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Review
. 2021 Jun 18;9(6):671.
doi: 10.3390/vaccines9060671.

What Constitutes Protective Immunity Following Yellow Fever Vaccination?

Affiliations
Review

What Constitutes Protective Immunity Following Yellow Fever Vaccination?

Jolynne Mokaya et al. Vaccines (Basel). .

Abstract

Yellow fever (YF) remains a threat to global health, with an increasing number of major outbreaks in the tropical areas of the world over the recent past. In light of this, the Eliminate Yellow Fever Epidemics Strategy was established with the aim of protecting one billion people at risk of YF through vaccination by the year 2026. The current YF vaccine gives excellent protection, but its use is limited by shortages in supply due to the difficulties in producing the vaccine. There are good grounds for believing that alternative fractional dosing regimens can produce strong protection and overcome the problem of supply shortages as less vaccine is required per person. However, immune responses to these vaccination approaches are yet to be fully understood. In addition, published data on immune responses following YF vaccination have mostly quantified neutralising antibody titers. However, vaccine-induced antibodies can confer immunity through other antibody effector functions beyond neutralisation, and an effective vaccine is also likely to induce strong and persistent memory T cell responses. This review highlights the gaps in knowledge in the characterisation of YF vaccine-induced protective immunity in the absence or presence of neutralising antibodies. The assessment of biophysical antibody characteristics and cell-mediated immunity following YF vaccination could help provide a comprehensive landscape of YF vaccine-induced immunity and a better understanding of correlates of protective immunity.

Keywords: cell-mediated immune response; humoral immune response; yellow fever; yellow fever vaccine; yellow fever virus.

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Conflict of interest statement

The authors declare no conflict of interest. The funders had no role in the in the writing of the review.

Figures

Figure 1
Figure 1
Genome organisation of YFV [2,7,8]. C: Capsid. pr: Precursor. M: Membrane. ED1: envelope domain I. EDII: Envelope domain II. EDIII: Envelope domain III. NS: Non-structural protein.
Figure 2
Figure 2
Phylogenetic tree showing 86 complete genome sequences of YFV isolated from biological samples obtained from human beings. Sequences obtained from Virus Pathogen Resource (https://www.viprbrc.org accessed on 26 May 2021). Maximum likelihood phylogenetic tree generated in IQ-TREE using the general time reversible nucleotide substitution model with gamma-distributed among-site rate variation (GTR + G) [20]. Phylogenetic tree rooted and visualised using FigTree program (http://tree.bio.ed.ac.uk/software/figtree/ accessed on 26 May 2021).
Figure 3
Figure 3
Countries with reported cases of yellow fever and YF transmission cycles [2,21]. Aedes species responsible for intermediate transmission include: Aedes furcifer, Aedes luteocephalus, Aedes taylori, Aedes metallicus, Aedes vittatus, Aedes simpsoni complex. Map made using (https://simplemaps.com accessed on 25 March 2021).
Figure 4
Figure 4
An algorithm for the diagnosis of YFV infection [22]. RT-PCR: Reverse Transcriptase Polymerase Chain Reaction. IgM: Immunoglobulin M. IgG: Immunoglobulin G. +: Positive. -: Negative. a RT-PCR performed on samples collected within less than 10 days of symptom onset. b Differential diagnosis of other flaviviruses such as DENV, WNV, ZIKV.
Figure 5
Figure 5
Kinetics of humoral and cellular immune response following vaccination with YFV-17D [38,39,41,42,43]. NK: Natural killer cells. The dotted line indicates that CD 4+ T cells may be present or absent in some individuals after years post-vaccination.

References

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