Pharmacological and computational evaluation of fig for therapeutic potential in hyperactive gastrointestinal disorders

High prevalence of gastrointestinal disorders among Asian population has caused significant suffering and it is generally considered by the health care professionals to be a leading cause for the incidence of a number of other concomitant disease conditions. Evidence based medicine has not yet succeeded in introducing any sufficiently safe and efficacious drug for the cure of gastrointestinal ailments. Most of the available remedies provide only short-term relief accompanied by various undesirable effects. Nevertheless, conventional phytotherapies have proved to be more cost-effective and long-lasting in the treatment of gastric problems [1]. These herbal products have emerged as a remarkable source to contribute to the discovery of a number of lead compounds and contemporary marketed medicines. Around 61% of the total drugs launched globally have been extracted from naturally originated herbal products [2].

In-vivo evaluation of crude plant extracts aids to screen out newer bioactive lead molecules and their further processing for structural exploration can lead to the development of novel therapies. For obtaining desirable therapeutic effects, pure form of bioactive constituents can be formulated into appropriate dosage forms as well as doses and dosing frequency can be decided [3]. Many chronic disorders have been successfully cured by phytotherapies particularly by edible fruits being consumed as functional foods as well as their active constituents. Several previous studies have demonstrated the potential of crude extracts of a number of edible fruits to treat the gastrointestinal tract diseases [4].

Ficus palmata commonly known as ‘Fig’ and locally “Injeer” belongs to the family Moraceae that consists of about 800 species [5]. It is found in the Himalayan region, so also named as Wild Himalayan Fig and is mainly the native of Northern areas of Pakistan. Majority of the members of the family are very tall trees, shrubs and sporadically herbs often with milky juice [6]. Variety of Ficus species are used in folk medicine as anti-inflammatory, anti-tumor and tonic medicament [7]. Diseases such as epilepsy, jaundice, influenza, whooping cough, tonsillitis, bronchitis, enteritis, bacillary dysentery, toothache and bruises are also reported to be cured by Ficus extracts. Antioxidant activity was exhibited by Ficus palmata [8]. Various pharmacological activities such as nephroprotective, hepatoprotective and anticoagulant activities are also possessed by this plant [9].

The chemical analysis on genus Ficus, reveals the presence of sterols, terpenes, isoflavones, lignans, glycosides [10], coumarins, furanocoumarin and chromone [11]. Phytochemical investigation of the aerial parts of Ficus palmata resulted in the isolation of 6 compounds; germanicol acetate, psoralene, bergapten, vanillic acid, psoralenoside and flavone glycoside rutin [10].

In the present study, we report anti-diarrheal, anti-secretary, anti-spasmodic, anti-motility and anti-ulcer effects. Aforementioned ethnomedicinal uses of the plant were validated by using baseline data from traditional uses and previous studies. Molecular docking of its constituents with known structure is done to find out the potential lead molecule responsible for pharmacological effects.

Based on ethnopharmacological use of Ficus palmata in hyperactive gut diseases, such as colic and diarrhea, its extract was evaluated for the possible anti-diarrheal, anti-secretory, charcoal meal gastrointestinal motility and anti-ulcer effects in rodents. Isolated intestinal tissue was used for the elucidation of possible underlying mechanism(s) to rationalize aforementioned ethnomedicinal uses of the plant and it was further supported by virtual screening tools.

Fp.Cr demonstrated an excellent antidiarrheal activity against castor oil induced diarrhea similar to the effect produced by loperamide, a standard drug [13]. Castor oil cause increases in the peristaltic activity and induce permeability changes to electrolytes and water in the mucosal membrane of the small intestine similar to an effect which is associated with prostaglandin release. Ricinoleic acid which is an active metabolite of castor oil is another major factor in causing diarrhea through a series of actions including activation of small intestinal peristaltic activity with reduction of Na⁺/K⁺ ATPase activity. These changes eventually results in disturbance in the intestinal mucosa, electrolyte permeability, hypersecretion of intestinal contents and a slogging of the transport time in the intestine [19]. Thus, a potential agent may exhibit its anti-diarrheal activity by these mechanisms. Intracellular Ca²⁺ levels had a huge impact on secretary functions of the gastrointestinal organs which lead towards consequences such as discharge of gastric acids and intestinal fluid release. This effect might be affected by some drugs that hinder calcium influx [20]. Fp.Cr shows protection against castor oil induced intestinal fluid secretions in mice. The anti-diarrheal and anti-secretory activities of Fp.Cr might be because of gastrointestinal relaxant component(s) present in the Fp.Cr [10].

Dose-dependent inhibition of spontaneous contractions in isolated rabbit jejunum preparations were exhibited by Fp.Cr, thus showing antispasmodic action. High K⁺ (80 Mm), as KCl, was used to depolarize the tissue to analyze whether the spasmolytic activity of this extract was mediated through calcium channel blockade or some other mechanism. High K⁺ (80 Mm) is known to cause smooth muscle contractions with opening of voltage gated L-type calcium channels, thus permitting the inflow of extracellular calcium causing contractility and the substance causing this inhibition of high K⁺-induced contractions is considered as calcium channel blocker [15]. Verapamil, a specific calcium antagonist have inhibitory effect against K⁺-induced contractions. Against spontaneous and K⁺-induced contractions Fp.Cr produces inhibitory pattern just like verapamil.

Gastric ulcer is the result of an imbalance between aggressive and defensive factors of the gastric mucosa which results in rupturing of mucosal protection and expose gastric lining to gastric acids. To explore the anti-ulcer effect of Fp.Cr, ethanol-HCl induced gastric model was used which through variety of mechanisms stimulates ulcer including mucus exhaustion, mucosal damage, release of superoxide anion, hydro-peroxy free radicals, all these mechanisms prolonged the tissue oxidative stress and release of inflammatory mediators. Fp.Cr significantly decreased the surface ulceration as compared to that of control animals which received saline. In view of these results, methanol extract showed significant cytoprotection. The potential of Fp.Cr to produce anti-ulcer effect might be due to its CCB effect, as Ca²⁺ antagonist are well known to demonstrate such effects [21]. In pathophysiology of gastric ulcers, oxidative stresss plays a vital role. Antioxidant and nitric oxide free scaveneging activity has been reported by Ficus palmata [10] which may be responsible for its effectiveness as anti-ulcer agent.

Intestinal transit travelling, an important measurement factor that regulates the bioavailability of orally administered drugs/foods and determines the absorption intensity of luminal contents. More oftenly, timely oral administration of active charcoal, as marker, to experimental animals are useful to measure the intestinal transit rate. This experimental model is sensitive to agents that inhibit/stimulate intestinal peristalsis regulated by autonomic nervous system. This is the rationale for using this assay to investigate the influence of natural products on intestinal peristalsis [22]. In the small intestinal transit test, Fp.Cr produces suppression of the propulsion of charcoal marker at all test doses just like atropine sulphate a standard drug, that has been reported to have anticholinergic effect on intestinal transit [21]. A decrease in the motility of gut muscles increases the stay of substances in the intestine, thus allows better water absorption. This finding suggests that Fp.Cr has the ability to influence the peristaltic movement of intestine thereby indicating the presence of an anti-motility activity. It is therefore presumed that the reduction in the intestinal propulsive movement in the charcoal meal model may be due to antispasmodic properties of the Fp.Cr [22].

The observed therapeutic effects of Ficus palmata may be due to the presence of phytochemicals, tannins and flavonoids, as these phytocontinuents are well known for gastrointestinal effects. Anti-diarrheal, anti-secretory, anti-ulcer and anti-spasmodic activities may be due to flavonoids [23].

Molecular docking is an effective tool for evaluating the affinity of various protein targets that may possibly be associated with the pathophysiology of gastric disorders. The traditionally acclaimed use of Ficus palmata in the management of gastric related diseases has been supported with scientific evidence using virtual screening tool and different chemically-induced gastrointestinal models like castor oil induced diarrhea, castor oil induced enteropooling, and charcoal meal gastrointestinal motility. The use of computational methodologies has end up being fundamental component of drug discovery and development process therefore computational screening becomes broadly employed tool in identifying the potential of structural chemical compounds before initiation of wet lab research. Since early 90’s, docking has been observed to play a primary role for virtual screening of different chemical structures and it is still an extremely dynamic region to look forward [24]. Lead compounds are virtually screened through molecular docking that turns out to be time saving as well as economically affordable on premise of structural conformations [25].

In this study, Auto Dock Vina program was used through PyRx [26]. Through gradient optimization method, binding mode predictions are improved. E-value, Lower desolvation, Hydrogen bonding, pi–pi and other hydrophobic interactions imparts their influential effect in gastrointestinal diseases [27] which are contributing factors in increasing affinity with protein and stabilization of ligand-receptor complex. It has been found that psoralenoside showed excellent score of binding against α₁ receptor with lowest E-value. This binding efficacy is greater than majority of the target proteins with better affinity as compared to other test compounds and standard drugs. Order of affinity of test compounds for α₁ and M₁ receptor was; psoralenoside > bergapten > psoralene > germanicol acetate. Compounds with higher affinity all together formed stronger pi–pi bonds, high number of hydrophobic interactions and polar hydrogen bonding against muscarinic M₁ and α₁ receptors. The order of affinity for ligands against muscranic M₃ receptor was found as; bergapten > psoralene > psoralenoside > germanicol acetate. Order of affinity of test compounds for dopaminergic D₂ receptor was found as; psoralenoside > bergapten > psoralene > germanicol acetate. Alongside hydrogen and hydrophobic interactions, different types of interactions, for example alky, pi-alky and vander waal interactions are appeared with high proclivity by test compounds. The affinity order of ligands against calmodulin was found as; bergapten > psoralene > psoralenoside > germanicol acetate. In addition, hydrogen bond is considered to be vital for complex of ligand with calmodulin. The affinity order for test compounds for voltage gated L-Type calcium channel was found as; bergapten > psoralene > psoralenoside > germanicol acetate. Order of affinity of test compounds for histaminergic H₁ receptor was found to be: psoralene > bergapten > psoralenoside > germanicol acetate. Ligands are not engaged with making any solid interactions on stated restricting sites. Order of affinity of test compounds for H⁺/K⁺ ATPase receptor was found as; bergapten > psoralenoside > psoralene > germanicol acetate. Hydrogen and hydrophobic associations are observed to be essential but no such interactions of test compounds with stated restricting site were seen [28]. In this regard, SER 477 is considered as important and vital amino acid. The affinity order of ligands against histaminergic H₂ receptor was found as; psoralenoside > psoralene > bergapten > germanicol acetate. Order of affinity of test compounds for mu-opioid receptor was found as: bergapten > psoralene > psoralenoside > germanicol acetate. Ligands having high restricting proclivity shaped interacts with TYR 272 and VAL 270.

Ficus palmata exhibited anti-diarrheal, anti-secretary, anti-spasmodic, anti-motility and anti-ulcer effects. The plant constituents: psoralenoside and bergapten showed high binding affinities (E-value ≥ − 6.5 Kcal/mol) against histaminergic H₁, calmodulin and voltage gated L-type calcium channels, while showed moderate affinities (E-value ≥7 Kcal/mol) against dopaminergic D₂, adrenergic α_1, muscarinic M₃, mu-opioid, whereas revealed lower affinities (E-value ≥9.5 Kcal/mol) vs. muscarinic M₁, histaminergic H₂ and H⁺/K⁺ ATPase pump. Germanicol acetate and psoralene exhibited weak affinities against aforementioned targets.