Herpes simplex virus helicase-primase inhibitors are active in animal models of human disease.

Herpes simplex virus infections are the cause of significant morbidity, and currently used therapeutics are largely based on modified nucleoside analogs that inhibit viral DNA polymerase function. To target this disease in a new way, we have identified and optimized selective thiazolylphenyl-containing inhibitors of the herpes simplex virus (HSV) helicase-primase enzyme. The most potent compounds inhibited the helicase, the primase and the DNA-dependent ATPase activities of the enzyme with IC50 (50% inhibitory concentration) values less than 100 nM. Inhibition of the enzymatic activities was through stabilization of the interaction between the helicase-primase and DNA substrates, preventing the progression through helicase or primase catalytic cycles. Helicase-primase inhibitors also prevented viral replication as demonstrated in viral growth assays. One compound, BILS 179 BS, displayed an EC50 (effective concentration inhibiting viral growth by 50%) of 27 nM against viral growth with a selectivity index greater than 2,000. Antiviral activity was also demonstrated for multiple strains of HSV, including strains resistant to nucleoside-based therapies. Most importantly, BILS 179 BS was orally active against HSV infections in murine models of HSV-1 and HSV-2 disease and more effective than acyclovir when the treatment frequency per day was reduced or when initiation of treatment was delayed up to 65 hours after infection. These studies validate the use of helicase-primase inhibitors for the treatment of acute herpesvirus infections and provide new lead compounds for optimization and design of superior anti-HSV agents.

Gain-of-function somatic cell lines for drug discovery applications generated by homologous recombination.

Gene targeting allows for precise genomic engineering and has been used extensively to generate both loss-of-function and gain-of-function models in mice. Similar manipulation of the genome of somatic cell lines holds high value in basic and applied research, but has been hampered by low recombination frequencies and the subsequent labor-intensive analysis of a large number of cell clones. By combining gene targeting methods with fluorescence-activated cell sorting, gain-of-function cell lines were generated and identified based on a functional readout. To demonstrate the general applicability of this approach to drug discovery, we generated targeted promoter insertion cell lines for two key drug target classes -- the G protein-coupled receptor melanocortin-receptor 4 and the nuclear receptor peroxisome proliferator-activated receptor-gamma. Molecular analysis of the engineered cell clones confirmed the predicted integration of a constitutive promoter into an endogenous allele, and the appropriate pharmacology for these targets validated the use of these gain-of-function cell lines in drug discovery applications, including high-throughput compound screening.

Assembly of major histocompatibility complex (MHC) class II transcription factors: association and promoter recognition of RFX proteins.

Major histocompatibility complex (MHC) class II genes are regulated at the transcriptional level by coordinate action of a limited number of transcription factors that include regulatory factor X (RFX), class II transcriptional activator (CIITA), nuclear factor Y (NF-Y), and cyclic AMP-response element binding protein (CREB). Here, the MHC class-II-specific transcription factors and CREB were expressed in insect cells with recombinant baculoviruses, isolated, and characterized by biochemical and biophysical methods. Analytical ultracentrifugation (AUC) has demonstrated that RFX is a heterotrimer. A heterodimer of RFX5 and RFX-AP was also observed. A high-affinity interaction (K(d) = 25 nM) between RFX5 and RFX-AP was measured by isothermal titration calorimetry (ITC), while the interaction between RFX-AP and RFX-ANK is at least an order of magnitude weaker. The biophysical data show that the interaction between RFX-AP and RFX5 is a key event in the assembly of the heterotrimer. Fluorescence anisotropy was used to determine protein-nucleic acid binding affinities for the RFX subunits and complexes binding to duplex DNA. The RFX5 subunit was found to drive recognition of the promoter, while the auxiliary RFX-AP and RFX-ANK subunits were shown to contribute to the specificity of binding for the overall complex. AUC experiments demonstrate that in the absence of additional subunits, monomeric RFX5 binds to X-box DNA with a 1:1 stoichiometry. Interactions between CREB, CIITA, and RFX in the absence of DNA were demonstrated using bead-based immunoprecipitation assays, confirming that preassociation with DNA is not required for forming the macromolecular assemblies that drive MHC class II gene expression.