Cdx1 is essential for the initiation of HoxC8 expression during early embryogenesis.

The Hox genes pattern the anterior-posterior axis in developing embryos through tightly regulated, partially overlapping, temporal and spatial expression domains. Initial regulation of Hox expression is important to establish these overlapping transcription domains. The Cdx homeodomain factors have been proposed as Hox regulators, but their precise role and mechanism during this regulatory interaction remain unclear. In Xenopus embryos, HoxC8 transcripts begin to accumulate during mid/late gastrula. Cdx1 overexpression and knockdown lead to precocious or slower HoxC8 expression, respectively. The mouse HoxC8 early enhancer when introduced into Xenopus embryos recapitulates the endogenous XHoxC8 temporal expression pattern and shows the same responsiveness to Cdx1 regulation. Three pairs of conserved Cdx binding sites were identified within the HoxC8 early enhancer. We demonstrate that Cdx1 binds directly these responsive elements during embryogenesis, as part of the mechanism for the timely activation of HoxC8 expression. We define the function and mechanism of Cdx1 regulation on HoxC8 expression and suggest the possibility that the temporal changes in Cdx activity levels during gastrulation, combined with differential DNA binding affinity, might play a role in the establishment of Hox sequential activation.

Negative autoregulation of Oct3/4 through Cdx1 promotes the onset of gastrulation.

Gastrulation marks the onset of germ layer formation from undifferentiated precursor cells maintained by a network including the Pou5f1 gene, Oct3/4. Negative regulation of the undifferentiated state is a prerequisite for germ layer formation and subsequent development. A novel cross-regulatory network was characterized including the Pou5f1 and Cdx1 genes as part of the signals controlling the onset of gastrulation. Of particular interest was the observation that, preceding gastrulation, the Xenopus Oct3/4 factors, Oct60, Oct25, and Oct91, positively regulate Cdx1 expression through FGF signaling, and during gastrulation the Oct3/4 factors become repressors of Cdx1. Cdx1 negatively regulates the Pou5f1 genes during gastrulation, thus contributing to the repression of the network maintaining the undifferentiated state and promoting the onset of gastrulation. These regulatory interactions suggest that Oct3/4 initiates its own negative autoregulation through Cdx1 up-regulation to begin the repression of pluripotency in preparation for the onset of gastrulation and germ layer differentiation.

The expression of the beta cell-derived autoimmune ligand for the killer receptor nkp46 is attenuated in type 2 diabetes.

NK cells rapidly kill tumor cells, virus infected cells and even self cells. This is mediated via killer receptors, among which NKp46 (NCR1 in mice) is prominent. We have recently demonstrated that in type 1 diabetes (T1D) NK cells accumulate in the diseased pancreas and that they manifest a hyporesponsive phenotype. In addition, we found that NKp46 recognizes an unknown ligand expressed by beta cells derived from humans and mice and that blocking of NKp46 activity prevented diabetes development. Here we investigated the properties of the unknown NKp46 ligand. We show that the NKp46 ligand is mainly located in insulin granules and that it is constitutively secreted. Following glucose stimulation the NKp46 ligand translocates to the cell membrane and its secretion decreases. We further demonstrate by using several modalities that the unknown NKp46 ligand is not insulin. Finally, we studied the expression of the NKp46 ligand in type 2 diabetes (T2D) using 3 different in vivo models and 2 species; mice and gerbils. We demonstrate that the expression of the NKp46 ligand is decreased in all models of T2D studied, suggesting that NKp46 is not involved in T2D.