

Author

Phipps KL, Marshall N, Tao H, Danzy S, Onuoha N, Steel J, and Lowen AC

Subjects

Animals, Disease Outbreaks, Female, Genetic Variation, Genome, Viral, Genotype, Guinea Pigs, HEK293 Cells, Humans, Phylogeny, Influenza A Virus, H1N1 Subtype genetics, Influenza A Virus, H3N2 Subtype genetics, Orthomyxoviridae Infections virology, Reassortant Viruses genetics, Viral Proteins genetics

Abstract

Reassortment of gene segments between coinfecting influenza A viruses (IAVs) facilitates viral diversification and has a significant epidemiological impact on seasonal and pandemic influenza. Since 1977, human IAVs of H1N1 and H3N2 subtypes have cocirculated with relatively few documented cases of reassortment. We evaluated the potential for viruses of the 2009 pandemic H1N1 (pH1N1) and seasonal H3N2 lineages to reassort under experimental conditions. Results of heterologous coinfections with pH1N1 and H3N2 viruses were compared to those obtained following coinfection with homologous, genetically tagged, pH1N1 viruses as a control. High genotype diversity was observed among progeny of both coinfections; however, diversity was more limited following heterologous coinfection. Pairwise analysis of genotype patterns revealed that homologous reassortment was random while heterologous reassortment was characterized by specific biases. pH1N1/H3N2 reassortant genotypes produced under single-cycle coinfection conditions showed a strong preference for homologous PB2-PA combinations and general preferences for the H3N2 NA, pH1N1 M, and H3N2 PB2 except when paired with the pH1N1 PA or NP. Multicycle coinfection results corroborated these findings and revealed an additional preference for the H3N2 HA. Segment compatibility was further investigated by measuring chimeric polymerase activity and growth of selected reassortants in human tracheobronchial epithelial cells. In guinea pigs inoculated with a mixture of viruses, parental H3N2 viruses dominated but reassortants also infected and transmitted to cage mates. Taken together, our results indicate that strong intrinsic barriers to reassortment between seasonal H3N2 and pH1N1 viruses are few but that the reassortants formed are attenuated relative to parental strains. IMPORTANCE The genome of IAV is relatively simple, comprising eight RNA segments, each of which typically encodes one or two proteins. Each viral protein carries out multiple functions in coordination with other viral components and the machinery of the cell. When two IAVs coinfect a cell, they can exchange genes through reassortment. The resultant progeny viruses often suffer fitness defects due to suboptimal interactions among divergent viral components. The genetic diversity generated through reassortment can facilitate the emergence of novel outbreak strains. Thus, it is important to understand the efficiency of reassortment and the factors that limit its potential. The research described here offers new tools for studying reassortment between two strains of interest and applies those tools to viruses of the 2009 pandemic H1N1 and seasonal H3N2 lineages, which currently cocirculate in humans and therefore have the potential to give rise to novel epidemic strains., (Copyright © 2017 American Society for Microbiology.)

Published

2017