Mechanosensitive ion channel Piezo2 is inhibited by D-GsMTx4

Enterochromaffin (_EC) cells are the primary mechanosensors of the gastrointestinal (GI) epithelium. In response to mechanical stimuli_EC cells release serotonin (5-hydroxytryptamine; 5-HT). The molecular details of_EC cell mechanosensitivity are poorly understood. Recently, our group found that human and mouse_EC cells express the mechanosensitive ion channel Piezo2. The mechanosensitive currents in a human_EC cell model QGP-1 were blocked by the mechanosensitive channel blocker D-GsMTx4.

In the present study we aimed to characterize the effects of the mechanosensitive ion channel inhibitor spider peptide D-GsMTx4 on the mechanically stimulated currents from both QGP-1 and human Piezo2 transfected HEK-293 cells. We found co-localization of 5-HT and Piezo2 in QGP-1 cells by immunohistochemistry. QGP-1 mechanosensitive currents had biophysical properties similar to dose-dependently Piezo2 and were inhibited by D-GsMTx4. In response to direct displacement of cell membranes, human Piezo2 transiently expressed in HEK-293 cells produced robust rapidly activating and inactivating inward currents. D-GsMTx4 reversibly and dose-dependently inhibited both the potency and efficacy of Piezo2 currents in response to mechanical force. Our data demonstrate an effective inhibition of Piezo2 mechanosensitive currents by the spider peptide D-GsMTx4.     

GABAB receptors suppress burst-firing in reticular thalamic neurons

Burst-firing in thalamic neurons is known to play a key role in mediating thalamocortical (TC) oscillations that are associated with non-REM sleep and some types of epileptic seizure. Within the TC system the primary output of GABAergic neurons in the reticular thalamic nucleus (RTN) is thought to induce the de-inactivation of T-type calcium channels in thalamic relay (TR) neurons, promoting burst-firing drive to the cortex and the propagation of TC network activity. However, RTN neurons also project back onto other neurons within the RTN. The role of this putative negative feedback upon the RTN itself is less well understood, although is hypothesized to induce de-synchronization of RTN neuron firing leading to the suppression of TC oscillations. Here we tested two hypotheses concerning possible mechanisms underlying TC oscillation modulation. Firstly, we assessed the burst-firing behavior of RTN neurons in response to GABA_B receptor activation using acute brain slices. The selective GABA_B receptor agonist baclofen was found to induce suppression of burst-firing concurrent with effects on membrane input resistance. Secondly, RTN neurons express Ca_V3.2 and Ca_V3.3 T-type calcium channel isoforms known to contribute toward TC burst-firing and we examined the modulation of these channels by GABA_B receptor activation. Utilizing exogenously expressed T-type channels we assessed whether GABA_B receptor activation could directly alter T-type calcium channel properties. Overall, GABA_B receptor activation had only modest effects on Ca_V3.2 and Ca_V3.3 isoforms. The only effect that could be predicted to suppress burst-firing was a hyperpolarized shift in the voltage-dependence of inactivation, potentially causing lower channel availability at membrane potentials critical for burst-firing. Conversely, other effects observed such as a hyperpolarized shift in the voltage-dependence of activation of both Ca_V3.2 and Ca_V3.3 as well as increased time constant of activation of the Ca_V3.3 isoform would be expected to enhance burst-firing. Together, we hypothesize that GABA_B receptor activation mediates multiple downstream effectors that combined act to suppress burst-firing within the RTN. It appears unlikely that direct GABA_B receptor-mediated modulation of T-type calcium channels is the major mechanistic contributor to this suppression.     

Regulation of transient receptor potential melastatin 4 channel by sarcoplasmic reticulum inositol trisphosphate receptors: Role in human detrusor smooth muscle function

We recently reported key physiologic roles for Ca²⁺-activated transient receptor potential melastatin 4 (TRPM4) channels in detrusor smooth muscle (DSM). However, the Ca²⁺-signaling mechanisms governing TRPM4 channel activity in human DSM cells are unexplored. As the TRPM4 channels are activated by Ca²⁺, inositol 1,4,5-trisphosphate receptor (IP₃R)-mediated Ca²⁺ release from the sarcoplasmic reticulum represents a potential Ca²⁺ source for TRPM4 channel activation. We used clinically-characterized human DSM tissues to investigate the molecular and functional interactions of the IP₃Rs and TRPM4 channels. With in situ proximity ligation assay (PLA) and perforated patch-clamp electrophysiology, we tested the hypothesis that TRPM4 channels are tightly associated with the IP₃Rs and are activated by IP₃R-mediated Ca²⁺ release in human DSM. With in situ PLA, we demonstrated co-localization of the TRPM4 channels and IP₃Rs in human DSM cells. As the TRPM4 channels and IP₃Rs must be located within close apposition to functionally interact, these findings support the concept of a potential Ca²⁺-mediated TRPM4-IP₃R regulatory mechanism. To investigate IP₃R regulation of TRPM4 channel activity, we sought to determine the consequences of IP₃R pharmacological inhibition on TRPM4 channel-mediated transient inward cation currents (TICCs). In freshly-isolated human DSM cells, blocking the IP₃Rs with the selective IP₃R inhibitor xestospongin-C significantly decreased TICCs. The data suggest that IP₃Rs have a key role in mediating the Ca²⁺-dependent activation of TRPM4 channels in human DSM. The study provides novel insight into the molecular and cellular mechanisms regulating TRPM4 channels by revealing that TRPM4 channels and IP₃Rs are spatially and functionally coupled in human DSM.     

激活SUR2B/Kir6.1通道扩张肺微动脉的分子机制

目的：以ATP敏感性钾通道（K_ATP） SUR2B/Kir6.1亚型开放剂埃他卡林（Ipt）为工具药,研究激活SUR2B/Kir6.1通道扩张肺微动脉作用特征,并探讨其可能的分子机制。方法：利用离体微血管压力-直径监测灌流技术,检测Ipt对大鼠四级肺微动脉的舒张效应（n=6~8）,观察内皮损伤后或用K_ATP通道拮抗剂格列苯脲（Gli）、环氧合酶（COX）抑制剂吲哚美辛（Indo）、一氧化氮合酶（NOS）抑制剂L-Nω-硝基精氨酸甲酯（L-NAME）预孵后肺微动脉舒张率的变化。结果：Ipt能够扩张肺微动脉,最大舒张率为（60.53±2.08）%。内皮细胞损伤后,Ipt扩张肺微动脉作用明显减弱,最大舒张率为（9.47±1.56）%,与对照组相比存在显著性差异（P<0.01）。预孵Gli、Indo、L-NAME后,最大舒张率分别下降为（17.49±1.47）%、（37.00±3.88）%、（24.91±2.30）%,与对照组相比均存在显著性差异（P<0.01）。结论：其选择性开放K_ATP通道SUR2B/Kir6.1扩张肺微动脉作用具有内皮细胞依赖性,与其促进内皮细胞释放一氧化氮（NO）和前列环素（PGI₂）相关。     

瞬时感受器电位M2通道抗原位点的兔单抗特异性检测

目的：筛选特异性较高的抗体以推动对瞬时感受器电位M2（TRPM2）通道结构和功能的研究。方法：以野生型昆明种小鼠大脑皮层、人胚肾293细胞、未诱导的TRPM2细胞及四环素诱导的TRPM2细胞为标本,采用免疫印迹和免疫荧光方法,以被检测抗体为一抗,荧光分子结合的抗体为二抗,根据170kD（TRPM2通道蛋白分子量）位置上是否有特异性条带,检测兔单抗的特异性。结果：抗体98927对鼠源TRPM2通道有特异性,抗体40622,抗体98721,抗体98921对人源TRPM2通道有特异性,另外抗体98721对鼠源TRPM2通道的突变型有特异性。结论：作为分子探针,抗体98927、40622、98721、98921可用于TRPM2通道结构和功能研究。     

昆虫击倒抗性基因突变对钠通道功能的影响

该文综述了昆虫钠通道基因的表达与功能特性、击倒抗性突变的功能和这些突变对钠通道门控的影响,以及钠通道基因突变与抗性表现型之间的因果关系;还讨论了这些突变增强击倒抗性的分子机理。     

The role of polyamines during <Emphasis Type="Italic">in vivo</Emphasis> and <Emphasis Type="Italic">in vitro</Emphasis> development

Polyamines are ubiquitous polycationic compounds that mediate fundamental aspects of cell growth, differentiation, and cell death in eukaryotic and prokaryotic organisms. In plants, polyamines are implicated in a variety of growth and developmental processes, in addition to abiotic and biotic stress responses. In the last decade, mutant studies conducted predominantly in Arabidopsis thaliana revealed an obligatory requirement for polyamines in zygotic and somatic embryogenesis. Moreover, our appreciation for the intricate spatial and temporal regulation of intracellular polyamine levels has advanced considerably. The exact molecular mechanism(s) through which polyamines exert their physiological response remains somewhat enigmatic and likely serves as a major area for future research efforts. In the following review, we discuss recent advances in the plant polyamine field, which range from metabolism and mutant characterization to molecular genetics and potential mode(s) of polyamine action during growth and development in vitro and in vivo. This review will also focus on the specific role of polyamines during embryogenesis and organogenesis.     

Identification and characterization of a novel O‐superfamily conotoxin from Conus litteratus

A novel conotoxin named lt6c, an O‐superfamily conotoxin, was identified from the cDNA library of venom duct of Conus litteratus. The full‐length cDNA contains an open reading frame encoding a predicted 22‐residue signal peptide, a 22‐residue proregion and a mature peptide of 28 amino acids. The signal peptide sequence of lt6c is highly conserved in O‐superfamily conotoxins and the mature peptide consists of six cysteines arranged in the pattern of C? C? CC? C? C that is defined the O‐superfamily of conotoxins. The mature peptide fused with thioredoxin, 6‐His tag, and a Factor Xa cleavage site was successfully expressed in Escherichia coli. About 12 mg lt6c was purified from 1L culture. Under whole‐cell patch‐clamp mode, lt6c inhibited sodium currents on adult rat dorsal root ganglion neurons. Therefore, lt6c is a novel O‐superfamily conotoxin that is able to block sodium channels. Copyright © 2008 European Peptide Society and John Wiley & Sons, Ltd.     

Structure,Function, and Modification of the Voltage Sensor in Voltage-Gated Ion Channels

Voltage-gated ion channels are crucial for both neuronal and cardiac excitability. Decades of research have begun to unravel the intriguing machinery behind voltage sensitivity. Although the details regarding the arrangement and movement in the voltage-sensor domain are still debated, consensus is slowly emerging. There are three competing conceptual models: the helical-screw, the transporter, and the paddle model. In this review we explore the structure of the activated voltage-sensor domain based on the recent X-ray structure of a chimera between Kv1.2 and Kv2.1. We also present a model for the closed state. From this we conclude that upon depolarization the voltage sensor S4 moves approximately 13 A outwards and rotates approximately 180 degrees, thus consistent with the helical-screw model. S4 also moves relative to S3b which is not consistent with the paddle model. One interesting feature of the voltage sensor is that it partially faces the lipid bilayer and therefore can interact both with the membrane itself and with physiological and pharmacological molecules reaching the channel from the membrane. This type of channel modulation is discussed together with other mechanisms for how voltage-sensitivity is modified. Small effects on voltage-sensitivity can have profound effects on excitability. Therefore, medical drugs designed to alter the voltage dependence offer an interesting way to regulate excitability.