The vast majority of the world population is infected with at least one member of the human herpesvirus family. Herpes simplex virus (HSV) infections are the cause of cold sores and genital herpes as well as life-threatening or sight-impairing disease mainly in immunocompromized patients, pregnant women and newborns. Since the milestone development in the late 1970s of acyclovir (Zovirax), a nucleosidic inhibitor of the herpes DNA polymerase, no new non-nucleosidic anti-herpes drugs have been introduced. Here we report new inhibitors of the HSV helicase-primase with potent in vitro anti-herpes activity, a novel mechanism of action, a low resistance rate and superior efficacy against HSV in animal models. BAY 57-1293 (N-[5-(aminosulfonyl)-4-methyl-1,3-thiazol-2-yl]-N-methyl-2-[4-(2-pyridinyl)phenyl]acetamide), a well-tolerated member of this class of compounds, significantly reduces time to healing, prevents rebound of disease after cessation of treatment and, most importantly, reduces frequency and severity of recurrent disease. Thus, this class of drugs has significant potential for the treatment of HSV disease in humans, including those resistant to current medications.
Human cytomegalovirus (HCMV) remains the leading viral cause of birth defects and life-threatening disease in transplant recipients. All approved antiviral drugs target the viral DNA polymerase and are associated with severe toxicity issues and the emergence of drug resistance. Attempts to discover improved anti-HCMV drugs led to the identification of the small-molecular-weight compound AIC246 (Letermovir). AIC246 exhibits outstanding anti-HCMV activity in vitro and in vivo and currently is undergoing a clinical phase IIb trial. The initial mode-of-action studies suggested that the drug acts late in the HCMV replication cycle via a mechanism distinct from that of polymerase inhibitors. Here, we extend our mode-of-action analyses and report that AIC246 blocks viral replication without inhibiting the synthesis of progeny HCMV DNA or viral proteins. The genotyping of mutant viruses that escaped AIC246 inhibition uncovered distinct point mutations in the UL56 subunit of the viral terminase complex. Marker transfer analyses confirmed that these mutations were sufficient to mediate AIC246 resistance. The mapping of drug resistance to open reading frame UL56 suggests that viral DNA processing and/or packaging is targeted by AIC246. In line with this, we demonstrate that AIC246 affects the formation of proper unit-length genomes from viral DNA concatemers and interferes with virion maturation. However, since AIC246-resistant viruses do not exhibit cross-resistance to previously published terminase inhibitors, our data suggest that AIC246 interferes with HCMV DNA cleavage/ packaging via a molecular mechanism that is distinct from that of other compound classes known to target the viral terminase.
Human cytomegalovirus (HCMV) remains a serious threat for immunocompromised individuals, including transplant recipients and newborns. To date, all drugs licensed for the treatment of HCMV infection and disease target the viral DNA polymerase. Although these drugs are effective, several drawbacks are associated with their use, including toxicity and emergence of drug resistance. Hence, new and improved antivirals with novel molecular targets are urgently needed. Here we report on the antiviral properties of AIC246, a representative of a novel class of low-molecular-weight compounds that is currently undergoing clinical phase II studies. The anti-HCMV activity of AIC246 was evaluated in vitro and in vivo using various cell culture assays and an engineered mouse xenograft model. In addition, antiviral properties of the drug were characterized in comparison to the current gold standard ganciclovir. We demonstrate that AIC246 exhibits excellent in vitro inhibitory activity against HCMV laboratory strains and clinical isolates, retains activity against ganciclovirresistant viruses, is well tolerated in different cell types (median selectivity index, 18,000), and exerts a potent in vivo efficacy in a mouse xenograft model. Moreover, we show that the antiviral block induced by AIC246 is reversible and the efficacy of the drug is not significantly affected by cell culture variations such as cell type or multiplicity of infection. Finally, initial mode-of-action analyses reveal that AIC246 targets a process in the viral replication cycle that occurs later than DNA synthesis. Thus, AIC246 acts via a mode of action that differs from that of polymerase inhibitors like ganciclovir.Human cytomegalovirus (HCMV) is a widespread opportunistic pathogen in immunocompromised individuals, including transplant recipients and tumor or AIDS patients, and remains the leading viral cause of birth defects (1,9,12,17,29). To date, a limited number of drugs are licensed for the systemic treatment of HCMV infection and disease: ganciclovir (GCV) (Cymevene; Roche), its oral prodrug valganciclovir (VGCV) (Valcyte; Roche), cidofovir (CDF) (Vistide; Gilead), and foscarnet (FOS) (Foscavir; Astra-Zeneca). In addition, valaciclovir (VACV) (Valtrex; GlaxoSmithKline), a drug that has been primarily developed for the treatment of herpes simplex virus (HSV) and varicella-zoster virus (VZV) infection, has gained marketing approval in certain countries for prophylaxis of HCMV infections in transplant patients. Although GCV, VGCV, CDF, and FOS are effective, several drawbacks are associated with the use of these drugs, including toxicity, poor oral bioavailability (except VGCV), and emergence of drug resistance (3,20). The active forms of GCV, CDF, and FOS share the same molecular target, the viral polymerase UL54. Consequently, drug-resistant strains of HCMV encoding UL54 mutations have been found for all three compounds, and the emergence of cross-resistant strains has been described in clinical settings. In addition, resistance to GCV is also associate...
After cessation of repeated, intermittent amphetamine, we detected an emergent Ca 2ϩ -dependent component of amphetamine-induced dopamine release and an increase in calmodulin and Ca 2ϩ -and calmodulin-dependent protein kinase activity in rat striatum. This study examined the involvement of calmodulin-dependent protein kinase II (CaM kinase II) and synaptic vesicles in the enhanced Ca 2ϩ -dependent dopamine release in response to amphetamine or K ϩ in rat striatum. Rats were pretreated for 5 d with 2.5 mg/kg amphetamine or saline and withdrawn from drug for 10 d. The selective CaM kinase II inhibitor KN-93 (1 M), but not the inactive analog KN-92, attenuated the Ca 2ϩ -dependent amphetaminemediated dopamine release from amphetamine-pretreated rats but had no effect in saline-pretreated controls.[ 3 H]Dopamine uptake was unaltered by repeated amphetamine or KN-93 and was Ca 2ϩ independent. Striatal dopamine release stimulated by 50 mM KCl was enhanced twofold after repeated amphetamine compared with that in saline controls but was unaffected by KN-93. To examine the requirement for dopaminergic vesicles in the Ca 2ϩ -dependent dopamine release, we administered reserpine to saline-and amphetamine-pretreated rats 1 d before killing. Reserpine pretreatment did not affect amphetamine-mediated dopamine release from either pretreatment group but completely ablated K ϩ -mediated dopamine release. Reserpine did not disrupt the ability of 1 M KN-93 to block the Ca 2ϩ -dependent amphetamine-mediated dopamine release from amphetamine-pretreated rats. The results indicate that the enhanced dopamine release elicited by amphetamine from chronically treated rats is dependent on Ca 2ϩ -and calmodulin-dependent phosphorylation and is independent of vesicular dopamine storage. On the contrary, the enhanced depolarization-mediated vesicular dopamine release is independent of Ca 2ϩ -and calmodulin-dependent phosphorylation.
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