Herpes simplex virus 1 ICP8 mutant lacking annealing activity is deficient for viral DNA replication.

Most DNA viruses that use recombination-dependent mechanisms to replicate their DNA encode a single-strand annealing protein (SSAP). The herpes simplex virus (HSV) single-strand DNA binding protein (SSB), ICP8, is the central player in all stages of DNA replication. ICP8 is a classical replicative SSB and interacts physically and/or functionally with the other viral replication proteins. Additionally, ICP8 can promote efficient annealing of complementary ssDNA and is thus considered to be a member of the SSAP family. The role of annealing during HSV infection has been difficult to assess in part, because it has not been possible to distinguish between the role of ICP8 as an SSAP from its role as a replicative SSB during viral replication. In this paper, we have characterized an ICP8 mutant, Q706A/F707A (QF), that lacks annealing activity but retains many other functions characteristic of replicative SSBs. Like WT ICP8, the QF mutant protein forms filaments in vitro, binds ssDNA cooperatively, and stimulates the activities of other replication proteins including the viral polymerase, helicase-primase complex, and the origin binding protein. Interestingly, the QF mutant does not complement an ICP8-null virus for viral growth, replication compartment formation, or DNA replication. Thus, we have been able to separate the activities of ICP8 as a replicative SSB from its annealing activity. Taken together, our data indicate that the annealing activity of ICP8 is essential for viral DNA replication in the context of infection and support the notion that HSV-1 uses recombination-dependent mechanisms during DNA replication.

ICP8 Filament Formation Is Essential for Replication Compartment Formation during Herpes Simplex Virus Infection.

UNLABELLED: Herpes simplex virus (HSV) dramatically reorganizes the infected-cell nucleus, leading to the formation of prereplicative sites and replication compartments. This process is driven by the essential viral single-stranded DNA (ssDNA) binding protein ICP8, which can form double-helical filaments in the absence of DNA. In this paper, we show that two conserved motifs, FNF (F1142, N1143, and F1144) and FW (F843 and W844), are essential for ICP8 self-interactions, and we propose that the FNF motif docks into the FW region during filament formation. Mammalian expression plasmids bearing mutations in these motifs (FNF and FW) were unable to complement an ICP8-null mutant for growth and replication compartment formation. Furthermore, FNF and FW mutants were able to inhibit wild-type (WT) virus plaque formation and filament formation, whereas a double mutant (FNF-FW) was not. These results suggest that single mutant proteins are incorporated into nonproductive ICP8 filaments, while the double mutant is unable to interact with WT ICP8 and does not interfere with WT growth. Cells transfected with WT ICP8 and the helicase-primase (H/P) complex exhibited punctate nuclear structures that resemble prereplicative sites; however, the FNF and FW mutants failed to do so. Taken together, these results suggest that the FNF and FW motifs are required for ICP8 self-interactions and that these interactions may be important for the formation of prereplicative sites and replication compartments. We propose that filaments or other higher-order structures of ICP8 may provide a scaffold onto which other proteins can be recruited to form prereplicative sites and replication compartments. IMPORTANCE: For nuclear viruses such as HSV, efficient DNA replication requires the formation of discrete compartments within the infected-cell nucleus in which replication proteins are concentrated and assembled into the HSV replisome. In this paper, we characterize the role of filament formation by the single-stranded DNA binding protein ICP8 in the formation of prereplicative sites and replication compartments. We propose that ICP8 protein filaments generate a protein scaffold for other cellular and viral proteins, resulting in a structure that concentrates both viral DNA and replication proteins. Replication compartments may be similar to other types of cellular membraneless compartments thought to be formed by phase separations caused by low-affinity, multivalent interactions involving proteins and nucleic acids within cells. ICP8 scaffolds could facilitate the formation of replication compartments by mediating interactions with other components of the replication machinery.