Prevalence of subtype-related polymorphisms associated with in vitro resistance to attachment inhibitor BMS-626529 in HIV-1 'non-B'-infected patients.

OBJECTIVES: BMS-626529 is a member of the new drug class of HIV-1 attachment inhibitors currently in development. Mutations selected during in vitro experiments with BMS-626529 are located in the gp120 region: L116P, A204D, M426L, M434I-V506M and M475I. A differential antiviral activity of BMS-626529 was observed depending of the viral subtype. The aim of our study was to assess the prevalence of subtype-related polymorphisms previously described as being associated with in vitro resistance to BMS-626529 in patients infected with different HIV-1 'non-B' subtypes. PATIENTS AND METHODS: The prevalence of substitutions in gp120 was assessed in 85 HIV-infected patients (not previously treated with attachment inhibitors and infected with HIV-1 'non-B' subtypes) by performing direct sequencing of the gp120 region. RESULTS: The most prevalent HIV-1 subtype was CRF02_AG (n = 46, 54%). The M426L substitution was found in virus from 10 patients (11.8%), mainly in subtypes D and CRF02_AG. The M434I substitution was found in virus from 11 patients (12.9%), mainly in subtypes CRF02_AG and CRF06_cpx. None of the CRF02_AG viruses harboured both M426L and M434I substitutions. CONCLUSIONS: In our series, the M426L substitution in the gp120 region was detected in 46% and 7% of subtype D and CRF02_AG samples, respectively, and might affect the activity of BMS-626529 against these specific subtypes. Further studies are needed to better describe associations between HIV-1 'non-B'-subtype-related polymorphism profiles and the level of phenotypic resistance to attachment inhibitor BMS-626529.

Vascular endothelial growth factor receptor 3 controls neural stem cell activation in mice and humans.

Neural stem cells (NSCs) continuously produce new neurons within the adult mammalian hippocampus. NSCs are typically quiescent but activated to self-renew or differentiate into neural progenitor cells. The molecular mechanisms of NSC activation remain poorly understood. Here, we show that adult hippocampal NSCs express vascular endothelial growth factor receptor (VEGFR) 3 and its ligand VEGF-C, which activates quiescent NSCs to enter the cell cycle and generate progenitor cells. Hippocampal NSC activation and neurogenesis are impaired by conditional deletion of Vegfr3 in NSCs. Functionally, this is associated with compromised NSC activation in response to VEGF-C and physical activity. In NSCs derived from human embryonic stem cells (hESCs), VEGF-C/VEGFR3 mediates intracellular activation of AKT and ERK pathways that control cell fate and proliferation. These findings identify VEGF-C/VEGFR3 signaling as a specific regulator of NSC activation and neurogenesis in mammals.