The Novel Cyclophilin Inhibitor CPI-431-32 Concurrently Blocks HCV and HIV-1 Infections via a Similar Mechanism of Action

HCV-related liver disease is the main cause of morbidity and mortality of HCV/HIV-1 co-infected patients. Despite the recent advent of anti-HCV direct acting antivirals (DAAs), the treatment of HCV/HIV-1 co-infected patients remains a challenge, as these patients are refractory to most therapies and develop liver fibrosis, cirrhosis and liver cancer more often than HCV mono-infected patients. Until the present study, there was no suitable in vitro assay to test the inhibitory activity of drugs on HCV/HIV-1 co-infection. Here we developed a novel in vitro “co-infection” model where HCV and HIV-1 concurrently replicate in their respective main host target cells—human hepatocytes and CD4+ T-lymphocytes. Using this co-culture model, we demonstrate that cyclophilin inhibitors (CypI), including a novel cyclosporin A (CsA) analog, CPI-431-32, simultaneously inhibits replication of both HCV and HIV-1 when added pre- and post-infection. In contrast, the HIV-1 protease inhibitor nelfinavir or the HCV NS5A inhibitor daclatasvir only blocks the replication of a single virus in the “co-infection” system. CPI-431-32 efficiently inhibits HCV and HIV-1 variants, which are normally resistant to DAAs. CPI-431-32 is slightly, but consistently more efficacious than the most advanced clinically tested CypI—alisporivir (ALV)—at interrupting an established HCV/HIV-1 co-infection. The superior antiviral efficacy of CPI-431-32 over ALV correlates with its higher potency inhibition of cyclophilin A (CypA) isomerase activity and at preventing HCV NS5A-CypA and HIV-1 capsid-CypA interactions known to be vital for replication of the respective viruses. Moreover, we obtained evidence that CPI-431-32 prevents the cloaking of both the HIV-1 and HCV genomes from cellular sensors. Based on these results, CPI-431-32 has the potential, as a single agent or in combination with DAAs, to inhibit both HCV and HIV-1 infections.     

Metaplasticity gated through differential regulation of GluN2A versus GluN2B receptors by Src family kinases

Metaplasticity is a higher form of synaptic plasticity that is essential for learning and memory, but its molecular mechanisms remain poorly understood. Here, we report that metaplasticity of transmission at CA1 synapses in the hippocampus is mediated by Src family kinase regulation of NMDA receptors (NMDARs). We found that stimulation of G-protein-coupled receptors (GPCRs) regulated the absolute contribution of GluN2A-versus GluN2B-containing NMDARs in CA1 neurons: pituitary adenylate cyclase activating peptide 1 receptors (PAC1Rs) selectively recruited Src kinase, phosphorylated GluN2ARs, and enhanced their functional contribution; dopamine 1 receptors (D1Rs) selectively stimulated Fyn kinase, phosphorylated GluN2BRs, and enhanced these currents. Surprisingly, PAC1R lowered the threshold for long-term potentiation while long-term depression was enhanced by D1R. We conclude that metaplasticity is gated by the activity of GPCRs, which selectively target subtypes of NMDARs via Src kinases.     

A highly conserved microsatellite in the dystrophin gene of diverse mammalian species

The presence of a CA repeat within the 3'-untranslated region (UTR) of the dystrophin gene has been reported previously in several species. Because microsatellites showing high cross-species homology can be conveniently used as markers in those species for which detailed linkage maps have not yet been developed, we evaluated whether the CA repeat could be amplified from a wide variety of mammalian species. Using a single pair of canine-specific oligonucleotide primers, we successfully amplified the 3'-UTR from 18 different carnivore and six additional species (human, chimpanzee, goat, cow, rabbit and mouse) and show conservation of the CA repeat in the dystrophin gene from a wide range of evolutionarily diverse mammalian species.     

The salt-induced dissociation and inactivation of a mammalian enolase: evidence for the formation of active monomers

The gamma gamma isozyme of rabbit enolase was labeled with fluorescein and the effects of NaClO4 on both enzymatic activity and fluorescence polarization were studied. NaClO4, but not NaCl, dissociates and partially inactivates the enzyme. If dissociation is prevented, either by the addition of substrate or by covalently crosslinking the enzyme, inactivation is also prevented. Analysis of the time and concentration dependence of inactivation and dissociation shows that the decrease in activity is a two-step process: D in equilibrium 2M in equilibrium 2M*. Both monomeric forms of the enzyme are catalytically active.