Sepantronium bromide (YM155) induces disruption of the ILF3/p54(nrb) complex, which is required for survivin expression.

YM155, a small-molecule survivin suppressant, specifically binds to the transcription factor ILF3, which regulates the expression of survivin[1]. In this experiment we have demonstrated that p54(nrb) binds to the survivin promoter and regulates survivin expression. p54(nrb) forms a complex with ILF3, which directly binds to YM155. YM155 induces disruption of the ILF3/p54(nrb) complex, which results in a different subcellular localization between ILF3 and p54(nrb). Thus, identification of molecular targets of YM155 in suppression of the survivin pathway, might lead to development of its use as a novel potential target in cancers.

Disruption of the ether-a-go-go K+ channel gene BEC1/KCNH3 enhances cognitive function.

The K+ channel, one of the determinants for neuronal excitability, is genetically heterogeneous, and various K+ channel genes are expressed in the CNS. The therapeutic potential of K+ channel blockers for cognitive enhancement has been discussed, but the contribution each K+ channel gene makes to cognitive function remains obscure. BEC1 (KCNH3) is a member of the K+ channel superfamily that shows forebrain-preferential distribution. Here, we show the critical involvement of BEC1 in cognitive function. BEC1 knock-out mice performed behavioral tasks related to working memory, reference memory, and attention better than their wild-type littermates. Enhanced performance was also observed in heterozygous mutants. The knock-out mice had neither the seizures nor the motor dysfunction that are often observed in K+ channel-deficient mice. In contrast to when it is disrupted, overexpression of BEC1 in the forebrain caused the impaired performance of those tasks. It was also found that altering BEC1 expression could change hippocampal neuronal excitability and synaptic plasticity. The results indicate that BEC1 may represent the first K+ channel that contributes preferentially and bidirectionally to cognitive function.

Identification of MrgX2 as a human G-protein-coupled receptor for proadrenomedullin N-terminal peptides.

Proadrenomedullin N-terminal 20 peptide (PAMP[1-20]/PAMP-20) and its truncated analog, PAMP[9-20]/PAMP-12, are endogenous peptides that elicit hypotension through inhibiting catecholamine secretion from sympathetic nerve endings and adrenal chromaffin cells. Although the binding sites for PAMP are widely distributed, the nature of its receptor has been elusive. In an effort to identify potential PAMP receptor(s), we found that a human G-protein-coupled receptor, MrgX2, was specifically activated by PAMP. Although a previous study revealed that MrgX2 was a receptor for cortistatin, a neuropeptide involved in sleep regulation and locomotor activity, our present data indicated that the rank order of the agonistic effect against MrgX2 was "PAMP-12> or =cortistatin>PAMP-20". These activities were confirmed by the inhibition of the forskolin-elevated cAMP accumulation, Ca(2+) mobilization, and [(35)S]guanosine 5'-(gamma-thio)triphosphate binding assays. These findings suggest that MrgX2 couples with not only G(alpha q) but also G(alpha i), consistent with previous reports on the pharmacological profile of PAMP signaling. Furthermore, by immunostaining, we found that MrgX2 was expressed in the adrenal chromaffin cells as well as the dorsal root ganglia. From these results, we concluded that MrgX2 is a potential human PAMP-12 receptor that regulates catecholamine secretion from adrenal glands. The present discovery will eventually lead to a better understanding of the pathophysiological role of proadrenomedullin peptides.