The multi-targeted kinase inhibitor sorafenib inhibits human cytomegalovirus replication

Human cytomegalovirus (HCMV) is a major pathogen in immunocompromised individuals. Here, non-toxic concentrations of the anti-cancer kinase inhibitor sorafenib were shown to inhibit replication of different HCMV strains (including a ganciclovir-resistant strain) in different cell types. In contrast to established anti-HCMV drugs, sorafenib inhibited HCMV major immediate early promoter activity and HCMV immediate early antigen (IEA) expression. Sorafenib is known to inhibit Raf. Comparison of sorafenib with the MEK inhibitor U0126 suggested that sorafenib inhibits HCMV IEA expression through inhibition of Raf but independently of signaling through the Raf downstream kinase MEK 1/2. In concordance, siRNA-mediated depletion of Raf but not of MEK-reduced IEA expression. In conclusion, sorafenib diminished HCMV replication in clinically relevant concentrations and inhibited HCMV IEA expression, a pathophysiologically relevant event that is not affected by established anti-HCMV drugs. Moreover, we demonstrated for the first time that Raf activation is involved in HCMV IEA expression

Additional file 2: of Human cytomegalovirus reactivation from latency: validation of a “switch” model in vitro

THP-1 macrophage (lytic model) infection with TB40E progeny derived from the THP-1 reactivation model. THP-1 macrophages (lytic model) were infected with the cell culture supernatant derived from the THP-1 reactivation model (as detailed in the Methods section), which had been infected with the TB40E strain at MOI of 0.5 (panels a, a’), 0.25 (panels b, b’) or 0.125 (panels c, c’) for 7 days; panels d, d’: uninfected cells. A–At 24 h p.i., THP-1 macrophages were fixed and labelled with an anti-IE antibody (“IE-positive THP-1 macrophages from the THP-1 reactivation model”). B–at 72 h p.i. they were fixed and labelled with an anti-pp65 antibody (“pp65-positive THP-1 macrophages from THP-1 reactivation model”). Bar: 25 μm. (PDF 1315 kb

Optimization of adeno-associated viral vector-mediated transduction of the corticospinal tract: comparison of four promoters.

Funder: This research was funded by a Nathalie Rose Barr award (NRB110) from the International Spinal Research Trust, and support from Medical Research Council (MR/R004544/1 & MR/R004463/1), NWO (013-16-002), Czech Ministry of Education (CZ.02.1.01/0.0./0.0/15_003/0000419), ERA-NET NEURON AxonRepair, Christopher and Dana Reeve Foundation, International Foundation for Research in Paraplegia, Hersenstichting Nederland.Adeno-associated viral vectors are widely used as vehicles for gene transfer to the nervous system. The promoter and viral vector serotype are two key factors that determine the expression dynamics of the transgene. A previous comparative study has demonstrated that AAV1 displays efficient transduction of layer V corticospinal neurons, but the optimal promoter for transgene expression in corticospinal neurons has not been determined yet. In this paper, we report a side-by-side comparison between four commonly used promoters: the short CMV early enhancer/chicken β actin (sCAG), human cytomegalovirus (hCMV), mouse phosphoglycerate kinase (mPGK) and human synapsin (hSYN) promoter. Reporter constructs with each of these promoters were packaged in AAV1, and were injected in the sensorimotor cortex of rats and mice in order to transduce the corticospinal tract. Transgene expression levels and the cellular transduction profile were examined after 6 weeks. The AAV1 vectors harbouring the hCMV and sCAG promoters resulted in transgene expression in neurons, astrocytes and oligodendrocytes. The mPGK and hSYN promoters directed the strongest transgene expression. The mPGK promoter did drive expression in cortical neurons and oligodendrocytes, while transduction with AAV harbouring the hSYN promoter resulted in neuron-specific expression, including perineuronal net expressing interneurons and layer V corticospinal neurons. This promoter comparison study contributes to improve transgene delivery into the brain and spinal cord. The optimized transduction of the corticospinal tract will be beneficial for spinal cord injury research