Adenosine A2B Receptors - Mediated Induction of Interleukin-6 in Skeletal Muscle Cells/Iskelet Kas Hucrelerinde Adenozin A2B Reseptor Aracili Interlokin-6 Induksiyonu.
Adenosine is a key endogenous signalling molecule produced by all types of cells, and documented as a major local regulator of tissue function. Adenosine can modulate cellular functions via binding to the four members that belong to the cell surface G protein-coupled receptor superfamily (P1 receptors), including adenosine A1, A2A, A2B and A3 receptor subtypes. (1) The adenosine A2A and A2B receptors share a relatively high homology and are coupled to Gs, (2) leading to increased levels of cyclic adenosine monophosphate (cAMP). In addition, the adenosine A2B receptors has been shown to couple to Gq, (3) thereby regulating intracellular calcium levels. In general, the adenosine A2B receptors have a lower affinity for adenosine. (4) Among adenosine receptors, adenosine A2B receptor requires higher concentrations of adenosine in many different cellular types for activation than the adenosine A1, A2, and A3 receptors subtypes. (1) Thus, adenosine A2B receptor can mostly be activated when interstitial adenosine concentrations are increased as a result of tissue hypoxia, injury, inflammation and cell stress, (5) even though adenosine A2B receptors are likely to remain silent under normal physiological conditions. (5)
Within the skeletal muscle tissue, adenosine potentially plays important roles in a large number of physiological processes (such as glucose homeostasis and insulin sensitivity). (6,7,8) Adenosine A2B receptor, in particular, has recently been proposed to act as a potentially functional adenosine receptor in skeletal muscle, (9) however, its pharmacology and biological function(s) remain largely unexplored. Recently, evidence has been accumulated, suggesting that adenosine is a significant modulator of inflammation in response to various stimuli. (10) There is growing evidence that the adenosine system plays an important role in regulating inflammation. Indeed, specific targeting of its components such as the adenosine A2B receptor continues to provide avenues towards the development of potential treatments for at least inflammatory diseases and related disorders, including insulin resistance and type 2 diabetes.
Inflammation is an important contributor to the pathophysiology of diseases related to skeletal muscle dysfunction. (11) Proinflammatory cytokines are important contributors to chronic inflammation found in many diseases. (12) One of these inflammatory cytokines is interleukin-6 (IL-6). IL-6, a mediator of inflammation, is a pleiotropic cytokine that has been proposed to be involved in both immune- and nonimmuno-regulation in most cell types and tissues outside the immune system, including skeletal muscle tissue. (13) Indeed, IL-6 is a biologically active cytokine which has a broad range of activities regulating not only inflammatory responses but also in cell proliferation, differentiation, growth and metabolism in skeletal muscle cells.14,15,16
Elevated levels of cytokines, such as IL-6 also seems to be the main pro-inflammatory cytokine involved in the pathophysiology of insulin resistance and type 2 diabetes and obesity. (17,18,19,20) Elevated circulating IL-6 levels have been observed in obese individuals and type 2 diabetic patients. (21) Several association studies and numerous clinical studies have suggested that IL-6 plasma concentration are associated with insulin resistance and increased with weight gain. (20) Moreover, some reports provide evidences for high circulating IL-6 levels, as a risk factor for the manifestation of type 2 diabetes. (22) Hence, high circulating IL-6 levels might contribute to the progression of skeletal muscle damage and dysfunction in chronic diseases and might exert pathogenic effects in these diseases. Recent evidence has demonstrated that significant levels of IL-6 is produced in and released from skeletal muscle cells per se in the absence of inflammation and stimulated by complex signalling cascades. (23,24) IL-6 is therefore considered as a myokine and its IL-6 signalling in skeletal muscle tissue has been suggested to be associated with skeletal muscle growth, myogenesis, and regulation of energy metabolism. (13)
Adenosine modulates the functions of many inflammatory cells such as macrophage. (25,26) Moreover, increasing evidence suggests that adenosine signalling plays a role in regulating cytokine network processes. In addition, adenosine increases the release of IL-6 from various cells. (27) In previous studies, it has been reported that skeletal muscle tissue is a source of IL-6 production. (23) As discussed above, increasing evidence indicates that skeletal muscle plays an active role in the inflammatory process by secreting cytokines. However, the effect of adenosine or adenosine analogue on inflammatory cytokine expression by skeletal muscle cells has not been determined. At the same time, adenosine-based approaches are currently being developed for the treatment of various diseases where inflammatory modulation is a key component. (28) Generally, adenosine receptors, in particular adenosine A2B receptors, are increasingly recognized as important orchestrators of inflammation. In fact, adenosine A2B receptor activation enhances the inflammatory responses of mast cells, fibroblasts, epithelial cells and smooth muscle cells. (29) However, the role of this receptor in skeletal muscle cells is yet unexplored.
Extensive in vitro and in vivo studies have identified potent pro-inflammatory or/and anti-inflammatory functions for all adenosine processes. Recent interest in the endocrine skeletal muscle has potentially revealed the presence of a functional adenosine system in skeletal muscle, however, the effects of adenosine and adenosine receptors modulation on downstream inflammatory signalling, in particular IL-6, still remains unclear. In the current study, an adenosine receptors, in particular adenosine A2B receptors, agonist and antagonist were evaluated for their effects on IL-6 messenger RNA (mRNA) expression level.
MATERIALS AND METHODS
N-ethylcarboxamidoadenosine (NECA), forskolin, 8-[4-[4-(4-chlorophenzyl)piperazide-1-sulfonyl) phenyl]]-1-propylxanthine (PSB 603) and 2-(4-[2-carboxyethyl]-phenethylamino) adenosine-52 -nethyluronamide (CGS21680) were obtained from Tocris Bioscience, UK; dimethyl sulphoxide reagent was sourced from Santa Cruz, USA; and Trizol and charcoal stripped serum were brought from Applied Biosystem, USA. Maxima Probe quantitative polymerase chain reaction (qPCR) Master Mix (2X) and Thermo Scientific RevertAid First Strand complementary DNA (cDNA) Synthesis were obtained from Thermo Scientific Company, USA. RNeasy Mini Total RNA Purification kits and RNase-Free DNase Set were brought from Qiagen, Germany. Fetal bovine serum (FBS) was supplied by Capricorn Scientific, USA. Horse serum was from Sigma company, Germany. Ham-F 10 was sourced from PAA Company, USA. Dulbecco's modified essential medium (DMEM) was from Caisson, USA.
Rat L6 skeletal muscle cell line and myoblast cell line were originally obtained from the American Type Culture Collection (USA). Cells were maintained as an attached monolayer culture in DMEM with high glucose (4500 mg/L) and L-glutamate supplemented with 10% (v/v) heat-inactivated FBS and 100 [micro]g/mL penicillin-streptomycin. Cells were incubated at 37[degrees]C in a 90% humidified atmosphere of 5% C[O.sub.2]. The cells were passaged upon reaching a state of approximately 60%-70% confluency, and the medium was changed three times per week (Figure 1).
Confluent cells in 25 c[m.sup.2] flasks were cultured for a further 14 days (to allow myotube formation), according to the protocol mentioned in (30) with slight modifications (Figure 2). 70%-90% confluent myotubes (approximately 2 weeks in culture) were serum-starved (incubated in Ham-F 10 medium alone) for 19 hours or 7 days. Then, cells (Figure 2) were treated for 1 hour with vehicle (0.1% dimethyl sulphoxide), NECA 100 nM and 10 [micro]M, PSB 603 100 nM, 1 [micro]M and 10 [micro]M, forskolin 100 nM, NECA and PSB 603 (cells were pre-treated with PSB 603 for 10 min prior to the addition of NECA). Following treatment, cells were washed with ice cold PBS, then lysed with TRIzol (Invitrogen product name) (2 mL per flask).
RNA extraction and cDNA synthesis
Rat L6 skeletal muscle cells (in 25 c[m.sup.2] flasks) were scraped in 2 mL of ice cold TRIzol (Applied Biosystems, USA) and RNA was then isolated according to the manufacturer's instructions. Total RNA clean-up and on-column DNAse digestion was performed using RNeasy purification columns (Qiagen, Germany). RNA concentration and purity was determined using a spectrophotometer (JENWAY Genova Nano). For cDNA synthesis, 500 ng of total RNA was reverse-transcribed using RevertAid First Strand cDNA Synthesis (Thermo Scientific, USA) in a total volume of 20 [micro]L for 5 min at 25[degrees]C, followed by 1 hour at 42[degrees]C, and the reaction was terminated at 70[degrees]C for 5 min.
Taqman quantitative real-time polymerase chain reaction The relative standard curve method based on Taqman quantitative real-time PCR (qRT-PCR) was used to quantify gene expression. Samples were prepared in a total reaction volume of 25 [micro]L [13 [micro]L Maxima Probe qPCR Master Mix 2X reagent, 1.5 [micro]L forward primer (10 [micro]M), 1.5 [micro]L reverse primer (10 mM), 2.5 [micro]L Probe (2 [micro]M), 5 [micro]L water, and 5 [micro]L cDNA]. The qRT-PCR analysis was performed using a RT-PCR system (Applied Biosystems, USA). Gene expression was determined relative to reference gene, TATA. Primers and probes for all genes (Table 1) were designed using Primer Express software (Applied Biosystems, USA) and synthesised by Integrated DNA Technologies, Inc., USA. The standard curve method was used, with a slope between -3.2 and -3.6 and [R.sup.2] values of more than 99%, indicating that amplification efficiency was nearly 100%.
Data are expressed as means [+ or -] standard error of mean of triplicate or quadruplicate wells generated from at least three independent experimental group. All mRNA data were analysed using one-way ANOVA with a Tukey test. Analysis was performed using GraphPad Prism, version 5.03 (GraphPad Software Inc). The level of statistical significance was set at p<0.05.
N-ethylcarboxamidoadenosine stimulates IL-6 mRNA gene expression in skeletal muscle cells
To assess whether stimulation of adenosine A2 receptors could induce IL-6 mRNA gene expression in rat L6 skeletal muscle cells, the effects of NECA were relatively quantified using a non-selective adenosine receptor agonist on IL-6 mRNA gene expression by qRT-PCR (probe-based). Starved skeletal muscle cells were incubated with NECA (10 [micro]M) for one hour, 3 hours and 24 hours, and mRNA gene expression of IL-6 was subsequently quantified.
Incubation of one week starved L6 skeletal muscle cells with 10 [micro]M of the non-selective adenosine analogue NECA for one hour increases significantly (p<0.001) mRNA gene expression of IL-6 (an average around 2.3-fold change compared to vehicle) (Figure 3). Moreover, incubation of 19 hours starved L6 skeletal muscle cells with 10 [micro]M (but, not 100 nM) of the non-selective adenosine analogue NECA for 3 hours (but, not for either one hour or 24 hours) increases significantly (p<0.05) mRNA gene expression of IL-6 (an average around 2.2-fold change compared to vehicle) (Figure 4).
Adenosine A2B receptors mediates N-ethylcarboxamidoa-denosine-induced IL-6 mRNA gene expression in skeletal muscle cells
To determine which subtype of adenosine A2 receptors mediate the increase IL-6 mRNA gene expression level, the adenosine receptor agonist CGS21680 (subtype A2A selective) was used. The concentration applied for CGS21680 could selectively activate the indicated subtype (Ki=27 nM). (31)
Furthermore, since no selective agonist exists for adenosine A2B receptors, the effect of a selective antagonist to the adenosine A2B receptors (PSB 603) was investigated. PSB 603 exhibits a strong affinity to adenosine A2B receptors and very weak affinity to three other adenosine receptors subtypes. Adenosine A2B receptors display >17000-fold selectivity over other adenosine receptors (Ki values: 0.553, >10000, >10000, and >10000 nM for A2B, A1, A2A, and A3 receptors, respectively). (32)
As shown in Figure 3 and Figure 4a, 4b, NECA (10 [micro]M) increases the mRNA gene expression level of IL-6 significantly. In contrast, the adenosine A2A receptor selective agonist CGS21680 (100 nM) does not cause a significant increase in the mRNA gene expression level of IL-6.
To investigate the effect of a selective adenosine A2B receptor antagonist, PSB 603, rat L6 skeletal muscle cells were incubated with 10 [micro]M NECA in combination with PSB 603 (which was added to cells 10 min prior to adding NECA) in concentrations of 100 nM, 1 [micro]M or 10 [micro]M, which blocks IL-6 mRNA gene expression significantly (p<0.01, p<0.05 and p<0.05, respectively) (Figure 3, 4a, 4b).
It is interesting to note that treatment the 19 hours starved cells for 24 hours with PSB 603 and NECA up-regulates IL-6 mRNA expression level. However, treatment the 19 hours starved cells for 24 hours with either PSB 603 or NECA alone does not modulate the IL-6 mRNA expression level.
Collectively, these results indicate that adenosine A2B receptors are the functionally expressed receptors of adenosine A2 receptors in skeletal muscle, whereas no functional expression of the adenosine A2A receptors was detected using mRNA gene expression levels for IL-6 as a functional readout.
It is worth to mention that the adenosine A2B receptors antagonists/inverse agonists, PSB 603 (at 100 nM, 1 [micro]M and 10 [micro]M), does not mediate a significant change in baseline IL-6 mRNA gene expression levels in skeletal muscle cells (Figure 3, 4). However, even though treatment the 19 hours starved skeletal muscle cells with 100 nM NECA does not up-regulates the IL-6 mRNA expression, incubation that cells with 100 nM NECA in combination with PSB 603 (which was added to cells 10 min prior to adding NECA) decrease baseline IL-6 mRNA gene expression level significantly (p<0.01) (Figure 4a, 4b).
Role of cyclic adenosine monophosphate pathway in the mRNA gene expression of IL-6
In previous studies, activation of adenosine A2B receptors in skeletal muscle by NECA increased cAMP accumulation, (33,34) and the NR4A mRNA gene expression. (9)
Experiments were conducted to investigate if the adenylyl cyclase pathway is involved in the activation of IL-6 transcription profile in skeletal muscle cells. In rat skeletal muscle cells, transcripts of adenosine A1, A2, and A3 receptors were detected. (33,34) In addition to gene expression, using cAMP accumulation as a functional readout, it has been confirmed the presence of functional adenosine A2B receptors in skeletal muscle cells, (33,34) whereas the presence of functional adenosine A1, A2A, and A3 receptors were not detected. Furthermore, using NR4A expression as a functional downstream signalling readout, it has been confirmed the presence of functional adenosine A2B receptors in skeletal muscle cells, (9) whereas the presence of functional adenosine A2A receptors were not detected.
Many physiologic roles of adenosine are mediated through cell surface adenosine receptors. In this present study, i provided evidence that the adenosine A2B receptors subtype mediates the effect of the adenosine analogue NECA on IL-6 expression. Our results show the following:
(1) The nonselective agonist NECA increases the expression of IL-6, whereas selective agonist for adenosine A2A receptors CGS21680 had no effect. This agonist is very potent and, at this concentration (100 nM), it fully activates their cognate receptors without significant activation of the adenosine A2B receptors. (31)
For this purpose, the adenylyl cyclase activator forskolin was used in the present study to understand the potential role of the cAMP pathway in NECA induces IL-6 mRNA gene expression in skeletal muscle.
Forskolin (100 nM and 1 [micro]M) increases the expression of IL-6 significantly (an average around 3.5 and 2.4 fold change compared to vehicle, respectively) (Figure 3, 4a, 4b), a result similar to that of NECA. These findings support the idea that the cAMP pathway plays an important role in NECA-induces IL-6 mRNA gene expression. However, treatment the 19 hours starved skeletal muscle cells for 24 hours with forskolin (1 [micro]M) does not induce the expression of IL-6.
The novel findings of this present study are that stable adenosine analogue NECA increases the expression of IL-6 by skeletal muscle cells, and that this effect of NECA is mediated by the adenosine A2B receptor subtype. To our knowledge, this is the first paper on the effect of adenosine analogue and its receptor subtype on inflammatory cytokine expression by skeletal muscle cells, and it may represent a novel mechanism for the role of adenosine analogue in skeletal muscle cytokine network. Several reports demonstrated the presence of adenosine receptors in skeletal muscle cells from different species. (35) This is the rationale for determining the effect of this agonist at a concentration of 100 nM.
(2) The effects of NECA on cytokine expression are dependently blocked by selective antagonist of the adenosine A2B receptors subtype, PSB 603. Collectively, these findings provide strong evidence for the role of the adenosine A2B receptors in up-regulating the expression of IL-6 caused by NECA.
These results are in agreement with those obtained in various cell types of different origins, including intestinal (36) and airway epithelial cells, (37) macrophages, (38,39) pulmonary fibroblasts, (40) bronchial smooth muscle cells, (41) astrocytoma cells, (42) astroglioma cells, (43) astrocytes (44) and cardiomyocytes, (45) osteoblasts, (46) and pituitary folliculostellate cells, (47) that all show NECA-induced IL-6 release was via the adenosine A2B receptors. Moreover, numerous in vivo studies have also demonstrated that adenosine A2B receptors activation can stimulate the release of IL-6, an important pro-inflammatory cytokine. (36,48) Accordingly, adenosine A2B receptors have been suggested to mediate the pro-inflammatory actions of adenosine. Yet, those results in this current study and above studies contradict a gene-knockout study in which it was reported that adenosine A2B receptors knockout mice show evidence of increased inflammation at baseline, in that levels of cytokines such as IL-6 were elevated in naive adenosine A2B receptors knockout mice. (39,49)
In this present study, cAMP elevation in skeletal muscle cells induces IL-6 expression in a similar to that effect of NECA is expected, because it is well documented that the Gs protein-coupled adenosine A2B receptor increases the formation of cAMP. In fact, several studies have supported the role of cAMP pathway. Indeed, some researchers have also shown that cAMP elevation induced IL-6 release in various cells. (50,51,52) In addition, recently, it has been demonstrated that NECA increased cAMP concentration in rat skeletal muscle cells. (33,34) These data suggest that adenosine A2B receptors mediate IL-6 expression through mainly a cAMP-dependent mechanism in rat skeletal muscle cells, although future studies are recommended to validate and investigate the exact signaling mechanism.
It is interesting to note that PSB 603 might act as a positive allosteric modulator for adenosine A2B receptors in case of treatment the 19 hours starved skeletal muscle cells with PSB 603 and NECA (10 [micro]M but not 100 nM) (cells were pre-treated with PSB 603 for 10 min prior to the addition of NECA) for 24 hours (but not 1 or 3 hours). In this situation, it seems that cAMP is not involved in the (NECA 10 [micro]M and PSB 603) induces IL-6 expression as forskolin does not induce that. However, whether or not Gq-signalling or other downstream targets is involved in the regulation of (NECA 10 [micro]M and PSB 603) induces IL-6 expression in skeletal muscle cells needs to be investigated further. In the literature, the adenosine A2B receptors driven production of these pro-inflammatory molecules has been attributed to both Gs and Gq pathways. (36,53)
It is reported in the current study that the NECA effect in Figure 3 is made on skeletal muscle cells that are starved for one week, and this is not physiologically relevant. However, the idea behind experimenting such a condition is that starvation might change the rate of RNA synthesis for IL-6 and/or the expression level of adenosine receptors subtypes. (54,55)
It should be highlighted that the 1 hour and 24 hours NECA stimulations did not work, but the 3 hours did on 19 hour-starved cells (Figure 4). The reason behind that that adenosine A2B receptors, as a G-protein coupled receptor, might need enough time to couple to G-protein and, then induce downstream signaling pathway to target IL-6 mRNA gene expression. While the cells concentrations of NECA do not explain the disparate effects of 3 hours and 24 hours treatment, duration of exposure may be a pivotal factor. The demonstration of adenosine A2B receptors expression level/density in skeletal muscle cells might fulfill a necessary condition for the specific action of a adenosine A2B receptors activator to alter expression of adenosine A2B receptor-responsive genes.
It is difficult to determine what a 2.5-fold increase in IL-6 transcripts at a single time point translates into IL-6 production. However, it is important to suggest that the relationship between the protein synthesis and RNA content in skeletal muscle cells might not be in a definite linear correlation. (56) One may argue that the changes in expression of IL-6 involved in inflammation observed in the present study may be transient and not reflected by changes in protein expression and therefore have little significance for inflammation developing in response to stable adenosine analogue NECA. The main reason total protein measurements were not included in the present study is the short duration of the treatment (i.e. 1 hour, 3 hours and up to 24 hours), which in line with my main aim was employed to identify the transcriptional events that precede the induction of inflammation under the activation of adenosine A2B receptors. It has shown previously (57) that most of the inflammatory transcripts studied (such as IL-6) in skeletal muscle cells are not translated into protein within that time frame. Therefore my future studies using longer durations of NECA (after 24 hours) will be recommended to investigate the translational changes in response to treatment. The use of primary skeletal muscle cells in future studies may also provide a better opportunity to investigate both transcriptional and translational changes over the time course of prolonged durations of NECA (up to four days).
In this regard, it is clear that adenosine receptors, in particular adenosine A2B receptors, are important molecular targets for adenosine-based therapeutics for inflammation. Approaches utilizing adenosine receptor-based therapeutics will be dependent on further investigation of signalling mechanism for adenosine A2B receptors in skeletal muscle, timing and duration of treatment, and monitoring of beneficial and adverse effects.
I showed that the activation of adenosine A2B receptors increases the expression of IL-6 in time- and concentration-dependent manners in rat skeletal muscle cells. These findings provide a novel mechanism whereby adenosine analogue acts as a pro-inflammatory mediator in the skeletal muscle tissue. Furthermore, these findings suggest that the adenosine A2B receptor antagonist at acute early states might have a potential therapeutic utility for the treatment of inflammatory-related skeletal muscle dysfunction.
I would like to thank Abdul Hameed Shoman Foundation for supporting scientific research in Jordan and for their kind generous financial support of this project. Without this support, I could not perform this work. Indeed, this project was supported by grants from mainly Abdul Hameed Shoman Foundation (Grant number 12/2015) and Philadelphia University.
Conflict of Interest: No conflict of interest was declared by the author.
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Department of Clinical Sciences, Faculty of Pharmacy, Philadelphia University, Amman, Jordan
(*) Correspondence: E-mail: email@example.com
Received: 02.06.2016, Accepted: 28.07.2016
Table 1. List of gene primer and probe sequences Gene Sequences (5'[right arrow]3') Probe: 5'-CTCTCCGCAAGAGACTTCCAGCCAGTT-3' IL-6 Forward primer: 5'-GCCCTTCAGGAACAGCTATGA-3' Reverse primer: 5'-TGTCAACAACATCAGTCCCAAGA-3' Probe 5'-TCCCAAGCGGTTTGCTGCAGTCA-3' TATA - BOX Forward primer 5'-TTCGTGCCAGAAATGCTGAA-3' Reverse primer 5'-GTTCGTGGCTCTCTTATTCTCATG-3' Gene Amplicon size (bp) IL-6 80 TATA - BOX 73 IL-6: Interleukin-6
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|Title Annotation:||ORIGINAL ARTICLE|
|Publication:||Turkish Journal of Pharmaceutical Sciences|
|Date:||Apr 1, 2017|
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