Dalia Alansary

Differential Redox Regulation of ORAI Ion Channels: A Mechanism to Tune Cellular Calcium Signaling

Redox sensitivity of T cells decreases through ORAI Ca2+ channel subunit switching during T cell differentiation. Adapting to Oxidizing Environments Reactive oxygen species (ROS) were thought for many years to be only detrimental, causing damage to DNA and proteins. However, it has become clear that ROS, particularly H2O2, can act as intracellular signaling molecules that link cellular redox state to such processes as proliferation and differentiation. Bogeski et al. have uncovered a role for ROS in regulating calcium channel activity—and intracellular Ca2+ signals crucial to the immune response—in T lymphocytes. They found that activity of ORAI1 calcium channels was blocked by H2O2, whereas that of the related ORAI3 channels was not. Redox sensitivity decreased as naïve human T helper lymphocytes differentiated into effector T helper lymphocytes, which was associated with an increase in the abundance of mRNA encoding the insensitive ORAI3 protein. The authors suggest that changes in the specific complement of ORAI channels, and thereby sensitivity to ROS, could enable T lymphocytes to fine tune cellular responses in oxidizing environments such as those found during inflammation. Reactive oxygen species (ROS) are involved in many physiological and pathophysiological cellular processes. We used lymphocytes, which are exposed to highly oxidizing environments during inflammation, to study the influence of ROS on cellular function. Calcium ion (Ca2+) influx through Ca2+ release–activated Ca2+ (CRAC) channels composed of proteins of the ORAI family is essential for the activation, proliferation, and differentiation of T lymphocytes, but whether and how ROS affect ORAI channel function have been unclear. Here, we combined Ca2+ imaging, patch-clamp recordings, and measurements of cell proliferation and cytokine secretion to determine the effects of hydrogen peroxide (H2O2) on ORAI channel activity and human T helper lymphocyte (TH cell) function. ORAI1, but not ORAI3, channels were inhibited by oxidation by H2O2. The differential redox sensitivity of ORAI1 and ORAI3 channels depended mainly on an extracellularly located reactive cysteine, which is absent in ORAI3. TH cells became progressively less redox-sensitive after differentiation into effector cells, a shift that would allow them to proliferate, differentiate, and secrete cytokines in oxidizing environments. The decreased redox sensitivity of effector TH cells correlated with increased expression of Orai3 and increased abundance of several cytosolic antioxidants. Knockdown of ORAI3 with small-interfering RNA rendered effector TH cells more redox-sensitive. The differential expression of Orai isoforms between naïve and effector TH cells may tune cellular responses under oxidative stress.

Calcium microdomains at the immunological synapse: how ORAI channels, mitochondria and calcium pumps generate local calcium signals for efficient T-cell activation

Cell polarization enables restriction of signalling into microdomains. Polarization of lymphocytes following formation of a mature immunological synapse (IS) is essential for calcium‐dependent T‐cell activation. Here, we analyse calcium microdomains at the IS with total internal reflection fluorescence microscopy. We find that the subplasmalemmal calcium signal following IS formation is sufficiently low to prevent calcium‐dependent inactivation of ORAI channels. This is achieved by localizing mitochondria close to ORAI channels. Furthermore, we find that plasma membrane calcium ATPases (PMCAs) are re‐distributed into areas beneath mitochondria, which prevented PMCA up‐modulation and decreased calcium export locally. This nano‐scale distribution—only induced following IS formation—maximizes the efficiency of calcium influx through ORAI channels while it decreases calcium clearance by PMCA, resulting in a more sustained NFAT activity and subsequent activation of T cells.

Trafficking and Assembly of the Cold-sensitive TRPM8 Channel

TRPM (transient receptor potential melastatin-like) channels are distinct from many other members of the transient receptor potential family in regard to their overall size (>1000 amino acids), the lack of N-terminal ankyrin-like repeats, and hydrophobicity predictions that may allow for more than six transmembrane regions. Common to each TRPM member is a prominent C-terminal coiled coil region. Here we have shown that TRPM8 channels assemble as multimers using the putative coiled coil region within the intracellular C terminus and that this assembly can be disturbed by a single point mutation within the coiled coil region. This mutant neither gives rise to functional channels nor do its subunits interact or form protein complexes that correspond to a multimer. However, they are still transported to the plasma membrane. Furthermore, wild-type currents can be suppressed by expressing the membrane-attached C-terminal region of TRPM8. To separate assembly from trafficking, we investigated the maturation of TRPM8 protein by identifying and mutating the relevant N-linked glycosylation site and showing that glycosylation is neither essential for multimerization nor for transport to the plasma membrane per se but appears to facilitate efficient multimerization and transport.

ORAI-mediated calcium influx in T cell proliferation, apoptosis and tolerance.

Ca(2+) homeostasis controls a diversity of cellular processes including proliferation and apoptosis. A very important aspect of Ca(2+) signaling is how different Ca(2+) signals are translated into specific cell functions. In T cells, Ca(2+) signals are induced following the recognition of antigen by the T cell receptor and depend mainly on Ca(2+) influx through store-operated CRAC channels, which are mediated by ORAI proteins following their activation by STIM proteins. The complete absence of Ca(2+) influx caused by mutations in Stim1 and Orai1 leads to severe immunodeficiency. Here we summarize how Ca(2+) signals are tuned to regulate important T cell functions as proliferation, apoptosis and tolerance, the latter one being a special state of immune cells in which they can no longer respond properly to an otherwise activating stimulus. Perturbations of Ca(2+) signaling may be linked to immune suppressive diseases and autoimmune diseases.

Mutations of the Ca2+-sensing Stromal Interaction Molecule STIM1 regulate Ca2+ influx by altered oligomerization of STIM1 and by destabilization of the Ca2+ channel Orai1

Background: Calcium influx (ICRAC) is important for proper cell function. Results: A novel STIM1 mutant increases ICRAC, Ca2+-dependently destabilizes Orai1, and alters clustering. A new mathematical model explains the phenotype. Conclusion: The molecular kinetics of STIM1 and Orai1 are major determinants of ICRAC. Significance: The diffusion trap model and alteration of Orai1 stability provide a tool for understanding ICRAC regulation. A drop of endoplasmic reticulum Ca2+ concentration triggers its Ca2+ ssensor protein stromal interaction molecule 1 (STIM1) to oligomerize and accumulate within endoplasmic reticulum-plasma membrane junctions where it activates Orai1 channels, providing store-operated Ca2+ entry. To elucidate the functional significance of N-glycosylation sites of STIM1, we created different mutations of asparagine-131 and asparagine-171. STIM1 NN/DQ resulted in a strong gain of function. Patch clamp, Total Internal Reflection Fluorescent (TIRF) microscopy, and fluorescence recovery after photobleaching (FRAP) analyses revealed that expression of STIM1 DQ mutants increases the number of active Orai1 channels and the rate of STIM1 translocation to endoplasmic reticulum-plasma membrane junctions with a decrease in current latency. Surprisingly, co-expression of STIM1 DQ decreased Orai1 protein, altering the STIM1:Orai1 stoichiometry. We describe a novel mathematical tool to delineate the effects of altered STIM1 or Orai1 diffusion parameters from stoichiometrical changes. The mutant uncovers a novel mechanism whereby “superactive” STIM1 DQ leads to altered oligomerization rate constants and to degradation of Orai1 with a change in stoichiometry of activator (STIM1) to effector (Orai1) ratio leading to altered Ca2+ homeostasis.

ATP modulates Ca2+ uptake by TRPV6 and is counteracted by isoform-specific phosphorylation

Ca2+ homeostasis requires balanced uptake and extrusion, and dysregulation leads to disease. TRPV6 channels are homeostasis regulators, are upregulated in certain cancers, and show an unusual allelespecific evolution in humans. To understand how Ca2+ uptake can be adapted to changes in metabolic status, we investigate regulation of Ca2+‐influx by ATP and phosphorylation. We show that ATP binds to TRPV6, reduces whole‐cell current increments, and prevents channel rundown with an EC50 of 380 μΜ. By using both biochemical binding studies and patch‐clamp analyses of wild‐type and mutant channels, we have mapped one relevant site for regulation by ATP to residues within the ankyrin repeat domain (ARD) and identify an additional C‐terminal binding region. Stimulation of PKC largely prevented the effects of ATP. This regulation requires PKCβII and defined phosphorylation sites within the ARD and the C‐terminus. Both regulatory sites act synergistically to constitute a novel mechanism by which ATP stabilizes channel activity and acts as a metabolic switch for Ca2+ influx. Decreases in ATP concentration or activation of PKCβII disable regulation of the channels by ATP, rendering them more susceptible to inactivation and rundown and preventing Ca2+ overload.—Al‐Ansary, D., Bogeski, I., Disteldorf B. M. J., Becherer, U., Niemeyer, B. A. ATP modulates Ca2+ uptake by TRPV6 and is counteracted by isoformspecific phosphorylation. FASEB J. 24, 425–435 (2010). www.fasebj.org

Facilitation of Orai3 targeting and store-operated function by Orai1.

Orai1 subunits interacting with STIM1 molecules comprise the major components responsible for calcium release-activated calcium (CRAC) channels. The homologs Orai2 and Orai3 yield smaller store-operated currents when overexpressed and are mostly unable to substitute Orai1. Orai3 subunits are also essential components of store independent channel complexes and also tune inhibition of ICRAC by reactive oxygen species. Here we use patch-clamp, microscopy, Ca(2+)-imaging and biochemical experiments to investigate the interdependence of Orai2, Orai3 and Orai1. We demonstrate that store-operation and localization of Orai3 but not of Orai2 to STIM1 clusters in HEK cells or to the immunological synapse in T cells is facilitated by Orai1 while Orai3s store-independent activity remains unaffected. On the other hand, one Orai3 subunit confers redox-resistance to heteromeric channels. The inefficient store operation of Orai3 is partly due to the lack of three critical C-terminal residues, the insertion of which improves interaction with STIM1 and abrogates Orai3s dependence on Orai1. Our results suggest that Orai3 down-tunes efficient STIM1 gating when in a heteromeric complex with Orai1.

Pharmacology of ORAI channels as a tool to understand their physiological functions

Store-operated Ca2+ entry is a major Ca2+ entry mechanism that is present in most cell types. In immune cells, store-operated Ca2+ entry is almost exclusively mediated by Ca2+ release-activated Ca2+ (CRAC) channels. Ca2+ entry through these channels and the corresponding cytosolic Ca2+ signals are required for many immune cell functions, including all aspects of T-cell activation. ORAI proteins are the molecular correlates for the CRAC channels. The three human members, ORAI1, ORAI2 and ORAI3, are activated through the stromal interaction molecules (STIM)1 and 2 following depletion of endoplasmic reticulum Ca2+ stores. Different combinations of STIM and ORAI can form different CRAC channels with distinct biophysical properties. In this article, we review and discuss mechanistic and functional implications of two important CRAC/ORAI inhibitors, 2-APB and BTP2, and the antibiotic G418 that has also been reported to interfere with ORAI channel function. The use of pharmacological tools should help to assign distinct physiological and pathophysiological functions to different STIM–ORAI protein complexes.

Thiol dependent intramolecular locking of Orai1 channels

Store-operated Ca2+ entry mediated by STIM1-gated Orai1 channels is essential to activate immune cells and its inhibition or gain-of-function can lead to immune dysfunction and other pathologies. Reactive oxygen species interacting with cysteine residues can alter protein function. Pretreatment of the Ca2+ selective Orai1 with the oxidant H2O2 reduces ICRAC with C195, distant to the pore, being its major redox sensor. However, the mechanism of inhibition remained elusive. Here we combine experimental and theoretical approaches and show that oxidation of Orai1 leads to reduced subunit interaction, slows diffusion and that either oxidized C195 or its oxidomimetic mutation C195D located at the exit of transmembrane helix 3 virtually eliminates channel activation by intramolecular interaction with S239 of transmembrane helix 4, thereby locking the channel in a closed conformation. Our results demonstrate a novel mechanistic model for ROS-mediated inhibition of Orai1 and identify a candidate residue for pharmaceutical intervention.

Cell type–specific glycosylation of Orai1 modulates store-operated Ca2+ entry

T cells and mast cells may use differential glycosylation of Orai1 to regulate store-operated calcium signaling. Sugary coating on Orai1 Glycosylation is the addition of sugars to proteins and the chemical modification of these sugars to form highly complex structures. Glycosylation can affect protein stability, protein-protein interactions, and protein function. Human Orai1 is the channel-forming subunit of a complex that mediates calcium entry into cells when calcium in the endoplasmic reticulum becomes depleted (a process called SOCE). Orai1 has a single N-glycosylation site. Dörr et al. found that cells, including several types of immune cells, exposed to conditions that altered Orai1 glycosylation specifically or cellular glycosylation globally exhibited cell-specific effects on SOCE. In many cases, disruption of glycosylation enhanced SOCE without affecting Orai1 abundance or presence at the cell surface, suggesting that glycosylation limited Orai1 activity. Excess SOCE and altered glycosylation are associated with various immune diseases and differences in Orai1 function may be an important molecular connection between these two cellular events. N-glycosylation of cell surface proteins affects protein function, stability, and interaction with other proteins. Orai channels, which mediate store-operated Ca2+ entry (SOCE), are composed of N-glycosylated subunits. Upon activation by Ca2+ sensor proteins (stromal interaction molecules STIM1 or STIM2) in the endoplasmic reticulum, Orai Ca2+ channels in the plasma membrane mediate Ca2+ influx. Lectins are carbohydrate-binding proteins, and Siglecs are a family of sialic acid–binding lectins with immunoglobulin-like repeats. Using Western blot analysis and lectin-binding assays from various primary human cells and cancer cell lines, we found that glycosylation of Orai1 is cell type–specific. Ca2+ imaging experiments and patch-clamp experiments revealed that mutation of the only glycosylation site of Orai1 (Orai1N223A) enhanced SOCE in Jurkat T cells. Knockdown of the sialyltransferase ST6GAL1 reduced α-2,6–linked sialic acids in the glycan structure of Orai1 and was associated with increased Ca2+ entry in Jurkat T cells. In human mast cells, inhibition of sialyl sulfation altered the N-glycan of Orai1 (and other proteins) and increased SOCE. These data suggest that cell type–specific glycosylation influences the interaction of Orai1 with specific lectins, such as Siglecs, which then attenuates SOCE. In summary, the glycosylation state of Orai1 influences SOCE-mediated Ca2+ signaling and, thus, may contribute to pathophysiological Ca2+ signaling observed in immune disease and cancer.