Molecular and cellular features of murine craniofacial and trunk neural crest cells as stem cell-like cells.

The outstanding differentiation capacities and easier access from adult tissues, cells derived from neural crest cells (NCCs) have fascinated scientists in developmental biology and regenerative medicine. Differentiation potentials of NCCs are known to depend on their originating regions. Here, we report differential molecular features between craniofacial (cNCCs) and trunk (tNCCs) NCCs by analyzing transcription profiles and sphere forming assays of NCCs from P0-Cre/floxed-EGFP mouse embryos. We identified up-regulation of genes linked to carcinogenesis in cNCCs that were not previously reported to be related to NCCs, which was considered to be, an interesting feature in regard with carcinogenic potentials of NCCs such as melanoma and neuroblastoma. Wnt signal related genes were statistically up-regulated in cNCCs, also suggesting potential involvement of cNCCs in carcinogenesis. We also noticed intense expression of mesenchymal and neuronal markers in cNCCs and tNCCs, respectively. Consistent results were obtained from in vitro sphere-forming and differentiation assays. These results were in accordance with previous notion about differential potentials of cNCCs and tNCCs. We thus propose that sorting NCCs from P0-Cre/floxed-EGFP mice might be useful for the basic and translational research of NCCs. Furthermore, these newly-identified genes up-regulated in cNCC would provide helpful information on NC-originating tumors, developmental disorders in NCC derivatives, and potential applications of NCCs in regenerative medicine.

Inhibitory effect of pranidipine on N-type voltage-dependent Ca2+ channels in mice.

We investigated the N-type voltage-dependent calcium channel blocking action of pranidipine, a novel dihydropyridine (DHP) derivative. Pranidipine significantly suppressed KCl-induced intracellular calcium changes ([Ca(2+)](i)) in a dose-dependent fashion in dorsal root ganglion neurons. A patch-clamp investigation revealed a dose-dependent blocking effect on N-type currents. Intrathecal injection of pranidipine significantly shortened the licking time in the late phase of the formalin test, as occurs with cilnidipine and amlodipine, which act on L- and N-type channels. Conversely, nicardipine, which acts exclusively on L-type channels, had no antinociceptive effect. Our results indicate that pranidipine inhibits N-type calcium channels. Furthermore, it exerts an antinociceptive effect, which might be related to an attenuation of synaptic transmission by nociceptive neurons due to the blocking effect of pranidipine on N-type calcium channels in primary nociceptive afferent fibers.

Differential inhibition of transient outward currents of Kv1.4 and Kv4.3 by endothelin.

The effects of endothelin on the transient outward K(+) currents were compared between Kv1.4 and Kv4.3 channels in Xenopus oocytes expression system. Both transient outward K(+) currents were decreased by stimulation of endothelin receptor ET(A) coexpressed with the K(+) channels. Transient outward current of Kv1.4 was decreased by about 85% after 10(-8) M ET-1, while that of Kv4.3 was decreased by about 60%. By mutagenesis experiments we identified two phosphorylation sites of PKC and CaMKII in Kv1.4 responsible for the decrease in I(to) by ET-1. In Kv4.3 a PKC phosphorylation site was identified which is in part responsible for the decrease in I(to). Differences in the suppression of I(to) could be ascribed to the difference in intracellular signaling including the number of phosphorylation sites. These findings might give clues for the understanding of molecular mechanism of ventricular arrhythmias in heart failure, in which endothelin is involved in the pathogenesis.

[Basic arrhythmogenic mechanisms in both inherited and acquired long QT syndrome].

The heterologous expression system will provide clues for understanding the basic mechanism of arrhythmogenicity in both inherited and acquired long QT syndrome, which are reviewed here, with emphasis on the K+ channels. Endothelin is implicated in the morphological and electrical remodeling of cardiac muscles in heart failure. The effects of endothelin on the transient outward K+ currents (Ito) were compared between Kv1.4 (rich in endocardial muscle) and Kv4.3 (rich in epicardial muscle) channels in the Xenopus oocytes expression system. Both Itos were decreased by stimulation of endothelin receptor ETA coexpressed with the K+ channels. Ito of Kv1.4 was decreased by about 85% after 10(-8) M ET-1, whereas that of Kv4.3 was decreased by about 60%. By mutagenesis experiments, we identified two phosphorylation sites of PKC and CaMKII in Kv1.4 responsible for the decrease in Ito by ET-1. In Kv4.3 we identified a PKC phosphorylation site that is partly responsible for the decrease. Differences in the suppression of Ito could be due to the differences in intracellular signaling including the number of phosphorylation sites. These findings show some of the molecular mechanisms of ventricular arrhythmias in heart failure, resulting in dispersion and prolongation of action potential which elicit reentry and after depolarization.

Analgesic action of loperamide, an opioid agonist, and its blocking action on voltage-dependent Ca2+ channels.

We investigated the relationship between the antinociceptive effect of the opiate agonist loperamide at the spinal level and its inhibitory effect on calcium influx. Intrathecal administration of loperamide showed a significant antinociceptive effect in the formalin test, which was not prevented by naloxone. On the other hand, no significant effects were observed by nicardipine, an L-type specific blocker, or by BAY K8644, an L-type specific agonist, suggesting no significant role of L-type calcium channels in nociceptive signal transduction. Loperamide suppressed the calcium influx in dorsal root ganglion neurons. As the antinociceptive effect of loperamide was not affected by naloxone or other calcium channel blocking toxins, and loperamide showed a direct inhibitory effect on calcium-influx, the analgesic effect of intrathecally injected loperamide might be due to its blockade of the voltage-dependent calcium channels at the terminals of the primary afferent fibers.

The effect of taurine on the salt-dependent blood pressure increase in the voltage-dependent calcium channel beta 3-subunit-deficient mouse.

To examine the anti-hypertensive effect of taurine, we studied the effects of taurine on the salt-dependent blood pressure elevation, the electrocardiogram, and plasma catecholamine levels in the voltage-dependent calcium channel beta3-subunit-deficient mouse. In the wild-type mice, chronic high-salt loading (8% NaCl in chow) did not increase the blood pressure, whereas there was a significant increase in the systolic blood pressure in the beta3-subunit-deficient mice given a high-salt diet. Oral supplementation of taurine (3% in drinking water) could attenuate the increase in the blood pressure elicited by the high-salt diet. Plasma catecholamine levels were significantly decreased by the high-salt diet, and supplementation of taurine prevented those decreases in beta3-subunit-deficient mice. It is suggested, therefore, that chronic supplementation of taurine has an anti-hypertensive action in salt-dependent blood pressure elevation.