Hox genes are essential regulators of embryonic development. Their step-wise transcriptional activation follows their genomic topology and the various states of activation are subsequently memorized into domains of progressively overlapping gene products. We have analyzed the 3D chromatin organization of Hox clusters during their early activation in vivo, using high-resolution circular chromosome conformation capture. Initially, Hox clusters are organized as single chromatin compartments containing all genes and bivalent chromatin marks. Transcriptional activation is associated with a dynamic bi-modal 3D organization, whereby the genes switch autonomously from an inactive to an active compartment. These local 3D dynamics occur within a framework of constitutive interactions within the surrounding Topological Associated Domains, indicating that this regulation process is mostly cluster intrinsic. The step-wise progression in time is fixed at various body levels and thus can account for the chromatin architectures previously described at a later stage for different anterior to posterior levels.DOI: http://dx.doi.org/10.7554/eLife.02557.001
1. Using the cell-attached and inside-out modes of the patch-clamp technique, we studied the Ca2+-dependent ionic channels activated by bradykinin in cultured pig coronary artery endothelial cells to further understand electrophysiological events underlying cellular activation.2. In the cell-attached mode, bradykinin (94 nM) activated two types of Ca2P-dependent channels: a high conductance K+ channel (285 pS in high symmetrical K+), whose open state probability was increased by depolarization, and a lower conductance inwardly rectifying non-selective cation channel (44 pS in high symmetrical K+). with nearly the same permeability (P) as monovalent cations (PK: PNa: Pca= 1: 1: 07). 6. The cation channel appeared to be more sensitive to Ca2+ than the K+ channel, with a halfmaximal open probability induced by 0 7 gm Ca2P on the intracellular side of the membrane. 7. In contrast to the K+ channel, the cation channel mean open time was clearly increased by bradykinin. This effect was delayed compared with the increase in the channel open state probability and was rapidly lost in the inside-out configuration. Caffeine also activated the cation channel but more transiently than bradykinin and without any effect on the open duration.8. In the absence of extracellular Ca2+, the bradykinin-induced increase in cytosolic free Ca2+ was shortened temporally by 52% and reduced in amplitude by 88%, whereas the bradykinin-induced hyperpolarization was not significantly reduced in amplitude but was shortened by 70%, thus illustrating the major role of Ca2P influx in endothelial cell activation by bradykinin. 9. We conclude that bradykinin activates two types of
Connexin40 (Cx40), connexin37 (Cx37) and connexin43 (Cx43) are subunit proteins of gap junction channels in the vascular wall which are presumably involved in the propagation of vasomotor signals. In this study we have investigated in Cx40-deficient versus wild-type aortic endothelium to which extent loss of Cx40 impairs intercellular communication. We show in Cx40-deficient mice that expression of both Cx37 and Cx43 protein was increased approximately 3- and 2-fold over the level in wild-type endothelium, respectively. Furthermore, Cx37 immunosignals were distributed more homogeneously on contacting plasma membranes in Cx40-deficient versus with wild-type endothelium. Cx43 was not detected in endothelium but only in smooth muscle cells of the vessel wall. Iontophoretic injection of Lucifer Yellow or neurobiotin into aortic endothelium of Cx40-deficient mice showed extensive intercellular transfer of neurobiotin but not of Lucifer Yellow. In contrast, intercellular spreading of Lucifer Yellow was observed in endothelium of wild-type aorta. As shown by electron microscopy, gap junctions in Cx40-deficient endothelium were morphologically different from those of wild-type vessels. These results demonstrate that dye diffusibility of endothelial gap junctions is different in Cx40-deficient and wild-type mice, although Cx40-deficient mice retain the capability of intercellular communication. Apparently, Cx40-deficient endothelial cells upregulate and redistribute Cx37 as a molecular adaptation to the lack of Cx40.
A regenerative calcium wave is an increase in cytosolic free calcium concentration ([Ca2+]i) which extends beyond the stimulated cells without decrement of amplitude, kinetics of [Ca2+]i increase and speed of propagation. The aim of the present study was to test the hypothesis that such a wave could be evoked by bradykinin stimulation and by scraping cultured endothelial cells from porcine coronary arteries. Calcium imaging was performed using the calcium‐sensitive dye fura‐2. A wound or a delivery of bradykinin to two to three cells on growing clusters of ≈300 cells caused an increase in [Ca2+]i which was propagated throughout the cluster in a regenerative manner over distances up to 400 μm. This wave spread through gap junctions since it was inhibited by the cell uncoupler palmitoleic acid. The same experiments performed in confluent cultures caused a rise in [Ca2+]i which failed to propagate in a regenerative way. The wave propagation probably failed because the confluent cells were less dye coupled than the growing cells. This was confirmed by immunohistology which detected a dramatic decrease in the number of connexin 40 gap junctions in the confluent cultures. The regenerative propagation of the wave was blocked by inhibitors of calcium‐induced calcium release (CICR) and phospholipase C (PLC), and by suppression of extracellular calcium, but not by clamping the membrane potential with high‐potassium solution. We conclude that regenerative intercellular calcium waves exist in cultured islets but not in confluent cultures of endothelial cells. An increase in [Ca2+]i is not sufficient to trigger a regenerative propagation. The PLC pathway, CICR and extracellular calcium are all necessary for a fully regenerated propagation.
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