Peripherally, TRPA1 channels are distributed in various organs such as gastrointestinal tract (GIT), pancreas, myenteric plexus, duodenal epithelial cells, bladder, keratinocytes, dorsal root ganglion and are therefore thought to facilitate secretory function. Supporting this statement, many studies have shown TRPA1 channels to be involved in various gastric and metabolic processes such as ghrelin release, changes in blood glucose levels, appetite control, GLP-1 regulation, gastric emptying and others (51–54). Elevated GLP-1 has been reported after AITC treatment in the GLUTag cells in a response similar to as shown by polyunsaturated fatty acids (PUFAs) (53).

TRPA1 channels, present in the rat pancreatic β-cells and rat pancreatic beta-cell line (RINm5F), facilitate the dose-dependent release of insulin after AITC treatment, similar to glucose treatment. These effects of AITC were diminished in the presence of HC-030031. The study also confirmed TRPA1-mediated enhancement in insulin release in the presence of tetrodotoxin (a voltage-dependent Na⁺ channel blocker) and nimodipine (a voltage-dependent Ca²⁺ channel blocker) (55). The antidiabetic and anti-obesity effects of TRPA1 agonists have been well reported. Cinnamaldehyde has been used in traditional medicine for its antidiabetic effects as it is known to enhance glucose uptake and increase expression of glucose transporter GLUT-1 (56), decrease glycosylated hemoglobin, serum triglyceride and cholesterol levels, increase high-density lipoprotein, insulin and hepatic glycogen (57). It also prevents lipid accretion, fasting-induced hyperphagia, visceral fat deposition and alterations in the levels of leptin and ghrelin caused by a high-fat diet (58, 59). It reduces ghrelin secretion in conjunction with improving insulin sensitivity (60). These antidiabetic effects of cinnamaldehyde were also seen in patients with T2DM receiving hypoglycemic agents. Cinnamaldehyde supplementation was able to significantly reduce glycated hemoglobin, mean systolic and diastolic blood pressure, fasting plasma glucose, and body mass index over the period of 12 weeks (61). Cinnamaldehyde also improves glucose tolerance as seen in oral glucose tolerance test after acute treatment in healthy people (62). Collectively, this evidence suggests a strong involvement of TRPA1 agonist cinnamaldehyde in controlling appetite and being a promising candidate to manage diabetes and obesity. Not just cinnamaldehyde, AITC has also shown prominent effects as a potential antidiabetic compound as it helps in improving insulin resistance, improves glucose intake, mitochondrial activity, glycosylated hemoglobin, GLUT-4 translocation to the membrane from the cytoplasm and protects the animals from high-fat diet-induced hepatic steatosis, body weight gain and lipid dysregulation (51). It is important to note that TRPA1 modulators not only regulate glucose and insulin homeostasis but also control insulin release from the pancreatic β-cells. AITC, hydrogen peroxide, 4-hydroxynonenal and prostaglandin J2 induced depolarization, Ca²⁺ influx and further insulin release from pancreatic β- cell lines (55) and RINm5F cells (63). This insulin release was blocked by HC-030031 and AP-18 indicating that TRPA1 channels play an imperative role in insulin secretion from the pancreas.

The involvement of TRPA1 in pain perception makes it a potential therapeutic target for the treatment of other comorbid conditions associated with diabetes. TRPA1 antagonists have shown reduced diabetic neuropathy development in animals, but detailed studies are still required (64, 65). Another interesting study has reported reduced TRPA1 channel function in the DRG neurons upon activation of AMP-activated protein kinase (AMPK). The study revealed that metformin (an AMPK activator) inhibits TRPA1 activity by means of diminishing the amount of membrane-associated TRPA1. AMPK plays a significant role in energy homeostasis, and its activation stimulates hepatic fatty acid oxidation, inhibition of cholesterol synthesis, increased glucose uptake, along with other regulatory effects. But this inhibition of TRPA1 activity by AMPK activation was seen to be a helpful factor in preventing diabetic neuropathy as it led to the deterrence of mechanical allodynia in diabetic mice (66).

TRPA1 channels are also involved in atherogenesis, a study conducted in 2016 has shown that apoE^-/- mice show higher TRPA1 channel expression in aortas than wild type mice (67). The study also revealed that genetic deletion of TRPA1 exacerbated the atherosclerotic lesion in apoE^-/- mice, whereas treatment with AITC reduced the atherosclerotic lesion in apoE^-/- mice but not in apoE^-/-TRPA1^-/- mice, suggesting its involvement in atherosclerosis development. TRPA1 inhibition by HC-030031 also led to lipid accumulation. Another study conducted in HEK293 cell lines and TRPA1 null mice showed that PUFAs activate mammalian TRPA1, and TRPA1 is needed for PUFAs to stimulate enteroendocrine cells and sensory neurons to elicit cholecystokinin (CCK) secretion (68). Another study reported that TRPA1 channels get activated in response to bradykinin, diacylglycerol and arachidonic acid, although the mechanism is not fully illustrated yet (69). Cinnamaldehyde in the form of cinnamon powder has also been shown to reduce glucose, total cholesterol, triglycerides, and LDL cholesterol levels in T2DM patients (70). Furthermore, cinnamaldehyde treatment reduced the serum levels of triglycerides, total cholesterol, c-LDL and elevated the c-HDL levels in high-fat diet rats (71). This evidence suggests the involvement of TRPA1 in lipid homeostasis. Additionally, a study in 3T3-L1 cells hinted towards TRPA1 activation as a potential mechanism for the anti-lipid accumulation effect of trans-pellitorine (72). Literature also points at the involvement of TRPA1 channels in regulating uncoupling protein 1 (UCP1) expression. Oleuropein aglycone present in extra virgin olive oil was found to activate both TRPA1 and TRPV1. Also, it enhanced the UCP1 expression in intrascapular brown adipose tissue by stimulating noradrenaline secretion via the β2- and β3-adrenoceptors following TRPA1 and TRPV1 activation and reduced the visceral fat content in high fat diet-fed rats (73).

Other than their involvement in lipid and insulin homeostasis, studies involving TRPA1 agonists suggest that TRPA1 channels are also involved in adipokine-cytokine (adiponectin, leptin, TNF- α and IL-6) regulation. Adiponectin is essential for fatty acid breakdown and is an anti-inflammatory adipokine, which is decreased in T2DM (74) and obese patients (75). In other words, adiponectin levels are inversely proportional to insulin resistance. Cinnamaldehyde treatment increases adiponectin levels while also maintaining lipid homeostasis in rats (76) as well as adipocytes (77). Leptin, another major hormone involved in controlling appetite, releases from the adipocytes. It directly binds to its receptors and mediates energy expenditure, reduces food intake, affects insulin signaling and growth hormone. Leptin receptors are present peripherally on adipocytes and centrally in the hypothalamus and hippocampus. Several evidences of dysfunction in leptin signaling have been identified in diabetes, obesity, and metabolic disorders (78, 79). Hyperphagia and weight gain are typical characteristics of leptin deficiency; however, leptin levels are seen to be increased in some cases of obesity and diabetes owing to leptin resistance. Interference in leptin signaling in the form of leptin resistance has also been seen with antipsychotic drugs such as olanzapine used to treat psychosis and other neuropsychiatric disorders (80). Cinnamaldehyde decreases the elevated leptin levels in high-fat diet-fed mice (58, 81). Further, inflammation is an essential factor in the pathogenesis of insulin resistance. Studies have demonstrated interlinking between inflammation and insulin resistance as well as obesity as one leading to another and vice versa. Obesity and insulin resistance are involved in producing low-grade inflammation in the adipose tissue, leading to systemic and local insulin resistance (82). Cytokines such as TNF-α, IL-6 and IL-1β are responsible for producing insulin resistance by reducing insulin secretion from the pancreatic β-cells and reducing the insulin utilizing ability of cells (83–86). Cinnamaldehyde decreases the mRNA expression of TNF-α in adipose tissue in mice (87) and has also shown anti-inflammatory properties in response to LPS-induced inflammation in mice by decreasing TNF-α, IL-1β and interferon-gamma (IFN-γ) levels in mice (88). AITC as well possesses anti-inflammatory potential as demonstrated by reduced mRNA expression of TNF-α, IL-1β and enhanced gene expression of the anti-inflammatory, antioxidant heme oxygenase-1 (HO-1) in vivo as well as in vitro (89). However, none of these studies has directly co-related these effects with TRPA1 channel activation, but as they all involve specific TRPA1 agonists, future studies are envisaged indicating direct relation.

The existence of TRPA1 channels in the enterochromaffin cells in the small intestine (specifically duodenum and jejunum) and cells expressing CCK and serotonin indicates its crucial role in controlling appetite as these both are major regulators of hunger in the GIT (90). Asserting this statement, a study in STC-1 cells showed increased CCK release upon AITC (91), naringenin (92) and hesperetin treatment (93) via stimulation of TRPA1 channels. This release was reduced upon ruthenium red or HC-030031 treatment. Additionally, this enhanced release was absent in the presence of L-type calcium channel blocker, which means that it is interwoven with intracellular calcium levels (91). Similarly, it was observed that inhibition of TRPA1 channels by HC-030031 suppresses aldehyde-induced CCK secretion in STC-1 cells (94). Cinnamaldehyde treatment decreased ghrelin secretion and gastric emptying rate in mice and also helped in reducing body weight in high-fat diet-induced obesity in mice (95). It also helped in normalizing the blood glucose levels as observed in the oral glucose tolerance test. It also increased the levels of acyl-CoA synthetase 4, an enzyme aiding in β-oxidation of fatty acids. However, recently there have been contradicting studies that have shown TRPA1 agonism to be responsible for enhanced contractions in the lower GIT and thus increases GIT motility (96). TRPA1 agonists have also been shown to play a role in adipogenesis. Oral cinnamaldehyde treatment helped in reducing mesenteric adipose tissue while upregulating expression of different GLUTs and carnitine palmitoyltransferase 1A (responsible for fatty acid oxidation) in the white adipose tissue (52).

In addition to the presence in the small intestine, TRPA1 channels are also present in the colon. Their presence in the colon was confirmed by in-situ hybridization and immunohistochemistry in the surface epithelium of the colon in rats. As described earlier, activation of TRPA1 channels induces PGE₂ activation leading to anion secretion in the epithelium of the colon. It was reported that TRPA1 activation impedes spontaneous contractions and transit by directly stimulating myenteric neurons. Therefore, TRPA1 may also play a role in washing out harmful compounds and preserving gut microbiota, thus helping relieve constipation (97). Also, TRPA1 activators such as carvacryl acetate are known to decrease intestinal mucositis in mice (98). A healthy gut is essential in conserving normal appetite and metabolic functions; these protective effects of TRPA1 channels also serve as an added advantage.

TRPA1 channels play a significant role in taste perception. As we know, TRPA1 channels are co-expressed with TRPV1 channels in trigeminal nerves, which are present in hefty volumes in the taste cells along with vagus and glossopharyngeal nerve (99). Because these channels are activated by many chemicals such as allicin (garlic), isothiocyanates (wasabi, horseradish), curcumin (turmeric), eugenol (clove), thymol, cinnamaldehyde; activation of these channels by these food components helps in taste perception (28). The food substances that are irritable in taste are mostly felt because of TRPA1 channel activation (100). TRPA1 channel agonists cinnamaldehyde, methyl syringate and AITC, showed abridged food consumption by delaying gastric emptying (101). On the other hand, these effects were seen to be absent in animals treated with TRPA1 antagonist HC-030031 or ruthenium red. Food intake regulation measured by the levels of plasma PYY and GLP-1 also demonstrated elevated plasma PYY by cinnamaldehyde and methyl syringate but not in the presence of HC-030031 and ruthenium red, indicating reduced food intake by the agonists. In a very recent study, it was observed that co-treatment with dietary TRPA1 agonist, allicin rich garlic juice was able to reverse increased food intake, body weight, impaired glucose homeostasis, elevated PYY, ghrelin and decreased GLP-1, CCK produced by high fat-diet (102).

Another major event serving a critical part in appetite regulation is GI inflammation. As TRPA1 channels are present on capsaicin-sensitive sensory neurons, they have also shown involvement in inflammatory bowel disease (IBD) along with TRPV1 channels. Patients suffering from ulcerative colitis and Crohn’s disease have shown upregulation in the expression of TRPA1 and TRPV1 mRNA, although results for TRPV1 are contradictory (103). TRPA1 antagonists, as well as knockdown, supposedly help in decreasing colitis severity and reversing visceromotor response in mice (104), but studies have also suggested the opposite (105). Lastly, TRPA1 channels are also involved in olfaction. The sense of smell is essential for stimulation of appetite and further release of gastric hormones for digestion of food. TRPA1 channels mediate nociception conjured by pungent substances. TRPA1 knockout mice are unable to sense foul odors and thus fail to avoid the chamber filled with formalin, acrolein or AITC whereas the wild type animals show avoidance behavior (106).

Not many studies have been conducted to confirm the presence of TRPA1 channels in the hypothalamus (mainly in the supraoptic nucleus) (39, 107), but the supporting evidence is convincing enough to say that TRPA1 channels could exist in the arcuate nucleus of the hypothalamus where they temper various appetite-controlling neuropeptides to modulate hunger and food intake. Moreover, as mentioned earlier, TRPV1 and TRPA1 are closely related in expression and functions; several studies have affirmed the presence of TRPV1 channels in the arcuate nucleus (20, 80). A study using TRPA1 agonist phenethyl isothiocyanate revealed enhanced mRNA expression of anorexigenic peptide POMC and reduced NPY/AgRP expression, which is orexigenic in nature, thus plummeting food intake in mice (108). Cinnamaldehyde supplementation also proved to enhance mRNA expression of anorectic peptides such as POMC, CART, and CCK in the hypothalamus of high-fat diet-fed mice (58). Vomitoxin (deoxynivalenol), which occurs as mycotoxin in grains such as wheat, oats, rice and barley, has been reported to induce TRPA1 mediated calcium signaling in murine STC-1 cell lines (109). In vivo study in mice showed a significant increase in POMC, CART and melanocortin four receptor (MC4R) mRNA expression in the arcuate nucleus of the hypothalamus after vomitoxin treatment and also leads to reduced food intake during the dark phase (110). Tominaga et al. (2016) also reported increased expression of hypothalamic POMC, MC4R, gastric CCK expression and TRPA1 expression in mice after vomitoxin treatment hinting that vomitoxin exerts is anorexic effects by increasing hypothalamic anorexic peptides via TRPA1 activation (111).

Regardless of numerous studies suggesting a positive role of TRPA1 agonists controlling appetite and metabolism, some studies tend to differ as well. A study in Wistar rats reported enhanced ghrelin levels in the blood and heightened food intake after treatment with TRPA1 agonist β-eudesmol, while TRPA1 knockout animals showed standard food intake. It also increased histamine levels in the hypothalamic tuberomammillary nucleus and elevates gastric vagal nerve activity (GVNA) responsible for the absorption and digestion of nutrients. However, pretreatment with HC-030031 eliminated the elevation in GVNA (112).