Project description:Viral respiratory infections significantly affect young children, particularly extremely premature infants, resulting in high hospitalization rates and increased health-care burdens. Despite posing substantial health risks, airway immune responses in early life remain largely unexplored. Nasal epithelial cells, the primary defense against respiratory infections, are vital for understanding nasal immune responses and serve as a promising target for uncovering underlying molecular and cellular mechanisms. Using a trans-well pseudostratified nasal epithelial cell system, we examined age-dependent developmental differences and antiviral responses to influenza A and respiratory syncytial virus through systems biology approaches. Our studies revealed differences in innate-receptor repertoires, distinct developmental pathways, and differentially connected antiviral network circuits between neonatal and adult nasal epithelial cells. Consensus network analysis identified unique and shared cellular networks for influenza A and respiratory syncytial virus, emphasizing highly relevant virus-specific pathways. This research highlights the importance of nasal epithelial cells in innate antiviral immune responses and offers novel insights that should enable a deeper understanding of age-related differences in nasal epithelial cell immunity following respiratory virus infections.

Project description:Nasal vaccination elicits a humoral immune response that provides protection from airborne pathogens, yet the origins and specific immune niches of antigen-specific IgA-secreting cells in the upper airways remain unknown. Here, we define glandular acinus structures of the nasal turbinates as an immunological niche that recruits IgA-secreting plasma cells from the nasal-associated lymphoid tissues (NALT) in response to intranasal vaccination. Using intact organ imaging, we investigated the cellular events that support antibody-mediated immune responses in the mouse upper airways. Through visualization of antigen-specific T and B cells in the upper airways, we demonstrate that nasal vaccination induced extensive B cell expansion in the subepithelial dome (SED) of the NALT, followed by invasion into commensal bacteria-driven chronic germinal centers (GCs) in a T cell-dependent manner. Antigen-specific B cell response in the NALT required pre-expansion of cognate T cells, which initiate the immune response in the inter-follicular regions of the NALT, and occurred effectively in the presence of Monophosphoryl-Lipid A (MPLA), a synthetic, non-toxic TLR-4 agonist. NALT ablation and blockade of PSGL-1 demonstrated that intranasal vaccination generates IgA+ plasma cells that home to the nasal turbinates through the blood circulation where they are positioned primarily around glandular acinus structures. Thus, the glandular part of the nasal turbinate is an immunological niche that hosts NALT-derived IgA-secreting cells. These cellular events can be manipulated to design vaccines against inhaled pathogens or in the treatment of upper airway allergic responses.

Project description:The determinants of influenza transmission remain poorly understood. Swine influenza viruses preferentially attach to receptors found in the upper airways; however, most swine influenza viruses fail to transmit efficiently from swine to humans, and from human-to-human. The pandemic 2009 H1N1 (H1N1pdm) virus was a rare exception of a swine virus that acquired efficient transmissibility from human-to-human, and is reflected in efficient respiratory droplet transmission in ferrets. We hypothesize that virus-induced host responses in the upper airways correlate with airborne transmission in ferrets. To address this question, we used the H1N1pdm virus and swine influenza A/swine/Hong Kong/201/2010 (HK201) virus that has comparable titre in the ferret nasopharynx, but it exhibits differential transmissibility in ferrets via respiratory droplet route. We performed a transcriptomic analysis of tissues from the upper and lower respiratory tract from ferrets infected with either H1N1pdm or HK201 viruses using ferret-specific Agilent oligonucleotide arrays. We found differences in the kinetics of the innate immune response elicited by these two viruses that varied across tissues.

Project description:The lack of a robust system to reproducibly propagate HRV-C substantially hampered our understanding of the common respiratory virus. We sought to develop an organoid-based system to reproducibly propagate HRV-C and characterize virus-host interaction using the respiratory organoids established by our team. We demonstrated that airway organoids sustained serial virus passage with the aid of CYT-387-mediated immunosuppression; nasal organoids, an organoid model more closely simulating the human upper airway, achieved this without any intervention. Nasal organoids were more susceptible to HRV-C than airway organoids. Intriguingly, we observed a more intensive innate immune response in airway organoids than nasal organoids upon HRV-C infection, which was reproduced in a Poly (I:C) stimulation assay. Treatment with an anti-CDHR3 and two antivirals significantly reduced HRV-C viral growth in nasal organoids. An organoid-based immunofluorescence assay was established to titrate HRV-C infectious particles. Collectively, we developed an organoid-based system to reproducibly propagate the previously uncultivable HRV-C, which enabled an in-depth elucidation of HRV-C infection and innate immunity unprecedentedly. The organoid-based HRV-C infection model can be extended for developing antiviral strategies. More importantly, our study has paved a new avenue for propagating and studying other uncultivable human and animal viruses.

Project description:Nasal vaccination elicits a humoral immune response that provides protection from airborne pathogens, yet the origins and specific immune niches of antigen-specific IgA-secreting cells in the upper airways remain unknown. Here, we define glandular acinus structures of the nasal turbinates as an immunological niche that recruits IgA-secreting plasma cells from the nasal-associated lymphoid tissues (NALT) in response to intranasal vaccination. Using intact organ imaging, we investigated the cellular events that support antibody-mediated immune responses in the mouse upper airways. Through visualization of antigen-specific T and B cells in the upperairways, we demonstrate that nasal vaccination induced extensive B cell expansion in the subepithelial dome (SED) of the NALT, followed by invasion into commensal bacteria-driven chronic germinal centers (GCs) in a T cell-dependent manner. Antigen-specific B cell response in the NALT required pre-expansion of cognate T cells, which initiate the immune response in the inter-follicular regions of the NALT, and occurred effectively in the presence of Monophosphoryl-Lipid A (MPLA), a synthetic, non-toxic TLR-4 agonist. NALT ablation and blockade of PSGL-1 demonstrated that intranasal vaccination generates IgA+ plasma cells that home to the nasal turbinates through the blood circulation where they are positioned primarily around glandular acinus structures. Thus, the glandular part of the nasal turbinate is an immunological niche that hosts NALT-derived IgA-secreting cells. These cellular events can be manipulated to design vaccines against inhaled pathogens or in the treatment of upper airway allergic responses.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.

Project description:The respiratory epithelium is the body’s first line of defense to pathogens, pollutants, and other potentially injurious agents that can be inhaled. Sampling the upper respiratory tract is becoming a widely used technique in the clinic to examine the molecular changes in the diseased airway; however, it is unclear as to whether the responses in the upper respiratory tract (i.e. the nasal turbinates) reflect the changes that occur in the lower respiratory tract (i.e. trachea and lungs). Here, we assessed the responses to poly I:C, a synthetic double-stranded RNA molecule that is meant to mimic the acute effects of a viral infection, in both the upper and lower respiratory tracts of cynomolgus macaques. To do this, we compared the in vivo response after a nasal poly I:C challenge in a nasal scrape samples (performed using a nasal curette) to responses that occurred after ex vivo poly I:C stimulation in nasal scrapes, tracheal epithelial brushings, and lung tissue explants in non-human primates.