Replication of viral DNA Some
DNA viruses replicate their genomic information in host cells via rolling circle replication. For instance,
human herpesvirus-6 (HHV-6)(hibv) expresses a set of "early genes" that are believed to be involved in this process. The long
concatemers that result are subsequently cleaved between the pac-1 and pac-2 regions of HHV-6's genome by
ribozymes when it is packaged into individual virions.
Human Papillomavirus-16 (HPV-16) is another virus that employs rolling replication to produce progeny at a high rate. HPV-16 infects human epithelial cells and has a double stranded circular genome. During replication, at the origin, the E1 hexamer wraps around the single strand DNA and moves in the 3' to 5' direction. In normal bidirectional replication, the two replication proteins will disassociate at time of collision, but in HPV-16 it is believed that the E1 hexamer does not disassociate, hence leading to a continuous rolling replication. It is believed that this replication mechanism of HPV may have physiological implications into the integration of the virus into the host chromosome and eventual progression into
cervical cancer. In addition,
geminivirus also utilizes rolling circle replication as its replication mechanism. It is a virus that is responsible for destroying many major crops, such as cassava, cotton, legumes, maize, tomato and okra. The virus has a circular, single stranded, DNA that replicates in host plant cells. The entire process is initiated by the geminiviral replication initiator protein, Rep, which is also responsible for altering the host environment to act as part of the replication machinery. Rep is also strikingly similar to most other rolling replication initiator proteins of eubacteria, with the presence of motifs I, II, and III at is N terminus. During the rolling circle replication, the ssDNA of geminivirus is converted to dsDNA and Rep is then attached to the dsDNA at the origin sequence TAATATTAC. After Rep, along with other replication proteins, binds to the dsDNA it forms a stem loop where the DNA is then cleaved at the nanomer sequence causing a displacement of the strand. This displacement allows the replication fork to progress in the 3’ to 5’ direction which ultimately yields a new ssDNA strand and a concatameric DNA strand.
Bacteriophage T4 DNA replication intermediates include circular and branched circular
concatemeric structures. These structures likely reflect a rolling circle mechanism of replication.
Replication of viral RNA Some RNA viruses and viroids also replicate their genome through rolling circle RNA replication. For viroids, there are two alternative RNA replication pathways that respectively followed by members of the family
Pospiviroidae (asymmetric replication) and
Avsunviroidae (symmetric replication). In the family Pospiviroidae (PSTVd-like), the circular plus strand RNA is transcribed by a host RNA polymerase into oligomeric minus strands and then oligomeric plus strands. These oligomeric plus strands are cleaved by a host RNase and ligated by a host RNA ligase to reform the monomeric plus strand circular RNA. This is called the asymmetric pathway of rolling circle replication. The viroids in the family Avsunviroidae (ASBVd-like) replicate their genome through the symmetric pathway of rolling circle replication. In this symmetric pathway, oligomeric minus strands are first cleaved and ligated to form monomeric minus strands, and then are transcribed into oligomeric plus strands. These oligomeric plus strands are then cleaved and ligated to reform the monomeric plus strand. The symmetric replication pathway was named because both plus and minus strands are produced the same way. Cleavage of the oligomeric plus and minus strands is mediated by the self-cleaving
hammerhead ribozyme structure present in the Avsunviroidae, but such structure is absent in the Pospiviroidae. == Rolling circle amplification (RCA) ==