Your search keyword '"Ericka Kirkpatrick"' showing total 9 results

1. Mutations in the Hemagglutinin Stalk Domain Do Not Permit Escape from a Protective, Stalk-Based Vaccine-Induced Immune Response in the Mouse Model

Author

Ericka Kirkpatrick Roubidoux, Juan Manuel Carreño, Meagan McMahon, Kaijun Jiang, Harm van Bakel, Patrick Wilson, and Florian Krammer

Subjects

Microbiology, QR1-502

Abstract

Broadly protective or universal influenza virus vaccines target viral epitopes that appear to be conserved. However, it is unclear whether the virus will be able to escape once immunological pressure is applied to these epitopes through vaccination of large proportions of the population. Studies that investigate the fitness and antigenic characteristics of viruses that escape immunological pressure on these conserved epitopes are therefore urgently needed.

Published

2021

2. H1 Hemagglutinin Priming Provides Long-Lasting Heterosubtypic Immunity against H5N1 Challenge in the Mouse Model

Author

Juan Manuel Carreño, Shirin Strohmeier, Ericka Kirkpatrick Roubidoux, Rong Hai, Peter Palese, and Florian Krammer

Subjects

influenza, heterosubtypic immunity, stalk antibodies, imprinting, Microbiology, QR1-502

Abstract

ABSTRACT Influenza virus infections leave a signature of immune memory that influences future responses to infections with antigenically related strains. It has been hypothesized that the first exposure in life to H1N1 influenza virus imprints the host immune system, potentially resulting in protection from severe infection with H5N1 later in life through hemagglutinin (HA) stalk-specific antibodies. To study the specific role of the HA on protection against infection without interference of cellular immunity or humoral antineuraminidase immunity, we primed mice with influenza B viruses that express an H1 HA (group 1; B-H1), H3 HA (group 2; B-H3), or wild-type influenza B virus and subsequently challenged them at different time points with an H5N1 virus. Weight loss and survival monitoring showed that the B-H1-primed mice exhibited better protection against H5N1 compared to the control mice. Analysis of H5-specific serum IgG, before and 21 days after H5N1 challenge, evidenced the presence of anti-stalk H5 cross-reactive antibodies in the BH-1 group that were boosted by H5N1 infection. The increased immune responses and protection induced by priming with the B-H1 viruses lasted at least up to 1 year. Hence, a single HA priming based on natural infection induces long-lasting protective immunity against heterosubtypic strains from the same phylogenetic HA group in mice. This study gives mechanistic support to the earlier finding in humans that imprinting by H1 HA protects against H5N1 infections and that highly conserved regions on the HA, like the stalk, are involved in this phenomenon. IMPORTANCE Current studies point out that an HA-mediated immunological imprint is established early in life during the first exposure to influenza viruses, which critically shapes and biases future immune responses. However, studies in animal models are limited and the precise mechanisms of this phenomenon are under investigation. Studies that explore the effect of HA-specific immunity induced during natural infection on future exposures to heterosubtypic influenza strains are needed.

Published

2020

3. Influenza Virus Infection Induces a Narrow Antibody Response in Children but a Broad Recall Response in Adults

Author

Philip Meade, Guillermina Kuan, Shirin Strohmeier, Hannah E. Maier, Fatima Amanat, Angel Balmaseda, Kimihito Ito, Ericka Kirkpatrick, Andres Javier, Lionel Gresh, Raffael Nachbagauer, Aubree Gordon, and Florian Krammer

Subjects

influenza virus, natural infection, imprinting, heterosubtypic immunity, cross-reactivity, influenza, Microbiology, QR1-502

Abstract

ABSTRACT In contrast to influenza virus vaccination, natural infection induces long-lived and relatively broad immune responses. However, many aspects of the antibody response to natural infection are not well understood. Here, we assessed the immune response after H1N1 influenza virus infection in children and adults in a Nicaraguan household transmission study using an influenza virus protein microarray (IVPM). This technology allows us to simultaneously measure IgG and IgA antibody responses to hemagglutinins of many different virus strains and subtypes quantitatively with a high throughput. We found that children under 6 years of age responded to natural infection with a relatively narrow response that targeted mostly the hemagglutinin of the strain that caused the infection. Adults, however, have a much broader response, including a boost in antibodies to many group 1 subtype hemagglutinins. Also, a strong recall response against historic H1 hemagglutinins that share the K133 epitope with the pandemic H1N1 virus was observed. Of note, some children, while responding narrowly within H1 and group 1 hemagglutinins, induced a boost to H3 and other group 2 hemagglutinins when infected with H1N1 when they had experienced an H3N2 infection earlier in life. This is an interesting phenomenon providing evidence for immune imprinting and a significant new insight which might be leveraged in future universal influenza virus vaccine strategies. Finally, preexisting immunity to pandemic H1 hemagglutinins was significantly associated with protection from infection in both children and adults. In adults, preexisting immunity to non-H1 group 1 hemagglutinins was also significantly associated with protection from infection. IMPORTANCE It is known since Thomas Francis, Jr. published his first paper on original antigenic sin in 1960 that the first infection(s) with influenza virus leaves a special immunological imprint which shapes immune responses to future infections with antigenically related influenza virus strains. Imprinting has been implicated in both protective effects as well as blunting of the immune response to vaccines. Despite the fact that this phenomenon was already described almost 60 years ago, we have very little detailed knowledge of the characteristics and breadth of the immune response to the first exposure(s) to influenza virus in life and how this compares to later exposure as adults. Here, we investigate these immune responses in detail using an influenza virus protein microarray. While our findings are mostly descriptive in nature and based on a small sample size, they provide a strong basis for future large-scale studies to better understand imprinting effects.

Published

2020

4. Mucosal Immunity against Neuraminidase Prevents Influenza B Virus Transmission in Guinea Pigs

Author

Meagan McMahon, Ericka Kirkpatrick, Daniel Stadlbauer, Shirin Strohmeier, Nicole M. Bouvier, and Florian Krammer

Subjects

influenza, influenza B, neuraminidase, transmission, vaccine, Microbiology, QR1-502

Abstract

ABSTRACT Despite efforts to control influenza virus infection and transmission, influenza viruses still cause significant morbidity and mortality in the global human population each year. Most of the current vaccines target the immunodominant hemagglutinin surface glycoprotein of the virus. However, reduced severity of disease and viral shedding have also been linked to antibodies targeting the second viral surface glycoprotein, the neuraminidase. Importantly, antineuraminidase immunity was shown to be relatively broad, in contrast to vaccine-induced antibodies to the hemagglutinin head domain. In this study, we assessed recombinant neuraminidase protein vaccination for its ability to prevent or limit virus transmission. We vaccinated guinea pigs either intramuscularly or intranasally with a recombinant influenza B virus neuraminidase to assess whether neuraminidase vaccination via these routes could prevent transmission of the homologous virus to a naive recipient. Guinea pigs vaccinated with neuraminidase showed reduced virus titers; however, only vaccination via the intranasal route fully prevented virus transmission to naive animals. We found high levels of antineuraminidase antibodies capable of inhibiting neuraminidase enzymatic activity in the nasal washes of intranasally vaccinated animals, which may explain the observed differences in transmission. We also determined that mucosal immunity to neuraminidase impaired the transmission efficiency of a heterologous influenza B virus, although to a lesser extent. Finally, we found that neuraminidase-vaccinated animals were still susceptible to infection via the airborne and contact transmission routes. However, significantly lower virus titers were detected in these vaccinated recipients. In summary, our data suggest that supplementing vaccine formulations with neuraminidase and vaccinating via the intranasal route may broadly prevent transmission of influenza B viruses. IMPORTANCE Recently, the protective effect of anti-neuraminidase immunity has been highlighted by several studies in humans and animal models. However, so far the role that anti-neuraminidase immunity plays in inhibition of virus transmission has not been explored. In addition, neuraminidase has been ignored as an antigen for influenza virus vaccines. We show here that neuraminidase-based vaccines can inhibit the transmission of influenza virus. Therefore, neuraminidase should be considered as an antigen for improved influenza virus vaccines that not only protect individuals from disease but also inhibit further spread of the virus in the population.

Published

2019

5. The Effect of Malnutrition on Norovirus Infection

Author

Danielle Hickman, Melissa K. Jones, Shu Zhu, Ericka Kirkpatrick, David A. Ostrov, Xiaoyu Wang, Maria Ukhanova, Yijun Sun, Volker Mai, Marco Salemi, and Stephanie M. Karst

Subjects

Microbiology, QR1-502

Abstract

ABSTRACT Human noroviruses are the primary cause of severe childhood diarrhea in the United States, and they are of particular clinical importance in pediatric populations in the developing world. A major contributing factor to the general increased severity of infectious diseases in these regions is malnutrition—nutritional status shapes host immune responses and the composition of the host intestinal microbiota, both of which can influence the outcome of pathogenic infections. In terms of enteric norovirus infections, mucosal immunity and intestinal microbes are likely to contribute to the infection outcome in substantial ways. We probed these interactions using a murine model of malnutrition and murine norovirus infection. Our results reveal that malnutrition is associated with more severe norovirus infections as defined by weight loss, impaired control of norovirus infections, reduced antiviral antibody responses, loss of protective immunity, and enhanced viral evolution. Moreover, the microbiota is dramatically altered by malnutrition. Interestingly, murine norovirus infection also causes changes in the host microbial composition within the intestine but only in healthy mice. In fact, the infection-associated microbiota resembles the malnutrition-associated microbiota. Collectively, these findings represent an extensive characterization of a new malnutrition model of norovirus infection that will ultimately facilitate elucidation of the nutritionally regulated host parameters that predispose to more severe infections and impaired memory immune responses. In a broad sense, this model may provide insight into the reduced efficacy of oral vaccines in malnourished hosts and the potential for malnourished individuals to act as reservoirs of emergent virus strains. IMPORTANCE Malnourished children in developing countries are susceptible to more severe infections than their healthy counterparts, in particular enteric infections that cause diarrhea. In order to probe the effects of malnutrition on an enteric infection in a well-controlled system devoid of other environmental and genetic variability, we studied norovirus infection in a mouse model. We have revealed that malnourished mice develop more severe norovirus infections and they fail to mount effective memory immunity to a secondary challenge. This is of particular importance because malnourished children generally mount less effective immune responses to oral vaccines, and we can now use our new model system to probe the immunological basis of this impairment. We have also determined that noroviruses evolve more readily in the face of malnutrition. Finally, both norovirus infection and malnutrition independently alter the composition of the intestinal microbiota in substantial and overlapping ways.

Published

2014

6. Mutations in the Hemagglutinin Stalk Domain Do Not Permit Escape from a Protective, Stalk-Based Vaccine-Induced Immune Response in the Mouse Model

Author

Harm van Bakel, Meagan McMahon, Florian Krammer, Juan Manuel Carreño, Ericka Kirkpatrick Roubidoux, Kaijun Jiang, and Patrick C. Wilson

Subjects

viruses, Population, Mutant, Hemagglutinin (influenza), stalk-based vaccines, Hemagglutinin Glycoproteins, Influenza Virus, Cross Reactions, Antibodies, Viral, Microbiology, Epitope, Antigenic drift, Virus, Madin Darby Canine Kidney Cells, 03 medical and health sciences, Mice, Dogs, Influenza A Virus, H1N1 Subtype, Antigen, Orthomyxoviridae Infections, Virology, Animals, education, 030304 developmental biology, 0303 health sciences, education.field_of_study, Mice, Inbred BALB C, biology, 030306 microbiology, Antibodies, Monoclonal, Editor's Pick, Antibodies, Neutralizing, QR1-502, Vaccination, universal influenza virus vaccines, Disease Models, Animal, Influenza Vaccines, Mutation, biology.protein, Female, influenza, Research Article

Abstract

Current seasonal influenza virus vaccines target regions of the hemagglutinin (HA) head domain that undergo constant antigenic change, forcing the painstaking annual reformulation of vaccines. The development of broadly protective or universal influenza virus vaccines that induce cross-reactive, protective immune responses could circumvent the need to reformulate current seasonal vaccines. Many of these vaccine candidates target the HA stalk domain, which displays epitopes conserved within and across influenza virus subtypes, including those with pandemic potential. While HA head-mediated antigenic drift is well understood, the potential for antigenic drift in the stalk domain is understudied. Using a panel of HA stalk-specific monoclonal antibodies (MAbs), we applied selection pressure to the stalk domain of A/Netherlands/602/2009 (pdmH1N1) to determine fitness and phenotypes of escape mutant viruses (EMVs). We found that HA stalk MAbs with lower cross-reactivity caused single HA stalk escape mutations, whereas MAbs with broader cross-reactivity forced multiple mutations in the HA. Each escape mutant virus greatly decreased mAb neutralizing activity, but escape mutations did not always ablate MAb binding or Fc-Fc receptor-based effector functions. Escape mutant viruses were not attenuated in vitro but showed attenuation in an in vivo mouse model. Importantly, mice vaccinated with a chimeric HA universal vaccine candidate were protected from lethal challenge with EMVs despite these challenge viruses containing escape mutations in the stalk domain. Our study indicates that while the HA stalk domain can mutate under strong MAb selection pressure, mutant viruses may have attenuated phenotypes and do not evade a polyclonal, stalk-based vaccine-induced response.IMPORTANCE Broadly protective or universal influenza virus vaccines target viral epitopes that appear to be conserved. However, it is unclear whether the virus will be able to escape once immunological pressure is applied to these epitopes through vaccination of large proportions of the population. Studies that investigate the fitness and antigenic characteristics of viruses that escape immunological pressure on these conserved epitopes are therefore urgently needed.

Published

2021

7. Mutations in the Hemagglutinin Stalk Domain Do Not Permit Escape from a Protective, Stalk-Based Vaccine-Induced Immune Response in the Mouse Model

Author

Roubidoux, Ericka Kirkpatrick, primary, Carreño, Juan Manuel, additional, McMahon, Meagan, additional, Jiang, Kaijun, additional, van Bakel, Harm, additional, Wilson, Patrick, additional, and Krammer, Florian, additional

Published

2021

8. Mucosal Immunity against Neuraminidase Prevents Influenza B Virus Transmission in Guinea Pigs

Author

Florian Krammer, Daniel Stadlbauer, Nicole M. Bouvier, Meagan McMahon, Shirin Strohmeier, and Ericka Kirkpatrick

Subjects

viruses, Population, Guinea Pigs, Hemagglutinin (influenza), Neuraminidase, Microbiology, Injections, Intramuscular, Virus, 03 medical and health sciences, Viral Proteins, Orthomyxoviridae Infections, Immunity, Virology, vaccine, Disease Transmission, Infectious, Animals, Viral shedding, education, Immunity, Mucosal, influenza B, Administration, Intranasal, 030304 developmental biology, 0303 health sciences, education.field_of_study, Vaccines, Synthetic, biology, 030306 microbiology, transmission, Therapeutics and Prevention, Editor's Pick, QR1-502, 3. Good health, Vaccination, Disease Models, Animal, Influenza B virus, Treatment Outcome, Influenza Vaccines, biology.protein, Antibody, influenza, Research Article

Abstract

Recently, the protective effect of anti-neuraminidase immunity has been highlighted by several studies in humans and animal models. However, so far the role that anti-neuraminidase immunity plays in inhibition of virus transmission has not been explored. In addition, neuraminidase has been ignored as an antigen for influenza virus vaccines. We show here that neuraminidase-based vaccines can inhibit the transmission of influenza virus. Therefore, neuraminidase should be considered as an antigen for improved influenza virus vaccines that not only protect individuals from disease but also inhibit further spread of the virus in the population., Despite efforts to control influenza virus infection and transmission, influenza viruses still cause significant morbidity and mortality in the global human population each year. Most of the current vaccines target the immunodominant hemagglutinin surface glycoprotein of the virus. However, reduced severity of disease and viral shedding have also been linked to antibodies targeting the second viral surface glycoprotein, the neuraminidase. Importantly, antineuraminidase immunity was shown to be relatively broad, in contrast to vaccine-induced antibodies to the hemagglutinin head domain. In this study, we assessed recombinant neuraminidase protein vaccination for its ability to prevent or limit virus transmission. We vaccinated guinea pigs either intramuscularly or intranasally with a recombinant influenza B virus neuraminidase to assess whether neuraminidase vaccination via these routes could prevent transmission of the homologous virus to a naive recipient. Guinea pigs vaccinated with neuraminidase showed reduced virus titers; however, only vaccination via the intranasal route fully prevented virus transmission to naive animals. We found high levels of antineuraminidase antibodies capable of inhibiting neuraminidase enzymatic activity in the nasal washes of intranasally vaccinated animals, which may explain the observed differences in transmission. We also determined that mucosal immunity to neuraminidase impaired the transmission efficiency of a heterologous influenza B virus, although to a lesser extent. Finally, we found that neuraminidase-vaccinated animals were still susceptible to infection via the airborne and contact transmission routes. However, significantly lower virus titers were detected in these vaccinated recipients. In summary, our data suggest that supplementing vaccine formulations with neuraminidase and vaccinating via the intranasal route may broadly prevent transmission of influenza B viruses.

Published

2019

9. The Effect of Malnutrition on Norovirus Infection

Author

Xiaoyu Wang, Stephanie M. Karst, Ericka Kirkpatrick, Yijun Sun, Shu Zhu, Melissa K. Jones, Marco Salemi, Danielle Hickman, Maria Ukhanova, Volker Mai, and David A. Ostrov

Subjects

Male, ved/biology.organism_classification_rank.species, Antibodies, Viral, medicine.disease_cause, Severity of Illness Index, Microbiology, Mice, fluids and secretions, Immune system, Pregnancy, Immunity, Virology, medicine, Animals, Caliciviridae Infections, business.industry, ved/biology, Body Weight, Malnutrition, Norovirus, Antiviral antibody, Viral Load, medicine.disease, digestive system diseases, QR1-502, Immunoglobulin A, Gastrointestinal Tract, Mice, Inbred C57BL, Disease Models, Animal, Diarrhea, Immunoglobulin G, Viral evolution, Immunology, Dysbiosis, Female, medicine.symptom, business, Spleen, Research Article, Murine norovirus

Abstract

Human noroviruses are the primary cause of severe childhood diarrhea in the United States, and they are of particular clinical importance in pediatric populations in the developing world. A major contributing factor to the general increased severity of infectious diseases in these regions is malnutrition—nutritional status shapes host immune responses and the composition of the host intestinal microbiota, both of which can influence the outcome of pathogenic infections. In terms of enteric norovirus infections, mucosal immunity and intestinal microbes are likely to contribute to the infection outcome in substantial ways. We probed these interactions using a murine model of malnutrition and murine norovirus infection. Our results reveal that malnutrition is associated with more severe norovirus infections as defined by weight loss, impaired control of norovirus infections, reduced antiviral antibody responses, loss of protective immunity, and enhanced viral evolution. Moreover, the microbiota is dramatically altered by malnutrition. Interestingly, murine norovirus infection also causes changes in the host microbial composition within the intestine but only in healthy mice. In fact, the infection-associated microbiota resembles the malnutrition-associated microbiota. Collectively, these findings represent an extensive characterization of a new malnutrition model of norovirus infection that will ultimately facilitate elucidation of the nutritionally regulated host parameters that predispose to more severe infections and impaired memory immune responses. In a broad sense, this model may provide insight into the reduced efficacy of oral vaccines in malnourished hosts and the potential for malnourished individuals to act as reservoirs of emergent virus strains., IMPORTANCE Malnourished children in developing countries are susceptible to more severe infections than their healthy counterparts, in particular enteric infections that cause diarrhea. In order to probe the effects of malnutrition on an enteric infection in a well-controlled system devoid of other environmental and genetic variability, we studied norovirus infection in a mouse model. We have revealed that malnourished mice develop more severe norovirus infections and they fail to mount effective memory immunity to a secondary challenge. This is of particular importance because malnourished children generally mount less effective immune responses to oral vaccines, and we can now use our new model system to probe the immunological basis of this impairment. We have also determined that noroviruses evolve more readily in the face of malnutrition. Finally, both norovirus infection and malnutrition independently alter the composition of the intestinal microbiota in substantial and overlapping ways.

Published

2014