Some assembly required: SOCE and Orai1 channels couple to NFAT transcriptional activity via calmodulin and calcineurin

Advances in our ability to monitor the temporal and spatial dynamics of intracellular second messengers such as Ca²⁺ and cyclic nucleotides at millisecond and sub-micron levels of resolution have greatly increased our understanding of cellular signal transduction mechanisms. Thus, it is now well appreciated that second messengers can rise and fall within discrete regions of the intracellular compartment, as opposed to global changes, and on a time scale determined by the local collection of signaling molecules responsible for the synthesis and degradation/re-uptake of the second messenger. Efforts to identify the components of such macromolecular signaling domains have revealed the presence of hormone receptors, modifying enzymes and scaffolding proteins that tend to assemble and organize these complexes. Emerging evidence now suggests that these signal transduction entities need not be pre-existing, static complexes within the cell, but in fact, may dynamically assemble in response to a specific stimulus. Such an arrangement would thus allow key signaling molecules to be trafficked where they are needed, thereby allowing a cell to utilize these resources more effectively. On the flip side, having such molecules constantly remain within a single cellular domain would facilitate rapid signaling responses and help maintain fidelity of the pathway.     

Lipids as bioeffectors in the immune system

Lipids, in addition to serving as fuel stores and structural components of cell membranes, act as effectors and second messengers in a variety of biological processes including those associated with the immune system. These lipid mediators and regulators differ in structural composition and exert a diverse array of effects on cellular functional activities including those linked to homeostasis, immune responsiveness, and inflammation. They function as intercellular mediators and at the intracellular level act as critical conduits of external stimuli in signal transduction cascades. Lipid derived messengers and their receptors also may interact with other signaling molecules. Exogenous compounds such as cannabinoids share functionally relevant receptor binding domains with those for endogenous lipid signaling ligands and have the potential to alter transductional cascades linked to immune functional activities.     

Phosphoinositides and vesicular membrane traffic

Phosphoinositide lipids were initially discovered as precursors for specific second messengers involved in signal transduction, but have now taken the center stage in controlling many essential processes at virtually every cellular membrane. In particular, phosphoinositides play a critical role in regulating membrane dynamics and vesicular transport. The unique distribution of certain phosphoinositides at specific intracellular membranes makes these molecules uniquely suited to direct organelle-specific trafficking reactions. In this regulatory role, phosphoinositides cooperate specifically with small GTPases from the Arf and Rab families. This review will summarize recent progress in the study of phosphoinositides in membrane trafficking and organellar organization and highlight the particular relevance of these signaling pathways in disease. This article is part of a Special Issue entitled Lipids and Vesicular Transport.     

The complexity of complexes in signal transduction

Many activities of cells are controlled by cell-surface receptors, which in response to ligands, trigger intracellular signaling reactions that elicit cellular responses. A hallmark of these signaling reactions is the reversible nucleation of multicomponent complexes, which typically begin to assemble when ligand-receptor binding allows an enzyme, often a kinase, to create docking sites for signaling molecules through chemical modifications, such as tyrosine phosphorylation. One function of such docking sites is the co-localization of enzymes with their substrates, which can enhance both enzyme activity and specificity. The directed assembly of complexes can also influence the sensitivity of cellular responses to ligand-receptor binding kinetics and determine whether a cellular response is up- or downregulated in response to a ligand stimulus. The full functional implications of ligand-stimulated complex formation are difficult to discern intuitively. Complex formation is governed by conditional interactions among multivalent signaling molecules and influenced by quantitative properties of both the components in a system and the system itself. Even a simple list of the complexes that can potentially form in response to a ligand stimulus is problematic because of the number of ways signaling molecules can be modified and combined. Here, we review the role of multicomponent complexes in signal transduction and advocate the use of mathematical models that incorporate detail at the level of molecular domains to study this important aspect of cellular signaling.     

Förster Resonance Energy Transfer — An approach to visualize the spatiotemporal regulation of macromolecular complex formation and compartmentalized cell signaling

Background

Signaling messengers and effector proteins provide an orchestrated molecular machinery to relay extracellular signals to the inside of cells and thereby facilitate distinct cellular behaviors. Formations of intracellular macromolecular complexes and segregation of signaling cascades dynamically regulate the flow of a biological process.

Scope of review

In this review, we provide an overview of the development and application of FRET technology in monitoring cyclic nucleotide-dependent signalings and protein complexes associated with these signalings in real time and space with brief mention of other important signaling messengers and effector proteins involved in compartmentalized signaling.

Major conclusions

The preciseness, rapidity and specificity of cellular responses indicate restricted alterations of signaling messengers, particularly in subcellular compartments rather than globally. Not only the physical confinement and selective depletion, but also the intra- and inter-molecular interactions of signaling effectors modulate the direction of signal transduction in a compartmentalized fashion. To understand the finer details of various intracellular signaling cascades and crosstalk between proteins and other effectors, it is important to visualize these processes in live cells. Förster Resonance Energy Transfer (FRET) has been established as a useful tool to do this, even with its inherent limitations.

General significance

FRET technology remains as an effective tool for unraveling the complex organization and distribution of various endogenous signaling proteins, as well as the spatiotemporal dynamics of second messengers inside a single cell to distinguish the heterogeneity of cell signaling under normal physiological conditions and during pathological events.     

Lipid second messengers and cell signaling in vascular wall

Agonists of cellular receptors, such as receptor tyrosine kinases, G protein-coupled receptors, cytokine receptors, etc., activate phospholipases (C(gamma), C(beta), A(2), D), sphingomyelinase, and phosphatidylinositol-3-kinase. This produces active lipid metabolites, some of which are second messengers: inositol trisphosphate, diacylglycerides, ceramide, and phosphatidylinositol 3,4,5-trisphosphate. These universal mechanisms are involved in signal transduction to maintain blood vessel functions: regulation of vasodilation and vasoconstriction, mechanical stress resistance, and anticoagulant properties of the vessel lumen surface. Different signaling pathways realized through lipid second messengers interact to one another and modulate intracellular events. In early stages of atherogenesis, namely, accumulation of low density lipoproteins in the vascular wall, cascades of pro-atherogenic signal transduction are triggered through lipid second messengers. This leads to atherosclerosis, the general immuno-inflammatory disease of the vascular system.     

Organizing signal transduction through A-kinase anchoring proteins (AKAPs)

A fundamental role for protein-protein interactions in the organization of signal transduction pathways is evident. Anchoring, scaffolding and adapter proteins function to enhance the precision and directionality of these signaling events by bringing enzymes together. The cAMP signaling pathway is organized by A-kinase anchoring proteins. This family of proteins assembles enzyme complexes containing the cAMP-dependent protein kinase, phosphoprotein phosphatases, phosphodiesterases and other signaling effectors to optimize cellular responses to cAMP and other second messengers. Selected A-kinase anchoring protein signaling complexes are highlighted in this minireview.     

选择性标记法及脂类信号转导途径的检测

确定由脂类分子介导的信号转导途径和细胞内某些信使分子的生成及改变是信号转导研究领域中的一个重要组成部分.如确定不同磷脂酶活性的调控及细胞内不同来源的第二信使分子及其他脂类生物活性分子的生成与调节,成为探讨生长因子或其他许多分子的生物效应及其作用机理的重要研究内容.为了增加人们对有关研究工作的了解及在方法上的选择,介绍了研究脂类代谢信号转导中广泛运用的一个基本而重要的方法——选择性标记法,并且以实际研究结果为例,说明如何运用该方法检测不同的信号传递途径和有关信号分子的生成与变化.该法针对性强而灵活,重复性高,能有效地检测某些不同来源的信号传递分子的生成及其变化.此外,对脂类代谢信号转导途径及对该途径的研究在信号转导领域的地位和意义也作了简要的介绍.     

Focal adhesion kinase: protein interactions and cellular functions

Integrin-mediated cell adhesion to extracellular matrix (ECM) plays important roles in a variety of biological processes. Recent studies suggested that integrins mediate signal transduction across the plasma membrane via activating several intracellular signaling pathways. Focal adhesion kinase (FAK) is a non-receptor tyrosine kinase that has been shown to be a major mediator of integrin signal transduction pathways. Upon activation by integrins, FAK undergoes autophosphorylation as well as associations with several other intracellular signaling molecules. These interactions in the signaling pathways have been shown to regulation a variety of cellular functions such as cell spreading, migration, cell proliferation, apoptosis and cell survival. Recent progress in the understanding of FAK interactions with other proteins in the regulation of these cellular functions will be discussed in this review.     

G protein-linked effector and second messenger systems involved in melatonin signal transduction

The isolation and characterization of multiple melatonin receptors in a wide range of tissues and cells signifies the functional diversity of melatonin. In different cellular environments, melatonin can regulate distinct second messengers or even positively or negatively regulate the same signal transduction pathway. The capacity by which melatonin receptors modulate the activities of various effector molecules is determined by the complement of signaling components present in any particular cell type. The specific interactions between many signaling molecules have been discerned in an increasing number of cellular systems and this information is being used to explain the physiological actions of melatonin. This review will attempt to summarize recent research by many groups that has revealed numerous subtleties of the melatonin-coupled signaling pathways.     

The Nck SH2/SH3 adaptor protein: a regulator of multiple intracellular signal transduction events

The process generally termed signal transduction involves the coordinated relay of information from extracellular cues to intracellular effectors, subsequently leading to a specified cellular response. The formation of multimeric protein complexes is a critical step in the activation of most intracellular signal transduction cascades. In many cases, these processes are initiated by a family of molecules consisting of protein association motifs known as src homology 2 and 3 (SH2 and SH3) domains. This review focuses on a group of proteins within this family that lack intrinsic enzymatic functions and consist almost entirely of SH2 and SH3 domains. Termed “adaptors,” these proteins serve to physically bridge activated cell surface receptors to various intracellular signal transduction pathways. Here, I briefly summarize current knowledge concerning the various adaptor proteins and place a particular emphasis on Nck. Various data are discussed which collectively support a role for Nck in the regulation of multiple intracellular signaling events. BioEssays 20:913–921, 1998. © 1998 John Wiley & Sons, Inc.     

Biophysics of ceramide signaling: interaction with proteins and phase transition of membranes

Ceramides have been implied in intracellular signal transduction systems regulating cellular differentiation, activation, survival and apoptosis and thus appear capable of changing the life style of virtually any cell type. Ceramide belongs to the group of sphingosine-based lipid second messenger molecules that are critically involved in the regulation of diverse cellular responses to exogenous stimuli. The emerging picture suggests that coupling of ceramide to specific signaling cascades is both stimulus and cell-type specific and depends on the subcellular topology of its production. However, little is understood about the molecular mode of ceramide action. In particular, in lieu of a defined ceramide binding motif it is not clear how ceramide would directly interact with putative target signaling proteins. This article proposes two modes of ceramide action. First, a protruding alkyl chain of ceramide may interact with a hydrophobic cavity of a signaling protein providing a lipid anchor to attach proteins to membranes. Second, the generation of ceramide generally increases the volume of hydrocarbon chains within the lipid bilayer thereby enhancing its propensity of to form a hexagonal II phase (Hex II). Besides the generation of a hydrophobic interaction site for proteins local hexagonal phase II formation can also change the membrane fluidity and permeability, which may impinge on membrane fusion processes, solubilization of detergent-resistant signaling rafts, or membrane receptor internalization. Thus, ceramide production by sphingomyelinases (SMase) can play a pivotal signaling role through direct interaction with signaling proteins or through facilitating the formation and trafficking of signal transduction complexes.     

Cross-Talk between Signaling Pathways Can Generate Robust Oscillations in Calcium and cAMP

Background

To control and manipulate cellular signaling, we need to understand cellular strategies for information transfer, integration, and decision-making. A key feature of signal transduction is the generation of only a few intracellular messengers by many extracellular stimuli.

Methodology/Principal Findings

Here we model molecular cross-talk between two classic second messengers, cyclic AMP (cAMP) and calcium, and show that the dynamical complexity of the response of both messengers increases substantially through their interaction. In our model of a non-excitable cell, both cAMP and calcium concentrations can oscillate. If mutually inhibitory, cross-talk between the two second messengers can increase the range of agonist concentrations for which oscillations occur. If mutually activating, cross-talk decreases the oscillation range, but can generate ‘bursting’ oscillations of calcium and may enable better filtering of noise.

Conclusion

We postulate that this increased dynamical complexity allows the cell to encode more information, particularly if both second messengers encode signals. In their native environments, it is unlikely that cells are exposed to one stimulus at a time, and cross-talk may help generate sufficiently complex responses to allow the cell to discriminate between different combinations and concentrations of extracellular agonists.     

AKAP signaling complexes: getting to the heart of the matter

Subcellular compartmentalization of protein kinases and phosphatases through their interaction with A-kinase anchoring proteins (AKAPs) provides a mechanism to control signal transduction events at specific sites within the cell. Recent findings suggest that these anchoring proteins dynamically assemble different cAMP effectors to control the cellular actions of cAMP spatially and temporally. In the heart, signaling events such as the onset of cardiac hypertrophy are influenced by muscle-specific mAKAP signaling complexes that target protein kinase A (PKA), the cAMP-responsive guanine-nucleotide exchange factor EPAC and cAMP-selective phosphodiesterase 4 (PDE4). Mediation of signaling events by AKAPs might also have a role in the control of lipolysis in adipocytes, where insulin treatment reduces the association of AKAPs with G-protein-coupled receptors. These are only two examples of how AKAPs contribute to specificity in cAMP signaling. This review will explore recent development that illustrates the role of multiprotein complexes in the regulation of cAMP signaling.     

Mitochondria-derived Hydrogen Peroxide Selectively Enhances T Cell Receptor-initiated Signal Transduction

T cell receptor (TCR)-initiated signal transduction is reported to increase production of intracellular reactive oxygen species, such as superoxide (O₂^⨪) and hydrogen peroxide (H₂O₂), as second messengers. Although H₂O₂ can modulate signal transduction by inactivating protein phosphatases, the mechanism and the subcellular localization of intracellular H₂O₂ as a second messenger of the TCR are not known. The antioxidant enzyme superoxide dismutase (SOD) catalyzes the dismutation of highly reactive O₂^⨪ into H₂O₂ and thus acts as an intracellular generator of H₂O₂. As charged O₂^⨪ is unable to diffuse through intracellular membranes, cells express distinct SOD isoforms in the cytosol (Cu,Zn-SOD) and mitochondria (Mn-SOD), where they locally scavenge O₂^⨪ leading to production of H₂O₂. A 2-fold organelle-specific overexpression of either SOD in Jurkat T cell lines increases intracellular production of H₂O₂ but does not alter the levels of intracellular H₂O₂ scavenging enzymes such as catalase, membrane-bound peroxiredoxin1 (Prx1), and cytosolic Prx2. We report that overexpression of Mn-SOD enhances tyrosine phosphorylation of TCR-associated membrane proximal signal transduction molecules Lck, LAT, ZAP70, PLCγ1, and SLP76 within 1 min of TCR cross-linking. This increase in mitochondrial H₂O₂ specifically modulates MAPK signaling through the JNK/cJun pathway, whereas overexpressing Cu,Zn-SOD had no effect on any of these TCR-mediated signaling molecules. As mitochondria translocate to the immunological synapse during TCR activation, we hypothesize this translocation provides the effective concentration of H₂O₂ required to selectively modulate downstream signal transduction pathways.     

Nuclear inositol lipid signaling and its potential involvement in malignant transformation

Growth, differentiation, and apoptosis of eukaryotic cells are mediated by extremely complex signaling pathways and a high degree of coordination is required for regulating cell proliferation.In multicellular organisms homeostasis is achieved through signal transduction events. If these homeostatic mechanisms are interrupted, a disease, such as cancer, may ensue. Lipid second messengers, particularly those derived from polyphosphoinositide cycle, play a pivotal role in several cell signaling networks. Evidence accumulated over the past 15 years has highlighted the presence of an autonomous nuclear inositol lipid metabolism, and suggests that lipid signaling molecules are important components of signaling pathways operating within the nucleus. Recent findings are starting to elucidate how the nuclear phosphoinositide cycle is regulated and what down-stream molecules are targeted through this cycle. In this review, we shall summarize the most updated data about inositol lipid-dependent nuclear signaling pathways that might have a relevance for the development of cancer. In the near future, this knowledge might also prove to have relevance for the diagnosis and treatment of the neoplastic disease.     

The cellular language of myo-inositol signaling

The simple polyol, myo-inositol, is used as a building block of a cellular language that plays various roles in signal transduction. This review describes the terminology used to denote myo-inositol-containing molecules, with an emphasis on how phosphate and fatty acids are added to create second messengers used in signaling. Work in model systems has delineated the genes and enzymes required for synthesis and metabolism of many myo-inositol-containing molecules, with genetic mutants and measurement of second messengers playing key roles in developing our understanding. There is increasing evidence that molecules such as myo- inositol(1,4,5)trisphosphate and phosphatidylinositol(4,5)bisphosphate are synthesized in response to various signals plants encounter. In particular, the controversial role of myo-inositol(1,4,5)trisphosphate is addressed, accompanied by a discussion of the multiple enzymes that act to regulate this molecule. We are also beginning to understand new connections of myo-inositol signaling in plants. These recent discoveries include the novel roles of inositol phosphates in binding to plant hormone receptors and that of phosphatidylinositol(3)phosphate binding to pathogen effectors.     

Cancer cell motility--on the road from c-erbB-2 receptor steered signaling to actin reorganization.

Cell migration depends mainly on actin polymerization and intracellular organization, which are influenced by a vast variety of actin binding proteins (ABPs). Regulation of ABP activity is mediated by second messengers such as phosphoinositides and calcium. Signaling via these second messengers is initiated and regulated by membrane receptors, e.g., receptor tyrosine kinases (RTKs), and by adhesion molecule interactions (e.g., integrins and selectins) and focal adhesion kinases. A major role in steering second-messenger signaling and thus in actin cytoskeleton reorganization and motility of cancer cells is played by the RTK c-erbB-2. This occurs through a number of signaling pathways which involve mainly enzymes, e.g., phospholipase Cgamma1 and GTPases, which modify signaling molecules. Furthermore large multiprotein complexes including actin-related protein 2/3, Wiskott-Aldrich syndrome protein, profilin, and capping protein among others play an important role in regulating actin reorganization. The complex picture of the mode of actin reorganization, which is involved in tumor cell migration, is slowly emerging from the mists of cellular signaling pathways, but this is still by no means a clear view.     

视网膜水平细胞钙离子信号的调节与功能

钙离子是细胞内功能最为广泛的第二信使之一,在为数众多的细胞内信号通路中发挥作用。对细胞内钙离子分布、调控及功能的研究是我们了解细胞生理的重要途径。本文基于我们实验室对视网膜的研究工作,介绍了视网膜水平细胞中钙离子信号的调控与生理功能。     

Enigmatic relationship of Pleckstrin homology domain with phospholipid breakdown mediated signal transduction.

Research into phospholipid signaling continues to flourish, as more and more bioactive lipids and proteins are being identified and their actions characterised. The Pleckstrin homology (PH) domain is one such newly recognized protein module thought to play an important role in intracellular signal transduction. The tertiary structures of several PH domains have been determined, some of them complexed with ligands and on the basis of structural similarities between PH domains and lipid binding proteins it has been suggested that PH domains may be binding to lipophilic molecules. In fact many of the proteins that contain this domain can interfere with the membrane association. This review examines the specificity of this binding and illustrates the importance of charge-charge interactions in PIP2-PH domain complex formation. The precise physiological functions of PH domain in vivo remains to be explored therefore this review examines the biochemical aspects of the interaction of PH domains with phospholipid breakdown mediated products and proto-oncogenic serine-threonine kinase (Akt), protein tyrosine kinases, which have been found to be a target of phospholipid second messengers. Thus, number of cellular processes mediated by this way, ranging from insulin signaling and protein synthesis to differentiation and cell survival are regulated by this intracellular signaling protein module.