β-G spectrin的显性基因突变破坏致密核心囊泡的分泌

β-spectrin是细胞膜骨架的重要组成蛋白,其主要分布于质膜的基底部位.在线虫中只有一个编码β-spectrin亚基(β-G)的基因即unc-70.除了稳定质膜,使细胞产生极性等功能外,有报道称它还参与细胞分泌的调节过程.研究发现,在线虫中β-G spectrin的显性基因突变体unc-70(n493)会导致DCVs的分泌缺陷.在活体下,unc-70(n493)突变虫系的神经多肽分泌显著下降.此外,在主要分泌致密核心囊泡的ALA神经元内,钙光解释放促发的快相分泌也比野生型减少.运用TIRFM成像技术,观察在unc-70缺失的情况下ALA神经元内DCVs的锚定过程,结果显示质膜附近囊泡的密度没有显著变化,但囊泡在细胞膜附近停留的时程变短,表明囊泡锚定受到阻碍.为了验证unc-70是否还同时参与调控突触囊泡的分泌过程,运用电生理记录活体线虫神经肌肉接头的方法,发现自发的突触后电流mEPSCs没有明显变化.上述试验结果表明,β-G spectrin的显性基因突变虫系能够影响致密核心囊泡的分泌过程,其机制可能是影响了囊泡的锚定过程.     

UNC-10在致密核心囊泡分泌过程中的作用

Rim是囊泡分泌活性区中的重要组成蛋白,它与细胞分泌和突触可塑性相关．在秀丽隐感线虫中只存在一种编码Rim的基因即unc-10．我们的研究发现,在线虫中Rim的基因突变unc-10(md1117)会导致致密核心囊泡的分泌缺陷．在活体中,unc-10突变虫系的神经多肽分泌显著下降．此外,在主要分泌致密核心囊泡的ALA神经元内,钙光解释放促发的快相分泌也比野生型减少．运用全内反射荧光显微成像技术,我们观察在unc-10缺失的情况下ALA 神经元中致密核心囊泡的锚定过程,结果显示在细胞膜附近停留的囊泡数目减少,表明囊泡锚定受到阻碍．上述试验结果表明,UNC-10能够影响致密核心囊泡的分泌过程,其机制可能是影响了囊泡的锚定过程．     

钙离子信号对胰岛素分泌的调控

胰岛素的分泌及其分泌的调控是维持机体内葡萄糖平衡的重要机制,胰岛素分泌量的不足会导致非胰岛素依赖的糖尿病的发生.胰岛素包裹在致密核心大囊泡中,胰腺β细胞通过调控致密核心大囊泡的胞吐过程来调节胰岛素的分泌.胞内Ca2 浓度是影响胰岛素分泌的重要因素.胰腺β细胞主要通过质膜上的ATP敏感的钾通道、钙通道和胞内钙库的活动改变胞内Ca2 浓度,从而调控β细胞胰岛素的分泌活动.     

PC12细胞中Synaptotagmin Ⅶ 的沉默抑制了致密核心大囊泡的分泌

Syt Ⅶ, 因其具有比Syt Ⅰ和Syt Ⅸ更高的钙离子亲和力, 以及在与脂质结合后表现出更慢的解离动力学过程, 被认为在致密核心大囊泡分泌的慢速动力学过程中起着钙离子感受器的作用, 而并不参与突触囊泡的快速分泌过程. 然而迄今为止, Syt Ⅶ的亚细胞定位和其在胞内具体的生理学功能尚未完全清楚. 在本研究中, 我们首先应用全内反射荧光显微镜技术表明, 在PC12细胞中Syt Ⅶ定位于致密核心囊泡. 通过综合运用高时间分辨率的细胞膜电容测量和碳纤维微电极安培检测, 确定了单独沉默内源性的Syt Ⅶ就可以明显减少PC12细胞中钙触发的致密核心囊泡和质膜的融合和抑制了融合孔的开放, 特别是减少了致密核心大囊泡胞吐触发相的幅值, 而对于其持续成分的速率则几乎没有影响. 这些发现提示我们Syt Ⅶ在PC12细胞致密核心囊泡融合机制中作为钙感受器, 对可释放致密核心大囊泡库的形成和维持起着非常重要的作用.     

Ca2+依赖和Ca2+不依赖的囊泡分泌研究进展

Ca2 是促发囊泡胞吐的关键调节因子.最近的研究表明,分泌囊泡和通道之间的空间距离调节囊泡分泌的过程和性质.Ca2 通道开口附近形成的Ca2 微区和Ca2 钠区和囊泡快速递质释放有非常紧密的联系.SNARE蛋白和钙离子传感器synaptotagmins等在触发分泌中起调控作用.同时另有一类不依赖于Ca2 的囊泡分泌存在.Latrotoxin和mastoparan等可以激活这一类不依赖于Ca2 的信号通路,从而触发囊泡释放.本文主要从ca2 对囊泡胞吐的调控作用着手,综述了Ca2 依赖和Ca2 不依赖的囊泡分泌过程和可能的调控机制.     

Ca^2＋依赖和Ca^2＋不依赖的囊泡分泌研究进展

Ca^2＋是促发囊泡胞吐的关键调节因子。最近的研究表明,分泌囊泡和通道之间的空间距离调节囊泡分泌的过程和挂质。Ca^2＋通道开口附近形成的Ca^2＋微区和Ca^2＋钠区和囊泡快速递质释放有非常紧密的联系。SNARE蛋白和钙离子传感器synaptotagmins等在触发分泌中起调控作用。同时另有一类不依赖于Ca^2＋的囊泡分泌存在。Latrotoxin和mastoparan等可以激活这一类不依赖于Ca^2＋的信号通路,从而触发囊泡释放。本文主要从Ca^2＋对囊泡胞吐的调控作用着手,综述了Ca^2＋依赖和Ca^2＋不依赖的囊泡分泌过程和可能的调控机制。     

以消散场成像和单微粒跟踪技术揭示GLUT4囊泡和分泌囊泡的不同动态过程

葡萄糖转运子蛋白4(glucose transporter 4,GLUT4)在维持体内葡萄糖动态平衡的过程中起着至关重要的作用。GLUT4贮存囊泡(GLUT4 storage vesicle,GSV)和神经内分泌细胞中的分泌囊泡含有许多相同的蛋白。研究证明这些蛋白调节了分泌囊泡的胞内转运过程,但是GLUT4囊泡和分泌囊泡是否具有相同的胞内动态过程还未阐明。文章以3T3-L1纤维原细胞中的GSV和神经内分泌细胞PC12细胞中的分泌囊泡:致密核心大囊泡(large dense core vesicle,LDCV)为研究对象,使用消散场显微成像技术和单微粒跟踪技术直观观察了活体细胞内单个GSV和LDCV的三维运动轨迹。通过以适当方程拟合单个囊泡的均方位移曲线,发现两种囊泡都具有三种运动模式。定量分析显示作自由扩散运动和方向性扩散运动的GSV数量明显多于LDCV。对比GSV和LDCV的三维扩散系数,发现GSV的扩散系数中值为7.2×10-4μm2/s,而LDCV的扩散系数中值仅为1.94×10-4μm2/s。这一结果说明GSV的活动性远大于LDCV,提示GSV的胞内转运过程涉及不同的分子机制。     

CAPS在囊泡分泌过程中作用的研究进展

钙依赖的分泌激活蛋白(CAPS)是一种可以重组通透化神经内分泌细胞的分泌的蛋白.一般认为CAPS是选择性的在致密核心大囊泡的分泌过程中起作用,而不是在清亮囊泡的分泌过程中起作用.但是至今,我们并没有完全了解CAPS的作用机制,并且CAPS中各个预测的功能结构域的作用也不完全清楚.本文将对CAPS的研究进展做详尽的综述.     

线虫荧光标记稳定表达系的建立

目的:建立稳定表达的PHluorin标记的线虫种系,为囊泡在线虫ALA神经元上分泌机制的研究提供模型。方法:采用了国际先进的线虫转基因技术,将构建的Pida-1IDA-1:PHluorin质粒通过显微注射到线虫的母代,通过筛选后得到稳定表达的种系。结果:通过DIC显微镜整体检测和全内反射荧光成像技术(Tirfm)细胞检测,蛋白表达的位置正确,通过高倍数体式显微镜确定稳定种系中阳性率高达99%。结论:建立了一个稳定表达的荧光标记线虫种系,为进一步在线虫上研究囊泡分泌提供了很好的模型。     

线虫全基因组RNAi筛选确定CAB-1为特异性调节致密核心囊泡分泌的因子

内分泌细胞和神经细胞通过释放激素和神经肽类物质来响应外界刺激,而这些物质的分泌,都是通过致密核心囊泡(dense core vesicle,DCV)来实现的.但是,现阶段关于DCV的生成、转运、释放的机制很大程度上是不清楚的.在本研究中,我们将线虫的排便行为和肠道分泌联系起来,并以此表型进行全基因组RNAi筛选,寻找调节DCV的新基因.我们成功筛选到了一些在肠道调节DCV生成或释放的基因.其中,CAB-1被确认为特异性调节DCV分泌的重要因子.在肠道中,cab-1突变会降低肠道DCV内容物的分泌,而在神经系统中,CAB-1的缺失也会导致DCV的标识物堆积在突触前,而突触囊泡(synaptic vesicle,SV)不受影响.     

PKA activation bypasses the requirement for UNC-31 in the docking of dense core vesicles from C. elegans neurons

The nematode C. elegans provides a powerful model system for exploring the molecular basis of synaptogenesis and neurotransmission. However, the lack of direct functional assays of release processes has largely prevented an in depth understanding of the mechanism of vesicular exocytosis and endocytosis in C. elegans. We address this technical limitation by developing direct electrophysiological assays, including membrane capacitance and amperometry measurements, in primary cultured C. elegans neurons. In addition, we have succeeded in monitoring the docking and fusion of single dense core vesicles (DCVs) employing total internal reflection fluorescence microscopy. With these approaches and mutant perturbation analysis, we provide direct evidence that UNC-31 is required for the docking of DCVs at the plasma membrane. Interestingly, the defect in DCV docking caused by UNC-31 mutation can be fully rescued by PKA activation. We also demonstrate that UNC-31 is required for UNC-13-mediated augmentation of DCV exocytosis.     

RIC-7 promotes neuropeptide secretion

Secretion of neurotransmitters and neuropeptides is mediated by exocytosis of distinct secretory organelles, synaptic vesicles (SVs) and dense core vesicles (DCVs) respectively. Relatively little is known about factors that differentially regulate SV and DCV secretion. Here we identify a novel protein RIC-7 that is required for neuropeptide secretion in Caenorhabditis elegans. The RIC-7 protein is expressed in all neurons and is localized to presynaptic terminals. Imaging, electrophysiology, and behavioral analysis of ric-7 mutants indicates that acetylcholine release occurs normally, while neuropeptide release is significantly decreased. These results suggest that RIC-7 promotes DCV-mediated secretion.     

Silence of Synaptotagmin VII inhibits release of dense core vesicles in PC12 cells

Synaptotagmin VII (Syt VII), which has a higher Ca²⁺ affinity and slower disassembly kinetics with lipid than Syt I and Syt IX, was regarded as being uninvolved in synaptic vesicle (SV) exocytosis but instead possibly as a calcium sensor for the slower kinetic phase of dense core vesicles (DCVs) release. By using high temporal resolution capacitance and amperometry measurements, it was demonstrated that the knockdown of endogenous Syt VII attenuated the fusion of DCV with the plasma membrane, reduced the amplitude of the exocytotic burst of the Ca²⁺-triggered DCV release without affecting the slope of the sustained component, and blocked the fusion pore expansion. This suggests that Syt VII is the Ca²⁺ sensor of DCV fusion machinery and is an essential factor for the establishment and maintenance of the pool size of releasable DCVs in PC12 cells.     

Intrapulmonary neuro-epithelial bodies in newborn rabbits

Summary Neonatal rabbit neuro-epithelial bodies (NEB) were investigated under various experimental conditions with light microscopy, microspectrography, morphometry and electron microscopy. (1) Hypoxia causes a decreased amine fluorescence intensity and an increased secretory exocytosis of dense core vesicles (DCV). Otherwise the NEB appear structurally normal. (2) Hypercapnia also produces a decreased fluorescence and an increased exocytosis; ultrastructurally, however, the dense core of DCV fragmentizes. (3) Hyperoxia does not appear to affect significantly either fluorescence or exocytosis. (4) The uptake of biogenic amines such as 5-HTP and L-DOPA was demonstrated by fluorometry and electron microscopy. (5) Reserpine, on the other hand, provokes an amine depletion with a decrease of the NEB fluorescence and an ultrastructural palor of the DCV. (6) Intratracheally administered nicotine is accompanied by a decreased fluorescence and a distinct exocytosis of fragmented DCV.The reaction of NEB to hypoxia and hypercapnia suggests that these corpuscles could be intrapulmonary chemoreceptors (in addition to the classically known central and peripheral chemoreceptors), inducing a reflex reaction through the liberation of DCV at the corpuscular sensible nerve endings and via the CNS. In addition, they may subserve a local intrapulmonary effect by modulating directly the hypoxic and hypercapnic pulmonary vasoconstriction and thus the V/Q ratio. Acknowledgment. This study was supported by a grant from The Council for Tobacco Research, U.S.A., and the Nationaal Fonds voor Wetenschappelijk Onderzoek, Belgium. We thank M.R. Van Hamme, R. Renwart and K. Armee for technical, G. Pison and St. Ons for photographical and N. Tyberghien and G. Verbeeck for secretarial assistanceMartin Deleersnyder (deceased May 11, 1976) was Candidate of the Nationaal Fonds voor Wetenschappelijk Onderzoek, Belgium     

ARF6 regulates a plasma membrane pool of phosphatidylinositol(4,5)bisphosphate required for regulated exocytosis

ADP-ribosylation factor (ARF) 6 regulates endosomal plasma membrane trafficking in many cell types, but is also suggested to play a role in Ca2+-dependent dense-core vesicle (DCV) exocytosis in neuroendocrine cells. In the present work, expression of the constitutively active GTPase-defective ARF6Q67L mutant in PC12 cells was found to inhibit Ca2+-dependent DCV exocytosis. The inhibition of exocytosis was accompanied by accumulation of ARFQ67L, phosphatidylinositol 4,5-bisphosphate (PIP2), and the phosphatidylinositol 4-phosphate 5-kinase type I (PIP5KI) on endosomal membranes with their corresponding depletion from the plasma membrane. That the depletion of PIP2 and PIP5K from the plasma membrane caused the inhibition of DCV exocytosis was demonstrated directly in permeable cell reconstitution studies in which overexpression or addition of PIP5KIgamma restored Ca2+-dependent exocytosis. The restoration of exocytosis in ARF6Q67L-expressing permeable cells unexpectedly exhibited a Ca2+ dependence, which was attributed to the dephosphorylation and activation of PIP5K. Increased Ca2+ and dephosphorylation stimulated the association of PIP5KIgamma with ARF6. The results reveal a mechanism by which Ca2+ influx promotes increased ARF6-dependent synthesis of PIP2. We conclude that ARF6 plays a role in Ca2+-dependent DCV exocytosis by regulating the activity of PIP5K for the synthesis of an essential plasma membrane pool of PIP2.     

Direct interaction of endogenous Kv channels with syntaxin enhances exocytosis by neuroendocrine cells

K(+) efflux through voltage-gated K(+) (Kv) channels can attenuate the release of neurotransmitters, neuropeptides and hormones by hyperpolarizing the membrane potential and attenuating Ca(2+) influx. Notably, direct interaction between Kv2.1 channels overexpressed in PC12 cells and syntaxin has recently been shown to facilitate dense core vesicle (DCV)-mediated release. Here, we focus on endogenous Kv2.1 channels and show that disruption of their interaction with native syntaxin after ATP-dependent priming of the vesicles by Kv2.1 syntaxin-binding peptides inhibits Ca(2+) -triggered exocytosis of DCVs from cracked PC12 cells in a specific and dose-dependent manner. The inhibition cannot simply be explained by the impairment of the interaction of syntaxin with its SNARE cognates. Thus, direct association between endogenous Kv2.1 and syntaxin enhances exocytosis and in combination with the Kv2.1 inhibitory effect to hyperpolarize the membrane potential, could contribute to the known activity dependence of DCV release in neuroendocrine cells and in dendrites where Kv2.1 commonly expresses and influences release.     

UNC-31/CAPS docks and primes dense core vesicles in C. elegans neurons

UNC-31 or its mammalian homologue, Ca²⁺-dependent activator protein for secretion (CAPS), is indispensable for exocytosis of dense core vesicle (DCV) and synaptic vesicle (SV). From N- to the C-terminus, UNC-31 contains putative functional domains, including dynactin 1 binding domain (DBD), C2, PH, (M)UNC-13 homology domain (MHD) and DCV binding domain (DCVBD), the last four we examined in this study. We employed UNC-31 null mutant C. elegans worms to examine whether UNC-31 functions could be rescued by ectopic expression of full length UNC-31 vs each of these four domain-deleted mutants. Full length UNC-31 cDNA rescued the phenotypes of C. elegans null mutants in response to Ca²⁺-elevation in ALA neurons. Surprisingly, MHD deletion also rescued UNC-31 exocytotic function in part because the relatively high Ca²⁺ level (pre-flash Ca²⁺ was 450 nM) used in the capacitance study could bypass the MHD defect. Nonetheless, the three other domain-truncation cDNAs had almost no rescue on Ca²⁺ evoked secretion. Importantly, this genetic null mutant rescue strategy enabled physiological studies at levels of whole organism to single cells, such as locomotion assay, pharmacological study of neurotransmission at neuromuscular junction, in vivo neuropeptide release measurement and analysis of vesicular docking. Our results suggest that each of these UNC-31 domains support distinct sequential molecular actions of UNC-31 in vesicular exocytosis, including steps in vesicle tethering and docking that bridge vesicle with plasma membrane, and subsequently priming vesicle by initiating the formation of soluble N-ethylmaleimide-sensitive factor attachment protein receptor (SNARE) core complex.     

Regulation of fusion pore closure and compound exocytosis in neuroendocrine PC12 cells by SCAMP1

During exocytosis, neuroendocrine cells can achieve partial release of stored secretory products from dense core vesicles (DCVs) by coupling endocytosis directly at fusion sites and without full discharge. The physiological role of partial secretion is of substantial interest. Much is known about SNARE-mediated initiation of exocytosis and dynamin-mediated completion of endocytosis, but little is known about coupling events. We have used real-time microscopy to examine the role of secretory carrier membrane protein SCAMP1 in exo-endocytic coupling in PC12 cells. While reduced SCAMP1 expression is known to impede dilation of newly opened fusion pores during onset of DCV exocytosis, we now show that SCAMP1 deficiency also inhibits closure of fusion pores after they have opened. Inhibition causes accumulation of fusion figures at the plasma membrane. Closure is recovered by restoring expression and accelerated slightly by overexpression. Interestingly, inhibited pore closure resulting from loss of SCAMP1 appears to increase secondary fusion of DCVs to already-fused DCVs (compound exocytosis). Unexpectedly, reinternalization of expanded DCV membranes following compound exocytosis appears to proceed normally in SCAMP1-deficient cells. SCAMP1's apparent dual role in facilitating dilation and closure of fusion pores implicates its function in exo-endocytic coupling and in the regulation of partial secretion. Secondarily, SCAMP1 may serve to limit the extent of compound exocytosis.