Notch and Hedgehog signaling cooperate to maintain self-renewal of human embryonic stem cells exposed to low oxygen concentration

BACKGROUND AND OBJECTIVES: Expansion and maintenance of human embryonic stem cells (hESCs) in undifferentiated state is influenced by complex signals in the microenvironment, including those contingent upon oxygen availability. Responses mediated by Notch and Hedgehog (Hh) have essential role in the growth and maintenance of hESCs, therefore this study examined their effect on the self-renewal of hESCs exposed to low oxygen. METHODS AND RESULTS: Using potent antagonists γ-secretase inhibitor and cyclopamine, we inhibited Notch and Hh pathways, respectively, in the CLS1 hESC line expanded continuously in a hypoxic atmosphere of 5% oxygen. Immunohistochemical staining and protein assays revealed loss of Oct4 and gain of stage-specific embryonic antigen 1 (SSEA1) markers in the inhibited cells. Semiquantitative real-time RT-PCR, and bromodeoxyuridine and thymidine incorporation assays demonstrated low Oct4 and Nanog mRNA expression, and decreased DNA synthesis, respectively, resulting from the block of each of the pathways. The loss increased significantly with co-inhibition of both pathways. Importantly, Notch and Hh downstream targets, including Hes1, Hey1, GIi1, and Ptc1, were surprisingly suppressed not only by the pathway-specific but also the unrelated inhibitor. CONCLUSIONS: These findings demonstrate complementary effect of Notch and Hh signaling in hypoxia enhanced maintenance of hESCs

Therapy with Minocycline Aggravates Experimental Rabies in Mice▿

Minocycline is a tetracycline derivative with antiapoptotic and anti-inflammatory properties, and the drug has been shown to have beneficial effects in a variety of models of neurological disorders. The potentially neuroprotective role of minocycline was assessed in experimental in vitro and in vivo models of rabies virus infection. In this study, 5 nM minocycline did not improve the viability of embryonic mouse cortical and hippocampal neurons infected in vitro with the attenuated SAD-D29 strain of rabies virus, based on assessments using trypan blue exclusion. Two-day-old ICR mice were inoculated in the right hind limb thigh muscle with SAD-D29, and they received daily subcutaneous injections of either 50 mg/kg minocycline or vehicle (phosphate-buffered saline). Infected minocycline-treated mice experienced an earlier onset of neurologic signs and greater mortality (83% versus 50%) than those receiving vehicle (log rank test, P = 0.002 and P = 0.003, respectively). Immunohistochemical analysis of rabies virus antigen distribution was performed at early time points and in moribund mice. There were greater numbers of infected neurons in the regional brain areas of minocycline-treated mice than in vehicle-treated mice, which was significant in the CA1 region of the hippocampus. There was less apoptosis (P = 0.01) and caspase 3 immunostaining (P = 0.0008) in the midbrains of mice treated with minocycline than in mice treated with vehicle, consistent with a neuroprotective role of neuronal apoptosis that may have had a mild effect of inhibiting viral spread. Reduced infiltration of CD3+ T cells was observed in the pons/medulla of moribund mice that received minocycline therapy (P = 0.008), suggesting that the anti-inflammatory actions of minocycline may intensify the neurologic disease. These findings indicate that minocycline has important detrimental effects in the therapy of experimental rabies. Empirical therapy with minocycline should therefore be approached with caution in cases of human rabies and possibly other viral encephalitides until more experimental data become available