Function of the bacteriophage P2 baseplate central spike Apex domain in the infection process.

The contractile tail of bacteriophage P2 functions to drive the tail tube across the outer membrane of its host bacterium, a prerequisite event for subsequent translocation of phage genomic DNA into the host cell. The tube is equipped with a spike-shaped protein (product of P2 gene V , gpV or Spike) that contains a membrane-attacking Apex domain carrying a centrally positioned Fe ion. The ion is enclosed in a histidine cage that is formed by three symmetry-related copies of a conserved HxH (histidine, any residue, histidine) sequence motif. Here, we used solution biophysics and X-ray crystallography to characterize the structure and properties of Spike mutants in which the Apex domain was either deleted or its histidine cage was either destroyed or replaced with a hydrophobic core. We found that the Apex domain is not required for the folding of full-length gpV or its middle intertwined ß-helical domain. Furthermore, despite its high conservation, the Apex domain is dispensable for infection in laboratory conditions. Collectively, our results show that the diameter of the Spike but not the nature of its Apex domain determines the efficiency of infection, which further strengthens the earlier hypothesis of a drill bit-like function of the Spike in host envelope disruption.

A qPCR assay for measuring the post-integrational DNA repair in HIV-1 replication.

The post-integrational gap repair is a critical and poorly studied stage of the lentiviral life cycle. It might be performed by various cellular DNA repair pathways but the exact mechanism of the repair process has not yet been described. One of the reasons for that is the lack of a functional quantitative assay that could precisely measure the amount of integrated viral DNA that has completed the post-integrational gap repair stage. Here, we present an approach that is based on a widely used Alu-specific PCR for the estimation of integrated viral DNA but includes several steps that allow discrimination between integrated-repaired and integrated-unrepaired viral DNA forms. We used the approach for the estimation of the kinetics of gap repair in a viral vector system and showed that the gap repair process starts at 17 h post infection and lasts 10 more hours. We also showed that the addition of Nu7441 - a small molecule inhibitor of DNA-breaks sensor kinase in the non-homologous end joining DNA repair pathway - specifically inhibits the gap repair process while having no influence on the integration itself.

Characterization of HIV-1 integrase interaction with human Ku70 protein and initial implications for drug targeting.

Human Ku70/Ku80 protein is known to influence HIV-1 replication. One of the possible reasons may be the protection of integrase from proteasomal degradation by Ku70 subunit. We demonstrated that recombinant HIV-1 integrase and Ku70 form a stable complex, while no interaction of Ku70 with integrase from prototype foamy virus was observed. By analyzing protein subdomains we determined two binding sites in the structure of both Ku70 and integrase: the 51-160 a.a. region of integrase interacts with residues 251-438 of Ku70, whereas Ku70 N-terminal domain (1-250 a.a.) contacts an α6-helix in the 200-220 a.a. integrase region. Single substitutions within integrase (E212A or L213A) block the interaction with Ku70 thus indicating that the binding site formed by the 200-220 a.a. integrase region is crucial for complex formation. E212A/L213A substitutions decreased the integrase capacity to bind Ku70 in HEK293T cells. A conjugate of 2'-ОMe-GGUUUUUGUGU oligonucleotide with eosin is shown by molecular modeling to shield integrase residues E212/L213 and is effective in blocking complex formation of Ku70 with integrase what makes the complex between α6-helix and Ku70(1-250) a possible target for drug development.

Human Ku70 protein binds hairpin RNA and double stranded DNA through two different sites.

Human protein Ku usually functions in the cell as a complex of two subunits, Ku70 and Ku80. The Ku heterodimer plays a key role in the non-homologous end joining DNA repair pathway by specifically recognizing the DNA ends at the site of the lesion. The binding of the Ku heterodimer to DNA has been well-studied, and its interactions with RNA have been also described. However, Ku70 subunit is known to have independent DNA binding capability, which is less characterized. RNA binding properties of Ku70 have not been yet specially studied. We have prepared recombinant full-length Ku70 and a set of its truncated mutants in E. coli, and studied their interactions with nucleic acids of various structures: linear single- and double-stranded DNA and RNA, as well as closed circular DNA and hairpin RNA. Ku70 has demonstrated a high affinity binding to double stranded DNA and hairpin RNA with a certain structure only. Interestingly, in contrast to the Ku heterodimer, Ku70 is found to interact with closed circular DNA. We also show for the first time that Ku70 employs two different sites for DNA and RNA binding. The double-stranded DNA is recognized by the C-terminal part of Ku70 including SAP domain as it has been earlier demonstrated, whereas hairpin RNA binding is provided by amino acids 251-438.