Project description:Genome replication is inefficient without processivity factors, which tether DNA polymerases to their templates. The vaccinia virus DNA polymerase E9 requires two viral proteins, A20 and D4, for processive DNA synthesis, yet the mechanism of how this tricomplex functions is unknown. This study confirms that these three proteins are necessary and sufficient for processivity, and it focuses on the role of D4, which also functions as a uracil DNA glycosylase (UDG) repair enzyme. A series of D4 mutants was generated to discover which sites are important for processivity. Three point mutants (K126V, K160V, and R187V) which did not function in processive DNA synthesis, though they retained UDG catalytic activity, were identified. The mutants were able to compete with wild-type D4 in processivity assays and retained binding to both A20 and DNA. The crystal structure of R187V was resolved and revealed that the local charge distribution around the substituted residue is altered. However, the mutant protein was shown to have no major structural distortions. This suggests that the positive charges of residues 126, 160, and 187 are required for D4 to function in processive DNA synthesis. Consistent with this is the ability of the conserved mutant K126R to function in processivity. These mutants may help unlock the mechanism by which D4 contributes to processive DNA synthesis.

Project description:Vaccinia virus polymerase holoenzyme is composed of the DNA polymerase E9, the uracil-DNA glycosylase D4 and A20, a protein with no known enzymatic activity. The D4/A20 heterodimer is the DNA polymerase co-factor whose function is essential for processive DNA synthesis. Genetic and biochemical data have established that residues located in the N-terminus of A20 are critical for binding to D4. However, no information regarding the residues of D4 involved in A20 binding is yet available. We expressed and purified the complex formed by D4 and the first 50 amino acids of A20 (D4/A20₁₋₅₀). We showed that whereas D4 forms homodimers in solution when expressed alone, D4/A20₁₋₅₀ clearly behaves as a heterodimer. The crystal structure of D4/A20₁₋₅₀ solved at 1.85 Å resolution reveals that the D4/A20 interface (including residues 167 to 180 and 191 to 206 of D4) partially overlaps the previously described D4/D4 dimer interface. A20₁₋₅₀ binding to D4 is mediated by an α-helical domain with important leucine residues located at the very N-terminal end of A20 and a second stretch of residues containing Trp43 involved in stacking interactions with Arg167 and Pro173 of D4. Point mutations of the latter residues disturb D4/A20₁₋₅₀ formation and reduce significantly thermal stability of the complex. Interestingly, small molecule docking with anti-poxvirus inhibitors selected to interfere with D4/A20 binding could reproduce several key features of the D4/A20₁₋₅₀ interaction. Finally, we propose a model of D4/A20₁₋₅₀ in complex with DNA and discuss a number of mutants described in the literature, which affect DNA synthesis. Overall, our data give new insights into the assembly of the poxvirus DNA polymerase cofactor and may be useful for the design and rational improvement of antivirals targeting the D4/A20 interface.

Project description:Smallpox was globally eradicated 30 years ago by vaccination. The recent threat of bioterrorism demands the development of improved vaccines and novel therapeutics to effectively preclude a reemergence of smallpox. One new therapeutic target is the vaccinia poxvirus processivity complex, comprising D4 and A20 proteins that enable the viral E9 DNA polymerase to synthesize extended strands. Five compounds identified from an AlphaScreen assay designed to disrupt A20:D4 binding were shown to be effective in: (i) blocking vaccinia processive DNA synthesis in vitro, (ii) preventing cellular infection with minimal cytotoxicity, and (iii) binding to D4, as evidenced by ThermoFluor. The EC(50) values for inhibition of viral infectivity ranged from 9.6 to 23 ?M with corresponding selectivity indices (cytotoxicity CC(50)/viral infectivity EC(50)) of 3.9 to 17.8. The five compounds are thus potential therapeutics capable of halting smallpox DNA synthesis and infectivity through disruptive action against a component of the vaccinia processivity complex.

Project description:Vaccinia virus Raw sequence reads

Project description:Vaccinia virus Genome sequencing

Project description:Vaccinia virus Genome sequencing and assembly

Project description:Vaccinia virus Post replicative transcription start sites.

Project description:recombination betweeon co-infecting vaccinia viruses

Project description:A new format of therapeutic proteins is bispecific antibodies, in which two different heavy chains heterodimerize to obtain two different binding sites. Therefore, it is crucial to understand and optimize the third constant domain (CH3-CH3) interface to favor heterodimerization over homodimerization, and to preserve the physicochemical properties, as thermal stability. Here, we use molecular dynamics simulations to investigate the dissociation process of 19 CH3-CH3 crystal structures that differ from each other in few point mutations. We describe the dissociation of the dimeric interface as a two-steps mechanism. As confirmed by a Markov state model, apart from the bound and the dissociated state, we observe an additional intermediate state, which corresponds to an encounter complex. The analysis of the interdomain contacts reveals key residues that stabilize the interface. We expect that our results will improve the understanding of the CH3-CH3 interface interactions and thus advance the developability and design of new antibodies formats.

Project description:The complex immune tumour microenvironment requires an equally complex immunotherapy approach, especially when the cancer-immune set point is non-inflamed. Oncolytic viruses expressing immune activating cytokines might optimally modify the immune microenvironment and improve the antitumour effects. In this study, we have explored a variety of IL-2 constructs expressed by a tumour-selective oncolytic vaccinia virus, designed to maintain IL-2 in the tumour microenvironment to reduce systemic toxicity. An IL-2 construct combining a glycosylphosphatidylinositol (GPI) anchor with a rigid peptide linker leads to functional IL-2 expression on the tumour cell surface and in the tumour microenvironment. This virus construct effectively modifies the cancer-immune set point and treats a variety of murine tumour models with no toxic side effects. In combination with PD-1/PD-L1 blockade this virus cures most of the mice with a high tumour burden. This combination represents a treatment for cancers which are to date unresponsive to immunotherapy.