Temporal deletion of Arl13b reveals that a mispatterned neural tube corrects cell fate over time.

Cilia are necessary for sonic hedgehog (Shh) signaling, which is required to pattern the neural tube. We know that ventral neural cell fates are defined by a specific cohort of transcription factors that are induced by distinct thresholds of Shh activity mediated by opposing gradients of Gli activator (GliA) and Gli repressor (GliR). Despite this understanding, the role of Shh as an instructive morphogen is viewed as increasingly complex, with current models integrating positive inputs in terms of ligand concentration and time, along with negative feedback via the downstream gene regulatory network. To investigate the relative contributions of the positive and negative inputs from Shh signaling in neural patterning, we took advantage of a protein that uncouples the regulation of GliA and GliR: the cilia protein ADP-ribosylation factor-like 13b (Arl13b). By deleting Arl13b in mouse, we induced low-level constitutive GliA function at specific developmental stages and defined a crucial period prior to E10.5 when shifts in the level of GliA cause cells to change their fate. Strikingly, we found that improperly patterned cells in these mice converted to the wild-type pattern by E12.5. We further showed that the recovery of patterning did not occur when we also deleted Gli3, the primary GliR in the neural tube, revealing a crucial role of Gli3 in the maintenance of neural patterning.

Mitochondrial retention of Opa1 is required for mouse embryogenesis.

Mitochondria are dynamic cellular organelles that balance fission and fusion to regulate organelle morphology, distribution, and activity, and Opa1 is one of three GTPases known to regulate mitochondrial fusion. In humans, loss of a single Opa1 allele causes dominant optic atrophy, a degenerative condition that leads to loss of vision. Here we demonstrate that the lilR3 mutant mouse phenotype is due to a point mutation in the Opa1 gene resulting in mislocalized Opa1 protein from the mitochondria to the cytosol. Importantly, the mutation is in the middle domain of the Opa1 protein, for which no function had been described. Lack of mitochondrial retention of Opa1 is sufficient to cause the cellular Opa1 loss-of-function phenotype as the mitochondria are fragmented, indicating an inability to fuse. Despite the normally ubiquitous expression of Opa1 and the essential nature of mitochondria, embryos with aberrant Opa1 survived through midgestation and died at E11.5. These mutants displayed growth retardation, exencephaly, and abnormal patterning along the anterior-posterior axis, although the A-P axis itself was intact. The complex relationship between mitochondrial dynamics and cell death is emphasized by apoptosis in specific cell populations of lilR3 embryos. Our results define, for the first time, a function of the middle domain of the Opa1 protein and demonstrate that mitochondrial retention of Opa1 protein is essential for normal embryogenesis.

Death receptor 5 regulation during selenium-mediated apoptosis in human prostate cancer cells.

Selenium is an essential micronutrient that is currently being tested for prostate cancer chemoprevention. In spite of its significant promise as a chemopreventive agent, the molecular mechanisms of selenium-mediated effects remain to be elucidated. Recent evidence suggests that selenium may mediate its chemopreventive effects by inducing apoptosis in human prostate cancer cells. Here we report that selenium-mediated apoptosis appears to involve membrane death receptor, DR5-dependent pathway in human prostate cancer cells. Selenium specifically upregulated DR5 expression but not that of DR4. Selenium upregulation of DR5 was coupled with caspase 8 activation and Bid cleavage thereby suggesting the existence of a potential cross-talk between the DR5 and the mitochondrial pathways. Thus, our results suggest that DR5 is specifically regulated by selenium and its activation may play an important role in selenium-mediated chemoprevention.

Antigenic and genetic characteristics of swine-origin 2009 A(H1N1) influenza viruses circulating in humans.

Since its identification in April 2009, an A(H1N1) virus containing a unique combination of gene segments from both North American and Eurasian swine lineages has continued to circulate in humans. The lack of similarity between the 2009 A(H1N1) virus and its nearest relatives indicates that its gene segments have been circulating undetected for an extended period. Its low genetic diversity suggests that the introduction into humans was a single event or multiple events of similar viruses. Molecular markers predictive of adaptation to humans are not currently present in 2009 A(H1N1) viruses, suggesting that previously unrecognized molecular determinants could be responsible for the transmission among humans. Antigenically the viruses are homogeneous and similar to North American swine A(H1N1) viruses but distinct from seasonal human A(H1N1).