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3. Striatal mechanism of the restless legs syndrome.

Author

Lai, Yuan-Yang, Hsieh, Kung-Chiao, Chew, Keng-Tee, Nguyen, Darian, and Siegel, Jerome M

Subjects
Nutrition, Sleep Research, Brain Disorders, Neurosciences, Neurological, Animals, Iron, Iron Deficiencies, Polysomnography, Pramipexole, Rats, Restless Legs Syndrome, pramipexole, thioperamide, periodic leg movement, iron deficient, iron therapy, neurotoxic lesions, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery
Abstract

Study objectivesBrain iron deficiency has been reported to be associated with the restless legs syndrome (RLS). However, 30%-50% of RLS patients do not respond to iron therapy, indicating that mechanisms other than brain iron deficiency may also participate in this disease. The striatum is known to be involved in the modulation of motor activity. We speculated that dysfunction of the striatum may induce RLS.MethodsTwo groups, wild-type (WT) and iron-deficient (ID) rats were used. Each group was divided into two subgroups, control and N-methyl-d-aspartate striatal-lesioned. After baseline recording, striatal-lesioned wild-type (WT-STL) and striatal-lesioned iron-deficient (ID-STL) rats were given pramipexole and thioperamide injections. Iron-deficient and ID-STL rats were then given a standard rodent diet for 4 weeks, and their sleep and motor activity were recorded.ResultsWT-STL rats showed periodic leg movements (PLM) in wake, an increase in PLM in slow wave sleep (SWS), a decrease in rapid-eye-movement sleep, and a decrease in the daily average duration of episodes in SWS. The sleep-wake pattern and motor activity did not differ between ID and ID-STL rats. Thioperamide or pramipexole injection decreased PLM in sleep and in wake in WT-STL rats and ID-STL rats. Unlike ID rats, whose motor hyperactivity can be reversed by iron replacement, PLM in wake and in sleep in ID-STL rats were not fully corrected by iron treatment.ConclusionsLesions of the striatum generate RLS-like activity in rats. Dysfunction of the striatum may be responsible for failure to respond to iron treatment in some human RLS patients.

Published
2022

6. In vivo inhibition of nuclear ACE2 translocation protects against SARS-CoV-2 replication and lung damage through epigenetic imprinting

Author

Tu, Wen Juan, Melino, Michelle, Dunn, Jenny, McCuaig, Robert D., Bielefeldt-Ohmann, Helle, Tsimbalyuk, Sofiya, Forwood, Jade K., Ahuja, Taniya, Vandermeide, John, Tan, Xiao, Tran, Minh, Nguyen, Quan, Zhang, Liang, Nam, Andy, Pan, Liuliu, Liang, Yan, Smith, Corey, Lineburg, Katie, Nguyen, Tam H., Sng, Julian D. J., Tong, Zhen Wei Marcus, Chew, Keng Yih, Short, Kirsty R., Le Grand, Roger, Seddiki, Nabila, and Rao, Sudha

Published
2023
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8. The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Published
2023
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9. Primary Chicken and Duck Endothelial Cells Display a Differential Response to Infection with Highly Pathogenic Avian Influenza Virus

Author

Tong, Zhen Wei Marcus, Karawita, Anjana C, Kern, Colin, Zhou, Huaijun, Sinclair, Jane E, Yan, Limin, Chew, Keng Yih, Lowther, Sue, Trinidad, Lee, Challagulla, Arjun, Schat, Karel A, Baker, Michelle L, and Short, Kirsty R

Subjects
Influenza, Pneumonia & Influenza, Vaccine Related, Emerging Infectious Diseases, Infectious Diseases, 2.1 Biological and endogenous factors, 2.2 Factors relating to the physical environment, Aetiology, Infection, Animals, Cells, Cultured, Chickens, Cytokines, Ducks, Endothelial Cells, Endothelium, Vascular, Influenza A Virus, H5N1 Subtype, Species Specificity, Transcriptome, avian influenza, endothelial cells, chicken, duck, cytokine storm, H5N1, Genetics
Abstract

Highly pathogenic avian influenza viruses (HPAIVs) in gallinaceous poultry are associated with viral infection of the endothelium, the induction of a 'cytokine storm, and severe disease. In contrast, in Pekin ducks, HPAIVs are rarely endothelial tropic, and a cytokine storm is not observed. To date, understanding these species-dependent differences in pathogenesis has been hampered by the absence of a pure culture of duck and chicken endothelial cells. Here, we use our recently established in vitro cultures of duck and chicken aortic endothelial cells to investigate species-dependent differences in the response of endothelial cells to HPAIV H5N1 infection. We demonstrate that chicken and duck endothelial cells display a different transcriptional response to HPAI H5N1 infection in vitro-with chickens displaying a more pro-inflammatory response to infection. As similar observations were recorded following in vitro stimulation with the viral mimetic polyI:C, these findings were not specific to an HPAIV H5N1 infection. However, similar species-dependent differences in the transcriptional response to polyI:C were not observed in avian fibroblasts. Taken together, these data demonstrate that chicken and duck endothelial cells display a different response to HPAIV H5N1 infection, and this may help account for the species-dependent differences observed in inflammation in vivo.

Published
2021

10. Striatal histamine mechanism in the pathogenesis of restless legs syndrome

Author

Lai, Yuan-Yang, Hsieh, Kung-Chiao, Cheng, Yu-Hsuan, Chew, Keng-Tee, Nguyen, Darian, Ramanathan, Lalini, and Siegel, Jerome M

Subjects
Biological Psychology, Pharmacology and Pharmaceutical Sciences, Biomedical and Clinical Sciences, Psychology, Sleep Research, Neurosciences, Brain Disorders, Development of treatments and therapeutic interventions, 5.1 Pharmaceuticals, Neurological, Animals, Corpus Striatum, Dopamine, Histamine, Iron, Rats, Restless Legs Syndrome, animal models, periodic leg movements, movement disorders, neuropharmacology, restless legs syndrome, pharmacology, Biological Sciences, Medical and Health Sciences, Psychology and Cognitive Sciences, Neurology & Neurosurgery, Biological sciences, Biomedical and clinical sciences
Abstract

Study objectivesRestless legs syndrome (RLS) has been hypothesized to be generated by abnormal striatal dopamine transmission. Dopaminergic drugs are effective for the treatment of RLS. However, long-term use of dopaminergic drugs causes adverse effects. We used iron-deficient (ID) and iron-replacement (IR) rats to address the neuropathology of RLS and to determine if a histamine H3 receptor (H3R) antagonist might be a useful treatment. Histamine H3R antagonists have been shown to decrease motor activity.MethodsControl and ID rats were surgically implanted with electrodes for polysomnographic recording. After 3 days of baseline polysomnographic recordings, rats were systemically injected with the H3R agonist, α-methylhistamine, and antagonist, thioperamide. Recordings were continued after drug injection. Striatal H3R levels from control, ID, and IR rats were determined by western blots. Blood from control, ID, and IR rats was collected for the measurement of hematocrit levels.Resultsα-Methylhistamine and thioperamide increased and decreased motor activity, respectively, in control rats. In ID rats, α-methylhistamine had no effect on motor activity, whereas thioperamide decreased periodic leg movement (PLM) in sleep. Sleep-wake states were not significantly altered under any conditions. Striatal H3R levels were highest in ID rats, moderate to low in IR rats, and lowest in control rats. Striatal H3R levels were also found to positively and negatively correlate with PLM in sleep and hematocrit levels, respectively.ConclusionsA striatal histamine mechanism may be involved in ID anemia-induced RLS. Histamine H3R antagonists may be useful for the treatment of RLS.

Published
2020

11. Nasal Delivery of Haemophilus haemolyticus Is Safe, Reduces Influenza Severity, and Prevents Development of Otitis Media in Mice.

Author

Scott, Naomi, Martinovich, Kelly M, Granland, Caitlyn M, Seppanen, Elke J, Tjiam, M Christian, Gier, Camilla de, Foo, Edison, Short, Kirsty R, Chew, Keng Yih, Fulurija, Alma, Strickland, Deborah H, Richmond, Peter C, and Kirkham, Lea-Ann S

Subjects
INTRANASAL administration, HAEMOPHILUS influenzae, BACTERIAL diseases, RESPIRATORY infections, OTITIS media
Abstract

Background Despite vaccination, influenza and otitis media (OM) remain leading causes of illness. We previously found that the human respiratory commensal Haemophilus haemolyticus prevents bacterial infection in vitro and that the related murine commensal Muribacter muris delays OM development in mice. The observation that M muris pretreatment reduced lung influenza titer and inflammation suggests that these bacteria could be exploited for protection against influenza/OM. Methods Safety and efficacy of intranasal H haemolyticus at 5 × 107 colony-forming units (CFU) was tested in female BALB/cARC mice using an influenza model and influenza-driven nontypeable Haemophilus influenzae (NTHi) OM model. Weight, symptoms, viral/bacterial levels, and immune responses were measured. Results Intranasal delivery of H haemolyticus was safe and reduced severity of influenza, with quicker recovery, reduced inflammation, and lower lung influenza virus titers (up to 8-fold decrease vs placebo; P ≤.01). Haemophilus haemolyticus reduced NTHi colonization density (day 5 median NTHi CFU/mL = 1.79 × 103 in treatment group vs 4.04 × 104 in placebo, P =.041; day 7 median NTHi CFU/mL = 28.18 vs 1.03 × 104; P =.028) and prevented OM (17% OM in treatment group, 83% in placebo group; P =.015). Conclusions Haemophilus haemolyticus has potential as a live biotherapeutic for prevention or early treatment of influenza and influenza-driven NTHi OM. Additional studies will deem whether these findings translate to humans and other respiratory infections. [ABSTRACT FROM AUTHOR]

Published
2024
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12. Opiates increase the number of hypocretin-producing cells in human and mouse brain and reverse cataplexy in a mouse model of narcolepsy.

Author

John, Joshi, Shan, Ling, Swaab, Dick, Wu, Ming-Fung, Ramanathan, Lalini, Chew, Keng-Tee, Cornford, Marcia, Yamanaka, Akihiro, Inutsuka, Ayumu, Fronczek, Rolf, Lammers, Gert, Worley, Paul, Siegel, Jerome, Thannickal, Thomas, and Mcgregor, Ronald

Subjects
Animals, Brain, Cataplexy, Cell Count, Disease Models, Animal, Dose-Response Relationship, Drug, Heroin, Humans, Male, Mice, Inbred C57BL, Morphine, Narcolepsy, Neurogenesis, Neurons, Opiate Alkaloids, Orexins, Rats, Sprague-Dawley, Substance-Related Disorders
Abstract

The changes in brain function that perpetuate opiate addiction are unclear. In our studies of human narcolepsy, a disease caused by loss of immunohistochemically detected hypocretin (orexin) neurons, we encountered a control brain (from an apparently neurologically normal individual) with 50% more hypocretin neurons than other control human brains that we had studied. We discovered that this individual was a heroin addict. Studying five postmortem brains from heroin addicts, we report that the brain tissue had, on average, 54% more immunohistochemically detected neurons producing hypocretin than did control brains from neurologically normal subjects. Similar increases in hypocretin-producing cells could be induced in wild-type mice by long-term (but not short-term) administration of morphine. The increased number of detected hypocretin neurons was not due to neurogenesis and outlasted morphine administration by several weeks. The number of neurons containing melanin-concentrating hormone, which are in the same hypothalamic region as hypocretin-producing cells, did not change in response to morphine administration. Morphine administration restored the population of detected hypocretin cells to normal numbers in transgenic mice in which these neurons had been partially depleted. Morphine administration also decreased cataplexy in mice made narcoleptic by the depletion of hypocretin neurons. These findings suggest that opiate agonists may have a role in the treatment of narcolepsy, a disorder caused by hypocretin neuron loss, and that increased numbers of hypocretin-producing cells may play a role in maintaining opiate addiction.

Published
2018

13. Opiates increase the number of hypocretin-producing cells in human and mouse brain and reverse cataplexy in a mouse model of narcolepsy.

Author

Thannickal, Thomas C, John, Joshi, Shan, Ling, Swaab, Dick F, Wu, Ming-Fung, Ramanathan, Lalini, McGregor, Ronald, Chew, Keng-Tee, Cornford, Marcia, Yamanaka, Akihiro, Inutsuka, Ayumu, Fronczek, Rolf, Lammers, Gert Jan, Worley, Paul F, and Siegel, Jerome M

Subjects
Brain, Neurons, Animals, Mice, Inbred C57BL, Humans, Rats, Sprague-Dawley, Narcolepsy, Cataplexy, Substance-Related Disorders, Disease Models, Animal, Morphine, Heroin, Cell Count, Dose-Response Relationship, Drug, Male, Opiate Alkaloids, Neurogenesis, Orexins, Drug Abuse (NIDA only), Brain Disorders, Neurosciences, Substance Misuse, Aetiology, 2.1 Biological and endogenous factors, Neurological, Good Health and Well Being, Biological Sciences, Medical and Health Sciences
Abstract

The changes in brain function that perpetuate opiate addiction are unclear. In our studies of human narcolepsy, a disease caused by loss of immunohistochemically detected hypocretin (orexin) neurons, we encountered a control brain (from an apparently neurologically normal individual) with 50% more hypocretin neurons than other control human brains that we had studied. We discovered that this individual was a heroin addict. Studying five postmortem brains from heroin addicts, we report that the brain tissue had, on average, 54% more immunohistochemically detected neurons producing hypocretin than did control brains from neurologically normal subjects. Similar increases in hypocretin-producing cells could be induced in wild-type mice by long-term (but not short-term) administration of morphine. The increased number of detected hypocretin neurons was not due to neurogenesis and outlasted morphine administration by several weeks. The number of neurons containing melanin-concentrating hormone, which are in the same hypothalamic region as hypocretin-producing cells, did not change in response to morphine administration. Morphine administration restored the population of detected hypocretin cells to normal numbers in transgenic mice in which these neurons had been partially depleted. Morphine administration also decreased cataplexy in mice made narcoleptic by the depletion of hypocretin neurons. These findings suggest that opiate agonists may have a role in the treatment of narcolepsy, a disorder caused by hypocretin neuron loss, and that increased numbers of hypocretin-producing cells may play a role in maintaining opiate addiction.

Published
2018

14. Motor hyperactivity of the iron‐deficient rat — an animal model of restless legs syndrome

Author

Lai, Yuan‐Yang, Cheng, Yu‐Hsuan, Hsieh, Kung‐Chiao, Nguyen, Darian, Chew, Keng‐Tee, Ramanathan, Lalini, and Siegel, Jerome M

Subjects
Biomedical and Clinical Sciences, Neurosciences, Clinical Sciences, Nutrition, Neurodegenerative, Brain Disorders, Sleep Research, 5.1 Pharmaceuticals, Development of treatments and therapeutic interventions, Analysis of Variance, Animals, Antiparkinson Agents, Benzothiazoles, Corpus Striatum, Disease Models, Animal, Dopamine Plasma Membrane Transport Proteins, Dose-Response Relationship, Drug, Electroencephalography, Electromyography, Hematocrit, Hyperkinesis, Iron, Iron Metabolism Disorders, Polysomnography, Pramipexole, Rats, Rats, Sprague-Dawley, Restless Legs Syndrome, sleep, hematocrit, periodic leg movement, Human Movement and Sports Sciences, Neurology & Neurosurgery, Clinical sciences
Abstract

BackgroundAbnormal striatal dopamine transmission has been hypothesized to cause restless legs syndrome. Dopaminergic drugs are commonly used to treat restless legs syndrome. However, they cause adverse effects with long-term use. An animal model would allow the systematic testing of potential therapeutic drugs. A high prevalence of restless legs syndrome has been reported in iron-deficient anemic patients. We hypothesized that the iron-deficient animal would exhibit signs similar to those in restless legs syndrome patients.MethodsAfter baseline polysomnographic recordings, iron-deficient rats received pramipexole injection. Then, iron-deficient rats were fed a standard rodent diet, and polysomnographic recording were performed for 2 days each week for 4 weeks.ResultsIron-deficient rats have low hematocrit levels and show signs of restless legs syndrome: sleep fragmentation and periodic leg movements in wake and in slow-wave sleep. Iron-deficient rats had a positive response to pramipexole treatment. After the iron-deficient rats were fed the standard rodent diet, hematocrit returned to normal levels, and sleep quality improved, with increased average duration of wake and slow-wave sleep episodes. Periodic leg movements decreased during both waking and sleep. Hematocrit levels positively correlated with the average duration of episodes in wake and in slow-wave sleep and negatively correlated with periodic leg movements in wake and in sleep. Western blot analysis showed that striatal dopamine transporter levels were higher in iron-deficient rats.ConclusionsThe iron-deficient rat is a useful animal model of iron-deficient anemic restless legs syndrome. © 2017 International Parkinson and Movement Disorder Society.

Published
2017

15. Cardiovascular symptoms of PASC are associated with trace-level cytokines that affect the function of human pluripotent stem cell derived cardiomyocytes

Author

Sinclair, Jane, primary, Vedelago, Courtney, additional, Ryan, Feargal, additional, Carney, Meagan, additional, Redd, Meredith, additional, Lynn, Miriam, additional, Grubor-Bauk, Branka, additional, Cao, Yuanzhao, additional, Henders, Anjali, additional, Chew, Keng Yih, additional, Gilroy, Deborah, additional, Greaves, Kim, additional, Labzin, Larisa, additional, Ziser, Laura, additional, Ronacher, Katharina, additional, Wallace, Leanne, additional, Zhang, Yiwen, additional, Macauslane, Kyle, additional, Ellis, Daniel, additional, Rao, Sudha, additional, Burr, Lucy, additional, Bain, Amanda, additional, Schulz, Benjamin L., additional, Li, Junrong, additional, Lynn, David J., additional, Palpant, Nathan, additional, Wuethrich, Alain, additional, Trau, Matt, additional, and Short, Kirsty, additional

Published
2024
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20. SARS-CoV-2 infection and viral fusogens cause neuronal and glial fusion that compromises neuronal activity

Author

Martínez-Mármol, Ramón, primary, Giordano-Santini, Rosina, additional, Kaulich, Eva, additional, Cho, Ann-Na, additional, Przybyla, Magdalena, additional, Riyadh, Md Asrafuzzaman, additional, Robinson, Emilija, additional, Chew, Keng Yih, additional, Amor, Rumelo, additional, Meunier, Frédéric A., additional, Balistreri, Giuseppe, additional, Short, Kirsty R., additional, Ke, Yazi D., additional, Ittner, Lars M., additional, and Hilliard, Massimo A., additional

Published
2023
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25. Elevated BMI reduces the humoral response to SARS‐CoV‐2 infection.

Author

Tong, Marcus ZW, Sng, Julian DJ, Carney, Meagan, Cooper, Lucy, Brown, Samuel, Lineburg, Katie E, Chew, Keng Yih, Collins, Neve, Ignacio, Kirsten, Airey, Megan, Burr, Lucy, Joyce, Briony A, Jayasinghe, Dhilshan, McMillan, Christopher LD, Muller, David A, Adhikari, Anurag, Gallo, Linda A, Dorey, Emily S, Barrett, Helen L, and Gras, Stephanie

Subjects
HUMORAL immunity, SARS-CoV-2, B cells, ANTIBODY titer, BODY mass index
Abstract

Objective: Class III obesity (body mass index [BMI] ≥ 40 kg m−2) significantly impairs the immune response to SARS‐CoV‐2 vaccination. However, the effect of an elevated BMI (≥ 25 kg m−2) on humoral immunity to SARS‐CoV‐2 infection and COVID‐19 vaccination remains unclear. Methods: We collected blood samples from people who recovered from SARS‐CoV‐2 infection approximately 3 and 13 months of post‐infection (noting that these individuals were not exposed to SARS‐CoV‐2 or vaccinated in the interim). We also collected blood samples from people approximately 5 months of post‐second dose COVID‐19 vaccination (the majority of whom did not have a prior SARS‐CoV‐2 infection). We measured their humoral responses to SARS‐CoV‐2, grouping individuals based on a BMI greater or less than 25 kg m−2. Results: Here, we show that an increased BMI (≥ 25 kg m−2), when accounting for age and sex differences, is associated with reduced antibody responses after SARS‐CoV‐2 infection. At 3 months of post‐infection, an elevated BMI was associated with reduced antibody titres. At 13 months of post‐infection, an elevated BMI was associated with reduced antibody avidity and a reduced percentage of spike‐positive B cells. In contrast, no significant association was noted between a BMI ≥ 25 kg m−2 and humoral immunity to SARS‐CoV‐2 at 5 months of post‐secondary vaccination. Conclusions: Taken together, these data showed that elevated BMI is associated with an impaired humoral immune response to SARS‐CoV‐2 infection. The impairment of infection‐induced immunity in individuals with a BMI ≥ 25 kg m−2 suggests an added impetus for vaccination rather than relying on infection‐induced immunity. [ABSTRACT FROM AUTHOR]

Published
2023
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26. Macrophage ACE2 is necessary for SARS-CoV-2 replication and subsequent cytokine responses that restrict continued virion release

Author

Labzin, Larisa I., primary, Chew, Keng Yih, additional, Eschke, Kathrin, additional, Wang, Xiaohui, additional, Esposito, Tyron, additional, Stocks, Claudia J., additional, Rae, James, additional, Patrick, Ralph, additional, Mostafavi, Helen, additional, Hill, Brittany, additional, Yordanov, Teodor E., additional, Holley, Caroline L., additional, Emming, Stefan, additional, Fritzlar, Svenja, additional, Mordant, Francesca L., additional, Steinfort, Daniel P., additional, Subbarao, Kanta, additional, Nefzger, Christian M., additional, Lagendijk, Anne K., additional, Gordon, Emma J., additional, Parton, Robert G., additional, Short, Kirsty R., additional, Londrigan, Sarah L., additional, and Schroder, Kate, additional

Published
2023
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27. Development of a novel angiotensin converting enzyme 2 stimulator with broad implications in SARS-CoV2 infection and type 1 diabetes

Author

Nomura, Haru, primary, Wu, Melanie, additional, Song, Jiangning, additional, Hung, Andrew, additional, Tran, Shirley, additional, TA, Hang, additional, Akther, Fahima, additional, Wu, Yuao, additional, Johansen, Matt, additional, Chew, Keng, additional, Kumar, Vinod, additional, Woodruff, Trent, additional, Clark, Richard, additional, Koehbach, Johannes, additional, Lomonte, Bruno, additional, Rosado, Carlos, additional, Thomas, Merlin, additional, Boudes, Marion, additional, Reboul, Cyril, additional, Rash, Lachlan, additional, Gallo, Linda, additional, Essid, Sumia, additional, Elmlund, Dominika, additional, Miemczyk, Stefan, additional, Hansbro, Nicole, additional, Saunders, Bernadette, additional, Britton, Warwick, additional, Sly, Peter, additional, Yamamoto, Ayaho, additional, Fernández, Julián, additional, Moyle, Peter, additional, Short, Kirsty, additional, Hansbro, Philip, additional, Kuruppu, Sanjaya, additional, Smith, Ian, additional, and Rajapakse, Niwanthi, additional

Published
2023
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28. IFI27 transcription is an early predictor for COVID-19 outcomes, a multi-cohort observational study

Author

Shojaei, Maryam, Shamshirian, Amir, Monkman, James, Grice, Laura, Tran, Minh, Tan, Chin Wee, Teo, Siok Min, Rodrigues Rossi, Gustavo, McCulloch, Timothy R., Nalos, Marek, Raei, Maedeh, Razavi, Alireza, Ghasemian, Roya, Gheibi, Mobina, Roozbeh, Fatemeh, Sly, Peter D., Spann, Kirsten M., Chew, Keng Yih, Zhu, Yanshan, Xia, Yao, Wells, Timothy J., Senegaglia, Alexandra Cristina, Kuniyoshi, Carmen Lúcia, Franck, Claudio Luciano, dos Santos, Anna Flavia Ribeiro, Noronha, Lucia de, Motamen, Sepideh, Valadan, Reza, Amjadi, Omolbanin, Gogna, Rajan, Madan, Esha, Alizadeh-Navaei, Reza, Lamperti, Liliana, Zuñiga, Felipe, Nova-Lamperti, Estefania, Labarca, Gonzalo, Knippenberg, Ben, Herwanto, Velma, Wang, Ya, Phu, Amy, Chew, Tracy, Kwan, Timothy, Kim, Karan, Teoh, Sally, Pelaia, Tiana M., Kuan, Win Sen, Jee, Yvette, Iredell, Jon, O’Byrne, Ken, Fraser, John F., Davis, Melissa J., Belz, Gabrielle T., Warkiani, Majid E., Gallo, Carlos Salomon, Souza-Fonseca-Guimaraes, Fernando, Nguyen, Quan, Mclean, Anthony, Kulasinghe, Arutha, Short, Kirsty R., Tang, Benjamin, Shojaei, Maryam, Shamshirian, Amir, Monkman, James, Grice, Laura, Tran, Minh, Tan, Chin Wee, Teo, Siok Min, Rodrigues Rossi, Gustavo, McCulloch, Timothy R., Nalos, Marek, Raei, Maedeh, Razavi, Alireza, Ghasemian, Roya, Gheibi, Mobina, Roozbeh, Fatemeh, Sly, Peter D., Spann, Kirsten M., Chew, Keng Yih, Zhu, Yanshan, Xia, Yao, Wells, Timothy J., Senegaglia, Alexandra Cristina, Kuniyoshi, Carmen Lúcia, Franck, Claudio Luciano, dos Santos, Anna Flavia Ribeiro, Noronha, Lucia de, Motamen, Sepideh, Valadan, Reza, Amjadi, Omolbanin, Gogna, Rajan, Madan, Esha, Alizadeh-Navaei, Reza, Lamperti, Liliana, Zuñiga, Felipe, Nova-Lamperti, Estefania, Labarca, Gonzalo, Knippenberg, Ben, Herwanto, Velma, Wang, Ya, Phu, Amy, Chew, Tracy, Kwan, Timothy, Kim, Karan, Teoh, Sally, Pelaia, Tiana M., Kuan, Win Sen, Jee, Yvette, Iredell, Jon, O’Byrne, Ken, Fraser, John F., Davis, Melissa J., Belz, Gabrielle T., Warkiani, Majid E., Gallo, Carlos Salomon, Souza-Fonseca-Guimaraes, Fernando, Nguyen, Quan, Mclean, Anthony, Kulasinghe, Arutha, Short, Kirsty R., and Tang, Benjamin

Abstract

Purpose: Robust biomarkers that predict disease outcomes amongst COVID-19 patients are necessary for both patient triage and resource prioritisation. Numerous candidate biomarkers have been proposed for COVID-19. However, at present, there is no consensus on the best diagnostic approach to predict outcomes in infected patients. Moreover, it is not clear whether such tools would apply to other potentially pandemic pathogens and therefore of use as stockpile for future pandemic preparedness. Methods: We conducted a multi-cohort observational study to investigate the biology and the prognostic role of interferon alpha-inducible protein 27 (IFI27) in COVID-19 patients. Results: We show that IFI27 is expressed in the respiratory tract of COVID-19 patients and elevated IFI27 expression in the lower respiratory tract is associated with the presence of a high viral load. We further demonstrate that the systemic host response, as measured by blood IFI27 expression, is associated with COVID-19 infection. For clinical outcome prediction (e.g., respiratory failure), IFI27 expression displays a high sensitivity (0.95) and specificity (0.83), outperforming other known predictors of COVID-19 outcomes. Furthermore, IFI27 is upregulated in the blood of infected patients in response to other respiratory viruses. For example, in the pandemic H1N1/09 influenza virus infection, IFI27-like genes were highly upregulated in the blood samples of severely infected patients. Conclusion: These data suggest that prognostic biomarkers targeting the family of IFI27 genes could potentially supplement conventional diagnostic tools in future virus pandemics, independent of whether such pandemics are caused by a coronavirus, an influenza virus or another as yet-to-be discovered respiratory virus.

Published
2023

30. International Pediatric COVID-19 Severity Over the Course of the Pandemic.

Author

Zhu, Yanshan, Almeida, Flávia Jacqueline, Baillie, J. Kenneth, Bowen, Asha C., Britton, Philip N., Brizuela, Martin Eduardo, Buonsenso, Danilo, Burgner, David, Chew, Keng Yih, Chokephaibulkit, Kulkanya, Cohen, Cheryl, Cormier, Stephania A., Crawford, Nigel, Curtis, Nigel, Farias, Camila G. A., Gilks, Charles F., von Gottberg, Anne, Hamer, Diana, Jarovsky, Daniel, and Jassat, Waasila

Published
2023
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32. IFI27 transcription is an early predictor for COVID-19 outcomes, a multi-cohort observational study

Author

Shojaei, Maryam, primary, Shamshirian, Amir, additional, Monkman, James, additional, Grice, Laura, additional, Tran, Minh, additional, Tan, Chin Wee, additional, Teo, Siok Min, additional, Rodrigues Rossi, Gustavo, additional, McCulloch, Timothy R., additional, Nalos, Marek, additional, Raei, Maedeh, additional, Razavi, Alireza, additional, Ghasemian, Roya, additional, Gheibi, Mobina, additional, Roozbeh, Fatemeh, additional, Sly, Peter D., additional, Spann, Kirsten M., additional, Chew, Keng Yih, additional, Zhu, Yanshan, additional, Xia, Yao, additional, Wells, Timothy J., additional, Senegaglia, Alexandra Cristina, additional, Kuniyoshi, Carmen Lúcia, additional, Franck, Claudio Luciano, additional, dos Santos, Anna Flavia Ribeiro, additional, Noronha, Lucia de, additional, Motamen, Sepideh, additional, Valadan, Reza, additional, Amjadi, Omolbanin, additional, Gogna, Rajan, additional, Madan, Esha, additional, Alizadeh-Navaei, Reza, additional, Lamperti, Liliana, additional, Zuñiga, Felipe, additional, Nova-Lamperti, Estefania, additional, Labarca, Gonzalo, additional, Knippenberg, Ben, additional, Herwanto, Velma, additional, Wang, Ya, additional, Phu, Amy, additional, Chew, Tracy, additional, Kwan, Timothy, additional, Kim, Karan, additional, Teoh, Sally, additional, Pelaia, Tiana M., additional, Kuan, Win Sen, additional, Jee, Yvette, additional, Iredell, Jon, additional, O’Byrne, Ken, additional, Fraser, John F., additional, Davis, Melissa J., additional, Belz, Gabrielle T., additional, Warkiani, Majid E., additional, Gallo, Carlos Salomon, additional, Souza-Fonseca-Guimaraes, Fernando, additional, Nguyen, Quan, additional, Mclean, Anthony, additional, Kulasinghe, Arutha, additional, Short, Kirsty R., additional, and Tang, Benjamin, additional

Published
2023
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33. Emulation of epidemics via Bluetooth-based virtual safe virus spread: Experimental setup, software, and data

Author

Asanjarani, Azam, primary, Shausan, Aminath, additional, Chew, Keng, additional, Graham, Thomas, additional, Henderson, Shane G., additional, Jansen, Hermanus M., additional, Short, Kirsty R., additional, Taylor, Peter G., additional, Vuorinen, Aapeli, additional, Yadav, Yuvraj, additional, Ziedins, Ilze, additional, and Nazarathy, Yoni, additional

Published
2022
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34. GPR183 antagonism reduces macrophage infiltration in influenza and SARS-CoV-2 infection

Author

Foo, Cheng Xiang, primary, Bartlett, Stacey, additional, Chew, Keng Yih, additional, Ngo, Minh Dao, additional, Bielefeldt-Ohmann, Helle, additional, Arachchige, Buddhika Jayakody, additional, Matthews, Benjamin, additional, Reed, Sarah, additional, Wang, Ran, additional, Smith, Christian, additional, Sweet, Matthew J., additional, Burr, Lucy, additional, Bisht, Kavita, additional, Shatunova, Svetlana, additional, Sinclair, Jane E., additional, Parry, Rhys, additional, Yang, Yuanhao, additional, Lévesque, Jean-Pierre, additional, Khromykh, Alexander, additional, Rosenkilde, Mette Marie, additional, Short, Kirsty R., additional, and Ronacher, Katharina, additional

Published
2022
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35. Additional file 13 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 13: Supplementary Table S11. Differentially expressed cytokine or cytokine related genes in infected avian endothelial cells.

Published
2023
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36. Additional file 4 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 4: Supplementary Table S2. BUSCO analysis of the final genomes.

Published
2023
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37. Additional file 5 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 5: Supplementary Table S3. CEGMA analysis of the final genomes.

Published
2023
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38. Additional file 7 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 7: Supplementary Table S5. List of genes known to affect plumage colour in birds.

Published
2023
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40. Additional file 2 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 2: Supplementary Table S1. Heterozygosity, QV and completeness values for swan genomes.

Published
2023
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41. Additional file 6 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 6: Supplementary Table S4. GO biological process annotation of inverted genes in the Mallard duck (relative to the black swan).

Published
2023
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42. Additional file 3 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 3: Online Methods.

Published
2023
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43. Additional file 8 of The swan genome and transcriptome, it is not all black and white

Author

Karawita, Anjana C., Cheng, Yuanyuan, Chew, Keng Yih, Challagulla, Arjun, Kraus, Robert, Mueller, Ralf C., Tong, Marcus Z. W., Hulme, Katina D., Bielefeldt-Ohmann, Helle, Steele, Lauren E., Wu, Melanie, Sng, Julian, Noye, Ellesandra, Bruxner, Timothy J., Au, Gough G., Lowther, Suzanne, Blommaert, Julie, Suh, Alexander, McCauley, Alexander J., Kaur, Parwinder, Dudchenko, Olga, Aiden, Erez, Fedrigo, Olivier, Formenti, Giulio, Mountcastle, Jacquelyn, Chow, William, Martin, Fergal J., Ogeh, Denye N., Thiaud-Nissen, Françoise, Howe, Kerstin, Tracey, Alan, Smith, Jacqueline, Kuo, Richard I., Renfree, Marilyn B., Kimura, Takashi, Sakoda, Yoshihiro, McDougall, Mathew, Spencer, Hamish G., Pyne, Michael, Tolf, Conny, Waldenström, Jonas, Jarvis, Erich D., Baker, Michelle L., Burt, David W., and Short, Kirsty R.

Abstract

Additional file 8: Supplementary Table S6. Immune gene families are contractive in black swans compared to mute swans. The number of genes in each immune gene sub-family identified is given in each column for the corresponding species.

Published
2023
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45. Ancestral SARS-CoV-2, but not Omicron, replicates less efficiently in primary pediatric nasal epithelial cells

Author

Zhu, Yanshan, primary, Chew, Keng Yih, additional, Wu, Melanie, additional, Karawita, Anjana C., additional, McCallum, Georgina, additional, Steele, Lauren E., additional, Yamamoto, Ayaho, additional, Labzin, Larisa I., additional, Yarlagadda, Tejasri, additional, Khromykh, Alexander A., additional, Wang, Xiaohui, additional, Sng, Julian D. J., additional, Stocks, Claudia J., additional, Xia, Yao, additional, Kollmann, Tobias R., additional, Martino, David, additional, Joensuu, Merja, additional, Meunier, Frédéric A., additional, Balistreri, Giuseppe, additional, Bielefeldt-Ohmann, Helle, additional, Bowen, Asha C., additional, Kicic, Anthony, additional, Sly, Peter D., additional, Spann, Kirsten M., additional, and Short, Kirsty R., additional

Published
2022
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47. Oxysterols drive inflammation via GPR183 during influenza virus and SARS-CoV-2 infection

Author

Foo, Cheng Xiang, primary, Bartlett, Stacey, additional, Chew, Keng Yih, additional, Ngo, Minh Dao, additional, Bielefeldt-Ohmann, Helle, additional, Arachchige, Buddhika Jayakody, additional, Matthews, Benjamin, additional, Reed, Sarah, additional, Wang, Ran, additional, Sweet, Matthew J., additional, Burr, Lucy, additional, Sinclair, Jane E., additional, Parry, Rhys, additional, Khromykh, Alexander, additional, Short, Kirsty R., additional, Rosenkilde, Mette Marie, additional, and Ronacher, Katharina, additional

Published
2022
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48. The swan genome and transcriptome: its not all black and white

Author

Karawita, Anjana C., primary, Cheng, Yuanyuan, additional, Chew, Keng Yih, additional, Challgula, Arjun, additional, Kraus, Robert, additional, Mueller, Ralf C., additional, Tong, Marcus Z. W., additional, Hulme, Katina D., additional, Beielefeldt-Ohmann, Helle, additional, Steele, Lauren E., additional, Wu, Melanie, additional, Sng, Julian, additional, Noye, Ellesandra, additional, Bruxner, Timothy J., additional, Au, Gough G., additional, Lowther, Suzanne, additional, Blommaert, Julie, additional, Suh, Alexander, additional, McCauley, Alexander J., additional, Kaur, Parwinder, additional, Dudchenko, Olga, additional, Aiden, Erez, additional, Fedrigo, Olivier, additional, Formenti, Giulio, additional, Mountcastle, Jacquelyn, additional, Chow, William, additional, Martin, Fergal J., additional, Ogeh, Denye N., additional, Thiaud-Nissen, Françoise, additional, Howe, Kerstin, additional, Collins, Joanna, additional, Tracey, Alan, additional, Smith, Jacqueline, additional, Kuo, Richard I., additional, Renfree, Marilyn B., additional, Kimura, Takashi, additional, Sakoda, Yoshihiro, additional, McDougall, Mathew, additional, Spencer, Hamish G., additional, Pyne, Michael, additional, Tolf, Conny, additional, Waldenström, Jonas, additional, Jarvis, Erich D., additional, Baker, Michelle L., additional, Burt, David W., additional, and Short, Kirsty R., additional

Published
2022
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49. Ancestral SARS-CoV-2, but not Omicron, replicates less efficiently in primary pediatric nasal epithelial cells

Author

Zhu, Yanshan, Chew, Keng Yih, Wu, Melanie, Karawita, Anjana C., McCallum, Georgina, Steele, Lauren E., Yamamoto, Ayaho, Labzin, Larisa I., Yarlagadda, Tejasri, Khromykh, Alexander A., Wang, Xiaohui, Sng, Julian D. J., Stocks, Claudia J., Xia, Yao, Kollmann, Tobias R., Martino, David, Joensuu, Merja, Meunier, Frédéric A., Balistreri, Giuseppe, Bielefeldt-Ohmann, Helle, Bowen, Asha C., Kicic, Anthony, Sly, Peter D., Spann, Kirsten M., Short, Kirsty R., Zhu, Yanshan, Chew, Keng Yih, Wu, Melanie, Karawita, Anjana C., McCallum, Georgina, Steele, Lauren E., Yamamoto, Ayaho, Labzin, Larisa I., Yarlagadda, Tejasri, Khromykh, Alexander A., Wang, Xiaohui, Sng, Julian D. J., Stocks, Claudia J., Xia, Yao, Kollmann, Tobias R., Martino, David, Joensuu, Merja, Meunier, Frédéric A., Balistreri, Giuseppe, Bielefeldt-Ohmann, Helle, Bowen, Asha C., Kicic, Anthony, Sly, Peter D., Spann, Kirsten M., and Short, Kirsty R.

Abstract

Children typically experience more mild symptoms of Coronavirus Disease 2019 (COVID-19) when compared to adults. There is a strong body of evidence that children are also less susceptible to Severe Acute Respiratory Syndrome Coronavirus 2 (SARS-CoV-2) infection with the ancestral viral isolate. However, the emergence of SARS-CoV-2 variants of concern (VOCs) has been associated with an increased number of pediatric infections. Whether this is the result of widespread adult vaccination or fundamental changes in the biology of SARS-CoV-2 remain to be determined. Here, we use primary nasal epithelial cells (NECs) from children and adults, differentiated at an air-liquid interface to show that the ancestral SARS-CoV-2 replicates to significantly lower titers in the NECs of children compared to those of adults. This was associated with a heightened antiviral response to SARS-CoV-2 in the NECs of children. Importantly, the Delta variant also replicated to significantly lower titers in the NECs of children. This trend was markedly less pronounced in the case of Omicron. It is also striking to note that, at least in terms of viral RNA, Omicron replicated better in pediatric NECs compared to both Delta and the ancestral virus. Taken together, these data show that the nasal epithelium of children supports lower infection and replication of ancestral SARS-CoV-2, although this may be changing as the virus evolves.

Published
2022

50. Macrophages only sense infectious SARS-CoV-2 when they express sufficient ACE2 to permit viral entry, where rapid cytokine responses then limit viral replication

Author

Labzin, Larisa I, primary, Chew, Keng Yih, additional, Eschke, Kathrin, additional, Wang, Xiaohui, additional, Esposito, Tyron, additional, Stocks, Claudia J, additional, Rae, James, additional, Patrick, Ralph, additional, Mostafavi, Helen, additional, Hill, Brittany, additional, Yordanov, Teodor E., additional, Holley, Caroline L, additional, Emming, Stefan, additional, Fritzlar, Svenja, additional, Mordant, Francesca L., additional, Steinfort, Daniel P., additional, Subbarao, Kanta, additional, Nefzger, Christian M., additional, Lagendijk, Anne K, additional, Gordon, Emma, additional, Parton, Robert, additional, Short, Kirsty R., additional, Londrigan, Sarah L., additional, and Schroder, Kate, additional

Published
2022
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