Abstract
Calcium is the most abundant mineral in the human body and is central to many physiological processes, including immune system activation and maintenance. Studies continue to reveal the intricacies of calcium signalling within the immune system. Perhaps the most well-understood mechanism of calcium influx into cells is store-operated calcium entry (SOCE), which occurs via calcium release-activated channels (CRACs). SOCE is central to the activation of immune system cells; however, more recent studies have demonstrated the crucial role of other calcium channels, including transient receptor potential (TRP) channels. In this review, we describe the expression and function of TRP channels within the immune system and outline associations with murine models of disease and human conditions. Therefore, highlighting the importance of TRP channels in disease and reviewing potential. The TRP channel family is significant, and its members have a continually growing number of cellular processes. Within the immune system, TRP channels are involved in a diverse range of functions including T and B cell receptor signalling and activation, antigen presentation by dendritic cells, neutrophil and macrophage bactericidal activity, and mast cell degranulation. Not surprisingly, these channels have been linked to many pathological conditions such as inflammatory bowel disease, chronic fatigue syndrome and myalgic encephalomyelitis, atherosclerosis, hypertension and atopy.
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Introduction
Immunomodulation is the process which results in regulation or alteration of the scope, type, duration, or competency of an immune response [1]. The enforcers of such scheme, immunomodulators, can be both extrinsic or intrinsic. In its broadest sense, immunomodulation encompasses any intervention directed at modifying the immune response with a therapeutic end point. Such strategies have clinical importance in the development of new vaccines, treatment of autoimmune diseases and allergies, strategies in regenerative medicine, transplantation and immunotherapy for cancer (Fig. 1) [1,2,3,4,5]. Our understanding of the complexity of the immune system has changed greatly over the past decade which has resulted in trials of new therapies against cancer and a whole subset of other diseases. Central to this expansion is our better understanding of the molecular aspect of immune system machinery.
Calcium as the most abundant mineral in the human body plays an important role in the regulation of physiological processes and is also involved in many pathological disorders [6,7,8,9]. More so, it plays an important role in regulating immune function [10, 11]. There are many complex routes for calcium entry into the cell. Stimulation of immune cells results in the depletion of endoplasmic reticulum (ER) Ca2+ stores [12]. This seems to be sensed by stromal interaction molecule 1 (STIM1) located within the ER through interaction with plasma proteins, namely Orai1 protein. In turn, this results in sustained activation of calcium release-activated channels (CRACs) resulting in calcium influx, a process known as store-operated calcium entry (SOCE) (reviewed in [13]). Such sustained calcium influx across the cell membrane is important for lymphocyte activation and the initiation of both innate and adaptive immune response [11, 14, 15]. Other routes of calcium entry into the cell include voltage-gated calcium channels, IP3R cell surface receptors that are activated by IP3 ligand, P2X receptors and NMDA receptors [16]. This review focusses on transient receptor potential (TRP) channels, as they are widely expressed throughout the immune system, have varied roles and offer new therapeutic potentials.
The TRP ion channels are a large and diverse family of proteins with their subunits united by a common primary structure and permeability to monovalent cations and divalent calcium ions (Fig. 2) [17,18,19]. They are involved in a continually growing number of cellular functions [20]. This is due to their large distribution in different organs. They have been found mainly not only in the brain but also in the heart, kidney, testis, lung, liver, spleen, ovary, intestine, prostate, placenta, uterus and vascular tissue [21]. They have also been found in many cell types, including both neuronal cells and non-neuronal tissues such as vascular endothelial cells, smooth muscle cells, as well as cells of the immune system [21]. In addition to being at the forefront of our sensor systems, responding to temperature, touch, pain, osmolarity, pheromones and taste [22, 23], they also play a role in vasorelaxation of blood vessels, metabolic stress and immune function regulation [21, 24]. Further to their physiological role, members of the TRP family are associated with several human diseases [25]. For example, mutations in the PKD2 gene, which encodes the TRP polycystin 2 (TRPP2) protein, have been identified in autosomal dominant polycystic kidney disease [26]. The developmental disorder mucolipidosis is caused by mutations in the MCOLN1 gene which encodes the TRP mucolipin 1 (TRPML1) channel [27]. Similarly, mutations within the TRP melastin 6 (TRPM6) channel are responsible for hereditary hypomagnesaemia and secondary hypocalcaemia [28]. There are less direct links to a range of autoimmune and inflammatory conditions such as asthma [29] and inflammatory bowel disease [30].
Therefore, a thorough understanding of TRP channels may enhance our knowledge of the underlying pathophysiology of an array of human conditions and potentially lead to novel therapeutic strategies.
After a brief introduction to TRP channel structure and function, the bulk of this review will cover evidence for TRP channel expression and function in individual immune cell populations. We will then highlight future approaches and new treatment options.
Methodology
The literature search for this review occurred as the paper was being prepared between November 2017 and March 2018. Searches were performed using PubMed (NCBI, at https://www.ncbi.nlm.nih.gov/pubmed/). Search terms are included in Table 1. There were no formal inclusion or exclusion criteria but more recent publications written in the English language were favoured. The vast majority of studies were experimental rather than clinical.
Discussion
TRP Channel Structure and Function
TRP channels are the most prominent emerging family of ion channels and the first to be identified in the post-genomic era using molecular biology approaches [31]. They are probably the most aggressively pursued drug targets over the past few years [32]. The revolution caused by sequencing the human genome substantially helped the identification of different members of TRP channels and facilitated an increase in the number of ‘players’ in many categories of biologically active proteins [20]. This is because, unlike other ion channels, TRP channels are identified by homology rather than by ligand function or selectivity due to their contrasting and unfamiliar functions [22]. Overall, they share 20–60% homology [20].
Based on sequence homology, the TRP family can be divided into three subfamilies: as short, long and osm-9-like [17] (a C. elegans TRP mutant) or TRPC (canonical) with seven members TRPC1–7; TRPV (named after the 1st group member vanilloid receptor) with six members TRPV1–6; TRPM (melastatin) has eight members TRPM1–8, in addition to TRPA (which has an ankyrin repeat domain). Other distantly related members of the mammalian family are TRPP (PKD) which lacks both ankyrin repeat and TRP domains [17, 21, 33,34,35]; TRPMN which lacks TRP domain and is characterised by its large ankyrin repeats domains; and TRPML subfamily (mucolipidin) where it plays a role in mucolipidosis type IV disease (developmental neurodegenerative disorder) [21]. These subfamilies are phylogenetically related [20] and TRPC family, which has been under considerable research especially with respect to their possible role in calcium entry [36, 37], is the most closely related member to the Drosophila TRP channel [20].
SOCE is a widespread phenomenon among cells where upon depletion of intracellular stores of calcium, cell surface channels are activated to allow entry of Ca2+ ions to replenish the stores. This highlights role of the Ca2+ entry for developmental and/or physiological process of different cells [38]. The first SOCE was identified by Hoth et al. [39] in mast cells and was named Ca2+ release-activated Ca2+ channels (CRAC, which is simply a specific SOCE with high Ca2+ selectivity; PCa2+/PaNa+ > 1000), and has been mainly found in haematopoietic cells [40, 41]. CRAC is subject to feedback inhibition by intracellular Ca2+ and is rightfully considered to be the best defined SOCE current that is activated by depletion of Ca2+ stores [40, 41]. Depletion of ER Ca2+ stores, in all non-excitable cells (apart from non-nucleated erythrocytes) and many types of excitable cells, causes activation of plasma membrane Ca2+-permeable channels [20]. This process is known as capacitative or store-operated Ca2+ entry, and the term ‘capacitative’ gives an appropriate impression as it is possible that close interactions between the ER and plasma membrane underlies SOC activation [20, 42, 43]. Above all, it should be noted that induction of ICRAC does not necessarily require the depletion of stores and that other store depletion-stimulated currents or channels have been identified [44]. As previously alluded to, STIM1 have been shown to sense the depletion in calcium stores and result in sustained activation of CRAC via interaction with Orai1, which is an essential pore subunit of CRAC [45]. Mutations in Orai1 can result in immune deficiency by abolition of CRAC channel function [46].
TRP Subfamilies in the Cells of the Adaptive and Innate Immune System
Cells of the Adaptive Immune System
T Lymphocytes
T cells comprise two main subsets. CD4+ T cells, or ‘helper’ T cells, are activated upon recognition of cognate antigen/major histocompatibility complex (MHC) class II which is expressed by specialised antigen-presenting cells. Antigen recognition leads to the production of a cocktail of soluble mediators such as cytokines and chemokines which orchestrate the subsequent immune response. CD8+ T cells, or ‘cytotoxic’ T cells, recognise antigen encased in MHC class I, which is expressed by the vast majority of human cell populations. Antigen recognition by CD8+ T cells triggers cytotoxicity. There are several other T lymphocyte populations and sub-populations (reviewed in [47]); however, the structure responsible for T cell activation in each case is the T cell receptor (TCR).
The details of TCR structure and signalling are complex and well beyond the scope of this review (reviewed in [14]). However, Ca2+ homeostasis is key to many downstream signalling pathways and effector functions. In summary, TCR stimulation leads to the recruitment of signalling molecules and adaptors to the TCR to form a proximal signalling complex. This results in the phosphorylation and activation of phospholipase-C (PLC)-γ, which cleaves phosphatidylinositol 4,5-bisphosphate (PIP2) to 1,4,5-inositol trisphosphate (IP3) and diacylglycerol (DAG). IP3 causes Ca2+ release from endoplasmic reticulum (ER) stores [14, 48]. Depletion of ER Ca2+ is sensed by STIM1 (stromal interaction molecule 1) whose Ca2+-binding domain is located on the luminal surface of the ER membrane [31]. STIM1 undergoes oligomerisation and translocation to the plasma membrane, enabling interaction with ORAI1 proteins, which are members of the CRAC channel [45]. This process, known as SOCE, is responsible for a large and sustained increase in intracellular Ca2+ levels [14, 48]. It is believed that several other Ca2+ channels expressed on the cell surface, including TRP channels, then modulate or fine-tune Ca2+ flux in T cells. Calcium signalling is crucial to the development and activation of T cells. Interestingly, STIM1 has been identified as a critical modulator of intracellular calcium in T cells [49]. Deficiencies of STIM1 expression have been linked to abnormal function of T cells. Here, we provide an overview of the role of TRP channels in the regulation of intracellular calcium in T lymphocytes (Fig. 3). The main TRP channels have been sub-grouped into TRPA, TRPC, TRPM and TRPV.
Identification and Function of the Individual TRP Channels in T Cells
TRPA
Stokes et al. [48] have demonstrated widespread expression of TRPA1 mRNA and protein throughout the human body, including in primary and secondary lymphoid organs such as thymus, spleen and lymph nodes [50]. They also demonstrated expression by Jurkat T cell lines [50]. Since then, the TRPA1 ion channel has been found to be expressed by both murine and human T cells [30].
TRPA1 has been linked to murine models of colitis and human inflammatory bowel disease (IBD) [30]. IL10−/−TRPA1−/− mice developed more severe CD4+ T cell-medicated colonic inflammation than their IL10−/− counterparts. In line with this, CD4+ T cells from TRPA1−/− mice experienced a greater and more sustained level of calcium influx upon TCR stimulation compared to wild-type (WT) cells. This manifested in greater expression of the Th1 transcription factor Tbet and the Th1 cytokines IFNγ and IL2. Similarly, in human CD4+ T cells, TPRA1 knockdown increased IFNγ and IL2 production [30].
Bertin et al. [30] have also gone some way towards explaining how TRPA1 exerted these anti-inflammatory effects in their experimental systems. TRPA1 and TRPV1 were co-localised at the plasma membrane of CD4+ T cells, with TRPA1 inhibiting the activity of the TRPV1 channel. Reduced expression of TRPA1 promoted TRPV1-mediated TCR-induced calcium influx and CD4 T cell activation [30]. Interestingly, colonic biopsies from IBD patients have a greater number of infiltrating TRPA1+TPRV1+ leukocytes [51] and T cells [30] compared to controls. TRPV1 transcript levels are downregulated in biopsies from patients with IBD compared to controls [30], while the opposite pattern is true for TRPA1 [30, 51]. Bertin et al. [30] therefore suggest that differential expression of TRP channels or altered infiltration of TRPA1+TRPV1+ T cells contributes to the pathophysiology of this condition.
TRPC
A number of studies have demonstrated expression of TRPC channels by murine T cells [52,53,54,55], human T cell lines [56,57,58,59,60] and human T cells [56, 61].
Studies have suggested an immunosuppressive role for TRPC5, linking this channel to murine models of multiple sclerosis (MS) and type 1 diabetes (T1D). Wang et al. [52] demonstrated that activation of murine CD4 and CD8 T cells upregulated the expression of GM1, a ligand for galectin-1. Galectin-1 mediates suppression by regulatory T cells (Tregs), and in this study, it conferred protection against experimental autoimmune encephalomyelitis (EAE) [54]. CD4+ and CD8+ T cell activation also upregulated TRPC5, which led to Ca2+ influx upon GM1 cross-linking by galectin-1 [54]. Importantly, TRPC5 knockdown prevented galectin-1-mediated Ca2+ influx and Treg suppression [54]. In another study, effector T cells from non-obese diabetic (NOD) mice were found to express lower levels of GM1 compared to non-autoimmune prone strains. These T cells experienced lower Ca2+ influx via TRPC5 and were resistant to Treg suppression [55].
In contrast to the murine system, the expression of TRPC channels by human T cells has been a matter of debate. The use of a range of T cell lines probably explains this to some extent [62]. However, primary human CD4+ T cells consistently express TRPC1 and TRPC3 [56]. TRPC3 is upregulated upon polyclonal T cell stimulation, whereupon it promotes Ca2+-associated cell proliferation [56, 63].
TRPV
Studies have consistently demonstrated expression of TRPV1 and TRPV2 by human peripheral blood leukocytes/lymphocytes [64,65,66] and by CD4+ T cells [56, 67]. Expression of the other TRPV channels is more controversial [56, 64, 68], leading Wenning et al. [54] to question whether TRPV3-6 play a prominent role in human T cell biology [56]. For example, Wenning et al. [54] found TRPV6 expression by T cells from some human donors but not others, despite consistent expression by Jurkat T cell lines [56]. More recently, however, Majhi et al. [67] described expression of TRPV1-4 in resting Jurkat T cells and primary human T cells using confocal microscopy and flow cytometry [69].
TRPV1 plays a key role in TCR signalling. Upon TCR stimulation, TRPV1 co-localises with the TCR, and is phosphorylated by Lck [67], leading to Ca2+ influx [67, 69]. Consequently CD4+ T cells from TRPV1−/− mice fail to produce pro-inflammatory cytokines after antigen-specific or polyclonal stimulation, and these T cells are unable to provoke colitis in IL10−/− mice unlike their WT counterparts [67]. Moreover, treatment of human CD4+ T cells with TRPV1 antagonists or TRPV1 siRNA reduces the expression of activation markers and the production of IL2 [67]. As mentioned previously, TRPA1 regulates the activity of TRPV1 in CD4+ T cells, protecting against the development of T-cell mediated colitis in experimental models [30].
TRPV1 has a potential role in T cell development in the thymus. Subsets of murine thymocytes express TRPV1 [70, 71]. Exposure to capsaicin, the TRPV1 agonist, triggers apoptosis [71] or autophagy [70] via Ca2+ mobilisation. Capsaicin-mediated apoptosis has also been demonstrated in Jurkat T cells and activated, but not resting, human T cells [72]. In this study, however, the rise in intracellular calcium levels was shown to be independent of the TRPV1 channel [72].
TRPV2 is also expressed by human leukocytes/lymphocytes [64, 65] and CD4+ T cells [56]. In a patent application, Sauer and Jegla [71] describe accumulation of TRPV2 mRNA within CD4+ and CD8+ T cell populations, as well as an array of other immune system cells [73]. In the same patent application, the authors used shDNA to lower expression of TRPV2 in a bid to understand its mechanism of action. Knockdown of TRPV2 in Jurkat cells led to reduced TCR-induced calcium influx [73]. Jurkat T cells also express stretch-sensitive TRPV2 channels. Mechanical stress leads to Ca2+ influx, which, again, can be blocked by siRNA-mediated TRPV2 knockdown [74].
There are studies reporting expression of TRPV3 by murine and human T cells, although levels of expression are relatively low compared to other members of the TRPV family [52, 64, 67, 69]. Moreover, TRPV3−/− mice have no discernible T cell phenotype [75].
Majhi et al. [67] demonstrated expression of TRPV4 by human T cells. Moreover, they show that exposure to a TRPV4 agonist triggers Ca2+ influx, and that exposure to a TRPV4 antagonist limits polyclonal T cell activation [69].
The role of TRPV5 and TRPV6 in T cell biology is more controversial [75]. Vassilieva et al. [74] demonstrated expression of both TRPV5 and TRPV6 by Jurkat T cells and human peripheral blood lymphocytes. Channel activation led to Ca2+ entry, which was blocked by a nonspecific inhibitor of TRPV5/6 channels [76]. However, TRPV6−/− mice have no notable immunological defects or alterations in TCR-induced Ca2+ influx [75].
TRPM
TRPM2, TRMP4 and TRPM7 appear to be consistently expressed by human CD4+ T cells, and TRPM2 is upregulated strongly upon T cell stimulation [56, 62, 75].
TRPM2 channels play an important role in T cell activation via Ca2+ influx. And studies have begun to elucidate the mechanisms by which this occurs. For example, Ca2+ influx via TRPM2 can be stimulated by adenosine 5′-diphosphoribose (ADPR) and β-nicotinamide adenine dinucleotide (β-NAD), suggesting that these nucleotides act as second messengers [77, 78]. ADPR-induced Ca2+ influx can be triggered by oxidative stress induced by hydrogen peroxide [79] and by concanavalin A (conA) [80]. ADPR is believed to be endogenously generated by β-NAD hydrolysis [77, 81]. Indeed, the Ca2+ response to mitogens such as conA is limited by lowering NAD levels [81]. More recently, Fliegert et al. [80] have demonstrated that 2′-deoxy-ADPR is a more potent activator of TRPM2 than ADPR, labelling it as a ‘super-agonist’. Importantly, they show that 2′deoxy-NAD is present in Jurkat T cells [82].
CD4+ T cells from mice deficient in TRPM2 are less receptive to polyclonal stimulation, having reduced proliferation and cytokine-secreting capacity compared to those from WT mice [83]. TRPM2-deficient mice are also more prone to the development of EAE [83].
In contrast to other TRP channels, TRPM4 appears to dampen Ca2+ signalling in at least one subset of T cells [84, 85]. si-RNA-mediated reduction in TRPM4 by Jurkat T cells leads to prolonged Ca2+ influx and increased IL2 production upon activation [84]. Because TRPM4 is predominantly a Na+ channel, the proposed mechanism by which this occurs is via membrane depolarisation, and therefore a reduction in the driving force for Ca2+ entry via SOCE [84]. Weber et al. [83] have described important differences between Th1 and Th2 T cell subsets. Th2 cells express higher levels of TRPM4 compared to Th1 cells [83]. Furthermore, inhibition of TRPM4 in Th2 cells leads to increased Ca2+ influx, motility and production of IL2. The opposite was true for the Th1 subset [85].
The non-selective cation channel kinase TRPM7 is involved in cellular Mg2+ homeostasis [86]. Selective deletion of TRPM7 in developing thymocytes leads to developmental arrest at the double-negative (i.e. CD4−CD8−) stage [87]. The TRPM7−/− T cells that do populate the periphery are unable to undergo apoptosis via the Fas-receptor pathway [88].
TRPM7 has also been linked to T cell migration. The presence TRPM7 at the uropod (the trailing edge of the cell as it migrates) is associated with Ca2+ oscillations required for migration. siRNA-mediated down-regulation of TRPM7 reduces the frequency of migrating cells and the speed of movement [89].
B Lymphocytes
B cells are responsible for antibody-driven immune responses. Like the TCR, activation of the B cell receptor (BCR) triggers Ca2+ influx via CRAC channels and the subsequent initiation of many adaptive immune functions (Fig. 4). Other Ca2+ channels, including TRP channels, have also been implicated in the regulation of Ca2+ influx in B cells (reviewed in [90]). Patients with mutations in the CRAC channel have a severe-combined immunodeficiency (SCID) phenotype. T cells from these patients display defective effector function; however, B cell activity appears to remain intact, suggesting that alternative Ca2+ influx mechanisms feature more heavily in B cells compared to T cells [91,92,93]. Despite this, our knowledge about the role of TRP channels in B cells is lacking.
Liu et al. [92, 152] demonstrated that primary human B cells express TRPC2, TRPC3 and TRPC6; TRPV2 and TRPC4; and TRPM1, TRPM5 and TRPM7 [94]. They also provided some evidence that one or more of these channels may be implicated in the B cell response to shear and osmotic stress; however, more work is required to elucidate the specifics of this signalling pathway [94].
Identification and Function of the Individual TRP Channels in B Cells
TRPC
Polyclonal CpG-mediated stimulation of B cells via the scavenger receptor B1 (SR-B1) leads to Ca2+ entry via PLCγ-mediated TRPC3 activation [95]. In BCR-induced signalling, it has been proposed that TRPC3 has dual roles. Firstly, TRPC3 is a DAG-activated Ca2+ channel, and secondly, it acts as a platform for PKCβ at the plasma membrane, thus promoting effective BCR signalling [96].
TRPC7 is involved in DAG-activated Ca2+ entry into DT40 B cells. TRPC7−/− cells display impaired Ca2+ flux, which can be reversed by transfection with the human TRPV7 channel [97].
TRPM
Using DT40 B cells, Beulow et al. have shown that TRPM2 can be activated by oxidative stress, via poly(ADP-ribose) polymerases (PARPs) [98].
In DT40 B cells, TRPM6 kinase activity regulates intracellular trafficking of TRPM7 and controls TRPM7-induced cell growth [99]. TRPM7 phosphorylates PLCγ2, which is a key signalling molecule downstream of the BCR [100].
Cells of the Innate Immune System
Natural Killer Cells
Natural killer (NK) cells are involved in surveillance and protection against viral infection and malignant cell transformation. Their functions, such as cytotoxicity and cytokine production, are tightly controlled by a range of activating and inhibitory receptors expressed on the cell surface (reviewed in [101]). NK cells isolated from patients with an ORAI1 or STIM1 deficiency have defective SOCE, and they are unable to initiate effective cell killing due to impaired cytotoxic granule exocytosis [102]. This demonstrates the importance of SOCE to NK cell function. However, studies are beginning to reveal that other channels, including TRP channels, are involved in Ca2+ homeostasis in NK cells.
Identification and Function of the Individual TRP Channels in NK Cells
TRPC
Recent studies have demonstrated that NK cells are able to directly respond to haptens. Stimulation with two haptens known to induce contact hypersensitivity cause Ca2+ influx, potentially via TRPC3 (Fig. 5) [103].
TRPM
The TRPM2 channel is involved in Ca2+ signalling within cytolytic NK cell granules. Upon recognition of a malignant cell, TRPM2 is activated by ADP-ribose, leading to Ca2+ mediated granule polarisation and degranulation [104].
TRPM3 is expressed on the NK cell surface [105, 106]. NK cells from patients with chronic fatigue syndrome/myalgic encephalomyelitis have lower expression of TRPM3, and altered cytoplasmic calcium flux, compared to those from healthy controls [105, 106]. Interestingly, Marshall-Gradisnik et al. [105] have discovered several single nucleotide polymorphisms associated with TRP ion channels (including TRPM3, TRPA1 and TRPC4) in patients with these conditions [107]. The role of NK cell functional defects in chronic fatigue syndrome and myalgic encephalomyelitis have yet to be fully explored.
Dendritic Cells
Dendritic cells (DCs) are the archetypal antigen-presenting cell. DCs recognise, process and display antigen encased in MHC class I or II to CD8+ and CD4+ T cells, thereby initiating an adaptive immune response. They are able to dictate the strength and direction of the immune response via cell surface receptors and the production of soluble mediators. Studies have described the CRAC channel as the predominant Ca2+ entry mechanism in DCs [108]; however, alternative Ca2+ entry pathways, for example TRP channels, are also believed to be involved in DC calcium flux (Fig. 6). Indeed, Vaeth et al. [107] demonstrated that SOCE via STIM1/2 is not required for many DC effector functions including phagocytosis, cytokine production and antigen presentation [109]. However, more recently, Maschalidi et al. [108] revealed a more prominent role for STIM1 in calcium regulation that is required for antigen cross-presentation and anti-tumour response [110]. STIM1 ablation leads to a decrease in cross-presentation. Interestingly, the endoplasmic reticulum Ca2+ sensor STIM1 seems to be activated by heat. Temperatures > 35 ℃ resulted in STIM1 clustering which then led to Orai-mediated Ca2+ influx as a heat off response [111]. Temperature seems to play an important role in immune system regulation and immune cell function [112,113,114,115,116,117]. One widely known benefit of fever is enhancement of immune response and release of pro-inflammatory cytokines that can further regulate immune cell function [116]. Furthermore, there is evidence for enhancement of DC function following fever, where elevated temperatures have substantially enhanced phagocytic ability of DCs [117,118,119,120,121]. The emerging evidence that intracellular calcium can be modulated to regulate immune function via STIM1 temperature-sensing mechanism would allow for potential tweaking of immune system function via pharmacological intervention or temperature.
Identification and Function of the Individual TRP Channels in Dendritic Cells
TRPV
Human DCs express TRPV1, TRPV2 and TRPV4 [122]. A role for TRPV1 in the generation of immune tolerance in the gut has been described. Ingestion of capsaicin promotes the development of tolerogenic antigen-presenting cells (APCs) in the murine lamina propria (LP) [123] or pancreatic draining lymph nodes [124]. DCs expressing the chemokine receptor CX3CR1 are believed to have regulatory properties [125]. In the LP, this population expresses higher levels of TRPV1 compared to their CX3CR1 negative counterparts [123]. Capsaicin is able to expand the size of regulatory antigen-presenting cells and enhance their tolerogenic properties, leading to protection from diabetes in NOD mice [123, 124].
Interestingly, TRPV1 may provide a link between the nervous and immune systems. After TRPV1, stimulation murine splenic DCs produce calcitonin-gene-related peptide (CGRP), a potent neuropeptide which has anti-inflammatory effects on both T cells and DCs [126].
TRPV2 has been linked to DC thermosensation. Temporary exposure to heat shock of 43 °C decreases endocytosis, an effect which can be reversed by TRPV2 siRNA [122].
TRPM
In bone marrow-derived DCs, TRPM2 expression is limited to endolysosomal storage vesicles, where it contributes to Ca2+ release upon stimulation with ADPR or chemokines [127]. DCs deficient in TRPM2 demonstrate impaired directional migration in response to chemokines or inflammatory mediators, suggesting that TRPM2 is involved in DC trafficking [127].
TRPM4 is also involved in DC migration, but via a different mechanism. Because TRPM4 is primarily a Na+ channel, blocking TRPM4 repolarises the plasma membrane, allowing for Ca2+ elevation [128]. This Ca2+ overload in TRPM4−/− DCs impairs migration to lymph nodes in vivo [128].
Neutrophils
Neutrophils are keys to the initiation of an immune response. In the early stages of an infection, they perform phagocytosis, release toxic granules, oxidative bursts and neutrophil extracellular traps (reviewed in [129]). They also produce a cocktail of cytokines in order to help shape the direction of the ongoing immune response [130]. Regulation of these effector functions—in order to achieve an effective immune response while limiting host damage—occurs by careful sensing of environmental cues [131].
Following stimulation with, for example, chemoattractants, neutrophils experience a sustained increase in intracellular calcium via receptor-mediated calcium influx and SOCE [132]. The rise in Ca2+ concentration is essential for subsequent effector function [133,134,135]; however, similar to DCs, SOCE is dispensable [109], suggesting that other Ca2+ channels are heavily involved.
TRPC, TRPV and TRPM channels have been linked to neutrophil function (Fig. 7).
Identification and Function of the Individual TRP Channels in Neutrophils
TRPC
Studies have demonstrated variable expression of TRPC1, TRPC3 and TRPC4, and consistent expression of TRPC6 by human neutrophils [136,137,138]. Bréchard et al. [137] demonstrated that TRPC3 acts primarily via SOCE-independent pathways whereas TRPC6 is involved in SOCE [139].
TRPC1 has been linked to the migration of murine neutrophils. TRPC1−/− neutrophils have enhanced Ca2+ influx upon chemotactic stimulation, which leads to reduced migration and transendothelial recruitment [140].
Using TRPC6−/− mice, Damann et al. [139] also demonstrated that TRPC6 is involved in neutrophil chemokine-induced migration [141]. TRPC6 was required for the correct organisation of filamentous actin in these migrating cells [141].
TRPV
Human neutrophils express TRPV1, TRPV2, TRPV4, TRPV5 and TRPV6 [136, 142]. There are, however, very few studies investigating the function of these channels.
Recently, Yin et al. [140] have shown that TRPV4 deficient neutrophils are less able to respond to proinflammatory stimuli in a murine model of acid-induced acute lung injury. However, the authors showed that TRPV4 expression by endothelial cells, rather than neutrophils, was more heavily involved in the pathophysiology of this condition [142].
TRPM
In contrast to DCs, TRPM2 is expressed on the plasma membrane of neutrophils, where it contributes to calcium influx [127, 136, 143]. TRPM2 forms an important part of the neutrophil sensory apparatus. By responding to environmental reactive oxygen species (ROS), TRPM2 terminates neutrophil migration at the site of infection, enabling for the appropriate initiation bactericidal activity [131]. Ca2+ influx via TRPM2 also primes neutrophil degranulation, increases proinflammatory cytokine production [144] and enhances bacterial killing [145]. In TRPM2−/− mice with dextran sulfate sodium (DSS)-induced colitis, recruitment of neutrophils to the inflamed colon is impaired [146]. This reflects reduced production of chemoattractants by macrophages [146].
TRPM2 is detrimental in murine models of stroke, whereby it promotes cerebral inflammation due to the accumulation of neutrophils and macrophages [147].
Monocytes and Macrophages
Circulating monocytes and tissue-resident macrophages form a diverse group of phagocytic cell populations that help to orchestrate the immune response by producing chemokines and cytokines in response to microenvironmental signals (reviewed in [148]).
Similarly to neutrophils, intracellular Ca2+ fluctuations regulate many cellular functions in monocytes/macrophages, including phagocytosis [109, 149, 150].
The studies described below have linked expression of TRPA1; TRPV1 and TRPV2; TRPC1, TRPC3 and TRPC6; and TRPM2, TRPM4 and TRPM7 to monocyte/macrophage function (Fig. 8).
Identification and Function of the Individual TRP Channels in Monocytes and Macrophages
TRPA
Kun et al. [49] examined TRPA1 mRNA expression in colonic biopsies of mice with DSS-induced colitis and humans with inflammatory bowel disease. TRPA1 was found to be expressed by colonic macrophages [51]. Interestingly, inflamed colons had greater TRPA1 expression. Similarly, TRPA1−/− mice had greater disease burden, suggesting that TRPA1 is protective in this condition [51]. However, the protective effect of TRPA1 in colitis has subsequently been linked to its role in T cells [30].
TRPA1 is responsible to monocyte detection of hypothermia, which has been associated with prolongation of inflammation in surgery [151].
More recent studies have suggested that TRPA1 protects against the development of atherosclerosis. Administration of a TRPA1 antagonist or genetic deletion of TRPA1 in apolipoprotein-E-deficient (Apo-E) mice increased plaque size, serum lipid levels and systemic inflammation [152]. Blocking TRPA1 expressed by macrophages led to lipid accumulation and the formation of foam cells in response to oxidised low-density lipoprotein (LDL) [152].
TRPC
TRPC1−/− mice rapidly succumb to severe bacterial infection. Ca2+ entry via TRPC1 is required for TLR4-induced proinflammatory cytokine production by alveolar macrophages [153].
Elevated TRPC3 expression by monocytes has been linked to spontaneous hypertension in rats [154, 155]. Moreover, monocytes from human subjects with essential hypertension have higher levels of TRPC3 [156], which is associated with elevated proinflammatory cytokine production [157] and increased chemoattractant-induced migration [158]. Increased expression of TRPC3 and TRPC6 by human monocytes has also been associated with diabetes [159].
TRPC3 expression is linked with macrophage survival. TRPC3−/− macrophages have increased rates of apoptosis, potentially due to reduced constitutive cation influx [160]. Using macrophages deficient in TRPC3, Solanki et al. [159] demonstrated reduced endoplasmic reticulum-stress induced apoptosis in the M1 inflammatory macrophage subset [161]. The same group later used the LDL receptor knockout mouse model of atherosclerosis transplanted with bone marrow from mice with a macrophage-specific loss of TRPC3, to further demonstrate that TRPC3-deficient macrophages have lower rates of apoptosis. The authors found a decreased number of apoptotic M1 macrophages and decreased plaque necrosis [162]. Recent RNA sequencing of M1 macrophages from mice with macrophage-specific TRPC deletion revealed 160 genes that were significantly differently expressed compared to their WT controls [163]. Genes that may be affected by loss of TRPC expression include those involved in cellular locomotion and lipid signalling [163]. Further work will need to be performed in order to fully understand the large amounts of data generated in this study.
Alveolar macrophages from chronic obstructive pulmonary disease (COPD) patients have increased TRPC6 expression, suggesting a potential role for TRPC6 in this condition [164].
Alveolar macrophages from cystic fibrosis (CF) patients have impaired acidification of phagosomes, which contributes to increased risk of chronic pulmonary infection. Riazanski et al. [163] have recently demonstrated that TRPC6 is able to restore macrophage bactericidal activity via translocation into the phagosomal membrane [165].
TRPV
TRPV2 plays a critical role in macrophage phagocytosis. The channel is required for phagocytic binding and internalisation [166]. TRPV2 is also involved in macrophage chemotaxis [167] and cytokine production [168]. Thus, TRPV2−/− mice have impaired defence against bacterial infection [166].
Interestingly, after a myocardial infarction, TRPV2+ macrophages infiltrate the peri-infarct region [169]. TRPV2−/− mice have a better recovery post-MI [170]. Moreover, infusion with WT macrophages leads to increased mortality, whereas this is not true TRPV2−/− macrophages, suggesting that TPPV2 contributes to cardiac injury post-MI [170].
TRPM
TRPM2−/− mice are more susceptible to infection compared to their WT littermates [171, 172]. Peritoneal macrophages from TRPM2−/− have defective phagosome maturation, which prevents fusion of the phagosome and lysosome and stops effective clearance of bacterial pathogens [171]. TRPM2 is also essential for the appropriate acidification of macrophage phagosomes [173].
In addition to its role in phagocytosis, TRPM2 is also involved in lipopolysaccharide (LPS)-induced proinflammatory cytokine production [174], and in ROS-triggered chemokine production, and subsequent recruitment of neutrophils to the site of inflammation [146]. Thus, TRPM1−/− mice are less susceptible to DSS-induced colonic ulceration [146].
Conversely, Di et al. [173] demonstrated a protective role for TRPM2 in endotoxin-induced lung injury, via inhibition of ROS production in phagocytes [175]. More recently, Beceiro et al. [174] have investigated the role of TRPM2 in Helicobacter pylori infection. They demonstrate that TRPM2 deficiency increases gastric inflammation and ROS production and reduces bacterial burden [176]. These conflicting results have led Beceiro et al. [174] to speculate that TRPM2 has distinct functions under different inflammatory conditions [176].
Mast Cells
Mast cells are specialised to defend against external pathogens such as parasites, but they are perhaps most well known for their involvement in the pathophysiology of asthma and allergy. Mast cell activation leads to the release of preformed mediators such as histamine into the extracellular space, a phenomenon known as degranulation [177]. Calcium influx via CRAC channels is central to the formation of de novo inflammatory mediators, and for degranulation itself (reviewed in [178]). There is increasing evidence that TRP channels are also essential for mast cell effector functions (Fig. 9) [179].
Identification and Function of the Individual TRP Channels in Mast Cells
TRPA
TRPA1 has been detected in vesicular structures in the mast cell line RBL2H3, whereby it interacts with secretogranin III, a protein involved in granulogenesis [180].
TRPC
Studies in murine models have shown that TRPC1 [181, 182], TRPC3 [181] and TRPC5 [183] contribute to mast cell Ca2+ influx and/or degranulation. However, although Wajdner et al. [182] have recently described expression of TRPC 1 and TRPC6 by human mast cells, they found no evidence for a functional contribution of these channels to receptor-induced calcium entry [184].
TRPV
A recent study has demonstrated that, although TRPV1, TRPV2 and TRPV4 are expressed by murine peritoneal lavage mast cells, these channels are not mediators of Ca2+ elevation or degranulation in response to a variety of stimuli [185].
TRPM
TRPM2 is involved in allergen-induced degranulation in mast cells. Thus, antigen-stimulated degranulation and cytosolic Ca2+ concentration are reduced in TRPM2−/− mice, and TRPM2 inhibitors reduce the pathological response to food allergens [186].
In contrast, TRPM4−/− mast cells have elevated Ca2+ influx [187, 188] and release increased levels of histamine and other inflammatory mediators upon activation [187]. Moreover, TRPM4−/− mice are prone to more severe anaphylactic responses after exposure to skin allergens compared to their WT littermates [187]. TRPM4 exerted this effect via membrane depolarisation, which limits the driving force for Ca2+ entry via the CRAC channel [187]. TRPM4 also regulates mast cell migration by regulating intracellular Ca2+ concentrations and modulating filamentus actin formation [189].
The TRPM7 channel is required for mast cell survival [190, 191] and function [29]. TRPM7 is expressed at higher levels in asthmatic rats compared to controls. Moreover, pharmacological blockade or shRNA-mediated knockdown of channel function reduced degranulation and cytokine release in asthmatic rats [29]. In contrast, Zierler et al. [190] found that TRPM7 kinase activity was able to regulate mast cell function independently of channel function by regulating the Ca2+ and Mg2+ sensitivity of G protein coupled receptor-mediated degranulation [192].
Platelets
Platelets are well known for their role in haemostasis, but increasing evidence demonstrates that they are keys to a coordinated and effective innate and adaptive immune response (reviewed in [193]). Ca2+ homeostasis is central to platelet function. Ca2+ levels are regulated by several mechanisms including SOCE via STIM1 and ORAI1 (reviewed in [194]). Human platelets express TRPC1, TRPC3, TRPC4, TRPC5 and TRPC6 [195, 196], as well as TRPV1 [197]. Increasing evidence suggests that TRPC channels are heavily involved in platelet activation.
Identification and Function of the Individual TRP Channels in Platelets
TRPC
The role of TRPC1 in platelets is somewhat controversial. SOCE can be inhibited in platelets by blocking TRPC1 function using a specific antibody [198] or reducing expression by shRNA [199]. However, TRPC1−/− mice have intact SOCE [200]. The reason for this discrepancy remains unknown.
TRPC6−/− mice have reduced or absent Ca2+ entry upon stimulation with 1-oleoyl-acetyl-sn-glycerol (OAG) [201, 202]. Studies have demonstrated involvement of TRPC6 in both SOCE [203] and SOCE-independent [204, 205] Ca2+ mobilisation. Although increasing evidence links TRP channel defects to cardiovascular and haemostatic pathology (reviewed in [206]), more work is required in order to understand associations with immunological or inflammatory conditions.
Clinical Implications of TRP Dysfunction
Respiratory Pathology
Acute respiratory distress syndrome (ARDS) is defined by acute hypoxemic respiratory failure, radiographic evidence of bilateral pulmonary opacities, and pulmonary oedema, not fully explained by cardiac failure or fluid overload [142]. It has an estimated incidence of 86.2 per 100,000 person-years and therefore presents a major cause of mortality and morbidity in critical care [142]. The cause can be due to numerous inflammatory triggers, both directly and indirectly including sepsis [142]. The characteristic pathology comprises of diffuse endothelial and epithelial injury, resulting in respiratory failure and formation of pulmonary oedema, and a strong inflammatory response characterised by the release of cytokines and the recruitment of granulocytes, monocytes and platelets into the lung [142].
TRPV4 has been implicated in this proinflammatory response and has been shown to be expressed on the key cell types involved in the pathogenesis of ARDS, as well as alveolar macrophages and neutrophils. TRPV4 also regulates the cellular responses in the pathogenesis of ARDS, such as lung endothelial barrier failure and macrophage activation. Studies have shown that therapeutic administration of TRPV4 inhibitors may alleviate lung injury in some, but not all, experimental models, and that further studies in different disease models and species are needed before this approach can be applied to patients [142].
COPD is currently sixth in the global impact of diseases and is predicted to be the third leading cause of death by 2020 [164]. A major risk factor for the development of COPD is cigarette smoking. Treatment for COPD is mainly symptomatic with no treatments that have any impact on the underlying inflammation of this disease. COPD encompasses chronic bronchitis, small airways disease and emphysema, with a characteristic feature of this disease being increased numbers of inflammatory cells located within the lungs of these patients. Studies have shown macrophages are increased numbers in the lung parenchyma of patients with COPD at the sites of alveolar destruction. These macrophages have been linked to TRPC6. Therefore, it has been suggested that these channels that might be responsible for much of the underlying pathophysiology of COPD [164].
Cardiology Pathology
Numerous TRP channels have been linked to cardiac pathology. Studies have shown up regulation of TRPV2 mRNA in the left ventricles (LVs) 3–5 days post-acute myocardial infarction and that TRPV2 expressing macrophages may play a significant role in the inflammatory processes that occur after permanent LAD occlusion at the local environment of the infarcted LV. TRPV2 gene overexpression may enhance the phagocytic activity of the peri-infarct macrophages [169].
In cardiac cells, several mutations in TRPM4 were found to be associated with human heart conduction dysfunction [35, 207]. Mutations have been also shown to be associated with progressive familial heart block type 1 [207].
Ischaemic stroke is the second most common cause of death worldwide. Studies have shown TRPM2 channels in neutrophils and macrophages regulate their migratory capacity to ischaemic brain thereby secondarily perpetuating brain injury. TRPM2-deficient mice are more protected from ischaemic stroke and show an improved neurological outcome compared with wild-type mice. TRPM2 activation in peripheral immune cells also leads to an exacerbation of ischaemic brain damage. Therefore, targeting TRPM2 systemically represents a promising therapeutic approach for ischaemic stroke [147].
The link between atherosclerosis, hypertension and TRPC3 has also been described in studies. The lack TRPC3 in macrophages was associated to an important reduction in plaque necrosis.[158, 162].
Primary Hypomagnesemia with Secondary Hypocalcaemia
Primary hypomagnesemia with secondary hypocalcaemia is an autosomal recessive disorder [28, 99]. It is caused by impaired intestinal absorption of magnesium accompanied by renal magnesium wasting due to a reabsorption defect in the distal convoluted tubule [28]. Mutations in the gene for TRPM6 were identified as the underlying genetic defect which included stop mutations, frame shift mutations, splice site mutations and deletions of exons [28]. This leads to patients failing to build a functional TRPM6 pore [99]. Patients with this disorder present in early infancy with neurological symptoms such as convulsions or muscle spasms.
Numerous studies have also established the role of magnesium as an essential nutrient contributing to the development of major risk factors leading to diseases, such as diabetes mellitus, hyperlipidaemia, atherosclerosis, and hypertension. This further highlights the importance of this nutrient and shows that TRPM6 genotyping or medications targeted to this area of the genome could be beneficial in the future.
Autoimmunity
Autoimmune diseases include diseases such as systemic lupus erythematous, rheumatoid arthritis, type 1 diabetes and multiple sclerosis. They occur when T cells attack a patient’s own cells [208]. T cell responses have also been implicated in graft rejection, allergy, asthma, dermatitis, psoriasis and graft versus host disease. Thus, treatment directed to inhibition of T cell activation and therefore TRP channels would be greatly desired to treat such undesired immune responses [73].
In addition to TRP cells in T cells, TRP channels have been show to be expressed in synoviocytes and studies have suggested that TRPV1-deficient mice develop reduced knee swelling [209].
Allergy
Activation and degranulation of mast cells is a key step in the pathogenesis of allergic diseases such as asthma and anaphylaxis [187]. An allergic reaction develops when allergens encountered by antigen-presenting cells are processed and presented to T cells. Studies have shown that TRPM4-deficient mice have a more severe acute anaphylactic response in the skin than control mice and therefore that TRPM4 channel activation is an efficient mechanism for limiting antigen-induced mast cell activation [10, 187].
Severe combined immunodeficiency syndrome (SCID) is a group of rare disorders caused by various mutations. Patients present with severe infections and usually die within the first few years of life. The standard treatment for SCID is stem cell transplantation or gene therapy [210]. TRPC channels have been linked to SCID and represent another potential treatment area [48].
Chronic Fatigue Syndrome
Chronic fatigue syndrome, also referred to as myalgic encephalomyelitis (ME) is a disorder identified by unexplained, debilitating fatigue accompanied by other neurological, immunological, autonomic and ion transport impairments [105, 106]. It has an unknown aetiology, and there are no specific diagnostic tests [107].
The most common finding reported in ME has been reduced NK cell cytotoxic activity [106, 107]. Atypical single nucleotide polymorphisms of the TRPM3 gene, from peripheral blood mononuclear cells, NK and B cells have been recently reported in ME groups compared with healthy controls [105, 106]. In addition, studies have shown a significantly reduced expression of TRPM3 on NK and B lymphocytes in ME patients [105]. This results in changes in Ca2+ ion concentration in the cytosol and intracellular stores which may change the NK cells’ activation threshold [106].
Polycystic Kidney Disease
TRPP subfamily has been linked to numerous cases of polycystic kidney disease [21, 207]. The proteins involved, PKD2, PKD2L1 and PKD2L2, are Ca2+ permanent channels called TRPP2, TRPP3 and TRPP5, respectively. Autosomal dominant polycystic kidney disease is caused by mutations in TRPP1 or TRPP2 which leads to alterations in the polarisation and function of cyst lining epithelial cells. Studies have shown that Mice with negative TRPP1 or TRPP2 are more likely to die in utero with cardiac septal defects and cystic changes in nephrons and pancreatic ducts [22].
Mucolipidosis
Mucolipin-1 (MCOLN1) is a novel membrane protein that is defective in mucolipidosis type 4 disease. It is part of the TRPML1 subfamily. Mucolipidosis is a developmental neurodegenerative disorder characterised by a lysosomal storage disorder, abnormal endocytosis of lipids and accumulation of large vesicles [21, 27]. Symptoms include severe psychomotor developmental delay, progressive visual impairment and achlorydia. It is an autosomal recessive disease, which typically presents in infancy. After the disease onset, a period of stability often ensures lasting for two to three decades. Treatment for the disorder includes enzyme replacement therapy, substrate reduction therapy and gene therapy [27, 207].
Inflammotory Bowel Disease IBD
TRPV1 has been linked to a number of conditions including inflammatory bowel disease [16, 67, 208].
TRPV4 may also have a role in colonic afferents as it is expressed in nerve fibres of patients with inflammatory bowel disease [23]. Inflammatory bowel diseases include ulcerative colitis and Crohn’s disease. Ulcerative colitis affects only the colon, Crohn’s may affect all parts of the gastrointestinal tract, but most commonly the distal part of the small intestine, the ileum and the colon. Clinical symptoms of IBD comprise of abdominal pain, diarrhoea, gastrointestinal bleeding and weight loss. The main management of IBD is immunosuppressive therapies, which are associated with significant adverse effects or it often has no effect on the disease [51].
Crohn’s is characterised by a T helper 1-mediated inflammatory response with overproduction of interferon and tumour necrosis factor. Ulcerative colitis is a T helper cell 2-mediated immune disease with massive production of interleukins 5, 9 and 13. As previously discussed, TRPV1 channels are expressed in CD4 T cells which increases their pro inflammatory properties in models of colitis. Studies have also shown mice without the TRPA1 develop severe spontaneous colitis [30].
Oncology
There are many neoplasms associated with TRP changed. TRPM1 is linked to the production of malastatin. This gene expression correlates with cutaneous melanoma tumour progression, thickness and potential for metastasis in normal skin, benign melanocytes naevi (moles) and primary cutaneous melanoma metastasis. Loss of the TRPM1 mRNA in the primary cutaneous tumour has been proven as a marker for metastasis in patients with melanoma [17, 21, 207].
TRPV2 overexpression was evidenced in patients with multiple myeloma. In hepatocellular carcinoma, it was associated with medium and well-differentiated tumours, where it was proposed as a prognostic marker. In prostate cancer, TRPV2 was shown to be involved in cancer cell migration and invasion, and may be specifically implicated in the progression to more aggressive phenotype. On the other hand, TRPV2 was shown to negatively control proliferation and resistance to Fas-induced apoptosis of glioblastoma multiforme [74].
TRP channels are heavily involved in calcium and vitamin D signalling in breast cancer. TRPV6 has been shown to be upregulated up to 15 times in breast cancer tissue when compared with that in normal breast tissue. The expression level of TRPV6 is also reduced in breast cancer cell lines in the presence of tamoxifen, an antagonist of oestrogen [6]. TRPV6 expression is also upregulated in prostate cancer and other cancers of epithelial origin, highlighting its potential as a target for cancer therapy [76].
Human myeloid leukaemia cells coexpress functional TRPV5 and TRPV6 calcium channels. Levels of both TRP channel have been found to be significantly higher in malignant cells than in quiescent lymphocytes. This indicates that TRPV6 upregulation is associated with increased proliferative activity in leukaemic cells and in activated lymphocytes which is in agreement with data showing elevated expression of TRPV6 in colon, breast, thyroid, ovarian and pancreatic carcinomas in comparison with normal tissues [76].
There are also numerous other TRP channels associated with cancers including TRPM4, which is linked to a variety of childhood and adult tumours and the cancer predisposing Beckwith-Wiedemann syndrome [17]. Downregulation of TRPC6 has been shown to be associated with autocrine tumours [21]. An exon 9 deletion in TRPC1 has also been linked to human ovarian adenocarcinoma [207].
TRP Pharmaco-immunomodulation (Summarised in Table 2)
Recent studies highlighting novel associations between TRP channels and the immune system point at potential drug targets for the future.
TRPV1 activators, for example capsaicin and resiniferatoxin (RTX), are among the most well-known TRP channel pharmacology (Fig. 10).
Capsaicin activates TRPV1 which can enhance regulatory macrophages in the gut [123]. It can also inhibit prostaglandin production in macrophages. They can lead to a large calcium influx that can produce degeneration of nociceptor axons at the site of applications into joints or onto nerves. They may even cause a loss of the sensory neuron itself by calcium-mediated mitochondrial damage and cytochrome c release leading to apoptosis when exposed close to the cell body [23]. It has been shown pharmalogically to induce a number of effects in different cell types including cell death [70].
Capsaicin can be used experimentally as an analgesic agent in the treatment of painful disorders such as peripheral neuropathy and rheumatoid arthritis [72]. Other uses include detrouser hyperreflexia, interstitial cystitis, pruritus associated with chronic renal failure and diabetic neuropathy [65]. When used in addition to a derivative of lidocarine, much more long-lasting pain relief can occur without impairing motor function or tactile sensitivity [82]. Capsaicin also exhibits anti‐inflammatory properties [69]. This is also known as Neuroges X when used for neuropathic post surgical pain.
Although studies have demonstrated that this molecule can promote immune tolerance in a murine model of type 1 diabetes [123, 124], future studies should examine its effects on TRP channels in human autoimmune conditions. There are also concerns about using this drug pharmacologically for side effects such as diminished response to damaging heat stimuli, altered body temperature and a reduction in the perception of taste which need to be fully explored before use on patients [23].
Resiniferatoxin is a more potent analgesic than capsaicin and can selectively ablate nociceptors when delivered intrathecally, which may have special utility for uncontrolled pain in a palliative setting [82]. This drug is currently under phase 1 trials and is also a TRPV1 agonist [208, 209]. It can be delivered by injection into the subarachnoid space in the spinal cord or into areas of the skin where nerves terminate [209]. Trials have suggested that the drug can be used for pain relief in numerous pathologies including Morton’s neuroma, neuropathic pain and burns. There are minimal side effects with its use [209].
Other exogenous TRPV1 agonists include piperidine, eugenol, gingerol and anandamide, as well as noxious heat (> 43–45 °C). These are still under trials, and side effects and uses are largely unknown. Anadamide is an endogenous cannabinoid receptor agonist that can also be used to induce vasodilation by activating vanillin receptor on perivascular sensory neurons [21, 126].
The main pharmacological tool for TRPV2 is cannabidiol, the major non-psychotropic cannabinoid compound derived from plant Cannabis sativa. It is a relatively selective TRPV2 agonist. It has been shown that administration of cannabidiol was shown to induce apoptosis in human T24 bladder cancer cells due to continuous influx of Ca2+ through TRPV2, and proposed as a potential therapeutic target for human urothelial carcinoma [74]. There are 2 main approved drugs available that use this compound (dronabinol and nabilone). There are also numerous side effects including liver damage, sedation and mood changes [210].
There are also a number of other pharmacological agents currently in trials with little information known about them:
-
1
Adenosine 5′-diphosphoribose (ADPR) has been shown to be the main agonist for TRPM2 [82]. This has been used in experimental trials
-
2
The TRPV1 antagonist, SB-705498 is currently the only published TRPV1 clinical study with efficacy data. It has been shown to reduce the area of capsaicin-evoked flare and to increase pain tolerance at the site of ultraviolet B irradiation [82].
-
3
TRPM2 inhibitors include clotrimazole, econazole and flufenamic acid [144].
-
4
HC-030031 is so far not used clinically but has been orally used in rat models and appears to be safe. It has been shown to be used as treatment options for hypothermia or instead of capsaicin [151].
-
5
TRPC3/6 selective antagonist (GSK-3503A) and agonist (GSK 2934A) are in trials [184].
-
6
A TRPV4 antagonist, GSK2220691, is not currently available, but there is also a commercially available TRPV4 inhibitor, HC-067047 [142].
-
7
Ruthenium red is a non‐selective TRP channel blocker, can suppress lipopolysaccharide (LPS)-induced tumour necrosis factor α (TNFα) and interleukin‐6 (IL‐6) production in macrophage cells [69].
-
8
Naturally occurring cinnamaldehyde is a TRPA1 agonist, which induces a vasorelaxant action via endothelium-dependent or endothelium-independent mechanisms [152].
Recent studies identifying these more potent TRP agonists [82] highlight how little we know about the intricacies of TRP channel activation and signalling. Studies should continue to elucidate these mechanisms in order to reveal important avenues for research into the pathophysiology of human disease and identify more potential therapeutic targets. Recent studies highlighting novel associations between TRP channels and the immune system point at potential drug targets for the future. Future studies should also examine its effects on TRP channels in human autoimmune conditions, as there is a lack of potential pharmacology in this area.
Conclusion
TRP channels have emerged as an essential component of calcium signalling machinery. TRP channels are involved in the activation of both innate and adaptive immune system cells. With links to diverse pathological conditions, including autoimmune and inflammatory states, TRP channels represent a promising future therapeutic target. The fact that these channels can sense changes in pH, temperature or even mechanical stress and change the function of the cell leaves these receptors amenable to a wide range of modulators. This leaves a window of opportunity to modulate immune cells via different means.
References
Lebish IJ, Moraski RM (1987) Mechanisms of immunomodulation by drugs. Toxicol Pathol 15(3):338–345
Hotaling NA et al (2015) Biomaterial strategies for immunomodulation. Annu Rev Biomed Eng 17:317–349
Foster AP (2004) Immunomodulation and immunodeficiency. Vet Dermatol 15(2):115–126
Hampton T (2018) Gut microbes may shape response to cancer immunotherapy. JAMA 319(5):430–431
Wang LT et al (2018) Differentiation of mesenchymal stem cells from human induced pluripotent stem cells results in downregulation of c-Myc and DNA replication pathways with immunomodulation toward CD4 and CD8 cells. Stem Cells.
Pu F, Chen N, Xue S (2016) Calcium intake, calcium homeostasis and health. Food Science and Human Wellness 5(1):8–16
Pozzan T et al (1994) Molecular and cellular physiology of intracellular calcium stores. Physiol Rev 74(3):595–636
Zamponi GW et al (2015) The physiology, pathology, and pharmacology of voltage-gated calcium channels and their future therapeutic potential. Pharmacol Rev 67(4):821–870
Tfelt-Hansen J, Brown EM (2005) The calcium-sensing receptor in normal physiology and pathophysiology: a review. Crit Rev Clin Lab Sci 42(1):35–70
Vig M, Kinet J-P (2008) Calcium signaling in immune cells. Nat Immunol 10:21
Feske S et al (2003) Ca2+/calcineurin signalling in cells of the immune system. Biochem Biophys Res Commun 311(4):1117–1132
Prakriya M et al (2006) Orai1 is an essential pore subunit of the CRAC channel. Nature 443:230
Parekh AB (2010) Store-operated CRAC channels: function in health and disease. Nat Rev Drug Discovery 9:399
Lewis RS (2001) Calcium signaling mechanisms in T lymphocytes. Annu Rev Immunol 19:497–521
Gallo EM, Canté-Barrett K, Crabtree GR (2005) Lymphocyte calcium signaling from membrane to nucleus. Nat Immunol 7:25
Nohara LL et al (2015) Tweeters, woofers and horns: the complex orchestration of calcium currents in T lymphocytes. Frontiers in Immunology 6:234
Clapham DE, Runnels LW, Strubing C (2001) The TRP ion channel family. Nat Rev Neurosci 2(6):387–396
Feng S (2017) TRPC channel structure and properties. Adv Exp Med Biol 976:9–23
Potier M, Trebak M (2008) New developments in the signaling mechanisms of the store-operated calcium entry pathway. Pflügers Archiv - European Journal of Physiology 457(2):405
Vazquez G et al (2004) The mammalian TRPC cation channels. Biochim Biophys Acta 1742(1–3):21–36
Minke B, Cook B (2002) TRP channel proteins and signal transduction. Physiol Rev 82(2):429–472
Clapham DE (2003) TRP channels as cellular sensors. Nature 426(6966):517–524
Patapoutian A, Tate S, Woolf CJ (2009) Transient receptor potential channels: targeting pain at the source. Nat Rev Drug Discovery 8:55
Grafton G et al (2018) Calcium channels in lymphocytes. Immunology 104(2):119–126
Yuan JP et al (2003) Homer binds TRPC family channels and is required for gating of TRPC1 by IP3 receptors. Cell 114(6):777–789
Qamar S, Vadivelu M, Sandford R (2007) TRP channels and kidney disease: lessons from polycystic kidney disease. Biochem Soc Trans 35(Pt 1):124–128
Wakabayashi K et al (2011) Mucolipidosis type IV: an update. Mol Genet Metab 104(3):206–213
Schlingmann KP et al (2005) Novel TRPM6 mutations in 21 families with primary hypomagnesemia and secondary hypocalcemia. J Am Soc Nephrol 16(10):3061–3069
Huang L et al (2014) Inhibition of TRPM7 channels reduces degranulation and release of cytokines in rat bone marrow-derived mast cells. Int J Mol Sci 15(7):11817–11831
Bertin S et al (2017) The TRPA1 ion channel is expressed in CD4+ T cells and restrains T-cell-mediated colitis through inhibition of TRPV1. Gut 66(9):1584–1596
Liou J et al (2005) STIM is a Ca2+ sensor essential for Ca2+-store-depletion-triggered Ca2+ influx. Curr Biol 15(13):1235–1241
Moran MM et al (2011) Transient receptor potential channels as therapeutic targets. Nat Rev Drug Discovery 10:601
Venkatachalam K et al (2002) The cellular and molecular basis of store-operated calcium entry. Nat Cell Biol 4:E263
Liao M et al (2013) Structure of the TRPV1 ion channel determined by electron cryo-microscopy. Nature 504:107
Guo J et al (2017) Structures of the calcium-activated, non-selective cation channel TRPM4. Nature 552:205
Putney JW Jr (2005) Capacitative calcium entry: sensing the calcium stores. J Cell Biol 169(3):381–382
Putney JW (2005) Physiological mechanisms of TRPC activation. Pflugers Arch 451(1):29–34
Montell C (1997) New light on TRP and TRPL. Mol Pharmacol 52(5):755–763
Hoth M, Penner R (1992) Depletion of intracellular calcium stores activates a calcium current in mast cells. Nature 355(6358):353–356
Nilius B, Droogmans G, Wondergem R (2003) Transient receptor potential channels in endothelium: solving the calcium entry puzzle? Endothelium 10(1):5–15
Bolotina VM, Csutora P (2005) CIF and other mysteries of the store-operated Ca2+-entry pathway. Trends Biochem Sci 30(7):378–387
Putney JW Jr et al (2004) Signalling mechanisms for TRPC3 channels. Novartis Found Symp 258: p. 123–33; discussion 133–9, 155–9, 263–6.
Zitt C, Halaszovich CR, Luckhoff A (2002) The TRP family of cation channels: probing and advancing the concepts on receptor-activated calcium entry. Prog Neurobiol 66(4):243–264
Feske S et al (2006) A mutation in Orai1 causes immune deficiency by abrogating CRAC channel function. Nature 441:179
Mahnke YD et al (2013) The who’s who of T-cell differentiation: human memory T-cell subsets. Eur J Immunol 43(11):2797–2809
Oh-hora M, Rao A (2008) Calcium signaling in lymphocytes. Curr Opin Immunol 20(3):250–258
Samakai E, Hooper R, Soboloff J (2013) The critical role of STIM1-dependent Ca2+ signalling during T-cell development and activation. Int J Biochem Cell Biol 45(11):2491–2495
Stokes A et al (2006) TRPA1 is a substrate for de-ubiquitination by the tumor suppressor CYLD. Cell Signal 18(10):1584–1594
Kun J et al (2014) Upregulation of the transient receptor potential ankyrin 1 ion channel in the inflamed human and mouse colon and its protective roles. PLoS ONE 9(9):e108164
Inada H, Iida T, Tominaga M (2006) Different expression patterns of TRP genes in murine B and T lymphocytes. Biochem Biophys Res Commun 350(3):762–767
Wu QY et al (2015) Activation of calcium-sensing receptor increases TRPC3/6 expression in T lymphocyte in sepsis. Mol Immunol 64(1):18–25
Wang J et al (2009) Cross-linking of GM1 ganglioside by galectin-1 mediates regulatory T cell activity involving TRPC5 channel activation: possible role in suppressing experimental autoimmune encephalomyelitis. J Immunol 182(7):4036–4045
Wu G et al (2011) Ganglioside GM1 deficiency in effector T cells from NOD mice induces resistance to regulatory T-cell suppression. Diabetes 60(9):2341–2349
Wenning AS et al (2011) TRP expression pattern and the functional importance of TRPC3 in primary human T-cells. Biochim Biophys Acta 1813(3):412–423
Rao GK, Kaminski NE (2006) Induction of intracellular calcium elevation by Delta9-tetrahydrocannabinol in T cells involves TRPC1 channels. J Leukoc Biol 79(1):202–213
Philipp S et al (2003) TRPC3 mediates T-cell receptor-dependent calcium entry in human T-lymphocytes. J Biol Chem 278(29):26629–26638
Carrillo C et al (2012) Diacylglycerol-containing oleic acid induces increases in [Ca(2+)](i) via TRPC3/6 channels in human T-cells. Biochim Biophys Acta 1821(4):618–626
Tseng PH et al (2004) The canonical transient receptor potential 6 channel as a putative phosphatidylinositol 3,4,5-trisphosphate-sensitive calcium entry system. Biochemistry 43(37):11701–11708
Gamberucci A et al (2002) Diacylglycerol activates the influx of extracellular cations in T-lymphocytes independently of intracellular calcium-store depletion and possibly involving endogenous TRP6 gene products. Biochem J 364(Pt 1):245–254
Schwarz EC et al (2007) TRP channels in lymphocytes. Handb Exp Pharmacol 179:445–456
Lin VH et al (2016) The rapid immunosuppression in phytohemagglutinin-activated human T cells is inhibited by the proliferative Ca(2+) influx induced by progesterone and analogs. Steroids 111:71–78
Spinsanti G et al (2008) Quantitative Real-Time PCR detection of TRPV1-4 gene expression in human leukocytes from healthy and hyposensitive subjects. Mol Pain 4:51
Saunders CI et al (2007) Expression of transient receptor potential vanilloid 1 (TRPV1) and 2 (TRPV2) in human peripheral blood. Mol Immunol 44(6):1429–1435
Bachiocco V et al (2011) Lymphocyte TRPV 1–4 gene expression and MIF blood levels in a young girl clinically diagnosed with HSAN IV. Clin J Pain 27(7):631–634
Bertin S et al (2014) The ion channel TRPV1 regulates the activation and proinflammatory properties of CD4+ T cells. Nat Immunol 15(11):1055–1063
Vasil’eva IO et al (2008) TRPV5 and TRPV6 calcium channels in human T cells. Tsitologiia 50(11):953–957
Majhi RK et al (2015) Functional expression of TRPV channels in T cells and their implications in immune regulation. FEBS J 282(14):2661–2681
Farfariello V, Amantini C, Santoni G (2012) Transient receptor potential vanilloid 1 activation induces autophagy in thymocytes through ROS-regulated AMPK and Atg4C pathways. J Leukoc Biol 92(3):421–431
Amantini C et al (2004) Distinct thymocyte subsets express the vanilloid receptor VR1 that mediates capsaicin-induced apoptotic cell death. Cell Death Differ 11(12):1342–1356
Macho A et al (1999) Selective induction of apoptosis by capsaicin in transformed cells: the role of reactive oxygen species and calcium. Cell Death Differ 6(2):155–165
Sauer K, TJ Jegla (2006) Methods for identifying T cell activation-modulating compounds. USA.
Pottosin I et al (2015) Mechanosensitive Ca2+-permeable channels in human leukemic cells: pharmacological and molecular evidence for TRPV2. Biochim Biophys Acta 1848(1 Pt A): p. 51–9.
Bertin S, Raz E (2016) Transient receptor potential (TRP) channels in T cells. Semin Immunopathol 38(3):309–319
Vassilieva IO et al (2013) Expression of transient receptor potential vanilloid channels TRPV5 and TRPV6 in human blood lymphocytes and Jurkat leukemia T cells. J Membr Biol 246(2):131–140
Sano Y et al (2001) Immunocyte Ca2+ influx system mediated by LTRPC2. Science 293(5533):1327–1330
Guse AH et al (1999) Regulation of calcium signalling in T lymphocytes by the second messenger cyclic ADP-ribose. Nature 398(6722):70–73
Beck A et al (2006) Nicotinic acid adenine dinucleotide phosphate and cyclic ADP-ribose regulate TRPM2 channels in T lymphocytes. FASEB J 20(7):962–964
Gasser A et al (2006) Activation of T cell calcium influx by the second messenger ADP-ribose. J Biol Chem 281(5):2489–2496
Magnone M et al (2012) NAD+ levels control Ca2+ store replenishment and mitogen-induced increase of cytosolic Ca2+ by Cyclic ADP-ribose-dependent TRPM2 channel gating in human T lymphocytes. J Biol Chem 287(25):21067–21081
Fliegert R et al (2017) 2’-Deoxyadenosine 5’-diphosphoribose is an endogenous TRPM2 superagonist. Nat Chem Biol 13(9):1036–1044
Melzer N et al (2012) TRPM2 cation channels modulate T cell effector functions and contribute to autoimmune CNS inflammation. PLoS ONE 7(10):e47617
Launay P et al (2004) TRPM4 regulates calcium oscillations after T cell activation. Science 306(5700):1374–1377
Weber KS et al (2010) Trpm4 differentially regulates Th1 and Th2 function by altering calcium signaling and NFAT localization. J Immunol 185(5):2836–2846
Kerschbaum HH, Kozak JA, Cahalan MD (2003) Polyvalent cations as permeant probes of MIC and TRPM7 pores. Biophys J 84(4):2293–2305
Jin J et al (2008) Deletion of Trpm7 disrupts embryonic development and thymopoiesis without altering Mg2+ homeostasis. Science 322(5902):756–760
Desai BN et al (2012) Cleavage of TRPM7 releases the kinase domain from the ion channel and regulates its participation in Fas-induced apoptosis. Dev Cell 22(6):1149–1162
Kuras Z et al (2012) KCa3.1 and TRPM7 channels at the uropod regulate migration of activated human T cells. PLoS One 7(8): p. e43859.
King LB, Freedman BD (2009) B-lymphocyte calcium influx. Immunol Rev 231(1):265–277
Partiseti M et al (1994) The calcium current activated by T cell receptor and store depletion in human lymphocytes is absent in a primary immunodeficiency. J Biol Chem 269(51):32327–32335
Le Deist F et al (1995) A primary T-cell immunodeficiency associated with defective transmembrane calcium influx. Blood 85(4):1053–1062
Feske S et al (2001) Gene regulation mediated by calcium signals in T lymphocytes. Nat Immunol 2(4):316–324
Liu QH et al (2005a) Distinct calcium channels regulate responses of primary B lymphocytes to B cell receptor engagement and mechanical stimuli. J Immunol 174(1):68–79
Zhu P et al (2009) Mechanism and regulatory function of CpG signaling via scavenger receptor B1 in primary B cells. J Biol Chem 284(34):22878–22887
Numaga T et al (2010) Ca2+ influx and protein scaffolding via TRPC3 sustain PKCbeta and ERK activation in B cells. J Cell Sci 123(Pt 6):927–938
Lievremont JP et al (2005) The role of canonical transient receptor potential 7 in B-cell receptor-activated channels. J Biol Chem 280(42):35346–35351
Buelow B, Song Y, Scharenberg AM (2008) The Poly(ADP-ribose) polymerase PARP-1 is required for oxidative stress-induced TRPM2 activation in lymphocytes. J Biol Chem 283(36):24571–24583
Brandao K et al (2014) TRPM6 kinase activity regulates TRPM7 trafficking and inhibits cellular growth under hypomagnesic conditions. Cell Mol Life Sci 71(24):4853–4867
Schmitz C, Brandao K, Perraud AL (2014) The channel-kinase TRPM7, revealing the untold story of Mg(2+) in cellular signaling. Magnes Res 27(1):9–15
Long EO et al (2013) Controlling natural killer cell responses: integration of signals for activation and inhibition. Annu Rev Immunol 31:227–258
Maul-Pavicic A et al (2011) ORAI1-mediated calcium influx is required for human cytotoxic lymphocyte degranulation and target cell lysis. Proc Natl Acad Sci USA 108(8):3324–3329
Grandclément C et al (2016) NK cells respond to haptens by the activation of calcium permeable plasma membrane channels. PLoS ONE 11(3):e0151031
Rah SY et al (2015) ADP-ribose/TRPM2-mediated Ca2+ signaling is essential for cytolytic degranulation and antitumor activity of natural killer cells. Sci Rep 5:9482
Nguyen T et al (2016) Novel identification and characterisation of Transient receptor potential melastatin 3 ion channels on Natural Killer cells and B lymphocytes: effects on cell signalling in Chronic fatigue syndrome/Myalgic encephalomyelitis patients. Biol Res 49(1):27
Nguyen T et al (2017) Impaired calcium mobilization in natural killer cells from chronic fatigue syndrome/myalgic encephalomyelitis patients is associated with transient receptor potential melastatin 3 ion channels. Clin Exp Immunol 187(2):284–293
Marshall-Gradisnik S et al (2016) Natural killer cells and single nucleotide polymorphisms of specific ion channels and receptor genes in myalgic encephalomyelitis/chronic fatigue syndrome. Appl Clin Genet 9:39–47
HSu Sf et al (2001) Fundamental Ca2+ signaling mechanisms in mouse dendritic cells: CRAC is the major Ca2+ entry pathway. J Immunol 166(10):6126–6133
Vaeth M et al (2015) Ca2+ signaling but not store-operated Ca2+ entry is required for the function of macrophages and dendritic cells. J Immunol 195(3):1202–1217
Maschalidi S et al (2017) UNC93B1 interacts with the calcium sensor STIM1 for efficient antigen cross-presentation in dendritic cells. Nat Commun 8(1):1640
Xiao B et al (2011) Temperature-dependent STIM1 activation induces Ca(2)+ influx and modulates gene expression. Nat Chem Biol 7(6):351–358
Lederman HM, Brill CR, Murphy PA (1987) Interleukin 1-driven secretion of interleukin 2 is highly temperature-dependent. J Immunol 138(11):3808–3811
Hanson DF et al (1983) The effect of temperature on the activation of thymocytes by interleukins I and II. J Immunol 130(1):216–221
Hanson DF (1993) Fever and the immune response. The effects of physiological temperatures on primary murine splenic T-cell responses in vitro. J Immunol 151(1):436–448
Gern JE et al (1991) Temperature is a powerful promoter of interleukin 2 transcription. Cytokine 3(5):389–397
Evans SS, Repasky EA, Fisher DT (2015) Fever and the thermal regulation of immunity: the immune system feels the heat. Nat Rev Immunol 15(6):335–349
Skitzki JJ, Repasky EA, Evans SS (2009) Hyperthermia as an immunotherapy strategy for cancer. Curr Opin Investig Drugs 10(6):550–558
Manzella JP, Roberts NJ Jr (1979) Human macrophage and lymphocyte responses to mitogen stimulation after exposure to influenza virus, ascorbic acid, and hyperthermia. J Immunol 123(5):1940–1944
Knippertz I et al (2011) Mild hyperthermia enhances human monocyte-derived dendritic cell functions and offers potential for applications in vaccination strategies. Int J Hyperthermia 27(6):591–603
Bachleitner-Hofmann T et al (2006) Heat shock treatment of tumor lysate-pulsed dendritic cells enhances their capacity to elicit antitumor T cell responses against medullary thyroid carcinoma. J Clin Endocrinol Metab 91(11):4571–4577
Mukhopadhaya A et al (2007) Localized hyperthermia combined with intratumoral dendritic cells induces systemic antitumor immunity. Cancer Res 67(16):7798–7806
Szöllősi AG et al (2013) Transient receptor potential vanilloid-2 mediates the effects of transient heat shock on endocytosis of human monocyte-derived dendritic cells. FEBS Lett 587(9):1440–1445
Acharya N et al (2017) Endocannabinoid system acts as a regulator of immune homeostasis in the gut. Proc Natl Acad Sci USA 114(19):5005–5010
Nevius E, Srivastava PK, Basu S (2012) Oral ingestion of Capsaicin, the pungent component of chili pepper, enhances a discreet population of macrophages and confers protection from autoimmune diabetes. Mucosal Immunol 5(1):76–86
Varol C, Zigmond E, Jung S (2010) Securing the immune tightrope: mononuclear phagocytes in the intestinal lamina propria. Nat Rev Immunol 10(6):415–426
Assas BM et al (2016) Transient receptor potential vanilloid 1 expression and function in splenic dendritic cells: a potential role in immune homeostasis. Immunology 147(3):292–304
Sumoza-Toledo A et al (2011) Dendritic cell maturation and chemotaxis is regulated by TRPM2-mediated lysosomal Ca2+ release. FASEB J 25(10):3529–3542
Barbet G et al (2008) The calcium-activated nonselective cation channel TRPM4 is essential for the migration but not the maturation of dendritic cells. Nat Immunol 9(10):1148–1156
Perobelli SM et al (2015) Plasticity of neutrophils reveals modulatory capacity. Braz J Med Biol Res 48(8):665–675
Tecchio C, Micheletti A, Cassatella MA (2014) Neutrophil-derived cytokines: facts beyond expression. Front Immunol 5:508
Wang G et al (2016) Oxidant sensing by TRPM2 inhibits neutrophil migration and mitigates inflammation. Dev Cell 38(5):453–462
Salmon MD, Ahluwalia J (2011) Pharmacology of receptor operated calcium entry in human neutrophils. Int Immunopharmacol 11(2):145–148
Edberg JC et al (1995) The Ca2+ dependence of human Fc gamma receptor-initiated phagocytosis. J Biol Chem 270(38):22301–22307
Steinckwich N et al (2007) Potent inhibition of store-operated Ca2+ influx and superoxide production in HL60 cells and polymorphonuclear neutrophils by the pyrazole derivative BTP2. J Leukoc Biol 81(4):1054–1064
Dixit N et al (2011) Migrational guidance of neutrophils is mechanotransduced via high-affinity LFA-1 and calcium flux. J Immunol 187(1):472–481
Heiner I et al (2003) Expression profile of the transient receptor potential (TRP) family in neutrophil granulocytes: evidence for currents through long TRP channel 2 induced by ADP-ribose and NAD. Biochem J 371(Pt 3):1045–1053
McMeekin SR et al (2006) E-selectin permits communication between PAF receptors and TRPC channels in human neutrophils. Blood 107(12):4938–4945
Itagaki K et al (2004) Cytoskeletal reorganization internalizes multiple transient receptor potential channels and blocks calcium entry into human neutrophils. J Immunol 172(1):601–607
Bréchard S et al (2008) Store-operated Ca2+ channels formed by TRPC1, TRPC6 and Orai1 and non-store-operated channels formed by TRPC3 are involved in the regulation of NADPH oxidase in HL-60 granulocytes. Cell Calcium 44(5):492–506
Lindemann O et al (2015) TRPC1 regulates fMLP-stimulated migration and chemotaxis of neutrophil granulocytes. Biochim Biophys Acta 1853(9):2122–2130
Damann N et al (2009) The calcium-conducting ion channel transient receptor potential canonical 6 is involved in macrophage inflammatory protein-2-induced migration of mouse neutrophils. Acta Physiol (Oxf) 195(1):3–11
Yin J et al (2016) Role of transient receptor potential vanilloid 4 in neutrophil activation and acute lung injury. Am J Respir Cell Mol Biol 54(3):370–383
Lange I et al (2008) Synergistic regulation of endogenous TRPM2 channels by adenine dinucleotides in primary human neutrophils. Cell Calcium 44(6):604–615
Ham HY et al (2012) Sulfur mustard primes human neutrophils for increased degranulation and stimulates cytokine release via TRPM2/p38 MAPK signaling. Toxicol Appl Pharmacol 258(1):82–88
Hong CW et al (2010) Lysophosphatidylcholine increases neutrophil bactericidal activity by enhancement of azurophil granule-phagosome fusion via glycine.GlyR alpha 2/TRPM2/p38 MAPK signaling. J Immunol 184(8): p. 4401–13.
Yamamoto S et al (2008) TRPM2-mediated Ca2+influx induces chemokine production in monocytes that aggravates inflammatory neutrophil infiltration. Nat Med 14(7):738–747
Gelderblom M et al (2014) Transient receptor potential melastatin subfamily member 2 cation channel regulates detrimental immune cell invasion in ischemic stroke. Stroke 45(11):3395–3402
Murray PJ, Wynn TA (2011) Protective and pathogenic functions of macrophage subsets. Nat Rev Immunol 11(11):723–737
Hishikawa T et al (1991) Calcium transients during Fc receptor-mediated and nonspecific phagocytosis by murine peritoneal macrophages. J Cell Biol 115(1):59–66
Young JD, Ko SS, Cohn ZA (1984) The increase in intracellular free calcium associated with IgG gamma 2b/gamma 1 Fc receptor-ligand interactions: role in phagocytosis. Proc Natl Acad Sci USA 81(17):5430–5434
Billeter AT et al (2015) TRPA1 mediates the effects of hypothermia on the monocyte inflammatory response. Surgery 158(3):646–654
Zhao JF et al (2016) Transient receptor potential ankyrin 1 channel involved in atherosclerosis and macrophage-foam cell formation. Int J Biol Sci 12(7):812–823
Zhou X et al (2015) Transient receptor potential channel 1 deficiency impairs host defense and proinflammatory responses to bacterial infection by regulating protein kinase Cα signaling. Mol Cell Biol 35(16):2729–2739
Liu D et al (2005b) Increased transient receptor potential channel TRPC3 expression in spontaneously hypertensive rats. Am J Hypertens 18(11):1503–1507
Liu DY et al (2007a) Monocytes from spontaneously hypertensive rats show increased store-operated and second messenger-operated calcium influx mediated by transient receptor potential canonical Type 3 channels. Am J Hypertens 20(10):1111–1118
Liu DY et al (2007b) Increased store-operated and 1-oleoyl-2-acetyl-sn-glycerol-induced calcium influx in monocytes is mediated by transient receptor potential canonical channels in human essential hypertension. J Hypertens 25(4):799–808
Thilo F et al (2008) Association of transient receptor potential canonical type 3 (TRPC3) channel transcripts with proinflammatory cytokines. Arch Biochem Biophys 471(1):57–62
Zhao Z et al (2012) Increased migration of monocytes in essential hypertension is associated with increased transient receptor potential channel canonical type 3 channels. PLoS ONE 7(3):e32628
Wuensch T et al (2010) High glucose-induced oxidative stress increases transient receptor potential channel expression in human monocytes. Diabetes 59(4):844–849
Tano JY et al (2011) Impairment of survival signaling and efferocytosis in TRPC3-deficient macrophages. Biochem Biophys Res Commun 410(3):643–647
Solanki S et al (2014) Reduced endoplasmic reticulum stress-induced apoptosis and impaired unfolded protein response in TRPC3-deficient M1 macrophages. Am J Physiol Cell Physiol 307(6):C521–C531
Solanki S et al (2017) Reduced Necrosis and content of apoptotic M1 macrophages in advanced atherosclerotic plaques of mice with macrophage-specific loss of Trpc3. Sci Rep 7:42526
Kumarasamy S et al (2017) Deep transcriptomic profiling of M1 macrophages lacking Trpc3. Sci Rep 7:39867
Finney-Hayward TK et al (2010) Expression of transient receptor potential C6 channels in human lung macrophages. Am J Respir Cell Mol Biol 43(3):296–304
Riazanski V et al (2015) TRPC6 channel translocation into phagosomal membrane augments phagosomal function. Proc Natl Acad Sci USA 112(47):E6486–E6495
Link TM et al (2010) TRPV2 has a pivotal role in macrophage particle binding and phagocytosis. Nat Immunol 11(3):232–239
Nagasawa M et al (2007) Chemotactic peptide fMetLeuPhe induces translocation of the TRPV2 channel in macrophages. J Cell Physiol 210(3):692–702
Yamashiro K et al (2010) Role of transient receptor potential vanilloid 2 in LPS-induced cytokine production in macrophages. Biochem Biophys Res Commun 398(2):284–289
Entin-Meer M et al (2014) The transient receptor potential vanilloid 2 cation channel is abundant in macrophages accumulating at the peri-infarct zone and may enhance their migration capacity towards injured cardiomyocytes following myocardial infarction. PLoS ONE 9(8):e105055
Entin-Meer M et al (2017) TRPV2 knockout mice demonstrate an improved cardiac performance following myocardial infarction due to attenuated activity of peri-infarct macrophages. PLoS ONE 12(5):e0177132
Zhang Z et al (2017) Transient receptor potential melastatin 2 regulates phagosome maturation and is required for bacterial clearance in Escherichia coli sepsis. Anesthesiology 126(1):128–139
Knowles H et al (2011) Transient receptor potential melastatin 2 (TRPM2) ion channel is required for innate immunity against Listeria monocytogenes. Proc Natl Acad Sci USA 108(28):11578–11583
Di A et al (2017) Role of the phagosomal redox-sensitive TRP channel TRPM2 in regulating bactericidal activity of macrophages. J Cell Sci 130(4):735–744
Wehrhahn J et al (2010) Transient receptor potential melastatin 2 is required for lipopolysaccharide-induced cytokine production in human monocytes. J Immunol 184(5):2386–2393
Di A et al (2011) The redox-sensitive cation channel TRPM2 modulates phagocyte ROS production and inflammation. Nat Immunol 13(1):29–34
Beceiro S et al (2017) TRPM2 ion channels regulate macrophage polarization and gastric inflammation during Helicobacter pylori infection. Mucosal Immunol 10(2):493–507
Wernersson S, Pejler G (2014) Mast cell secretory granules: armed for battle. Nat Rev Immunol 14(7):478–494
Di Capite J, Parekh AB (2009) CRAC channels and Ca2+ signaling in mast cells. Immunol Rev 231(1):45–58
Freichel M, Almering J, Tsvilovskyy V (2012) The Role of TRP Proteins in Mast Cells. Frontiers in Immunology 3:150
Prasad P et al (2008) Secretogranin III directs secretory vesicle biogenesis in mast cells in a manner dependent upon interaction with chromogranin A. J Immunol 181(7):5024–5034
Cohen R et al (2009) Ca2+ waves initiate antigen-stimulated Ca2+ responses in mast cells. J Immunol 183(10):6478–6488
Suzuki R et al (2010) Loss of TRPC1-mediated Ca2+ influx contributes to impaired degranulation in Fyn-deficient mouse bone marrow-derived mast cells. J Leukoc Biol 88(5):863–875
Ma HT et al (2008) Canonical transient receptor potential 5 channel in conjunction with Orai1 and STIM1 allows Sr2+ entry, optimal influx of Ca2+, and degranulation in a rat mast cell line. J Immunol 180(4):2233–2239
Wajdner HE et al (2017) Orai and TRPC channel characterization in FcεRI-mediated calcium signaling and mediator secretion in human mast cells. Physiol Rep 5:5
Solís-López A et al (2017) Analysis of TRPV channel activation by stimulation of FCεRI and MRGPR receptors in mouse peritoneal mast cells. PLoS ONE 12(2):e0171366
Oda S et al (2013) TRPM2 contributes to antigen-stimulated Ca2+ influx in mucosal mast cells. Pflugers Arch 465(7):1023–1030
Vennekens R et al (2007) Increased IgE-dependent mast cell activation and anaphylactic responses in mice lacking the calcium-activated nonselective cation channel TRPM4. Nat Immunol 8(3):312–320
Rixecker T et al (2016) TRPM4-mediated control of FcεRI-evoked Ca(2+) elevation comprises enhanced plasmalemmal trafficking of TRPM4 channels in connective tissue type mast cells. Sci Rep 6:32981
Shimizu T et al (2009) TRPM4 regulates migration of mast cells in mice. Cell Calcium 45(3):226–232
Wykes RC et al (2007) Functional transient receptor potential melastatin 7 channels are critical for human mast cell survival. J Immunol 179(6):4045–4052
Ng NM, Jiang SP, Lv ZQ (2012) Retrovirus-mediated siRNA targeting TRPM7 gene induces apoptosis in RBL-2H3 cells. Eur Rev Med Pharmacol Sci 16(9):1172–1178
Zierler S et al (2016) TRPM7 kinase activity regulates murine mast cell degranulation. J Physiol 594(11):2957–2970
Ali RA, Wuescher LM, Worth RG (2015) Platelets: essential components of the immune system. Curr Trends Immunol 16:65–78
Berna-Erro A et al (2016) Regulation of platelet function by Orai, STIM and TRP. Adv Exp Med Biol 898:157–181
Berna-Erro A et al (2012) Capacitative and non-capacitative signaling complexes in human platelets. Biochim Biophys Acta 1823(8):1242–1251
Brownlow SL, Sage SO (2005) Transient receptor potential protein subunit assembly and membrane distribution in human platelets. Thromb Haemost 94(4):839–845
Harper AG, Brownlow SL, Sage SO (2009) A role for TRPV1 in agonist-evoked activation of human platelets. J Thromb Haemost 7(2):330–338
Rosado JA, Brownlow SL, Sage SO (2002) Endogenously expressed Trp1 is involved in store-mediated Ca2+ entry by conformational coupling in human platelets. J Biol Chem 277(44):42157–42163
López E et al (2013) FKBP52 is involved in the regulation of SOCE channels in the human platelets and MEG 01 cells. Biochim Biophys Acta 1833(3):652–662
Berna-Erro A et al (2014) The canonical transient receptor potential 6 (TRPC6) channel is sensitive to extracellular pH in mouse platelets. Blood Cells Mol Dis 52(2–3):108–115
Albarran L et al (2014) TRPC6 participates in the regulation of cytosolic basal calcium concentration in murine resting platelets. Biochim Biophys Acta 1843(4):789–796
Jardin I et al (2009) Dynamic interaction of hTRPC6 with the Orai1-STIM1 complex or hTRPC3 mediates its role in capacitative or non-capacitative Ca(2+) entry pathways. Biochem J 420(2):267–276
Hassock SR et al (2002) Expression and role of TRPC proteins in human platelets: evidence that TRPC6 forms the store-independent calcium entry channel. Blood 100(8):2801–2811
Vemana HP et al (2015) A critical role for the transient receptor potential channel type 6 in human platelet activation. PLoS ONE 10(4):e0125764
Lopez JJ, Salido GM, Rosado JA (2017) Cardiovascular and hemostatic disorders: SOCE and Ca2+ handling in platelet dysfunction. Adv Exp Med Biol 993:453–472
Szallasi A (ed) (2015) TRP channels as therapeutic targets: from basic science to clinical use. Saint Louis, Elsevier Science & Technology
Parenti A, De Logu F, Geppetti P, Benemei S (2016) What is the evidence for the role of TRP channels in inflammatory and immune cells? Br J Pharmacol 173(6):953–969
Severe Combined Immunodeficiency (SCID) [Internet]. Niaid.nih.gov. 2020 [cited 28 September 2020]. Available from: https://www.niaid.nih.gov/diseases-conditions/severe-combined-immunodeficiency-scid
Szallasi, A (ed.) 2015, TRP channels as therapeutic targets: from basic science to clinical use, Elsevier Science & Technology, Saint Louis. Available from: ProQuest Ebook Central. [26 September 2020].
Iadarola M, Gonnella G (2013) Resiniferatoxin for pain treatment: an interventional approach to personalized pain medicine. The Open Pain Journal 6(1):95–107
Meissner H, Cascella M. Cannabidiol (CBD) [Internet]. Ncbi.nlm.nih.gov. 2020 [cited 29 September 2020]. Available from: https://www.ncbi.nlm.nih.gov/books/NBK556048/
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We are grateful for HCA Wellington Hospital for ongoing support of the Fellowship post and associated research Both SF and CRG have contributed equally to the conception of the paper.
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Highlights
• Calcium signalling is important in immune system activation and maintenance
• Transient receptor operated (TRP) channels are considered a major source of Ca2+ entry into cells
• TRP channels have a diverse subtype and are expressed in most of immune cells
• TRP channels can respond to heat, pH changes, mechanical cues and result in surge of calcium entry
• They offer a potential therapeutic target that can be useful in modulation of immune system in conditions such as allergy, transplantation and cancero
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Froghi, S., Grant, C.R., Tandon, R. et al. New Insights on the Role of TRP Channels in Calcium Signalling and Immunomodulation: Review of Pathways and Implications for Clinical Practice. Clinic Rev Allerg Immunol 60, 271–292 (2021). https://doi.org/10.1007/s12016-020-08824-3
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DOI: https://doi.org/10.1007/s12016-020-08824-3