Abstract

Diospyros lotus, also known as date-plum, belongs to the Ebenaceae family and is mostly recognized as a rootstock for D. kaki. Similar classes of naphthoquinones in D. lotus are investigated against cancer and inflammation and have antimicrobial, sedative, and analgesic properties. Six chemical constituents (1-6) were isolated from Diospyros lotus and tested for anti-inflammatory effects at the dose of 2.5 and 5 mg/kg, i.p., using carrageenan (1%, 0.05 ml)-induced paw edema. The maximum protection against carrageenan-induced edema was observed for compounds 1 and 2. Both studied compounds demonstrated significant anti-inflammatory effect after the 3rd hour of posttreatment. The maximum anti-inflammatory effect of compound 1 was 85.96%, while that of compound 2 was 81.44%, followed by compounds 5 and 6, which exhibited 80.11% and 82.45% effect, respectively. Similarly, histamine-induced inflammation was significantly antagonized by 1, 2, 5, and 6 with 87.99%, , , and 77.44% effects, respectively, at 5 mg/kg after the 2nd hour of posttreatment. The rest of the tested compounds did not show any significant effect as compared to the negative control. Interestingly, no toxicity was observed at higher doses. Moreover, the extracted compounds showed remarkable antibacterial activity against the Gram-positive bacteria and no effect against the Gram-negative bacteria. Docking studies on target cyclooxygenases showed that all the compounds established interactions with the key amino acid residues present in the additional pocket of COX-2. Hence, these compounds may act as selective COX-2 inhibitors. In conclusion, the findings of the current study suggest that the roots of Diospyros lotus may contain some anti-inflammatory and antibacterial agents with minimal toxicological effects and accordingly this plant product is recommended for further investigations.

1. Introduction

The genus Diospyros comprises various species (nearly 760) and belongs to the family of flowering plants (shrubs and trees) known as Ebenaceae. This diverse genus is commonly available in the subtropical (Pakistan and India) and tropical (tropical America and Africa) regions around the globe [1]. Since ancient times, numerous species of Diospyros have been utilized as therapeutic agents in folk medications. Diospyros lotus, also known as date-plum, can achieve the height of up to 15 to 30 meters under optimum (semishaded) cultivation environment. Scientific investigations have reported different medicinal perspectives of various parts of D. lotus like analgesic (leaves), carminative (fruit), sedative (seeds), and febrifuge (bark) [2, 3].

Similarly, leaf extracts from Japanese persimmon (Diospyros kaki) along with jasmine have been employed in antitobacco toffees. Numerous triterpenes like ursane, oleanane, and lupine are efficiently isolated from plant cellular structures and have shown anti-inflammatory characteristics [2]. Traditionally, Diospyros species are used as therapeutic medicine for treatment of hiccups, bedwetting, insomnia, hypertension, dyspnea, pains (muscular and joints), intestinal worms, and fever [4, 5]. Isolated bioactive compounds and extracts from different parts of D. lotus have also been reported to possess strong antiproliferative potentials [6].

It is evident from the already-published literature that quinone molecules are the main moieties in currently available drugs (saintopin, mitomycin, daunorubicin, anthracyclines, mitoxantrones, and doxorubicin) used for the treatment of cancers [79]. Additionally, few naphthoquinones (plumbagin) isolated from plant matrices of various Diospyros species have demonstrated significant potent cytotoxic characteristics [1013]. Therefore, this study was designed to investigate the anti-inflammatory potential of six (1-6) di-naphthodiospyrols isolated from D. lotus roots.

2. Materials and Methods

2.1. Plant Material

In May 2009, roots of Diospyros lotus were brought from Razagram (Dir, Khyber Pakhtunkhwa), Pakistan. A voucher specimen (Bot. 20036 (PUP)) was placed in the Herbarium of the Botany Department at UOP, Pakistan, after authentication by Dr. Abdur Rashid (taxonomist).

2.2. Animals

In this experimentation, BALB/c male mice were used to authenticate the anti-inflammatory potential of six isolated compounds from roots of D. lotus. These male mice were bought from National Institute of Health (NIH), Islamabad, Pakistan. In the animal room, they were kept at 25°C and maintained in light-dark cycle (12-12 hours) conditions along with ad libitum provision of water and normal food. All the experimental procedure received prior approval from the ethical committee of the Department of Pharmacy, University of Peshawar (UOP), KPK, Pakistan.

2.3. Extraction and Isolation

Initially, D. lotus roots weighing 14 kg were dried under shade and were converted to powder by using a commercial scale grinder. Powdered Diospyros lotus roots were repeatedly extracted at room temperature by placing them in methanol (MeOH) solvent for 6 days along with periodic mixing through maceration. Collected extracts were pooled together and subjected to rotary concentration () for evaporation of MeOH and concentration of extracts under vacuum conditions. This vacuum concentration resulted in the collection of a red residue (202 grams) which was suspended in water prior to its partitioning with four different solvents, i.e., n-butanol (n-BuOH), ethyl acetate (EtOAc), chloroform (CHCl3), and n-hexane (n-hx), by following the procedures adopted by Padhyem et al. [8], Rauf et al. [9], and Bawazeer et al. [10, 11].

The chloroform fraction, i.e., F-1 (30 grams) was applied to column chromatography prepared from silica gel 60 (Merck-) followed by elution with the gradient n-hexane-ethyl acetate (100 : 0 to 0 : 100) solvent system. On the basis of TLC profiling, 105 fractions, i.e., RF1 to RF105, were obtained. By combining RF1-RF10 (fractions), a new subfraction, i.e., SF1 (2 grams) was obtained and was again applied to column chromatography (C.C). This chromatographic system was eluted using n-hexane as eluting solvent to collect red color fatty acid residue. Depending upon TLC profile, RF11-RF105 (fractions) were pooled together to form SF3 (9.89 grams) and SF4 (9.89 grams) as two new major subfractions. Afterwards, SF4 (9.89 grams) was further subjected to C.C and was eluted through n-hexane-ethyl acetate (100 : 0 to 100 : 15). This resulted in the collection of sixty fractions which were again pooled depending upon TLC profile and generated major fractions (MF1: 5.44 grams; MF2: 3.41 grams). The major fraction (MF1) was applied on preparative TLC prepared from Merck silica gel 60 (F254, a florescence indicator). Moreover, this chromatographic system was eluted through the n-hexane-ethyl acetate solvent system (85 : 15, 84 : 16, and 80 : 20) resulting in six (1-6) dimeric naphthoquinones (Figure 1). These isolated compounds, namely, 5,4-dihydroxy-1-methoxy-6,6-dimethyl-7,3-binaphthyl-1,4,5,8-tetraone (1), 5,8-dihydroxy-5-methoxy-6,6-dimethyl-7,3-binaphthyl-1,4,1,4-tetraone (2), 8,5,8-trihydroxy-6,6-dimethyl-7,3-binaphthyl-1,4,1,4-tetraone (3), 5,8-dihydroxy-6,6-dimethyl-7,3-binaphthyl-1,4,1,4-tetraone (4), 5,8-dihydroxy-5,8-dimethoxy-6,6-dimethyl-7,3-binaphthyl-1,4,1,4-tetraone (5), and 5,8,5-trihydroxy-8-methoxy-6,6-dimethyl-7,3-binaphthyl-1,4,1,4-tetraone (6), were previously reported by our group. The chemical structures of compounds 1, 2, and 3 were identified by NMR data by our group [12]. The same group has elucidated the structures of compounds 4 and 5 by using NMR data [13]. Similarly, the same group has also reported compound 6 by advanced spectroscopic analysis [14].

2.4. Anti-inflammatory Activity
2.4.1. Carrageenan-Induced Paw Edema

BALB/c mice weighing 25 to 30 grams were procured to assess the anti-inflammatory properties of the six (1-6) dimeric naphthoquinones isolated from roots of D. lotus [14]. Mice were randomly categorized into various groups depending on treatment. Purposely, Group I acted as the negative control (treated with distilled water-10 ml kg-1) and Group II acted as the positive control (intraperitoneally treated with diclofenac sodium, 5 mg kg-1), while the other groups were classified as tested groups (intraperitoneally treated with the six isolated compounds, 2.5 and 5 mg kg-1). Thirty minutes after the intraperitoneal subjection of the abovementioned treatments, 1% carrageenan (0.05 ml) was subcutaneously injected in the right hind paw (subplantar tissues) of each mouse. Inflammation in each mouse was recorded after 1, 2, 3, 4, and 5 hours of carrageenan administration through plethysmometer (LE 7500 plan lab S.L). Anti-inflammatory activity (percent inhibition) of the six isolated compounds against paw edema was obtained through the following formula: where is the paw edema of the control group and is the paw edema of the tested group.

2.4.2. Histamine-Induced Paw Edema

Histamine-induced paw edema methods were also used to assess the anti-inflammatory activity of the isolated compounds 1 and 6, according to standard methods [14, 15]. For the induction of inflammatory paw edema, 0.1 ml of histamine solution (0.5%) was administered at the subplantar region. The paw volume was noted at 1, 2, 3, 4, and 5 hours after administering the inflammatory drug. Each group of mice was pretreated orally with compounds 1-6 (2.5 and 5 mg kg-1), 1 hour before inducing paw edema. The effect of paw edema was compared with a standard drug (loratadine) against histamine-induced edema, respectively.

2.5. Antibacterial Activity

The antibacterial activity of isolated compounds was assessed by an agar well diffusion method as per reported methods. The Mueller Hinton Agar (MHA) was used as a medium. The culture was incubated in triplicate, and the incubation was done for 24-72 hrs, at 37°C. 0.6 ml broth culture of the tested organism was poured onto a sterile Petri dish, and then, the sterile molten (20 ml) was mixed. Then, 6.0 mm holes were bored in the prepared medium and 0.2 ml compounds were added to each well. Streptomycin (2 mg/ml) was used as a standard antimicrobial agent. After incubation (37°C/2 hours), the diameter was measured in millimeters (mm) to analyze the inhibition of microbial growth.

2.6. Toxicology Study

The acute toxicity of isolated compounds 1-6 was determined as per our previously reported method [14]. The animals were divided into six groups each comprising six mice (). The isolated pure compounds at doses of 5, 10, 20, 100, and 200 mg/kg body weight of animal were used in this study. After administration of compounds at the test doses, the animals of each group were kept under observation for 24 hrs. The number of survived and dead animals of each group was recorded, and the mortality was calculated as per standard procedure [16].

2.7. Statistical Analysis

Results of this study are stated as . To find out the significant difference ( or 0.01) among the experimental groups, one-way Analysis of Variance (ANOVA) was performed followed by Dunnett’s multiple comparison test.

2.8. Computational Studies
2.8.1. Docking Studies

Molecular operating environment (MOE 2016.08) was used for performing the docking studies [17]. Protein Data Bank (PDB; code: 1CX2) was used for the retrieval purpose of crystalline structure of COX-2 along with SC-558. For COX-1, the 3D structure was retrieved as accession number 1EQG with ibuprofen as the native ligand. Validation of the docking method was ensured through redocking of the native ligands. For ligand preparation, protonation of 3D coordinates, binding site determination, and downloaded enzymes, our previously published methods were adopted [1820]. The builder option in a drug discovery software program, i.e., molecular operating environment, was used for drawing of ligand structures. All the database regarding tested compounds was built as ligand.mdb. Further, the MMFF94X force field was used for minimizing the energy of compounds up to 0.01. The structure of enzymes was opened in a molecular operating environment window. 3D protonation of all the atoms was achieved under solvated conditions (temperature: 300 K; pH: 7; salt content: 0.1). The MMFF94X force field was used for minimizing the energy of the complete structure. Lastly, binding pockets of target enzymes were docked with all the compounds. After setting all the default docking parameters, 10 different conformations were produced for each compound. The MOE ligand interaction module was used to assess the least binding energy of ligand-enzyme complexes. Then, the Discovery Studio visualizer was employed for production of the 3D interaction plot [21].

2.8.2. In Silico Pharmacokinetic Prediction

An online tool named pkCSM was employed to predict the in silico pharmacokinetic characteristics of the isolated biomolecules [21]. SMILES (Simplified Molecular-Input Line-Entry Specification) notations were used as sequential inputs that represent a two-dimensional chemical structure through strings.

3. Results

3.1. Anti-inflammatory Effect

Figure 2 shows the anti-inflammatory properties of different doses (2.5 and 5 mg kg-1) of six (1-6) compounds isolated from roots of D. lotus. The maximum protection against carrageenan-induced paw edema was observed in groups of mice treated with compounds 1 and 2. Both of the tested compounds demonstrated significant anti-inflammatory effect after the 3rd hour of treatment. Percent inhibition of paw edema in groups administered with compound 1 was 85.96%, while in the case of groups subjected to compounds 2, 5, and 6, this value was 81.44%, 80.11%, and 82.45%, respectively. Furthermore, inhibitory action of these compounds against paw edema was in a concentration-dependent manner. Of all the tested compounds, 3 and 4 did not reveal any significant effect as compared to the negative control; meanwhile, the effect of the positive control (diclofenac sodium) was maximum (96.4%) among tested samples.

3.2. Histamine-Induced Paw Edema

Histamine-induced inflammatory paw edema was significantly inhibited by compounds 1, 2, 5, and 6 at 5 mg/kg, i.p. The maximum effect of compound 1 was 84.98% and compound 2 was 82.18%, while compounds 5 and 6 were 84.39% and 77.44%, respectively, after the 2nd hour of posttreatment in a concentration-dependent manner and remained good up to the 5th hour of administration as given in Figure 3.

3.3. Antibacterial Effect

The isolated compounds 1-6 were also screened against five Gram-positive and Gram-negative bacterial strains (Table 1). The tested compounds exhibited good activities against the Gram-positive bacteria, namely, Staphylococcus aureus, Bacillus subtilis, and Streptococcus epidermis with inhibition zones ranging from 8.0 to 22.0 mm. On the other hand, the Gram-negative bacteria (Klebsiella pneumoniae and Escherichia coli) did not reveal any susceptibility against the tested compounds.

3.4. Acute Toxicity Effect

The acute toxicity of isolated compounds 1-6 was evaluated in the dose range of 5, 10, 100, and 200 mg/kg, respectively. After administering the tested doses of compounds 1-6 intraperitoneally (i.p.), the animals were kept for 2 days under observation. Then, the numbers of dead and surviving animals were calculated. All the animals survived up to the maximum tested doses. All isolated compounds were assessed for toxicity test, and interestingly, all the animals were found safe up to the maximum tested doses. No toxicity was observed for compounds 1-6; their overall acute toxicity was found safe at all test doses (5, 10, 100, and 200 mg/kg) over the 24 h assessment period.

3.5. Docking Results

Docking studies were performed on target enzymes for the authentication of the results of in vitro experimentation, analysis of binding orientation, and ligand-enzyme interactions. In this part of the study, results of in vivo experimentation were explored. The model of carrageenan-induced rat paw edema was adopted to assess the anti-inflammatory potential of isolated compounds. This model is known as the COX-2-dependent model of inflammation and is performed to validate the anti-inflammatory characteristics of drugs. Moreover, we used diclofenac as the standard drug in this assay. The mechanism of diclofenac for its anti-inflammatory action is the inhibition of the synthesis of prostaglandin by inhibition of the transiently expressed COX-2 isozyme. Hence, the COX-2 enzyme was used for docking simulations in this study. The molecular operating environment [17] suit was used for this purpose. All the isolated active phytochemicals (1-6) were docked at binding sites of COX-1 and COX-2 isoforms. The binding poses of the phytochemicals superposed on the native ligand S58 are shown in Figure 4. It can be observed that all these compounds occupied the binding site of the native ligand.

From analysis, the three-dimensional interaction plot of the compounds into the binding site of COX-2 showed that almost all the compounds interacted with the amino acid residues (Ser353, Leu352, Gln192, Arg513, His90, and Val523) that existed at an additional secondary site. Compound 1 established a hydrogen bond interaction (HBI) with Arg513, while the phenyl ring showed π-π interactions with Tyr355 (Figure 5(a)). Compound 2 formed HBIs with Leu352, Tyr385, Gly526, and Ala527 (Figure 5(b)).

The phenyl ring showed π-π interactions with Tyr355, while compound 3 showed HBIs with Arg120, Val523, and Ser530. Tyr355 formed π-lone pair interaction with the oxygen atom of the hydroxyl group (Figure 6(a)). Compound 4 also showed HBI with Tyr355, Tyr385, and Arg513. Met522 formed π-sulfur-type interactions (Figure 6(b)).

The 3D interaction plot of compounds 5 and 6 is shown in Figures 7(a) and 7(b). Compound 5 established HBIs with His90, Arg120, Tyr385, Arg513, and Glu524 (Figure 7(a)). Compound 6 formed π-lone pair interaction with Tyr355. It also showed HBIs with Arg120, Tyr385, and Trp387 (Figure 7(b)). The binding affinity values of all the compounds against COX-2 are shown in Table 2. Docking studies on the COX-1 isozyme were also performed using the 3D structure of 1EQG. The 3D interaction plots of isolated compounds 1-6 are shown in Figures 8(a)8(f). Figures 8(a)8(f) show that all the compounds had stable hydrogen bond interactions as well as π-π interactions with Arg120, Tyr355, and Ser530. The binding affinity results are shown in Table 2.

3.6. In Silico Predictions of Pharmacokinetics

For the establishment of in vivo-in silico relationship, initiation of in silico pharmacokinetic prediction for all the isolated biomolecules was investigated. The main aim of this experimentation was to predict the in vivo pharmacokinetic properties of the compounds isolated (1-6) from Diospyros lotus, depending upon their virtual structure and derived parameters. For this purpose, various molecular descriptors as indicators of molecular properties (Lipinski rule of 5), absorption (water solubility, human intestinal absorption), distribution (volume of distribution, fraction of unbound, blood-brain barrier permeability, and CNS penetration), excretion (total clearance), and toxicity (hERG I and II inhibitors, AMES toxicity, and hepatotoxicity) were computed. The molecular descriptors were calculated by using the pkCSM online tool. The results are presented in Table 3.

Almost all the phytochemicals (1-6) fulfilled the Lipinski Ro5 parameters. Data indicates that all compounds showed good human intestinal absorption (HIA, ). The water solubility value is given in log (mol/l). The value of indicates that the substance is insoluble. Highly soluble compounds showed . For the distribution of the drug in the brain, compounds having logBB values less than 0.3 are able to cross the BBB. Meanwhile, compounds having logBB values less than -1 are not considered to cross BBB easily. The distribution of the drug in various tissues is measured by the volume of distribution (VD). Here, VD is considered to be lower when the value of log VDss is less than -0.15 and high when it is greater than 0.45. In our case, almost all compounds, except 4, showed high volume of distribution. The elimination of the drug from the body is mainly associated with hydrophilicity and molecular weight of the drug. The computed results (in log ml/min/kg) shown in Table 3 revealed that compound 1 has the highest clearance rate. The order of the clearance for other compounds is 5>6>2>4>3. The toxicity of the compounds was predicted in terms of hERG channel inhibition (cardiotoxicity), AMES, and hepatotoxicity. The results shown in Table 3 revealed that all the 6 compounds might not have inhibitory action on the hERG channel. Therefore, these compounds might not pose cardiotoxicity.

4. Discussion

Inflammation is a painful edematous condition associated with various disorders. Prostaglandins (PGE2 and PGE2α) are considered to be responsible for inflammation due to increased capillary permeability. COX-1 and COX-2 are the enzymes that produce these prostaglandins (PGs). Anti-inflammatory drugs (nonsteroidal) prescribed during inflammation and available in the market actually block the activity of these enzymes (COX-1 and COX-2), hence resulting in reduction of inflammation. In traditional medicine, plants comprising naphthoquinones are investigated against inflammation and cancer to function as sedative and analgesic [22]. However, under chronic inflammatory conditions, these drugs are administrated for a longer period of time. This prolonged exposure could lead to various gastrointestinal tract problems like ulcer. Therefore, it is a challenging task for modern-day medicinal chemists and pharmacists to discover safe and effective molecules having the least adverse effects. Interestingly, the compounds 1-6 were not toxic at test doses. Diospyros lotus is traditionally used in different inflammatory conditions. The chloroform fraction of D. lotus has been documented for significant anti-inflammatory action [23]. The current compounds were isolated from the chloroform fraction of Diospyros lotus and tested for the same effect in order to investigate the chemical constituents of this fraction as anti-inflammatory agents. The antibacterial evaluation showed that the extracted compounds are most effective against the Gram-positive bacteria. In fact, the Gram-negative bacteria are considered difficult-to-treat microorganisms, due to the nature of their outer membrane which protects them from lethal effects of antibacterial agents [24]. However, the noticeable inhibition effect of the extracted compounds against the Gram-negative bacteria requires further antibacterial investigation to understand the minimum inhibitory bactericidal concentrations and the mode of action. Docking results revealed that almost all the compounds showed good interactions with the amino acid residues of the additional pocket present in the COX-2 isozyme. Hence, in the absence of in vitro results, we suggest that these compounds may be selective COX-2 inhibitors. This was also confirmed by the computed binding affinity data. All compounds showed more negative binding affinity for COX-2 inhibition than COX-1. Drug likeness of the compounds was predicted by using the online pkCSM tool. Almost all the results are within the acceptable ADMET range. The Lipinski rule was followed by all the isolated compounds. Steady-state volume of distribution (VDss) was estimated and revealed that almost all the compounds isolated may be distributed evenly. The crossing of the BBB by exogenous compounds 1-6 may cause side effects and toxicity. However, some neurological disorders like Alzheimer’s disease (AD) may require the drug to cross BBB. The BBB permeability was predicted in a study as logBB. The negative values showed that all the isolated compounds 1-6 cannot cross the BBB. As such, it can be concluded that these drugs may not be used against neuroinflammation. The toxicity of the isolated compounds in this study was predicted in terms of hERG inhibition, AMES toxicity, and hepatotoxicity. As far as cardiotoxicity is concerned, inhibition of the human ether-a-go-go-related gene (hERG) channel also has great effects on human health. Results in the current screening exhibited that all the tested compounds 1-6 were safe and possessed no cardiotoxicity. Moreover, these compounds were predicted to have no hepatotoxicity and to be non-AMES toxic [25, 26].

5. Conclusions

This study has revealed that compound 1, 2, 5, and 6 exhibited significant anti-inflammatory properties in carrageenan-induced paw edema among all the six (1-6) compounds isolated from roots of Diospyros lotus. Results of this study could provide a baseline data for pharmacological use of these isolated compounds as anti-inflammatory agents. All isolated compounds were also assessed for antibacterial sensitivity, among which compounds 1-6 exhibited remarkable activity against Staphylococcus aureus, Bacillus subtilis, and Streptococcus epidermis. Docking studies on the COX-2 enzyme were also performed. In the absence of in vitro results, it is suggested that these compounds may be selective COX-2 inhibitors. Drug likeness of the compounds was predicted by using the online pkCSM tool. Almost all the results obtained are within the acceptable drug-like properties.

Abbreviations

AD:Alzheimer’s disease
ADMET:Absorption, distribution, metabolism, excretion, and toxicity
BBB:Blood-brain barrier
COX-1:Cyclooxygenase-1
COX-2:Cyclooxygenase-2
hERG:Human ether-a-go-go-related gene
HIA:Human intestinal absorption
i.p.:Intraperitoneally
MMFF:Merck molecular force field
MOE:Molecular operating environment
PDB:Protein Data Bank
PGs:Prostaglandins
pkCSM:Predicting Small-Molecule Pharmacokinetic and Toxicity Properties
VD:Volume of distribution
VDss:Steady-state volume of distribution.

Data Availability

The data such as spectra and associated analysis used to support the finding of this study are available from the corresponding author upon request.

Conflicts of Interest

The authors declare no potential conflict of interest.

Acknowledgments

The authors are grateful to Higher Education Commission (HEC) of Pakistan. Also, the authors acknowledge the Deanship of Scientific Research at King Khalid University for funding this prolific research group no. R.G.P.2.115/41.