Respiratory syncytial virus (RSV) fusion protein expressed by recombinant Sendai virus elicits B-cell and T-cell responses in cotton rats and confers protection against RSV subtypes A and B

Zhan, Xiaoyan; Hurwitz, Julia L.; Krishnamurthy, Sateesh; Takimoto, Toru; Boyd, Kelli L.; Scroggs, Ruth Ann; Surman, Sherri L.; Portner, Allen; Slobod, Karen S.

doi:10.1016/j.vaccine.2007.10.038

Cited by 59 publications

(73 citation statements)

References 43 publications

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“…In addition to providing a mouse model to study respiratory paramyxovirus dissemination and pathogenesis, Sendai virus is also a promising Jennerian vaccine candidate against HPIV1 (1,56) and vaccine vector for preclinical HPIV2, HPIV3, and HRSV vaccines (57)(58)(59)(60)(61)(62)(63). There are no confirmed cases of pathogenic Sendai virus infection in humans, and i.n.…”

Section: Discussionmentioning

confidence: 99%

Relationships among Dissemination of Primary Parainfluenza Virus Infection in the Respiratory Tract, Mucosal and Peripheral Immune Responses, and Protection from Reinfection: a Noninvasive Bioluminescence-Imaging Study

Burke

Hurwitz

et al. 2015

J Virol

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Respiratory paramyxoviruses such as respiratory syncytial virus (RSV) and human parainfluenza virus type 1 (HPIV1) to HPIV4 infect virtually all children by the age of 2 to 5 years, leading to partial but incomplete protection from reinfection. Here, we used luciferase-expressing reporter Sendai viruses (the murine counterpart of HPIV1) to noninvasively measure primary infection, immune responses, and protection from reinfection by either a lethal challenge or natural transmission in living mice. Both nonattenuated and attenuated reporter Sendai viruses were used, and three inoculation strategies were employed: intramuscular (i.m.), intranasal (i.n.) at a low dose and low volume, and i.n. at a high dose and high volume. High-dose, high-volume i.n. inoculation resulted in the highest levels of antibody responses and protection from reinfection. Low-dose, low-volume i.n. inoculation afforded complete protection from contact transmission and protection from morbidity, mortality, and viral growth during lethal challenge. i.m. inoculation was inferior to i.n. inoculation at inducing antibody responses and protection from challenge. For individual mice and across groups, the levels of serum binding and neutralizing antibody responses correlated with primary infection and protection from reinfection in the lungs. Contact transmission, the predominant mode of parainfluenza virus transmission, was modeled accurately by direct i.n. inoculation of Sendai virus at a low dose and low volume and was completely preventable by i.n. vaccination of an attenuated virus at a low dose and low volume. The data highlight differences in infection and protection from challenge in the upper versus lower respiratory tract and bear upon live attenuated vaccine development. IMPORTANCEThere are currently no licensed vaccines against HPIVs and human RSV (HRSV), important respiratory pathogens of infants and children. Natural infection leads to partial but incomplete protective immunity, resulting in subsequent reinfections even in the absence of antigenic drift. Here, we used noninvasive bioluminescence imaging in a mouse model to dissect relationships among (i) the mode of inoculation, (ii) the dynamics of primary infection, (iii) consequent immune responses, and (iv) protection from high-dose, high-volume lethal challenge and contact transmission, which we find here to be similar to that of a mild low-dose, low-volume upper respiratory tract (URT)-biased infection. Our studies demonstrate the superiority of i.n. versus i.m. vaccination in protection against both lethal challenge and contact transmission. In addition to providing correlates of protection that will assist respiratory virus vaccine development, these studies extend the development of an increasingly used technique for the study of viral infection and immunity, noninvasive bioluminescence imaging.H uman respiratory syncytial virus (HRSV), human metapneumovirus (HMPV), and human parainfluenza virus type 1 (HPIV1) to HPIV4 are leading viral causes of pediatric hospitaliza...

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Section: Discussionmentioning

confidence: 99%

Relationships among Dissemination of Primary Parainfluenza Virus Infection in the Respiratory Tract, Mucosal and Peripheral Immune Responses, and Protection from Reinfection: a Noninvasive Bioluminescence-Imaging Study

Burke

Hurwitz

et al. 2015

J Virol

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“…Unmodified wild-type SeV elicits protective immunity against HPIV1 without causing adverse events in nonhuman primates (17,40) and is associated with no adverse events after intranasal inoculation into seropositive humans (18). Just as SeV is a promising Jennerian vaccine candidate against HPIV1, rSeV too is being developed as a vaccine vector against HPIV3, as reported here and in our earlier study (15), and other respiratory paramyxoviruses such as HRSV (13,14,41) and HPIV2 (16). Intranasal vaccination with the SeV-vectored HRSV vaccine, in which the HRSV F gene was inserted into the F-HN gene junction of rSeV, elicits protective immunity without causing pathology in both cotton rats (14) and African green monkeys (42).…”

Section: Discussionmentioning

confidence: 53%

“…Just as SeV is a promising Jennerian vaccine candidate against HPIV1, rSeV too is being developed as a vaccine vector against HPIV3, as reported here and in our earlier study (15), and other respiratory paramyxoviruses such as HRSV (13,14,41) and HPIV2 (16). Intranasal vaccination with the SeV-vectored HRSV vaccine, in which the HRSV F gene was inserted into the F-HN gene junction of rSeV, elicits protective immunity without causing pathology in both cotton rats (14) and African green monkeys (42). Analogous experimental trials in African green monkeys with the HPIV3 vaccine candidates described in our study are needed to compare rSeV-HPIV3HN(P-M) and rSeV-HPIV3HN(F-HN) for immunogenicity, protective capacity, and potential pathology in an animal model more closely related to humans.…”

Section: Discussionmentioning

confidence: 60%

“…Sendai virus (SeV), the murine counterpart of HPIV1, is also being developed as a Jennerian vaccine against HPIV1 and as a respiratory vaccine vector when containing an inserted F gene from the respiratory syncytial virus (RSV) or the HN gene from HPIV3 or HPIV2 (13)(14)(15)(16). SeV and HPIV1, like HPIV3, are from the genus Respirovirus and have an amino acid sequence homology of Ͼ75% among their six structural genes (13).…”

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Influence of Antigen Insertion Site and Vector Dose on Immunogenicity and Protective Capacity in Sendai Virus-Based Human Parainfluenza Virus Type 3 Vaccines

Mason

Elbahesh

Russell

2013

J Virol

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“…This cross-reactivity applies to virus-specific B-and T-cells, and targets several distinct viral proteins. 13,14 SeV is pathogenic in mice, but is not known to cause disease in humans; SeV is now being developed as a xenotropic vaccine administered intranasally to prevent hPIV-1 infection or disease, and also as a delivery system (vector) for antigens from other human viruses including hPIV-3, 15 hPIV-2, 16 and RSV [17][18][19][20] and more recently for HIV. [21][22][23][24] SeV is also used as a vector to deliver human fibroblast growth factor 2, 25 and angiopoietin-1, 26 genes for the treatment of peripheral artery disease, oncolytic virotherapy, 27 and cancer immunotherapy.…”

Section: Discussionmentioning

confidence: 99%

Prevalence of specific neutralizing antibodies against Sendai virus in populations from different geographic areas: Implications for AIDS vaccine development using Sendai virus vectors

et al. 2011

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Respiratory syncytial virus (RSV) fusion protein expressed by recombinant Sendai virus elicits B-cell and T-cell responses in cotton rats and confers protection against RSV subtypes A and B

Cited by 59 publications

References 43 publications

Relationships among Dissemination of Primary Parainfluenza Virus Infection in the Respiratory Tract, Mucosal and Peripheral Immune Responses, and Protection from Reinfection: a Noninvasive Bioluminescence-Imaging Study

Relationships among Dissemination of Primary Parainfluenza Virus Infection in the Respiratory Tract, Mucosal and Peripheral Immune Responses, and Protection from Reinfection: a Noninvasive Bioluminescence-Imaging Study

Influence of Antigen Insertion Site and Vector Dose on Immunogenicity and Protective Capacity in Sendai Virus-Based Human Parainfluenza Virus Type 3 Vaccines

Prevalence of specific neutralizing antibodies against Sendai virus in populations from different geographic areas: Implications for AIDS vaccine development using Sendai virus vectors

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