Project description:LAIV and TIV are effective for prevention of influenza infection in children, but the mechanisms associated with protection are still not well defined. We analyzed the differences in B cell responses and transcriptional profiles. Compared to baseline, LAIV elicited a significant increase in naM-CM-/ve, memory and transitional B cells on day 30, while vaccination with TIV elicited an increase in number of plasmablasts on day 7. Antibody titers against the three vaccine strains (H1N1, H3N2 and B) were significantly higher in the TIV group and correlated with number of antibody-secreting cells. Regarding transcriptional profiles, both vaccines induced expression of interferon signaling, but at different time points, TIV on 1 day, and LAIV on day 7 day post-vaccination, the last only in children younger than 5 years old. Interferon-related genes over expressed in both vaccinated groups correlated with antibody titers of H3N2 vaccines strain. These results suggest that LAIV and TIV induced significant different B cell responses in vaccinated children. Early induction on interferon genes appears important for development of effective antibody responses. Longitudinal study with time points at baseline (day 0), 24hr, day 7 and day 30. 136 total samples analyzed. This was a prospective cohort of previously healthy children 6 months to 14 years of age enrolled between October 2011 and February 2012. Thirty seven subjects were randomized to receive one dose of either LAIV (FluMistM-BM-., MedImmune) (n= 20) or TIV (FluzoneM-BM-., Sanofi Pasteur) (n= 17). Two exceptions were applied to the randomization: four children with ages between 6 months and 2 years old received TIV, since LAIV is not licensed on this age group, and four children with controlled asthma also received TIV following CDCM-bM-^@M-^Ys recommendations. One child aged 6 months at the time of enrollment received two doses of the vaccine with one month interval apart, since it was his first influenza vaccination. Exclusion criteria included any medical comorbidities or chronic conditions (lung, kidney or heart disease), use of systemic steroids in the previous 2 weeks, and congenital or acquired immunodeficiencies. The 2011-2012 LAIV and TIV vaccines contained A/California/7/2009 (H1N1)-like, A/Perth/16/2009 (H3N2)-like and B/Brisbane/60/2008-like antigens, the same strains used on the 2010-2011 influenza vaccine. TIV recipients aged 6 to 35 months old received 0.25 mL intramuscularly and recipients aged 36 months and older received 0.5 mL. LAIV recipients received 0.2 mL by intranasal route, 0.1 mL per nostril. Blood samples were collected at four time points, on day zero prior to vaccination, and day 1, day 7 (range 6-8) and day 30 (range 27-33) post-vaccination.

Project description:Proteomic profiling of serum antibody repertoire response to FluZone trivalent influenza vaccine in four healthy human subjects. Dataset consists of collected pre-vaccination (Day 0) and post-vaccination (Days 28 and 180) serum IgG samples enriched by affinity chromatography against individual monovalent inactivated components of the 2011-2012 trivalent vaccine (H1 A/California/07/2009 X-179A, H3 A/Victoria/210/2009, and B/Brisbane/60/2008).

Project description:Clinical data showed sex variability in the immune response to influenza vaccination, this study aimed to investigate differentially expressed genes that contribute to sex-bias immune responses to quadrivalent inactivated influenza vaccines (QIVs) in older subjects. A cohort of 60 healthy older adults aged 60 to 80 years old were vaccinated with quadrivalent inactivated influenza vaccines (QIVs), and gene expression was analyzed at Day 0 pre-vaccination, Day 3, Day 28 and Day 180 post-vaccination. Sexual dimorphism of humoral immunity was analyzed by HAI assay, and the correlation of gene expression patterns of two sex groups with humoral immune response to vaccination was analyzed. The differentially expressed genes involved in type I interferon signaling pathway and complement activation of classical pathway were upregulated within 3 days post-vaccination in females. At Day 28 after immunization, the immune response showed a man-bias pattern associated with the regulation of protein processing and complement activation of classical pathway. A list of differentially expressed genes associated with variant responses to influenza vaccination between women and men were identified by biology-driven clustering. Old women have a greater immune response to QIVs but rapid decline of antibody levels, while old men have the advantages to sustain a durable response to influenza vaccination. In addition, we identified genes that may contribute to the sex variations toward influenza vaccination in the aged. Our findings highlight the importance of developing personalized seasonal influenza vaccines.

Project description:Seasonal influenza contributes to a substantial disease burden annually, resulting in approximately 10 million hospital visits and 50 thousand deaths in a typical year in the US. 90% of the annual mortality from influenza occurs in people over the age of 65. While influenza vaccination is the best protection against the virus, it is less effective for the elderly. This may be due to differences in the quantity or type of B cells induced by vaccination in older individuals. To investigate this possibility, we leveraged recent development in single-cell technology that allows for simultaneous measurement of both gene expression profile and the B cell receptor (BCR) at single-cell resolution. Pre- and post-vaccination peripheral blood B cells were sorted from three young and three older adults who responded to the inactivated influenza vaccine and were profiled using single-cell RNAseq with paired BCR sequencing. At pre-vaccination, we observed a higher somatic hypermutation frequency and a higher abundance of activated B cells in older adults than in young adults. Following vaccination, young adults mounted a more clonal response than older adults. The response involved a mix of plasmablasts, activated B cells, and resting memory B cells in both age groups. The response in young adults was dominated by expansion in plasmablasts, while the response in older adults also involved activated B cells. We observed a consistent change in gene expression in plasmablasts after vaccination between age groups but not in the activated B cells. These quantitative and qualitative differences in the B cell response may provide insights into the age-related change of influenza vaccination response.

Project description:Seasonal influenza contributes to a substantial disease burden annually, resulting in approximately 10 million hospital visits and 50 thousand deaths in a typical year in the US. 90% of the annual mortality from influenza occurs in people over the age of 65. While influenza vaccination is the best protection against the virus, it is less effective for the elderly. This may be due to differences in the quantity or type of B cells induced by vaccination in older individuals. To investigate this possibility, we leveraged recent development in single-cell technology that allows for simultaneous measurement of both gene expression profile and the B cell receptor (BCR) at single-cell resolution. Pre- and post-vaccination peripheral blood B cells were sorted from three young and three older adults who responded to the inactivated influenza vaccine and were profiled using single-cell RNAseq with paired BCR sequencing. At pre-vaccination, we observed a higher somatic hypermutation frequency and a higher abundance of activated B cells in older adults than in young adults. Following vaccination, young adults mounted a more clonal response than older adults. The response involved a mix of plasmablasts, activated B cells, and resting memory B cells in both age groups. The response in young adults was dominated by expansion in plasmablasts, while the response in older adults also involved activated B cells. We observed a consistent change in gene expression in plasmablasts after vaccination between age groups but not in the activated B cells. These quantitative and qualitative differences in the B cell response may provide insights into the age-related change of influenza vaccination response.

Project description:In this study, we performed a systems-level analysis of immune responses to the trivalent inactivated influenza vaccine adjuvanted with MF-59 in children (15-24 months old) and in young healthy adults. We analyzed transcriptional responses elicited by vaccination in peripheral blood, as well as cellular and antibody responses following primary and booster vaccinations. The pediatric population is a major target of vaccination, yet there is a paucity of studies on the transcriptional response of immunity to vaccination in this special population. In this study, we performed a systems-level analysis of immune responses to the trivalent inactivated influenza vaccine adjuvanted with MF-59 in children (15-24 months old) and in young healthy adults. We analyzed transcriptional responses elicited by vaccination in peripheral blood, as well as cellular and antibody responses following primary and booster vaccinations. Our analysis revealed that primary vaccination induced a persistent transcriptional signature of innate immunity; booster vaccination induced a transcriptional signature of an enhanced memory-like innate response, which was consistent with enhanced activation of myeloid cells assessed by FACS. Furthermore, we identified a transcriptional signature of type 1 IFN response post booster vaccination and at baseline that was correlated with the local reactogenicity to vaccination, and defined an early signature of the hemagglutinin antibody titers. These results highlight an adaptive behavior of the innate immune system in evoking a memory-like response to secondary vaccination and define molecular correlates of reactogenicity and immunogenicity in infants.

Project description:To describe vaccine associated changes in the expression of microRNAs 21 days after vaccination in children receiving one of two pandemic influenza (H1N1) vaccines.

Project description:LAIV and TIV are effective for prevention of influenza infection in children, but the mechanisms associated with protection are still not well defined. We analyzed the differences in B cell responses and transcriptional profiles. Compared to baseline, LAIV elicited a significant increase in naïve, memory and transitional B cells on day 30, while vaccination with TIV elicited an increase in number of plasmablasts on day 7. Antibody titers against the three vaccine strains (H1N1, H3N2 and B) were significantly higher in the TIV group and correlated with number of antibody-secreting cells. Regarding transcriptional profiles, both vaccines induced expression of interferon signaling, but at different time points, TIV on 1 day, and LAIV on day 7 day post-vaccination, the last only in children younger than 5 years old. Interferon-related genes over expressed in both vaccinated groups correlated with antibody titers of H3N2 vaccines strain. These results suggest that LAIV and TIV induced significant different B cell responses in vaccinated children. Early induction on interferon genes appears important for development of effective antibody responses.

Project description:The reasons for differences in vaccine effectiveness between live attenuated influenza vaccine (LAIV) and inactivated influenza vaccine (IIV) are not clea Blood samples were obtained before vaccination and at days 7 and 21 postvaccination with 2015-2016 quadrivalent IIV or LAIV. Serologic response to the vaccine was measured by hemagglutination inhibition assay. Targeted RNA sequencing and serum cytokine analysis were performed. Paired analyses were used to determine gene expression and were compared between IIV and LAIV recipients.

Project description:Breastfeeding protects against mucosal infections in infants. The underlying mechanisms through which immunity develops in human milk following maternal infection with mucosal pathogens are not well understood. We simulate mucosal influenza infection through live attenuated influenza vaccination (LAIV) and compared milk and blood immune responses to inactivated influenza vaccination (IIV). Transcriptomic analysis was performed on RNA extracted from human milk and whole blood. Differentially expressed genes (DEGs) and gene set enrichment analysis (GSEA) on days 1 and 7 post-vaccination were compared to pre-vaccination.