Progenitor cell proliferation in the retina is dependent on Notch-independent Sonic hedgehog/Hes1 activity

Sonic hedgehog (Shh) is an indispensable, extrinsic cue that regulates progenitor and stem cell behavior in the developing and adult mammalian central nervous system. Here, we investigate the link between the Shh signaling pathway and Hes1, a classical Notch target. We show that Shh-driven stabilization of Hes1 is independent of Notch signaling and requires the Shh effector Gli2. We identify Gli2 as a primary mediator of this response by showing that Gli2 is required for Hh (Hedgehog)-dependent up-regulation of Hes1. We also show using chromatin immunoprecipitation that Gli2 binds to the Hes1 promoter, which suggests that Hes1 is a Hh-dependent direct target of Gli2 signaling. Finally, we show that Shh stimulation of progenitor proliferation and cell diversification requires Gli2 and Hes1 activity. This paper is the first demonstration of the mechanistic and functional link between Shh, Gli, and Hes1 in the regulation of progenitor cell behavior

Effects of Mutant Ubiquitin on ts1 Retrovirus-Mediated Neuropathology

ts1 is a temperature-sensitive mutant of Moloney murine leukemia virus that induces a rapid spongiform encephalopathy in mice infected as newborns. The pathological features include the formation of ubiquitinated inclusions resembling Lewy bodies. To determine how perturbation of the ubiquitin-proteasome pathway might affect ts1-mediated neurodegeneration, the virus was introduced into transgenic mice in which the assembly of ubiquitin chains was compromised by the expression of dominant-negative mutant ubiquitin. The onset of symptoms was greatly delayed in a transgenic mouse line expressing K48R mutant ubiquitin; no such delay was observed in mice expressing a wild-type ubiquitin transgene or K63R mutant ubiquitin. The extended latency was found to correlate with a delayed increase in viral titers. Pathological findings in K48R transgenic mice at 60 days were found to be similar to those in the other strains at 30 days, suggesting that while delayed, the neurodegenerative process in K48R mice was otherwise similar. These data demonstrate the sensitivity of retroviral replication to the partial disruption of ubiquitin-mediated proteolysis in vivo, a finding that may have therapeutic potential

Oct-3/4 dose dependently regulates specification of embryonic stem cells toward a cardiac lineage and early heart development

The transcriptional mechanisms underlying lineage specification and differentiation of embryonic stem (ES) cells remain elusive. Oct-3/4 (POU5f1) is one of the earliest transcription factors expressed in the embryo. Both the pluripotency and the fate of ES cells depend upon a tight control of Oct-3/4 expression. We report that transgene- or TGFbeta-induced increase in Oct-3/4 mRNA and protein levels in undifferentiated ES cells and at early stages of differentiation triggers expression of mesodermal and cardiac specific genes through Smad2/4. cDNA antisense- and siRNA-mediated inhibition of upregulation of Oct-3/4 in ES cells prevent their specification toward the mesoderm and their differentiation into cardiomyocytes. Similarly, Oct-3/4 siRNA injected in the inner cell mass of blastocysts impairs cardiogenesis in early embryos. Thus, quantitative Oct-3/4 expression is regulated by a morphogen, pointing to a pivotal and physiological function of the POU factor in mesodermal and cardiac commitments of ES cells and of the epiblas