Abstract
Melatonin (MLT) reportedly reduces side effects associated with certain antineoplastic agents. Accordingly, we investigated the effect of MLT on cisplatin (CP)-induced gastric emptying (GE) delay. Mice were intraperitoneally pretreated with vehicle (ethanol 5%; control group), MLT (5, 10, or 20 mg/kg), or N-acetylcysteine (NAC; 150 mg/kg), followed by CP treatment (5 mg/kg). Pharmacological modulation was analyzed using relevant receptor antagonists (luzindole: non-selective MT1/MT2 antagonist; 5 mg/kg or 4-P-PDOT: selective MT2 antagonist; 4 mg/kg) before treatment with MLT plus CP. All treatments were performed once daily for three days. GE was assessed using phenol red. Gut morphology was examined using scanning electron microscopy and optical microscopy. Compared with the control, CP decreased GE. Pretreatment with NAC and MLT (5 and 10 mg/kg) did not prevent CP-induced gastric dysmotility; however, pretreatment with 20 mg/kg MLT prevented this effect. In addition, luzindole and 4-P-PDOT suppressed MLT-mediated gastroprotection against cytotoxic effects of CP. CP caused degeneration of the gut mucosa, which was attenuated by MLT treatment. Thus, 20 mg/kg MLT prevented the GE delay and decreased CP-induced adverse effects on the gut mucosa. In addition, the gastroprotective activity was mediated via the MT2 receptor.
Keywords: Gastric emptying; Gut motility; Gastrointestinal; Chemotherapy
INTRODUCTION
Cisplatin (cis-diamminedichloroplatinum II; CP) is one of the most effective and widely employed drugs for treating adult and pediatric cancers, including testicular, ovarian, bladder, breast, head, neck, and gastric cancers (Babu et al., 2019; Kim et al., 2019). However, treatment with CP has been associated with the development of serious adverse effects, impacting the kidney, heart, liver, reproductive, nervous, and gastrointestinal (GI) systems (Vera et al., 2011; Viana-Cardoso et al., 2011; Madhu, Reddy, Reddy, 2015).
Notably, CP-induced GI dysfunctions, such as gastroparesis, gastric distension, mucositis, diarrhea, and delayed gastric emptying (GE), are caused by peripheral neuropathy and/or local tissue damage (Cabezos et al., 2010; Vera et al., 2011; Viana-Cardoso et al., 2011; Pini et al., 2016; Babu et al., 2019), triggered by nuclear and mitochondrial DNA platination, along with the increased production of reactive oxygen species (ROS) and decreased activity of antioxidant enzymes (Ko et al., 2016; Shahid, Farooqui, Khan, 2018). Therefore, treatment with antioxidant agents can ameliorate CP-mediated toxic effects on the GI tract (Ko et al., 2016; Riyaz et al., 2017).
N-acetylcysteine (NAC) contains a sulfhydryl group that acts as a source of cysteine for glutathione (GSH) synthesis, affording long-term antioxidant protection. NAC is administered to patients at relatively high levels, exhibiting an excellent toxicity profile, and is currently used in clinical practice (Monti et al., 2017). In addition, NAC possesses anti-inflammatory effects (Anand et al., 2015; Abdel-Wahab, Moussa, 2019). Furthermore, NAC can potentiate the effects of antineoplastic agents by decreasing the growth of tumor cells, in addition to mitigating the adverse effects of chemotherapy (Anand et al., 2015; Muldoon et al., 2015). Melatonin (N-acetyl-5- methoxytryptamine; MLT) is another efficient antioxidant agent that reduces toxic reactions associated with drugs and other processes known to generate free radicals (Reiter et al., 2016; Farhood et al., 2019).
MLT, a hormone primarily synthesized in the pineal gland, regulates circadian rhythms, immune responses, and reproductive functions (Tamura et al., 2013; Reiter et al., 2016). Additionally, MLT can be synthesized in various peripheral organs, including bone marrow, blood cells, skin, and the GI tract (Singh, Jadhav, 2014). It is well-established that GI enterochromaffin cells can secrete MLT, presenting a concentration that surpasses the blood (10- to 100-fold) and pineal gland (approximately 400-fold). Accordingly, it can be suggested that MLT may also play an important role in the GI system (Konturek et al., 2007).
MLT, a lipophilic compound, diffuses rapidly across biological membranes to act on the muscular mucosa or GI myenteric plexus (Chen et al., 2011; Söderquist, Hellström, Cunningham, 2015), promoting the regulation of GI motility, epithelial protection, epithelial permeability, vascular function, and entero-pancreatic endocrine crosstalk to impact metabolic control (Thor et al., 2007; Söderquist, Hellström, Cunningham, 2015). In addition, MLT maintains gut regional blood circulation, increases bicarbonate release from the gastric mucosa, decreases neutrophil infiltration, and reduces the release of inflammatory cytokines induced by deleterious stimuli on the GI tract, for example, drugs (Flemström, Sjöblom, 2005; Shahrokhi et al., 2016). These MLT effects are possibly mediated via interactions with membrane receptors type 1 (MT1) and/or type 2 (MT2), known to be present in the GI tract (Thor et al., 2007; Söderquist, Hellström, Cunningham, 2015). However, the effects of MLT on CP-induced GI toxicity, as well as the underlying mechanisms, remain unclear.
Given that MLT modulates chemotherapy-induced toxicity, improves chemotherapeutic efficacy (Lu et al., 2019), and can be employed as a complementary treatment to enhance the quality of life and survival of patients undergoing chemotherapy (Ginzac et al., 2020), we aimed to investigate the effect of MLT on GI motility in an experimental mouse model of CP-induced dysautonomia. Additionally, we examined the role of MT1 and/or MT2 receptors in mediating the potential effects of MLT on gastroparesis.
MATERIAL AND METHODS
Animals
The present study was conducted in accordance with the guidelines of the Ethics Committee on Animal Use at the Federal University of São Francisco Valley (protocol number 0022/220515). Adult female Swiss mice (n=58), 8-week-old and weighing 30-45 g, were housed in an air-conditioned atmosphere at 25°C with alternating 12 h/12 h light-dark cycles. Animals were maintained on a diet of standard pellets (Presence Rats and Mice® - Agribands Purina do Brasil Ltda) and water ad libitum.
Experimental Study
Phase I - Effect of different melatonin doses on cisplatin-induced GE delay
Mice (n=30) were randomly divided into six experimental groups (five animals per group) and treated for three days as follows: the first group, i.e., the control group, was administered an intraperitoneal injection (i.p.) of the vehicle (ethanol 5% in NaCl 0.15 M, 0.15 mL/ mouse), once daily, over three days (grouped termed “S”). The second group received CP (5 mg/kg body weight, i.p.; Libbs Farmacêutica Ltda, São Paulo, Brazil) 30 min after vehicle administration, once daily, for three days (total of 15 mg/kg CP). Mice in the third, fourth, and fifth groups were treated with MLT (Sigma Aldrich Chemical Co., St. Louis, MO, USA) at 5, 10, or 20 mg/kg body weight (i.p.), respectively, once daily; then, mice were administered CP (5 mg/kg body weight, i.p.) 30 min after the MLT injection, once daily for three days (total of 15 mg/kg CP). Finally, the positive control (sixth group) was administered the antioxidant NAC (150 mg/kg body weight; i.p.) before CP, replacing MT pretreatment.
In the present study, the CP dose employed was as reported by Viana-Cardoso et al. (2011) and Shin et al. (2018); this dose sufficiently induced GE delay by dysautonomia. The dose of MLT was based on previous studies indicating its protective effects (Kasimay et al., 2005; Konturek et al., 2007; Barberino et al., 2017; Kim et al., 2019). The NAC dose utilized was described by Anand et al. (2015) and Barberino et al. (2017).
Evaluation of gastric emptying of the liquid test meal
GE was measured in mice subjected to an 18 h fasting period, with free access to water for up to 2 h prior to experimentation. Then, all mice were fed a liquid test meal (0.3 mL phenol red, 0.5 mg/mL in 5% glucose) 24 h after the last injection. Over 10 min intervals, mice were sacrificed by cervical dislocation, and their stomach contents were emptied and measured. Briefly, after laparotomy, the gut was quickly ligated and divided into two consecutive segments: the stomach and small intestine. The volume of each segment was calculated by flooding it within a graduated cylinder containing 20 mL of NaOH (0.1 N). After homogenization of each segment, proteins were precipitated using 200 µL of 20% trichloroacetic acid. After centrifugation, 600 µL of the supernatant was added to 800 µL of 0.5 N NaOH. Samples were spectrophotometrically measured at 560 nm to construct dilution curves by plotting dye concentrations against optical densities. The amount of dye emptied by the stomach was expressed as a percentage (Silva et al., 2015).
Gut morphology examined by scanning electron microscopy (SEM)
For assessing gut morphology using SEM, another set of mice (n=9) was randomly divided into three experimental groups (three animals per group) and treated once daily for three days with vehicle (ethanol 5% in NaCl 0.15 M; control group: S), CP (5 mg/kg body weight), or 20 mg/kg MLT plus CP (which produced the best results), as described previously. Twenty-four hours after the last injection, mice were sacrificed to assess gut morphology, as described by Lu et al. (2017). Briefly, 2 cm distal to the pylorus, 1 cm duodenal sections were harvested and washed with 0.1 M phosphate buffer and phosphate-buffered saline, fixed in 3% glutaraldehyde and 1.5% paraformaldehyde, 0.1 M phosphate-buffered saline, pH 7.4. Then, sections were sequentially fixed in a 1% magnesium tetroxide solution, dehydrated in a graded series of ethanol, and stored in a vacuum desiccator for 10 h. The samples were metalized with gold for 120 s in the Quorum Q15OR ES metallizer, forming a 50 nm metallic layer. We employed a scanning electron microscope (Tescan, Vega 3XM) to obtain SEM micrographs, with a 16 mm working distance, standard amplitudes, and accelerating voltage of 5 kV in the secondary electron detection mode.
Gut morphology examined by optical microscopy
Twenty-four hours after the last injection, 1- to 2-cm duodenal samples were harvested (at least 2 cm distal to the pylorus) from three animals per group (S, CP, or 20 mg/kg MLT plus CP), fixed in 10% buffered formalin (Dinâmica, São Paulo, Brazil), dehydrated in increasing concentrations of ethanol (Dinâmica), and clarified in xylene (Dinâmica). After paraffin embedding (Dinâmica), the fragments were cut into 5-μm thick serial sections, mounted on glass slides, and stained with hematoxylin and eosin (HE; Vetec, São Paulo, Brazil) to examine morphological changes under a light microscope (Nikon, Tokyo, Japan) (Uranga et al., 2017).
Phase II - Effect of administering melatonin receptor 1 and 2 (MT1 and MT2) antagonists before melatonin treatment on cisplatin-induced GE delay
We next evaluated the possible mechanism of the protective effect of MLT on CP-induced GE delay. Accordingly, pharmacological modulation via MT1 and MT2 receptors was analyzed by administering MT1 and/ or MT2 antagonists. In this experiment, the first, second, and third groups were control (S), CP, and MLT 20 mg/ kg plus CP, which afforded the best results. All groups were described in phase I. For the fourth and fifth groups, mice (n=10; five animals per group) were pretreated with luzindole (LZD), a non-selective MT1/MT2 antagonist (5 mg/kg body weight, i.p.; Sigma Aldrich Chemical Co.) or 4-phenyl-2-propionamidotetralin (4-P-PDOT), a selective MT2 antagonist (4 mg/kg body weight, i.p.; Sigma Aldrich Chemical Co.), respectively. MLT (20 mg/kg body weight, i.p.) was administered after 15 min. Then, 30 min after the MLT injection, mice received CP (5 mg/kg body weight, i.p.). The treatment was performed once daily for three days. The doses of LZD and 4-P-PDOT were as reported by Chen et al. (2014).
As described in phase I, mice were sacrificed for GE assessment 24 h after the last injection, as described previously (Silva et al., 2015).
Statistical analysis
Data are presented as the mean ± standard error for each group. One-way analysis of variance (ANOVA) was performed for multi-group comparisons, followed by Tukey’s test. Statistical significance was set at P < 0.05. All statistical analyses were performed using GraphPad Prism software (version 6.0; GraphPad, San Diego, CA, USA).
RESULTS AND DISCUSSION
Rapidly proliferating cells increase the susceptibility of the GI tract to CP-mediated cytotoxic effects. The most common CP-associated clinical GI symptoms include nausea, emesis, anorexia, diarrhea, delayed gastric motility, mucositis, gut malabsorption, and barrier impairment (Shahid, Farooqui, Khan, 2018). These symptoms are initiated in 4-8 h, typically peaking on day 4 after starting chemotherapy (Viana- Cardoso et al., 2011; Guo et al., 2019). In addition, some symptoms may persist even after completion of the therapeutic regimen (Stojanovska, Sakkal, Nurgali, 2015; Liu et al., 2019). Thus, in experimental studies, CP reportedly induces dose-related gastric distention and gastric stasis in rodents (Cabezos et al., 2010; Pini et al., 2016; Liu et al., 2019). Considering that gastric motility reduces within 2-4 days of CP treatment in animals (Viana-Cardoso et al., 2011; Guo et al., 2019), we evaluated the GE of liquids in mice 3 days after CP treatment and examined the possible gastroprotective effect of MLT.
In the present study, Figure 1 shows that CP treatment decreased (P < 0.05) GE of the liquid meal (29.5 ± 2.6%) when compared with the control group (56.4 ± 3.1%). Consistent with our findings, Nam et al. (2016) and Shin et al. (2018) have reported CP-induced delayed GE of phenol red solution in rodents. Studies have suggested that CP stimulates the excessive release of 5-hydroxytryptamine (5-HT) from enterochromaffin cells in the GI tract, which induces peripheral 5-HT receptors on the vagal afferent fibers and enteric nerves. This stimulation can cause relaxation of the stomach, possibly leading to delayed GE (Ando et al., 2012). Based on our findings, MLT pretreatment at 5 and 10 mg/kg failed to prevent (P > 0.05) CP-induced GE delay (26.4 ± 2.1% and 29.1 ± 3.7%, respectively); however, pretreatment with 20 mg/kg MLT prevented this effect (P < 0.05) (49.9% ± 3.7%). Interestingly, treatment with NAC (positive control) did not prevent (P > 0.05) CP- induced GE delay (27.5 ± 3.0%; Figure 1).
Effects of pretreatment with melatonin (MLT) or N-acetylcysteine (NAC) on the percentage of gastric dye emptied, as induced by cisplatin (CP) in mice. P < 0.05, *compared with the control group (S), #compared with the group treated only with cisplatin (ANOVA followed by Tukey test).
To the best of our knowledge, this is the first study to demonstrate the protective role of MLT against the inhibitory action of CP on GE in mice. MLT is a small lipophilic compound that easily diffuses across cell membranes and rapidly accesses different tissues, allowing paracrine and endocrine actions (Söderquist, Hellström, Cunningham, 2015). In vivo animal studies have revealed that MLT exerts both excitatory and inhibitory effects on gut motility depending on the dose employed (Kasimay et al., 2005; Thor et al., 2007; Chen et al., 2011; Carrascal et al., 2018). In the present study, a pharmacological dose of MLT (20 mg/ kg) prevented CP-induced gastroparesis. Some reports have highlighted the protective effects of MLT on drug- induced GI motility disorders and gut mucosal lesions (Zhu et al., 2018). In the case of neurodegenerative processes, such as those induced by chemotherapy, the protective effect of MLT has been examined in numerous experimental systems generating oxidative stress and inflammatory processes, both directly or indirectly (Carrascal et al., 2018; Wongprayoon, Govitrapong, 2020). This possible CP-induced neurodegeneration may be related to an increase in gastric volume (Cabezos et al., 2010; Pini et al., 2016). In the present study, on opening the abdomen, gastric distension in CP-treated mice (Figure 2B1) appeared more notable when compared with control (Figure 2A1) or MLT-treated mice (Figure 2C1). The vagus nerve has important functions in the GE of liquid, and a previous report has indicated that the antioxidant and gastroprotective effects of MLT were mediated by the vagus nerve (Shahrokhi et al., 2016). Thus, we cannot exclude the possibility that MLT mediated vagus nerve neuroprotection in the present study.
Effects of melatonin (MLT) on cisplatin (CP)- induced gastrointestinal damage in mice. Gross anatomy of mice stomachs after excision from the abdomen (section 1), upper intestinal dye transit (section 2), scanning electron microscopy (SEM) images acquired at 10 kV (section 3), and qualitative optical microscopy (100×, section 4) showing the luminal surface of the duodenum. Box A1-4: control group, animals treated with vehicle (ethanol 5% in NaCl 0.15 M); Box B1-4: Cisplatin group, animals treated with 5 mg/kg CP; BOX C1-4: melatonin group, animals pretreated with 20 mg/Kg MLT plus 5 mg/kg CP. White arrow: Proximal duodenum.
Numerous studies have reported improvements in oxidative status and attenuation of morphological changes following the antioxidant activity of NAC on CP- induced toxicity in various tissues (testis; Anand et al., 2015; ovary; Barberino et al., 2017; brain; Abdel-Wahab, Moussa, 2019). However, in the present study, 150 mg/ kg NAC did not influence CP-induced gastroparesis. In other experimental models simulating gastric damage in rats, NAC afforded protective effects at a higher dose (500 mg/kg) (Hegab, Abd-Ellatif, Sadek, 2018), which can be evaluated in future assays for CP-induced gastroparesis in mice.
Herein, we used phenol red as a marker to observe GI dye propulsion. We noted that upper intestinal transit (Figure 2A2) was reduced in the control group after CP treatment (Figure 2B2). However, this reduced gut dye transit was restored in 20 mg/kg MLT-treated mice (2C2). Considering that CP-induced GE delay can result in injuries in the gut wall general structure, as well as in mucosal, submucosal, and muscular layers (Uranga et al., 2017), we determined the efficiency of MLT in protecting the gut mucosa using SEM to provide real-time visualization of the surface of gut structures (Lu et al., 2017) and the histological pattern in HE-stained duodenal wall sections. As shown in Figures 2A3 and 2A4, no changes in the duodenal structural morphology were observed in vehicle- treated animals (control group). However, following CP treatment, the intestinal structural villi showed significant damage, with eruptions and atrophied villi (Figure 2B3), further augmented by histological alterations (e.g., shortening and fragmentation of villi and deepening of the crypts), as observed in Figure 2B4. In CP-treated mice, structural examination showed a significant decrease in mucosa thickness and epithelium height, which could be attributed to the loss of cell rows in the spinous layer, given the antimitotic properties of CP on proliferating spinous cells (Konturek et al., 2007; Shahid, Farooqui, Khan, 2018; Kim et al., 2019). In addition, studies have revealed that CP (doses ≥ 6 mg/kg body weight) can induce distortion of glandular mucosa architecture, crypt ablation or abscess formation, intense inflammatory cell infiltration, degeneration, density reduction, or diminished villi height, accompanied by acute necrosis and apoptosis of the intestinal epithelial cells (Shahid, Farooqui, Khan, 2018), thus reducing fluid and electrolyte absorption from the gut. Therefore, the prevention of small intestine injury is a critical therapeutic strategy during CP therapy. Accordingly, Figures 2C3 and 2C4 present that pretreatment with MLT 20 mg/kg attenuated CP-induced duodenal morphological injury, demonstrating that MLT maintains the gut tissue integrity, despite the use of an antineoplastic agent with well-known destructive effects on the GI mucosa (Pandit et al., 2015; Shahid, Farooqui, Khan, 2018). Laboratory and clinical studies indicate that MLT can prevent or treat pathological conditions such as esophageal and gastric ulcers, irritable bowel syndrome (IBS), constipation- predominant IBS, diarrhea-predominant IBS, Crohn’s disease, ulcerative colitis, and necrotizing enterocolitis (Brzozowska et al., 2002; Konturek et al., 2013; Bang, Yang, Baik, 2019).
Furthermore, it has been established that MLT exerts complex actions in the GI tract by binding and activating two distinct receptor types: membrane receptors MT1 and MT2 (Thor et al., 2007; Söderquist, Hellström, Cunningham, 2015). MLT receptor-dependent protective effects have recently been reported in various animal models, including protection against myocardial injury (Han et al., 2019), brain injury (Wongprayoon, Govitrapong, 2020), and protection against CP-induced ovarian damage (Barberino et al., 2017). However, the participation of MLT receptors in CP-induced gastroparesis needs to be comprehensively elucidated.
To determine whether the gastroprotection afforded by MLT is mediated via membrane MT1 and/or MT2 receptors, the influence of LZD (an antagonist of both MT1 and MT2) and 4-P-PDOT (a selective MT2 antagonist) on CP-induced GE delay was examined. Our data revealed that the protective effect of MLT on CP-induced GE delay was suppressed (P < 0.05) by LZD and 4-P-PDOT pretreatment (Figure 3), indirectly indicating that the gastroprotective effect of MLT against CP-mediated effects might be mediated via MT2 receptors.
Effects of melatonin (MLT) on the percentage of gastric dye emptied, as induced by cisplatin (CP) in mice pretreated with luzindole (LZD, 5 mg/kg) or 4-phenyl- 2-propionamidotetralin (4-P-PDOT, 4 mg/kg). P < 0.05, *compared with the control group (S), #compared with the group treated only with MLT (ANOVA followed by Tukey test).
Detection of MT2 receptors in the gut muscle layers provides strong evidence that these receptors play a role in regulating GI motility (Stebelová et al., 2010). MT2 receptors can interact with multiple signal transduction pathways, including phosphoinositol production, inhibition of adenylate cyclase, and inhibition of the soluble guanylate cyclase pathway, which are directly involved in smooth muscle contraction (Stebelová et al., 2010; Chen et al., 2011; Söderquist, Hellström, Cunningham, 2015). In addition, MT2 receptors may be involved in the overall enhancement of gastric microcirculation, probably mediated by nitric oxide (NO), known to exert gastroprotective and ulcer healing actions (Brzozowska et al., 2002; Konturek et al., 2013). Thus, given that MLT receptors are targets for therapeutic management of GI disorders such as gastroesophageal reflux disease and IBS (Siah, Wong, Ho, 2014; Bang, Yang, Baik, 2019), our results reinforce the use of MLT as complementary therapy during chemotherapy and highlight a promising therapeutic target (MT2 receptor), which could be used to promote the development of gastroprotective agents. Considering that MLT can also act on 5-HT and cholecystokinin B (CCK2) receptors involved in motility and permeability of the GI tract (Sjöblom, Flemström, 2001; Ando et al., 2014), future studies should attempt to elucidate the role of neurohumoral pathways in the protective effects of MLT against CP-induced gut injury.
In conclusion, pretreatment with 20 mg/kg MLT prevented GE delay and preserved the morphology of the gut mucosa during CP treatment, demonstrating the contribution of MLT in maintaining gastrointestinal functionality during CP therapy. In addition, the use of MLT receptor antagonists confirms that at least MT2 receptors mediate MLT action against CP-induced GI damage. Thus, clarifying the actions of MLT and its receptors in the GI tract could establish the therapeutic potential, which should be explored for developing novel gastroprotective strategies/ agents. However, further studies need to be conducted to assess the activity of the association between CP and MLT against the growth of tumor cells.
ACKNOWLEDGMENTS
The present study was supported by CAPES, CNPq, and FACEPE scholarships.
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Publication Dates
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Publication in this collection
02 Dec 2022 -
Date of issue
2022
History
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Received
11 June 2020 -
Accepted
05 Nov 2021