David Baltimore (Nobel Prize in 1975) proposed a virus classification in 1971,
focusing on the mode of viral replication. The classification was adopted by the
virologists in parallel to standard virus taxonomy, which is based on evolutionary
history (Chapter 2).
The general steps involved in virus replication include transport of the virus to
the cellular membrane, attachment that might be mediated by specific receptors on
the cell membrane, direct penetration, or endosome-mediated entry in the cell cy-
toplasm and uncoating of the virus structure as early events. Within the cells, the
viral genomic coding sequences will determine the early gene transcription-the
genome replication-late gene transcription/translation as middle events. Finally,
late events include assembly and egress of the virion. Any of these steps and events
are viral specifics but remain essential in determining the kinetics of replication in
the cell-culture production process.
From a processing standpoint, there are two types of viruses, the ones that end
with the lytic cycle (non-enveloped) and the ones that will bud from the cell
surface (enveloped). For example, adenovirus has a lytic infection cycle and
would infect the cells, replicate, accumulate, and then the cell will lyse and the
virus will be released. An example of an enveloped virus is the coronavirus that
will bud off the cells at maturation of the virion. The enveloped or non-enveloped
nature of the virus has critical effects on the selection of upstream and down-
stream processing steps of the associated viral vaccines. Therefore, the nature of
the infectious viral unit and its interaction with the host cell needs to be well
integrated in the design of viral-structure-based vaccines (inactivated, attenuated,
and vectored-vaccines) and the overall manufacturing stream. These mechanisms
will be described in detail in the virology chapter as well as in the specific case
study chapters (Figure 1.4).
Cell culture technology is the most effective mode of production of viral
vaccines. Primary cell lines such as chick embryo fibroblasts are used in the
production of measles and mumps vaccines, whereas human diploid cell lines
VIH
Rabies Virus
Sars Cov-2
Herpes Virus
Papillomavirus
Influenza
Hepatitis B
Rotavirus
Adenovirus
Ebola Virus
FIGURE 1.3 Example of different types of viruses.
Viral vaccines
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