Episomal latency Episomal latency refers to the use of genetic
episomes during latency. In this latency type, viral genes are stabilized, floating in the
cytoplasm or
nucleus as distinct objects, either as linear or
lasso-shaped structures. Episomal latency is more vulnerable to
ribozymes or host foreign gene degradation than proviral latency (see below).
Herpesviridae One example is the
herpes virus family, Herpesviridae, all of which establish latent infection. Herpes virus include
chicken-pox virus and
herpes simplex viruses (HSV-1, HSV-2), all of which establish episomal latency in
neurons and leave linear genetic material floating in the
cytoplasm.
Epstein-Barr virus The
Gammaherpesvirinae subfamily is associated with episomal latency established in cells of the
immune system, such as
B-cells in the case of
Epstein–Barr virus. Epstein–Barr virus
lytic reactivation (which can be due to
chemotherapy or radiation) can result in
genome instability and
cancer.
Herpes simplex virus In the case of herpes simplex (HSV), the virus has been shown to fuse with
DNA in neurons, such as nerve
ganglia or neurons, and HSV reactivates upon even minor
chromatin loosening with stress, although the chromatin compacts (becomes latent) upon oxygen and nutrient deprivation.
Cytomegalovirus Cytomegalovirus (CMV) establishes latency in
myeloid progenitor cells, and is reactivated by
inflammation.
Immunosuppression and critical illness (
sepsis in particular) often results in CMV reactivation. CMV reactivation is commonly seen in patients with severe
colitis.
Advantages and disadvantages Advantages of episomal latency include the fact that the virus may not need to enter the
cell nucleus, and hence may avoid
nuclear domain 10 (ND10) from activating
interferon via that pathway. Disadvantages include more exposure to cellular defenses, leading to possible degradation of viral gene via cellular
enzymes.
Reactivation Reactivation in herpesviruses may be due to stress stimuli imposed on neurons, at a nearby site innervated by the infected ganglion, or systemically, through means such as high temperature.
Proviral latency A
provirus is a virus genome that is integrated into the DNA of a host cell.
Advantages and disadvantages Advantages include automatic host cell division results in replication of the virus's genes, and the fact that it is nearly impossible to remove an integrated provirus from an infected cell without killing the
cell. A disadvantage of this method is the need to enter the nucleus (and the need for packaging proteins that will allow for that). However, viruses that integrate into the host cell's genome can stay there as long as the cell lives.
HIV One of the best-studied viruses that exhibits viral latency is
HIV. HIV uses
reverse transcriptase to create a DNA copy of its RNA genome. HIV latency allows the virus to largely avoid the immune system. Like other viruses that go latent, it does not typically cause symptoms while latent. HIV in proviral latency is nearly impossible to target with
antiretroviral drugs. Several classes of
latency reversing agents (LRAs) are under development for possible use in shock-and-kill strategies in which the latently infected cellular reservoirs would be reactivated (the shock) so that anti-viral treatment could take effect (the kill). == Maintaining latency ==