11.3.3.2
VSV-Based COVID-19 Vaccine Candidates
In the race of COVID-19 vaccines, several rVSV-based vaccine candidates against
COVID-19 expressing the spike protein of SARS-CoV-2 are evaluated in pre-
clinical trials (University of Western Ontario, Canada; University of Manitoba,
Canada; Aurobindo Pharma, India; FBRI SRC VB VECTOR, Russia; and Israel
Institute for Biological Research/Weizmann Institute of Science, Israel) and clinical
trials (Table 11.3). The construct of rVSVInd-msp-SF-Gtc used in COVID-19 vac-
cine candidates is temperature-sensitive (VSVInd-GML mutant), which is avirulent
in vivo and shows reduced cytopathic effect in vitro at 37°C, but replicates well at
31°C [77]. This characteristic can increase the safety of rVSV for human use. The
rVSVInd-msp-SF-Gtc expressed the SARS-CoV-2 spike protein, the honeybee
melittin signal peptide, and the VSV-G transmembrane protein.
11.4
OVERALL CONCLUSION ON VECTORED VACCINES
In 2013, the WHO had informal consultations on the topic “Where are we with the
development of viral vectored vaccine?” [78] The response to this question years later
can be summarized in the following. In the case of AdV vectors, there are a number of
human and non-human primates AdV serotypes that have been evaluated in pre-
clinical and clinical trials, including HAd5, HAd26, HAd35, ChAd63, etc. Successful
applications have been achieved during the COVID-19 pandemic with the licensing
of vectored vaccines using HAd5, HAd26, and ChAdY25 serotypes. Vaccination
against colds provoked by the HAd4 and HAd7 in the U.S. army is delivered orally in
the form of tablets. There is also progress in developing orally delivered HAd4 with
the H5N1 avian strain, as illustrated by advanced clinical trials.
The recommendation from the WHO working group is that platforms should be
developed in the case of a pandemic situation. They called for the development of
novel vectors as potential platforms, evaluation of viral vectors in heterologous
prime-boost regimens, improvement on manufacturing technology toward con-
tinuous cell culture (e.g., poxvirus uses chicken fibroblasts that are generated each
time), and closer collaboration between veterinary and human vaccine developers.
“Live viral vectors that express heterologous antigens are being extensively
investigated in the development of novel vaccines and it is believed that these will
provide an optimum immune response toward the expressed antigen” is one of the
guidelines from the European Medical Agency underlining a solid trend in the
development of vectored vaccines [79].
Years later, large-scale convincing demonstrations have been achieved through
the successful COVID-19 vaccination of hundreds of millions of people worldwide
with the live vectored vaccines that eventually bring together all the components to
induce an appropriate immune response for broad protection.
REFERENCES
[1] S. A. Mendonca, R. Lorincz, P. Boucher, and D. T. Curiel, “Adenoviral vector
vaccine platforms in the SARS-CoV-2 pandemic,” NPJ Vaccines, vol. 6, no. 1,
p. 97, Aug. 2021, doi: 10.1038/s41541-021-00356-x
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Bioprocessing of Viral Vaccines