Evaluation of reproductive protection against bovine viral diarrhea virus and bovine herpesvirus-1 afforded by annual revaccination with modified-live viral or combination modified-live/killed viral vaccines after primary vaccination with modified-live viral vaccine

Walz, Paul H.; Givens, M. Daniel; Rodning, Soren P.; Riddell, K.P.; Brodersen, Bruce W.; Scruggs, Daniel W.; Short, Thomas H.; Grotelueschen, Dale M.

doi:10.1016/j.vaccine.2017.01.006

Cited by 34 publications

(22 citation statements)

References 16 publications

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“…However, as neutralization assays are difficult to standardize and behave slightly differently depending on the specific techniques used, only broad comparisons can be made. Exceptionally high vaccine-induced neutralizing titers are not required to protect against congenital brain damage after infection of pregnant cows with bovine viral diarrhea virus (family Flaviviridae , genus Pestivirus ) [ 43 , 44 , 45 ] or infection of pregnant mothers with rubella virus [ 46 , 47 ]. Our observations thus support the contention that a ZIKV vaccine may protect against fetal brain infection, without the need to induce and maintain exceptionally high levels of neutralizing antibody titers.…”

Section: Discussionmentioning

confidence: 99%

A Zika Vaccine Generated Using the Chimeric Insect-Specific Binjari Virus Platform Protects against Fetal Brain Infection in Pregnant Mice

et al. 2020

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Zika virus (ZIKV) is the etiological agent of congenital Zika syndrome (CZS), a spectrum of birth defects that can lead to life-long disabilities. A range of vaccines are in development with the target population including pregnant women and women of child-bearing age. Using a recently described chimeric flavivirus vaccine technology based on the novel insect-specific Binjari virus (BinJV), we generated a ZIKV vaccine (BinJ/ZIKA-prME) and illustrate herein its ability to protect against fetal brain infection. Female IFNAR−/− mice were vaccinated once with unadjuvanted BinJ/ZIKA-prME, were mated, and at embryonic day 12.5 were challenged with ZIKVPRVABC59. No infectious ZIKV was detected in maternal blood, placenta, or fetal heads in BinJ/ZIKA-prME-vaccinated mice. A similar result was obtained when the more sensitive qRT PCR methodology was used to measure the viral RNA. BinJ/ZIKA-prME vaccination also did not result in antibody-dependent enhancement of dengue virus infection or disease. BinJ/ZIKA-prME thus emerges as a potential vaccine candidate for the prevention of CSZ.

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Section: Discussionmentioning

confidence: 99%

A Zika Vaccine Generated Using the Chimeric Insect-Specific Binjari Virus Platform Protects against Fetal Brain Infection in Pregnant Mice

et al. 2020

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“…Given this, reproductive vaccines represent an essential strategy for the control of infections caused by both BVDV and BoHV-1, in an attempt to limit losses related to lower conception rates, early embryonic death, abortions, stillbirths and birth of premature calves caused by viral infections (Walz et al 2017). Vaccination of cattle against BVDV and BoHV-1 is not yet a widespread practice in our country (Silva et al 2007b), but a large number of commercial vaccines licensed against these agents in Brazil shows a trend towards continuous use vaccination protocols associated with reproduction.…”

Section: Introductionmentioning

confidence: 99%

Serological response against bovine herpesvirus and bovine viral diarrhea virus induced by commercial vaccines in Holstein heifers

et al. 2019

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Vaccination is a strategy to the prevention and control of reproductive diseases caused by bovine viral diarrhea virus (BVDV) and bovine herpesvirus type 1 (BoHV-1), however the various compositions of commercial vaccines should be evaluated for their ability to induce protection mediated by antibodies. The objective of this research was to evaluate the production of specific neutralizing Abs against BVDV-1 and 2, and BoHV-1 induced by commercial vaccines composed by different adjuvants. Holstein heifers were vaccinated and distributed in three experimental groups: Group I (G1) was vaccinated with a commercial vaccine containing inactivated BVDV-1, BVDV-2 and BoHV-1 diluted in alum hydroxide as adjuvant (n=9); Group II (G2) was vaccinated with an product containing inactivated strains of BVDV-1, BVDV-2, BoHV-1 and BoHV-5 diluted in oil emulsion as adjuvant (n=10); Group III (G3) was vaccinated with a commercial vaccine containing inactivated BVDV-1 and BVDV-2, besides live modified thermosensitive BoHV-1, diluted in Quil A, amphigen and cholesterol (n=10); A control, non-vaccinated group (n=6) was mock vaccinated with saline. Heifers received two subcutaneous doses of 5mL of each commercial vaccine on the right side of the neck, with 21 days interval. Humoral immune response was assessed by the virus neutralization test (VN) against BVDV-1 (NADL and Singer strains), BVDV-2 (SV253 strain) and BoHV-1 (Los Angeles strain) in serum samples collected on vaccination days zero (D0), 21 (D21) and 42 (D42; 21 days after boosting). Neutralizing Abs against BVDV-1 NADL was detected only in D42, regardless of the vaccine used. Similar geometric mean titers (GMT) for BVDV-1 NADL were observed between G1 (log2=5.1) and G3 (log2=5.1). The seroconversion rate (%) was higher in G1 (78%) when compared to G2 (10%) and G3 (40%). For BVDV-1 Singer, it was also possible to detect Abs production in G1 (log2=5.8, 100% seroconversion rate) and G3 (log2=3.5, seroconversion rate = 60%), only after the booster dose (D42). Neutralizing Abs to BVDV-2 (SV253) were detected only in G3, observing 90% seroconversion associated with high titers of Abs (log2=6.7) after the 2nd dose of vaccine (D42). Heifers from G1 and G3 responded to BoHV-1 after the first dose (D21): G1 (log2=2.5, seroconversion rate = 67%) and G3 (log2=0.7, seroconversion rate = 80%). In D42, a higher magnitude response was observed in the heifers from G3 (log2=6.1, 100%) compared with G1 (log2=4.3, 100%) and G2 (log2=2.7, 60%). Based on the data obtained, it can be concluded that the commercial vaccine contained aluminum hydroxide (G1) was most effective in the induction of antibodies against BVDV-1. On the other hand, this vaccine did not induce the production of neutralizing Abs against BVDV-2. Only the heifers from G3 (Quil A, amphigen and cholesterol) generated neutralizing Abs against BVDV-2. The animals that received commercial vaccine containing oil emulsion as adjuvant (G2) had a weak/undetectable response against BVDV-1 and BVDV-2. The best protective response against BoHV-1 was observed in heifers vaccinated with the live modified thermosensitive virus.

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“…While this concept is plausible, fetal protection studies using currently licensed US vaccines have demonstrated protection against BVDV1b challenge or exposure 23‐25 . However, when naïve control dams are exposed to the same number of BVDV1a, BVDV1b, and BVDV2a PI cattle, BVDV1a 23 or BVDV2a 26 could be detected most often in the resulting PI calves and fetuses, indicating that in the absence of BVDV 1a‐ or 2a‐specific immunity, there might not be a selection pressure for BVDV1b to predominate. Naïve control animals provide a population of susceptible cattle that lack any specific immunity against BVDV and demonstrate which of the viruses used to expose the dams would predominate in the case of an unprotective immune response.…”

Section: Virus Biology: What Factors Have Prompted Changes In the Dismentioning

confidence: 99%

“…A previous study and a field investigation reported reproductive losses attributed to BHV‐1 after vaccination of pregnant cattle with MLV vaccines within label recommendations 214,217 . Two randomized clinical trials evaluated the effect of revaccination of pregnant cattle with an MLV BVDV and BHV‐1 vaccine or an inactivated BVDV and temperature‐sensitive MLV BHV‐1 vaccine between 63 and 200 days of gestation 23,217 . One of the trials evaluated clinical protection provided by annual revaccination against rigorous challenge with PI cattle and intravenous BHV‐1 injection.…”

Section: Vaccination Against Bvdv: What Factors Impact Vaccine Efficamentioning

confidence: 99%

Bovine viral diarrhea virus: An updated American College of Veterinary Internal Medicine consensus statement with focus on virus biology, hosts, immunosuppression, and vaccination

Walz

Chamorro

Falkenberg

et al. 2020

Veterinary Internal Medicne

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Consensus Statements of the American College of Veterinary Internal Medicine (ACVIM) provide the veterinary community with up-to-date information on the pathophysiology, diagnosis, and treatment of clinically important animal diseases. The ACVIM Board of Regents oversees selection of relevant topics, identification of panel members with the expertise to draft the statements, and other aspects of assuring the integrity of the process. The statements are derived from evidence-based medicine whenever possible and the panel offers interpretive comments when such evidence is inadequate or contradictory. A draft is prepared by the panel, followed by solicitation of input by the ACVIM membership which may be incorporated into the statement. It is then submitted to the Journal of Veterinary Internal Medicine, where it is edited prior to publication. The authors are solely responsible for the content of the statements.

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Evaluation of reproductive protection against bovine viral diarrhea virus and bovine herpesvirus-1 afforded by annual revaccination with modified-live viral or combination modified-live/killed viral vaccines after primary vaccination with modified-live viral vaccine

Cited by 34 publications

References 16 publications

A Zika Vaccine Generated Using the Chimeric Insect-Specific Binjari Virus Platform Protects against Fetal Brain Infection in Pregnant Mice

A Zika Vaccine Generated Using the Chimeric Insect-Specific Binjari Virus Platform Protects against Fetal Brain Infection in Pregnant Mice

Serological response against bovine herpesvirus and bovine viral diarrhea virus induced by commercial vaccines in Holstein heifers

Bovine viral diarrhea virus: An updated American College of Veterinary Internal Medicine consensus statement with focus on virus biology, hosts, immunosuppression, and vaccination

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