IP3R,RYR与Ca^2＋信号

Ｃａ＾２＋在生命活动中起着至关重要的作用,细胞接受外界刺激后,通过胞膜转导,将信息传入胞内。胞内两大Ｃａ＾２＋通道家族－三磷酸肌醇受体（ＩＰ３Ｒ）和斯里兰卡肉桂碱（ｒｙａｎｏｄｉｎｅ,ＲＹ）受体（ＲＹＲ）将胞内信息以周期性的Ｃａ＾２＋波动或振动编码,并藉此形式将所载信息转递给相应的受体,从而诱导复杂的生物学应答,本在介绍ＩＰ３Ｒ和ＲＹＲｃＤＮＡ克隆,受体结构与功能的关系及其活性调节的基础上,讨论     

钙依赖性激酶和磷酸化酶控制着IP_3介导的钙释放

钙依赖性激酶和磷酸化酶控制着ＩＰ_３介导的钙释放以往认为，细胞内ＩＰ３浓度的升高可以引起内质网中Ｃａ２＋的释放，但实际情形并不总是如此，也就是说，ＩＰ３浓度的升高不是Ｃａ２＋释放的唯一条件，后来发现，ＩＰ３介导的Ｃａ２＋释放受到［Ｃａ２＋］ｉ本身的调?..     

一种新的IP_3受体亚型基因得到克隆

一种新的ＩＰ_３受体亚型基因得到克隆三磷酸肌醇（ＩＰ３）可作为神经递质、激素和生长因子的第二信使发挥作用。它通过与Ｃａ２＋通道偶联的特异受体结合,引起Ｃａ２＋从细胞内库中释放。近年来的研究表明,机体存在一个ＩＰ３受体家族,已经克隆出该家族两个成员的完?..     

环化二磷酸腺苷核糖研究进展

环化二磷酸腺苷核糖（ｃＡＤＰＲ） 是细胞内的一种活性物质,可提高钙库膜上的ｒｙａｎｏｄｉｎｅ 受体活性,通过钙引起的钙释放（ｃａｌｃｉｕ ｍ ｉｎｄｕｃｅｄ ｃａｌｃｉｕ ｍ ｒｅｌｅａｓｅ ,ＣＩＣＲ） 机制释放Ｃａ２ ＋ ,进行信号转导。从植物到哺乳动物,许多种系的细胞对ｃＡＤＰＲ 敏感。在细胞内,ＡＤＰ 核糖环化酶催化ＮＡＤ＋ 生成ｃＡＤＰＲ,并受多种因素的调节。本文介绍了ｃＡＤＰＲ 的分子结构、生物合成及降解、功能等方面的进展。     

外源性神经节苷脂对人－肝癌培养细胞内钙的作用及其方式

本工作采用荧光探针Ｆｕｒａ－２ＡＭ观察了外源性神经节苷脂ＧＭ３和ＧＤ３对ＳＭＭＣ－７７２１人肝癌培养细胞钙的影响,证明ＧＭ３和ＧＤ３均能升高细胞内钙浓度（［Ｃａ２＋］ｉ）,但程度上有极大差异。１０ｎｍｏｌ／ｍＬＧＭ３或１．０ｎｍｏｌ／ｍＬＧＤ３可使［Ｃａ２＋］ｉ上升高是明显,与对照相比［Ｃａ２＋］ｉ分别增加２１５～２５０％和４２％。进一步用Ｖｅｒａｐａｍｉｌ阻断钙通道和内质网钙释放、去除细胞外Ｎａ＋以抑制Ｎａ＋－Ｃａ２＋交换以及去除细胞外Ｃａ２＋在无外钙内流等系统观察了ＧＭ３和ＧＤ３的作用方式,结果提示ＧＭ３升高［Ｃａ２＋］ｉ的机制是一个同时增加内质网钙释放、激活钙通道并伴有质膜Ｃａ２＋－ＡＴＰ酶激活的综合结果;而ＧＤ３则主要抑制Ｎａ＋－Ｃａ２＋交换系统。     

阿片类物质与Ca^2^＋的关系

本文介绍近来有关阿片类物质与Ｃａ＾２＾＋相互作用的研究进展。Ｃａ＾２＾＋作为第二信使参与信号转导作用。Ｃａ＾２＾＋可对抗阿片类物质的镇痛作用。Ｃａ＾２＾＋对阿片类物质的其他作用也表现出类似的作用。阿片类物质可抑制钙电流，降低胞内游离钙浓度。通过阻断钙通道，抑制久钙内和内钙释放柯能是阿片类物质产生作用的机制之一。     

钙信号基本单位和特征的研究进展

细胞内存在多种不同的Ｃａ＾２＋信号基本单位,这些Ｃａ＾２＋信号基本单位依赖于刺激浓度的等级体系组织。低水平的刺激激活单通道开放,产生Ｃａ＾２＋脉冲或Ｃａ＾２＋夸克;在等组织水平刺激则产生喷烟和火花,似乎与一小簇通道的激活有关;高浓度刺激时,Ｃａ＾２＋信号基本单位协同产生球形Ｃａ＾２＋波。这些Ｃａ＾２＋基本单位既本现了钙释放单位（Ｃａ＾２＋ｒｅｌｅａｓｅ ｕｎｉｔ）的特征,又导致Ｃａ＾２＋信号传播在     

GM_3、GD_3作用下SMMC－7721肝癌细胞内磷脂酰肌醇（1，4，5）三

外源性ＧＭ３（１０ｎｍｏｌ／ｍＬ）、ＧＤ３（１ｎｍｏｌ／ｍＬ）可使ＳＭＭＣ－７７２１人肝癌培养细胞内钙浓度呈快速的短暂升高,其到达峰值时间为４５秒,一次作用后,内钙水平于２－３ｍｉｎ内恢复至对照水平。在一定时间间隔中连续几次加入ＧＭ３或ＧＤ３后内钙水平的变化表明,ＧＭ３所引起的［Ｃａ２＋］ｉ的增加依赖于内质网钙贮的释放和细胞外钙的流入;而ＧＤ３增加［Ｃａ２＋］ｉ与此二系统无关。进一步研究表明,在细胞内钙达峰值时,１０ｎｍｏｌ／ｍＬＧＭ３可使ＩＰ３（１,４,５）浓度增加９．３倍,ｃＡＭＰ浓度增加８２％;１ｎｍｏｌ／ｍＬＧＤ３反使Ｉｐ３浓度增加１．２倍,提示ＧＭ３、ＧＤ３升高内钙的不同机制。     

培养大鼠心肌细胞缺氧与复氧时H^＋—Ca^2＋交换的研究

大量研究表明：心肌细胞缺氧后再复氧,可因氧反常和ＰＨ反常造成细胞内Ｃａ＾２＋超载。通常认为,在心肌细胞发生ＰＨ反常后,Ｈ＾＋Ｎａ＾＋－Ｃａ＾２＋交换加强是细胞内Ｃａ＾２＋超载的重要机制。本实验结果表明：阻断了Ｈ＾＋－Ｎａ＾＋－Ｃａ＾２＋交换后,仍有部分Ｃａ＾２＋进入细胞,Ｃａ＾２＋内流量与缺氧时间成正比关系。在无Ｎａ＾＋溶液中也得到了同样结果,表明此时Ｃａ＾２＋内流是通过与Ｎａ＾＋无关的通路进入细     

钙的光释入技术及其在细胞研究中的应用

Ｃａ＾２＋的光释放技术通过光解作用使预先引入细胞内的光敏感性螯合剂对Ｃａ＾２＋的亲和性改造从而实现细胞内游离钙离子浓度的调控,有助于阐明Ｃａ＾２＋作为第二信使对电兴奋性、肌肉收缩等细胞功能的调制作用。     

The brain ryanodine receptor: a caffeine-sensitive calcium release channel.

The release of stored Ca2+ from intracellular pools triggers a variety of important neuronal processes. Physiological and pharmacological evidence has indicated the presence of caffeine-sensitive intracellular pools that are distinct from the well-characterized inositol 1,4,5,-trisphosphate (IP3)-gated pools. Here we report that the brain ryanodine receptor functions as a caffeine- and ryanodine-sensitive Ca2+ release channel that is distinct from the brain IP3 receptor. The brain ryanodine receptor has been purified 6700-fold with no change in [3H]ryanodine binding affinity and shown to be a homotetramer composed of an approximately 500 kd protein subunit, which is identified by anti-peptide antibodies against the skeletal and cardiac muscle ryanodine receptors. Our results demonstrate that the brain ryanodine receptor functions as a caffeine-sensitive Ca2+ release channel and thus is the likely gating mechanism for intracellular caffeine-sensitive Ca2+ pools in neurons.     

The conformation of calsequestrin determines its ability to regulate skeletal ryanodine receptors

Ca2+ efflux from the sarcoplasmic reticulum decreases when store Ca2+ concentration falls, particularly in skinned fibers and isolated vesicles where luminal Ca2+ can be reduced to very low levels. However ryanodine receptor activity in many single channel studies is higher when the luminal free Ca2+ concentration is reduced. We investigated the hypothesis that prolonged exposure to low luminal Ca2+ causes conformational changes in calsequestrin and deregulation of ryanodine receptors, allowing channel activity to increase. Lowering of luminal Ca2+ from 1 mM to 100 microM for several minutes resulted in conformational changes with dissociation of 65-75% of calsequestrin from the junctional face membrane. The calsequestrin remaining associated no longer regulated channels. In the absence of this regulation, ryanodine receptors were more active when luminal Ca2+ was lowered from 1 mM to 100 microM. In contrast, when ryanodine receptors were calsequestrin regulated, lowering luminal Ca2+ either did not alter or decreased activity. Ryanodine receptors are regulated by calsequestrin under physiological conditions where calsequestrin is polymerized. Since depolymerization occurs slowly, calsequestrin can regulate the ryanodine receptor and prevent excess Ca2+ release when the store is transiently depleted, for example, during high frequency activity or early stages of muscle fatigue.     

Unique phosphorylation site on the cardiac ryanodine receptor regulates calcium channel activity.

Ryanodine receptors have recently been shown to be the Ca2+ release channels of sarcoplasmic reticulum in both cardiac muscle and skeletal muscle. Several regulatory sites are postulated to exist on these receptors, but to date, none have been definitively identified. In the work described here, we localize one of these sites by showing that the cardiac isoform of the ryanodine receptor is a preferred substrate for multifunctional Ca2+/calmodulin-dependent protein kinase (CaM kinase). Phosphorylation by CaM kinase occurs at a single site encompassing serine 2809. Antibodies generated to this site react only with the cardiac isoform of the ryanodine receptor, and immunoprecipitate only cardiac [3H]ryanodine-binding sites. When cardiac junctional sarcoplasmic reticulum vesicles or partially purified ryanodine receptors are fused with planar bilayers, phosphorylation at this site activates the Ca2+ channel. In tissues expressing the cardiac isoform of the ryanodine receptor, such as heart and brain, phosphorylation of the Ca2+ release channel by CaM kinase may provide a unique mechanism for regulating intracellular Ca2+ release.     

Dynamic regulation of intracellular calcium signals through calcium release channels

After the seminal work of Ebashi and coworkers which established the essential role of the intracellular Ca2+ concentration ([Ca2+]i) in the regulation of skeletal muscle contraction, we have witnessed an explosive elongation of the list of cell functions that are controlled by the [Ca2+]i. In numerous instances, release of intracellular Ca2+ stores plays important roles in Ca2+ signalling which displays significant variation in spatio-temporal pattern. There are two families of Ca2+ release channels, ryanodine receptors and inositol 1,4,5-trisphosphate (IP3) receptors. These Ca2+ release channels are structurally and functionally similar. In particular, the activity of both types of channels is regulated by the [Ca2+]i. The [Ca2+]i dependence of the Ca2+ release channel activity provides both types of channels with properties of a Ca2+ signal amplifier. This function of the ryanodine receptor is important in striated muscle excitation-contraction coupling, whereas that of the IP3 receptor seems to be the basis of the generation of Ca2+ waves. Thus the wide variety of Ca2+ signalling patterns seem to be critically dependent on the [Ca2+]i dependence of the Ca2+ release channels.     

'Quantal' Ca2+ release and the control of Ca2+ entry by inositol phosphates--a possible mechanism

The release of Ca2+ from intracellular stores by sub-optimal doses of inositol trisphosphate has been shown to be dose-related ('quantal'), and a simple model is proposed here to account for this phenomenon. It is suggested that there is a regulatory Ca2(+)-binding site on, or associated with, the luminal domain of the InsP3 receptor, which allosterically controls Ca2+ efflux, and the affinity for Ca2+ of that site is modulated by InsP3 binding to the cytoplasmic domain of the receptor; a similar mechanism applied to the ryanodine receptor might also explain some aspects of Ca2(+)-induced Ca2+ release. The stimulated entry of Ca2+ into a cell which occurs upon activation of inositide-linked receptors has been variously and confusingly proposed to be regulated by InsP3, InsP4, and/or a 'capacitative' Ca2+ pool; the mechanism of InsP3 receptor action suggested here is shown to lead to a potential reconciliation of all these conflicting proposals.     

Sphingosine releases Ca2+ from intracellular stores via the ryanodine receptor in sea urchin egg homogenates

Various reports have demonstrated that the sphingolipids sphingosine and sphingosine-1-phosphate are able to induce Ca2+ release from intracellular stores in a similar way to second messengers. Here, we have used the sea urchin egg homogenate, a model system for the study of intracellular Ca2+ release mechanisms, to investigate the effect of these sphingolipids. While ceramide and sphingosine-1-phosphate did not display the ability to release Ca2+, sphingosine stimulated transient Ca2+ release from thapsigargin-sensitive intracellular stores. This release was inhibited by ryanodine receptor blockers (high concentrations of ryanodine, Mg2+, and procaine) but not by pre-treatment of homogenates with cADPR, 8-bromo-cADPR or blockers of other intracellular Ca2+ channels. However, sphingosine rendered the ryanodine receptor refractory to cADPR. We propose that, in the sea urchin egg, sphingosine is able to activate the ryanodine receptor via a mechanism distinct from that used by cADPR.     

Cyclic ADP-ribose regulation of ryanodine receptors involved in agonist evoked cytosolic Ca2+ oscillations in pancreatic acinar cells.

We have investigated the role of the ryanodine-sensitive intracellular Ca2+ release channel (ryanodine receptor) in the cytosolic Ca2+ oscillations evoked in pancreatic acinar cells by acetylcholine (ACh) or cholecystokinin (CCK). Ryanodine abolished or markedly inhibited the agonist evoked Ca2+ spiking, but enhanced the frequency of spikes evoked by direct internal inositol trisphosphate (InsP3) application. We have also investigated the possibility that cyclic ADP-ribose (cADP-ribose), the putative second messenger controlling the ryanodine receptor, plays a role in Ca2+ oscillations. We found that cADP-ribose could itself induce repetitive Ca2+ spikes localized in the secretory pole and that these spikes were blocked by ryanodine, but also by the InsP3 receptor antagonist heparin. Our results indicate that both the ryanodine and the InsP3 receptors are involved in Ca2+ spike generation.     

NAADP-induced calcium release in sea urchin eggs

Nicotinic acid adenine dinucleotide phosphate (NAADP) is the most potent activator of Ca2+ release from intracellular stores described. It acts on a mechanism distinct from inositol trisphosphate and ryanodine receptors, the two major Ca2+ release channels characterised. NAADP-gated Ca2+ release channels do not appear to be regulated by Ca2+ and may be better suited for triggering Ca2+ signals rather than propagating them. They exhibit a remarkable pharmacology for a putative intracellular Ca2+ release channel in that they are selectively blocked by potassium and L-type Ca2+ channel antagonists. Furthermore, in contrast to microsomal Ca2+ stores expressing IP3Rs and RyRs, those sensitive to NAADP are thapsigargin-insensitive, suggesting that they may be expressed on a different part of the endoplasmic reticulum. Perhaps the most unusual feature of the NAADP-gated Ca2+ release mechanisms is its inactivation properties. Unlike the mechanisms regulated by IP3 and cADPR in sea urchin eggs which after induction of Ca2+ release appear to become refractory to subsequent activation, very low concentrations of NAADP are able to inactivate NAADP-induced Ca2+ release fully at concentrations well below those required to activate Ca2+ release. The mechanism and physiological significance of this most unusual desensitisation phenomenon are unclear. More recently, NAADP has been shown to mobilise Ca2+ in ascidian oocytes, brain microsomes and pancreatic acinar cells suggesting a more widespread role in Ca2+ signalling. A possible role for this novel Ca2+ release mechanism in sea urchin egg fertilisation is discussed.     

Regulation of Ca2+ release from internal stores in cardiac and skeletal muscles

It is widely accepted that Ca2+ is released from the sarcoplasmic reticulum by a specialized type of calcium channel, i.e., ryanodine receptor, by the process of Ca2+-induced Ca2+ release. This process is triggered mainly by dihydropyridine receptors, i.e., L-type (long lasting) calcium channels, directly or indirectly interacting with ryanodine receptor. In addition, multiple endogenous and exogenous compounds were found to modulate the activity of both types of calcium channels, ryanodine and dihydropyridine receptors. These compounds, by changing the Ca2+ transport activity of these channels, are able to influence intracellular Ca2+ homeostasis. As a result not only the overall Ca2+ concentration becomes affected but also spatial distribution of this ion in the cell. In cardiac and skeletal muscles the release of Ca2+ from internal stores is triggered by the same transport proteins, although by their specific isoforms. Concomitantly, heart and skeletal muscle specific regulatory mechanisms are different.     

Ca2+ release via ryanodine receptors and Ca2+ entry: major mechanisms in NAADP-mediated Ca2+ signaling in T-lymphocytes

Nicotinic acid adenine dinucleotide phosphate (NAADP) is a potent Ca2+ mobilizing nucleotide essentially involved in T cell activation. Using combined microinjection and single cell calcium imaging, we demonstrate that co-injection of NAADP and the D-myo-inositol 1,4,5-trisphosphate antagonist heparin did not inhibit Ca2+ mobilization. In contrast, co-injection of the ryanodine receptor antagonist ruthenium red efficiently blocked NAADP induced Ca2+ signalling. This pharmacological approach was confirmed using T cell clones stably transfected with plasmids expressing antisense mRNA targeted specifically against ryanodine receptors. NAADP induced Ca2+ signaling was strongly reduced in these clones. In addition, inhibition of Ca2+ entry by SK&F 96365 resulted in a dramatically decreased Ca2+ signal upon NAADP injection. Gd3+, a known blocker of Ca2+ release activated Ca2+ entry, only partially inhibited NAADP mediated Ca2+ signaling. These data indicate that in T cells (i) ryanodine receptor are the major intracellular Ca2+ release channels involved in NAADP induced Ca2+ signals, and that (ii) such Ca2+ release events are largely amplified by Ca2+ entry.