白念珠菌细胞内钙离子稳态和钙离子/钙调磷酸酯酶信号途径的调控机理研究进展

钙离子稳态和钙离子/钙调磷酸酯酶信号途径在真核细胞中高度保守。与最简单的模式真核生物(酿酒酵母菌)一样,人体病原真菌白念珠菌的细胞中存在各种钙通道、钙泵和钙交换器以及完整的钙离子/钙调磷酸酯酶信号途径成员,它们在维持白念珠菌胞内钙离子稳态以及应答外界环境压力、耐药性、形态发生和致病性等方面有着至关重要的作用。对白念珠菌钙离子稳态和钙离子/钙调磷酸酯酶信号途径调控机理的认知,有助于了解其致病过程和耐药机理,同时可以为发现和开发新的抗真菌药物提供研究基础。该文结合所在实验室相关研究工作对这一领域的最新研究进展作了综述。     

神经元钙信号系统异常与阿尔茨海默病的“钙假说”

钙信号是细胞调节各项生命活动的重要机制。神经元通过胞外钙离子(calcium ion, Ca²⁺)内流、内质网Ca²⁺释放以及Ca²⁺释放介导的Ca²⁺内流等方式产生具有时空特异性的钙信号,用于调控多种生物学过程,例如动作电位的调节、神经递质的释放、轴突的生长以及突触可塑性等。神经元胞内Ca²⁺浓度因受到细胞精确调控而处于动态平衡之中。若钙信号失调导致平衡被打破,则会造成神经元功能异常甚至死亡。近年来多项研究表明,钙稳态失衡与神经退行性疾病,例如阿尔茨海默病等的产生和发展密切相关,由此发展出关于阿尔茨海默病的钙假说。该假说认为,神经元钙稳态调节机制的持续性改变是神经元功能失常、大脑产生慢性疾病的重要因素。阿尔茨海默病发生发展过程中,神经元胞浆钙水平异常增高,致使多种钙依赖性酶的活性异常,进而影响基因转录。虽然内质网钙稳态的变化目前仍存在一定的争议,但较为确定的是线粒体中存在着钙超载的现象,导致氧化磷酸化反应下调,活性氧的产量增加,进而引发细胞凋亡。本文主要介绍了神经元钙信号系统及其功能,简要梳理了阿尔茨海默病钙假说的相关研究,并对后续研究进行了展望。     

线粒体稳定高钙信号诱发超氧炫

线粒体对于细胞钙信号和活性氧信号转导有重要的调控作用．超氧炫是新近发现的单个线粒体超氧阴离子短时程爆发现象,反映了活性氧生成动力学的一种新形式．线粒体钙信号作为重要的细胞功能调控信号,能否及如何调控超氧炫尚待深入研究．本研究对HeLa细胞进行高胞外钙和离子霉素刺激,或用皂苷穿孔细胞质膜后置于高钙细胞内液中,两种方法均显著增加了超氧炫发生的频率．其中,穿孔细胞胞浆高钙诱导的超氧炫依赖于线粒体钙单向转运体,表明超氧炫由线粒体基质内高钙信号所诱发．重要的是,离子霉素诱导的超氧炫发生频率与线粒体稳态钙水平线性相关,而与瞬态线粒体钙无相关性,提示钙离子对超氧炫的调控是一个多步骤、相对缓慢的过程．综上,线粒体基质的稳态高钙是超氧炫的重要调控因子．     

钙火花研究进展与瞻望

钙离子是最广泛而又最重要的细胞内第二信使。自1993年以来,钙火花等一系列钙信号基本单元相继发现,揭示了细胞钙信号转导的数字-模拟二元特征：纳米-微米尺度上短暂的钙信号事件（数字系统）随机叠加于连续的全细胞钙信号（模拟系统）背景中。数字模式的微区域钙信号赋予细胞钙信号在时间、空间、幅度上多尺度多层次的精细结构。对钙火花激活机制、协同机制、终止机制等方面的研究,为钙释放通道阵列的门控及调节提出了新的见解和问题。钙火花等对于高域值钙依赖性过程（如肌细胞兴奋-收缩耦联、细胞兴奋性和神经细胞分泌）的激活和时空调控具有特别重要的生理和病理意义。钙信号“激-模二元性”的研究可望进一步揭示细胞钙信号的简单性与复杂性的统一。     

核钙信号

尽管核周隙与内质网的腔相通,核膜上存在钙信号分子的受体等事实表明,细胞核存在一套相对独立的钙信号机制。作为核钙的贮存库,核被是核钙信号的发源地。核被中钙离子的充盈状态影响着核孔复合体的构象,从而调节核质间物质交流。已有证据显示,核钙信号与胞质钙信号在基因转录中的作用有所区别。核钙信号在细胞凋亡中发挥重要作用,其中,钙蛋白酶起着较为关键的作用。核钙信号研究为完整理解钙信号的生理功能开辟了新视野。     

CaMKII在细胞钙稳态维持及心肌保护中作用的研究进展

钙/钙调素依赖性蛋白激酶II(CaMKII)是主要表达于心脏的一种多功能苏氨酸/丝氨酸蛋白激酶,通过磷酸化与Ca2+调节相关的蛋白影响心肌的兴奋收缩耦联及细胞钙稳态.在心肌缺血缺氧等病理条件下,心肌细胞钙离子循环出现异常,CaMKII通过代偿性活性改变起到维持Ca2+稳态及心肌保护效应.深入了解CaMKII对钙循环的调节、在间歇性高海拔缺氧介导的心脏保护及心肌细胞内酸中毒后心肌收缩力恢复过程中的作用机制,具有重要的基础研究及临床应用前景.     

钙网蛋白与神经系统病变

钙网蛋白（calreticulin,CRT）是内质网中的一种多功能的分子伴侣,在协助蛋白质正确折叠和维持细胞Ca2＋稳态（Ca2＋信号）中发挥重要作用。近来的研究发现,钙网蛋白与神经系统病变包括阿尔茨海默氏病、帕金森病等有密切关系。     

用于细胞核钙成像的新型钙指示剂的构建与鉴定

细胞核钙离子是基因转录等细胞核反应过程重要的调控因子.然而,细胞核内钙离子信号的调控机制尚不清楚.缺乏稳定的、敏感的细胞核钙指示剂,是导致其调控机制难以研究的重要原因之一.针对这一问题,设计了能够在细胞核内特异性表达的、具有核定位功能的钙指示剂.以基因编码钙指示剂（GECIs）家族成员GCaMP6为模板,首先融合了对钙离子不敏感的红色荧光蛋白tdTomato来对局部的钙信号进行量化,其次融合了核定位信号（NLS）,使GCaMP6能够特异定位于细胞核中.结果表明,NLS-GCaMP6-tdTomato能够在细胞核中有效发挥作用,并且在钙敏感性与动力学上,也与GCaMP6相当. 这一新型细胞核钙指示剂将为研究细胞核钙离子的功能及其调控机制提供新的方法与途径.     

通过CRISPR/Cas9基因编辑手段构建白念珠菌CaHSL1基因的失活突变体及其表型分析

钙离子稳态和钙离子信号途径对白念珠菌的形态发生、耐药性以及毒力都十分重要。白念珠菌和酿酒酵母菌的细胞质膜蛋白质Rch1p均富集在母细胞和子细胞之间的芽颈部位,负向调控胞外钙离子的内流。与细胞周期调控相关的蛋白激酶Hsl1p也存在于白念珠菌和酿酒酵母菌的芽颈部位。该研究发现,抑制CaHSL1基因的表达或者通过CRISPR(clustered regularly interspaced short palindromic repeat)/Cas9新方法失活CaHSL1基因,均可导致白念珠菌对钙离子敏感,这种钙离子敏感性可以被钙调磷酸酯酶的专一性抑制剂环孢霉素抑制。这个结果表明,钙离子稳态和钙信号转导途径可能与细胞周期调控有关。此外,CaHSL1基因失活突变体对十二烷基磺酸钠、氟康唑、酮康唑、刚果红、潮霉素B、卡泊芬净和Anidualafungin敏感,表明CaHsl1p与细胞质膜和细胞壁胁迫的应答相关。     

钙结合蛋白calreticulin

钙结合蛋白ｃａｌｒｅｔｉｃｕｌｉｎ由Ｎ、Ｐ和Ｃ三个区域的氨在酸序列组成,具有很主的钙结合容量,主要存在于内质网上;其蛋白和基因在生物进化过程中具有极高的保守性,提示它在许多细胞功能的调节中发挥重要作用;它是一种独特的内质网膜分子伴侣,参与胞内钙信号、细胞粘际及基因表达的调控。     

Calcium homeostasis and signaling in yeast cells and cardiac myocytes

Calcium ions are the most ubiquitous and versatile signaling molecules in eukaryotic cells. Calcium homeostasis and signaling systems are crucial for both the normal growth of the budding yeast Saccharomyces cerevisiae and the intricate working of the mammalian heart. In this paper, we make a detailed comparison between the calcium homeostasis/signaling networks in yeast cells and those in mammalian cardiac myocytes. This comparison covers not only the components, structure and function of the networks but also includes existing knowledge on the measured and simulated network dynamics using mathematical models. Surprisingly, most of the factors known in the yeast calcium homeostasis/signaling network are conserved and operate similarly in mammalian cells, including cardiac myocytes. Moreover, the budding yeast S. cerevisiae is a simple organism that affords powerful genetic and genomic tools. Thus, exploring and understanding the calcium homeostasis/signaling system in yeast can provide a shortcut to help understand calcium homeostasis/signaling systems in mammalian cardiac myocytes. In turn, this knowledge can be used to help treat relevant human diseases such as pathological cardiac hypertrophy and heart failure.     

Reduction of calcium release from the endoplasmic reticulum could only provide partial neuroprotection against beta-amyloid peptide toxicity

Beta-amyloid (Abeta) peptide has been suggested to play important roles in the pathogenesis of Alzheimer's disease (AD). Abeta peptide neurotoxicity was shown to induce disturbance of cellular calcium homeostasis. However, whether modulation of calcium release from the endoplasmic reticulum (ER) can protect neurons from Abeta toxicity is not clearly defined. In the present study, Abeta peptide-triggered ER calcium release in primary cortical neurons in culture is modulated by Xestospongin C, 2-aminoethoxydiphenyl borate or FK506. Our results showed that reduction of ER calcium release can partially attenuate Abeta peptide neurotoxicity evaluated by LDH release, caspase-3 activity and quantification of apoptotic cells. While stress signals associated with perturbations of ER functions such as up-regulation of GRP78 was significantly attenuated, other signaling machinery such as activation of caspase-7 transmitting death signals from ER to other organelles could not be altered. We further provide evidence that molecular signaling in mitochondria play also a significant role in determining neuronal apoptosis because Abeta peptide-triggered activation of caspase-9 was not significantly reduced by attenuating ER calcium release. Our results suggest that neuroprotective strategies aiming at reducing Abeta toxicity should include molecular targets linked to ER perturbations associated with ER calcium release as well as mitochondrial stress.     

The Contribution of TRPV4-Mediated Calcium Signaling to Calcium Homeostasis in Endothelial Cells

A large variety of cation transport systems are involved in the regulation of calcium homeostasis in endothelial cells. The focus of the present study is to determine the contribution of nonselective cation channels from the TRP (transient receptor potential) family to cellular calcium homeostasis of porcine aortic endothelial cells (PAEC). One member of the TRPV (vanniloid) subfamily, TRPV4, has previously been shown to be involved in cation transport induced by a large variety of stimulations including osmolarity, temperature, mechanical stress, and phosphorylation. Here, we demonstrate the existence of several TRP proteins, including TRPV4, in PAEC using RT-PCR. To test whether this channel is functional, we performed FURA-2 calcium measurements and whole-cell patch-clamp experiments. We observed the induction of large calcium signals following mechanical stress, altered extracellular temperature, and the selective TRPV4 activator 4-α -PDD. These effects were diminished in the presence of the TRPV4 inhibitor miconazole, suggesting the involvement of this channel in mediating endothelial calcium signals. The large amounts of transported calcium and the short signaling ways suggest a potentially important role of this channel in many physiological processes.     

钙信号重构调控肿瘤发生发展

钙离子是细胞内最重要的第二信使之一,对肿瘤细胞的发生发展起着重要的调控作用.无节制的增殖、降低的凋亡和高度的转移能力是肿瘤细胞的三大特征.细胞过度增殖需要胞浆钙升高,而逃避凋亡则需要较低的胞浆钙.在肿瘤发生发展过程中,早期过表达的胞膜钙通道倾向于调低,而内质网钙通道表达升高,并伴有通道定位的改变和新通道的形成.迁移细胞中的微区钙信号可决定细胞转移的方向.综上所述,钙信号可作为药物靶点,在肿瘤药物研发中具有一定的潜力.     

Lysosomal calcium regulates autophagy

Recent evidence has indicated that the lysosome is able to act as a signaling organelle that senses nutrient availability and generates an adaptive response that is important for cellular homeostasis. We recently discovered another example of lysosomal signaling where lysosomal calcium release activates the master autophagy regulator TFEB via the phosphatase calcineurin.     

Calcium signaling in neurodegeneration

Calcium is a key signaling ion involved in many different intracellular and extracellular processes ranging from synaptic activity to cell-cell communication and adhesion. The exact definition at the molecular level of the versatility of this ion has made overwhelming progress in the past several years and has been extensively reviewed. In the brain, calcium is fundamental in the control of synaptic activity and memory formation, a process that leads to the activation of specific calcium-dependent signal transduction pathways and implicates key protein effectors, such as CaMKs, MAPK/ERKs, and CREB. Properly controlled homeostasis of calcium signaling not only supports normal brain physiology but also maintains neuronal integrity and long-term cell survival. Emerging knowledge indicates that calcium homeostasis is not only critical for cell physiology and health, but also, when deregulated, can lead to neurodegeneration via complex and diverse mechanisms involved in selective neuronal impairments and death. The identification of several modulators of calcium homeostasis, such as presenilins and CALHM1, as potential factors involved in the pathogenesis of Alzheimer's disease, provides strong support for a role of calcium in neurodegeneration. These observations represent an important step towards understanding the molecular mechanisms of calcium signaling disturbances observed in different brain diseases such as Alzheimer's, Parkinson's, and Huntington's diseases.     

Effects of ethanol on calcium homeostasis in the nervous system

Ethanol is a major health concern, with neurotoxicity occurring after bothin utero exposure and adult alcohol abuse. Despite a large amount of research, the mechanism(s) underlying the neurotoxicity of ethanol remain unknown. One of the cellular aspects that has been investigated in relationship to the neuroteratogenicity and neurotoxicity of ethanol is the maintenance of calcium homeostasis. Studies in neuronal cells and other cells have shown that ethanol can alter intracellular calcium levels and affect voltage and receptor-operated calcium channels, as well as G protein-mediated calcium responses. Despite increasing evidence of the important roles of glial cells in the nervous systems, few studies exist on the potential effects of ethanol on calcium homeostasis in these cells. This brief review discusses a number of reported effects of alcohol on calcium responses that may be relevant to astrocytes' functions.     

Comparative genomic and phylogenetic analyses of calcium ATPases and calcium-regulated proteins in the apicomplexa

The phylum Apicomplexa comprises a large group of early branching eukaryotes that includes a number of human and animal parasites. Calcium controls a number of vital processes in apicomplexans including protein secretion, motility, and differentiation. Despite the importance of calcium as a second messenger, very little is known about the systems that control homeostasis or that regulate calcium signaling in parasites. The recent completion of many apicomplexan genomes provides new opportunity to define calcium response pathways in this group of parasites in comparison to model organisms. Whole-genome comparison between the apicomplexans Plasmodium spp., Cryptosporidium spp., and Toxoplasma gondii revealed the presence of several P-Type Ca2+ transporting ATPases including a single endoplasmic reticulum (ER)-type sarcoplasmic-endoplasmic reticulum Ca2+ ATPase, several Golgi-like Ca2+ ATPases, and a single Ca2+/H+ exchanger. Only T. gondii showed evidence of plasma membrane-type Ca2+ ATPases or voltage-gated calcium channels. Despite pharmacological evidence for IP3 and ryanodine-mediated calcium release, animal-type calcium channels were not readily identified in parasites, indicating they are more similar to plants. Downstream of calcium release, a variety of EF-hand-containing proteins regulate calcium responses. Our analyses detected a single conserved calmodulin (CaM) homologue, 3 distinct centrin (CETN)-caltractin-like proteins, one of which is shared with ciliates, and a variety of deep-branching, CaM-CETN-like proteins. Apicomplexans were also found to contain a wide array of calcium-dependent protein kinases (CDPKs), which are commonly found in plants. Toxoplasma gondii contains more than 20 CDPK or CDPK-related kinases, which likely regulate a variety of responses including secretion, motility, and differentiation. Genomic and phylogenetic comparisons revealed that apicomplexans contain a variety of unusual calcium response pathways that are distinct from those seen in vertebrates. Notably, plant-like pathways for calcium release channels and calcium-dependent kinases are found in apicomplexans. The experimental flexibility of T. gondii should allow direct experimental manipulation of these pathways to validate their biological roles. The central importance of calcium in signaling and development, and the novel characteristics of many of these systems, indicates that parasite calcium pathways may be exploited as new therapeutic targets for intervention.