Unbalanced expression of CK2 kinase subunits is sufficient to drive epithelial-to-mesenchymal transition by Snail1 induction.

Epithelial-to-mesenchymal transition (EMT) is closely linked to conversion of early-stage tumours into invasive malignancies. Many signalling pathways are involved in EMT, but the key regulatory kinases in this important process have not been clearly identified. Protein kinase CK2 is a multi-subunit protein kinase, which, when overexpressed, has been linked to disease progression and poor prognosis in various cancers. Specifically, overexpression of CK2α in human breast cancers is correlated with metastatic risk. In this article, we show that an imbalance of CK2 subunits reflected by a decrease in the CK2ß regulatory subunit in a subset of breast tumour samples is correlated with induction of EMT-related markers. CK2ß-depleted epithelial cells displayed EMT-like morphological changes, enhanced migration, and anchorage-independent growth, all of which require Snail1 induction. In epithelial cells, Snail1 stability is negatively regulated by CK2 and GSK3ß through synergistic hierarchal phosphorylation. This process depends strongly on CK2ß, thus confirming that CK2 functions upstream of Snail1. In primary breast tumours, CK2ß underexpression also correlates strongly with expression of EMT markers, emphasizing the link between asymmetric expression of CK2 subunits and EMT in vivo. Our results therefore highlight the importance of CK2ß in controlling epithelial cell plasticity. They show that CK2 holoenzyme activity is essential to suppress EMT, and that it contributes to maintaining a normal epithelial morphology. This study also suggests that unbalanced expression of CK2 subunits may drive EMT, thereby contributing to tumour progression.

Paracrine control of the adult adrenal cortex vasculature by vascular endothelial growth factor.

The extensive vascular network that irrigates the adult adrenal cortex is essential for both the delivery of oxygen and nutrients to glandular steroidogenic cells and for the rapid and efficient export of corticosteroid products from these cells into the blood flow. During experimental and pathological changes in adrenal cortex size caused by ACTH overproduction or deficiency, the vasculature evolves in a coordinated manner with the mass of glandular cells so that blood vessel formation/regression and cortical gowth/atrophy are respectively synchronized. In addition to its previously reported expression in human fetal adrenocortical cells, the angiogenic factor VEGF-A appears also to be strongly expressed by both glomerulosa and fasciculata cells of the adult bovine adrenal cortex, when the endothelium is quiescent. Moreover, the expression of the two major transcripts encoding the 121 and the 165 amino acid-long isoforms of VEGF-A was observed to be rapidly (within 2-4 h) up-regulated (2-3 fold) by ACTH in primary cultures of bovine fasciculata and glomerulosa cells. The expression of the signalling VEGF receptors R1 (flt-1) and R2 (flk-1) was restricted to the endothelial cells of the cortex whereas neuropilin-1 was expressed by both endothelial and steroidogenic cells. This suggests that, under the control of the pituitary hormone ACTH, VEGF exerts a paracrine control over the vasculature of the adult adrenal cortex. Given its known effects as an anti-apoptotic agent and an inducer of endothelial fenestration, VEGF is likely to play a role in the maintenance of the dense and fenestrated vascular bed of the adrenal cortex. The vasculature thus appears as an important secondary target of ACTH action in the physiological control of adrenal cortex homeostasis.