Abstract
Wrightia tinctoria is a constituent of several ayurvedic preparations against skin disorders including psoriasis and herpes, though not yet has been explored for anticancer potential. Herein, for the first time, we report the significant anticancer properties of a semi-purified fraction, DW-F5, from the dichloromethane extract of W. tinctoria leaves against malignant melanoma. DW-F5 exhibited anti-melanoma activities, preventing metastasis and angiogenesis in NOD-SCID mice, while being non-toxic in vivo. The major pathways in melanoma signaling mediated through BRAF, WNT/β-catenin and Akt-NF-κB converging in MITF-M, the master regulator of melanomagenesis, were inhibited by DW-F5, leading to complete abolition of MITF-M. Purification of DW-F5 led to the isolation of two cytotoxic components, one being tryptanthrin and the other being an unidentified aliphatic fraction. The overall study predicts Wrightia tinctoria as a candidate plant to be further explored for anticancer properties and DW-F5 as a forthcoming drug formulation to be evaluated as a chemotherapeutic agent against malignant melanoma.
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Introduction
Scientific validation of ethno botanical knowledge may lead to the discovery of specific and non-toxic anti-cancer formulations. Here we report the anti-melanoma efficacy of a semi- purified fraction (DW-F5) isolated from Wrightia tinctoria (Roxb.) R.Br., a small medicinal tree native to India and Burma and is known in Siddha and Ayurvedic system of Indian traditional medicine as a cure for various skin related ailments. Different parts of this plant have been accredited for alleviating diseases such as psoriasis and herpes1,2 and for the preparation of hair oils used for treating various scalp and skin disorders1,3. Additionally, the antioxidant, antiviral, antiulcer and wound healing properties of Wrightia tinctoria have also been well documented4,5,6,7. However no scientific study has been reported on the anti-cancer activity of this plant except some anecdotal information regarding its use as a traditional remedy for curing lung and breast cancer, which is not validated through scrupulous scientific experiments or systematic studies8.
Melanoma is an aggressive form of human cancer arising from the malignant transformation of the pigmented cells of skin. Constitutive activation of MAPK [Mitogen-activated protein kinase] due to the gain-of-function mutation of its up-stream regulator BRAF(serine/threonine-protein kinase B-Raf)12 and survival signals activated due to the over-expression of oncogenic transcriptional factors such as MITF-M [Microphthalmia-associated transcription factor], β-catenin and Brn-2 (POU domain, class 3, transcription factor 2)11,22,23,24,25,28, are crucial factors known to play significant role in melanoma progression. These signaling malfunctions, in solo or in combination, could create a cellular environment conducive for melanoma propagation leading to its aggressiveness. Despite extensive research, the chemotherapeutic options for melanoma cure remain dismal due to the insensitivity of melanoma cells to conventional anti-cancer drugs. This study demonstrates the promising effects of DW-F5 in blocking the melanoma growth both in vitro and in vivo along with its efficacy in modulating signals known to play a crux role in melanoma progression.
Results
Dichloromethane extract of Wrightia tinctoria leaves induces maximum cytotoxicity towards melanoma cells
Human cancer cells of different origin were treated with hexane (HEWL-Hexane Extract of Wrightia Leaves), dichloromethane (DEWL- Dichloromethane Extract of Wrightia Leaves), ethyl acetate (EEWL- Ethyl acetate Extract of Wrightia Leaves) and methanol (MEWL- Methanol Extract of Wrightia Leaves) extracts (SI methods), which were obtained by a polarity graded successive extraction of the leaves. The cytotoxic effect of these extracts was evaluated using MTT assay. The results showed that DEWL and EEWL induced considerable cytotoxicity towards skin cancer cells (IC50-20 μg/ml and 36 μg/ml respectively), compared to HEWL and MEWL (IC50-100-250 μg/ml) (Supplementary Fig. 1a–d). As DEWL was the most active extract (Patent Application No. 2743/CHE/2010), it was selected for further purification and its cytotoxicity was tested in skin cancer cell lines A375, A431 and SK-MEL-2 (SI methods), which confirmed A375 as the most sensitive cell line (Supplementary Fig. 2) and hence it was selected for subsequent studies.
Bioactivity guided fractionation of DEWL leads to the isolation of DW-F5
Successive silica gel column chromatography of DEWL led to the isolation of DW-F5 [DCM Wrightia-Fraction 5] (SI methods), which exhibits a drastic increase in cytotoxicity (IC50-8.8 μg/ml) (Supplementary Fig. 3). IR spectrum of DW-F5 exhibited peaks indicative of two carbonyl groups and 1H NMR spectrum (Supplementary Fig. 4a,b) displayed peaks due to aromatic protons, demonstrating that the fraction contains an aromatic compound with carbonyl functionality. The spectrum also contains peaks in the aliphatic region which may be indicative of an impurity or another molecule contributing to the activity of the fraction.
Toxicological evaluation of DW-F5
While the fraction induced significant cytotoxicity in melanoma cells (IC50-8.8 μg/ml) (Fig. 1a,b), it was non-toxic to normal skin fibroblasts and melanocytes even at double the concentration (Fig. 1a,b) that almost completely killed the cancer cells, indicating its biological safety. Pilot studies revealed that a dose of 120 mg/Kg of DW-F5 in NOD-SCID [Non Obese Diabetic-Severe Combined Immuno Deficiency ] mice displayed significant inhibition of tumour growth in 90% of the animals studied without mortality. We confirmed the pharmacological safety of this dose by including a five times higher concentration (600 mg/Kg) in the acute and chronic toxicity studies (SI Methods)9. None of the doses induced liver toxicity except a mild dilation of sinusoids in the group treated with 600 mg/Kg of DW-F5, which indicates mild cholestasis (Fig. 1c,d). No necro inflammatory reactions, fatty changes or obvious/irreversible liver damage were observed in any of these tissues. Though some of the biochemical parameters reveal significant deviation in response to DW-F5 administration during toxicity evaluation, none of it exceeds beyond the normal range (Fig. 1e–j), establishing the pharmacological safety of DW-F5, in vivo. Hence, 120mg/Kg dose was selected for evaluating the anticancer potential.
Evaluation of DW-F5 for apoptotic and anticlonogenic activity
To test whether DW-F5 induces apoptosis in A375 cells, we compared the extent of Annexin-PI [Propidium Iodide] positivity in both DW-F5-treated and control cells, by confocal microscopy as well as FACS analysis (SI Methods). Annexin V has a strong affinity towards phosphatidyl serine, which is externalized due to membrane flip-flop, an early event of apoptotic program. A dose dependent increase in the number of Annexin-PI positive cells was observed in DW-F5 treated cells, thus authenticating apoptosis (Fig. 2a). Corroborating this observation, flow cytometric analysis of DW-F5 treated cells stained with fluorescein isothiocyanate conjugated Annexin V and propidium iodide displayed a very significant increase in the percentage of apoptotic cells (Fig. 2b). The involvement of classical caspase cascade leading to DNA fragmentation was also investigated in DW-F5-induced apoptosis. The fraction brought about a dose dependent cleavage of both initiator (Fig. 2c,d) and effector caspases (Fig. 2e,f) and their downstream substrate, PARP [Poly ADP ribose polymerase] (Fig. 2g,h) which resulted in fragmentation of DNA (Fig. 2i).
DAPI staining was also performed to substantiate apoptosis in DW-F5 treated A375 cells (SI methods), which exhibited momentous increase in the number of fragmented or condensed chromatin, as assessed by enhancement in fluorescence intensity (Supplementary Fig. 5a).
The efficacy of the fraction to inhibit the proliferative capacity of the cells was determined by clonogenic assay (SI methods). Compared to the untreated cells, DW-F5 induced a dose dependent and highly significant reduction in the number and size of A375 clones (Supplementary Fig. 5b,c).
DW-F5 down-regulates survival signals prevalent in melanoma
Our next attempt was to analyse the effect of DW-F5 on constitutive and PMA (phorbol-12-myristate-13-acetate)-induced expression of survival signals and transcription factors prevalent in melanoma signaling (SI methods). Mutated BRAF leads to the constitutive activation of MAPK signaling in melanoma10 and its inhibition leads to tumour regression11. DW-F5 down-regulate almost completely the oncogenic BRAF (Fig. 3a), which is reported to be mutated and activated in A375 cells12. We also tested whether DW-F5 is able to down-regulate the activation of ERK1/2 [Extracellular signal-regulated kinases 1/2], which is constitutively activated in A375 cells due to their mutant BRAF status 13 and observed that 6h pre-treatment with DW-F5 down- regulates both the constitutive and PMA-induced phosphorylation of ERK1/2 (Fig. 3b). BRAF mutation activates ERK1/2 which in turn up-regulates Brn-2, a molecule highly over-expressed in BRAF mutant melanoma cells, but not in melanocytes or melanoblasts 14. Interestingly, DW-F5 could completely abolish Brn-2 expression (Fig. 3c).
Since Wnt/ β-catenin signaling pathway is strongly implicated in melanoma progression, we tested whether the cytotoxic effect exerted by DW-F5 is associated with the down-regulation of key proteins involved in this pathway. A substantial down-regulation of β-catenin upon treatment of cells with DW-F5 was observed (Fig. 3d) indicating that Wnt signaling pathway may have a regulatory role in DW-F5-induced cytotoxicity. All the pathways discussed above converge into MITF-M, which is reported to be the pivotal molecule in melanoma progression15. Interestingly, DW-F5 completely abolished the constitutively expressed MITF-M in melanoma (Fig. 3e).
To evaluate whether the melanoma specific molecules, Brn-2 and MITF-M have crucial role in regulating DW-F5-induced cytotoxicity, we analysed the expression pattern of these molecules in response to DW-F5, in all the three skin cancer cell lines, which were initially screened for DEWL-induced cytotoxicity. While the melanoma cell lines A375 and SK-MEL-2 over-express these molecules, the non-melanoma cell line, A431 had a very feeble expression (Supplementary Fig. 6b,c), which is correlating with their cytotoxicity data (Supplementary Fig. 2). While DW-F5 abolished both the molecules in A375, it failed to completely inhibit MITF-M in SK-MEL-2 at the concentrations used (Supplementary Fig. 6b,c), though there was a substantial down-regulation, which may be the reason for the resistance of this cell line to DW-F5 compared to A375 (Supplementary Fig. 6a).
Moreover, both constitutive16,17 and PMA-induced activation of Akt [Protein kinase B (PKB)] (Fig. 3f) and NF-κB [nuclear factor kappa-light-chain-enhancer of activated B cells] (Fig. 3g,h) were also down-regulated by DW-F5 in A375 cells. Next we investigated the effect of DW-F5 on COX-2 [Cyclooxygenase-2] and Bcl-2 [B-cell lymphoma 2], which in many occasions function as down-stream targets of NF-κB, though Bcl-2 can also act independent of NF-κB17. Interestingly, DW-F5 treatment abolished PMA-induced up-regulation of COX-2 and Bcl-2 (Fig. 3i,j).
DW-F5 inhibits development of melanoma tumour in NOD-SCID mice
An orthotopic xenograft model (Supplementary Fig. 7) of melanoma was used to validate the anticancer efficacy of DW-F5 in vivo (SI methods & Fig. 4a,b). Surprisingly, compared to untreated (Group 4A) animals (623 mm3 ± 51.61), no measurable tumours were developed till the end of the experiment in group 5 and 6 animals [Group 5 & 6 A], which started receiving DW-F5, the very next day after tumour implantation [Day 1 experiment], though very small tumours (40 mm3 ± 7.07 for i.d. [Intradermal] & 141 ± 6.36 for i.p. [Intraperitoneal]) were observed beneath the skin after sacrificing. Some of these animals did not develop even palpable tumours, which arouse a confusion that, administration of the drug, the very next day of implantation might have killed the cells, without allowing them to form a tumour. Hence representatives of these animals [Group 6A& B] were kept for two more weeks, keeping proper controls [Group 4B], without giving DW-F5. Interestingly, tumours developed in these animals, though very small (98 ± 9.89 mm3 for i.d. & 382 ± 21.21 mm3 for i.p.) compared to that of untreated controls (1224 ± 84.85) (Fig. 4a). Moreover, intradermal administration of DW-F5 was found to be more effective, as evidenced by a significant reduction in tumour volume, when compared to that of intraperitoneal mode of administartion. On the other hand, group 2 and 3 animals that started receiving DW-F5, 15 days after tumour implantation [Day 15 experiment], developed measurable tumours, the growth of which were also significantly inhibited by DW-F5 [control:1728 ± 103.23; i.d. :348 ± 35.35 & i.p. : 271 ± 64.34] (Fig. 4b). Histopathological analysis indicated a massive destruction of cells in DW-F5 treated tissues (Fig. 4c). The drastic decrease in the expression of the cell proliferation biomarker, PCNA [Proliferating cell nuclear antigen] observed in the tumour tissues of mice treated with DW-F5 [Group 5A] as assessed by IHC analysis also correlated with the extent of tumour reduction (Fig. 4d).
Supporting the in vitro results (Fig. 3a), the tissue expression status of BRAF in DW-F5-treated group [Group 5A] was considerably less compared to that of untreated controls (Fig. 5a). A strong down-regulation in the BRAF-induced constitutive expression of p-ERK1/2 (Fig. 5b) was also noted in these tissues authenticating the in vitro results (Fig. 3b). Moreover, a complete abolition in the expression of Brn-2 (Fig. 5c), the down-stream target of both BRAF/ERK1/2 and WNT/β-catenin pathways and a drastic inhibition in the nuclear translocation of β-catenin (Fig. 5d) were also observed in the treated tissues [Group 5A], substantiating the in vitro results (Fig. 3c,d). These results confirm that both these pathways have a considerable role in regulating the anticancer effect of DW-F5. Most importantly, the expression of MITF-M, which is considered as the master regulator of melanoma signaling was drastically down-regulated by DW-F5 (Fig. 5e), exactly correlating with the in vitro data (Fig. 3e), authenticating its regulatory role.
The inhibitory effect of DW-F5 in Akt- NF-κB pathway was also illustrated in the IHC data, which exhibited complete inhibition in the nuclear translocation of p-p65, the active subunit of NF-κB and its downstream target Bcl-2 in the treated [Group 5A] tissues (Fig. 5f,g), which strongly supports the in vitro data (Fig. 3g,h,j).
DW-F5 reduces the melanoma metastasis & angiogenesis in NOD-SCID mice model
To study the anti-metastatic and anti-angiogenic potential of DW-F5, A375-Ren-Luc (A375-Renilla-Luciferase) were injected intradermally to the flank region of the mice to produce orthotopic tumours (SI Methods) and were kept for two months along with DW-F5 administration and analysed for metastasis. We observed that DW-F5 treatment has significantly reduced the metastatic spread of A375-Ren-Luc cells to the prominent sites of melanoma metastasis, such as the liver and lungs by DW-F5 treatment, as assessed by in vitro luciferase assay (SI Methods). The relative renila luciferase activity (Rluc) was found to be more than 3 × 105 times greater in the liver (P-value ≤ 0.0001) and 2.5 × 103 times in the lung tissues (P-value ≤ 0.001) of the untreated animals than that of DW-F5 treated animals, demonstrating its potential as a strong inhibitor of metastasis (Fig. 6a,b). The anti-metastatic potential of DW-F5 was further confirmed by the extensive reduction in the expression of MMP-9 in tumours harvested from mice treated with DW-F5 (Fig. 6c) confirming the in vitro results (Fig. 3l).
DW-F5 treatment markedly blocked blood vessel formation in and around the tumour mass (Fig. 7a). This observation was further supported by a considerable reduction in the major angiogenesis marker protein, VEGF in tumour sections of DW-F5-treated mice as assessed by IHC (Fig. 7b), corroborating the in vitro results (Fig. 3k). Taken together, the above noted novel observations strongly attest the candidature of DW-F5 as a potential nominee to be evaluated for its anticancer, anti-metastatic and anti-angiogenic efficacy against malignant melanoma.
DW-F5 on further fractionation yields tryptanthrin and an aliphatic fraction, both of which are cytotoxic to melanoma cells
We tried to further purify DW-F5 by repeated column chromatography, which lead to the isolation of two cytotoxic components, one of which is aromatic and the other is aliphatic. While DW-F5 showed an IC 50 of 8.8 μg/ml, the aromatic fraction and the aliphatic fraction exhibited a substantial decrease in IC 50 values [0.8 and 5.9 μg/ml respectively] (Fig. 8a).
In the 1H NMR [Nuclear Magnetic Resonance] spectrum of the aromatic component, the peaks were observed in the region ranging from δ 7.33–8.55 ppm, confirming its aromatic nature and the peaks corresponds to the eight protons of the phenyl ring (Fig. 8b). The 13C NMR spectrum exhibited peaks in the region 117.97–182.54 corresponding to fifteen carbons of which 182.54 and 177.82 are characteristic of carbonyl carbons (Fig. 8c). In the ESI [Electrospray Ionization] mass spectrum, the molecular ion [M+H]+ was observed at m/z 249 (Fig. 8d). The melting point of the isolated compound was observed between 259–260 °C (Fig. 8e). Based on the above analytical data the isolated compound was identified as Indolo[2,1-b]quinazoline-6,12-dione [tryptanthrin] (Fig. 8f) (SI methods). The melting point and spectral data of the isolated compound is in accordance with the reported synthetic compound18.
In the 1H NMR spectrum of the aliphatic component, peaks are observed in the region, δ 0.8–5.3, which corresponds to protons in aliphatic compound/s (Fig. 8g). Silica gel column chromatography and spectral analyses is going on to further purify and identify the active molecule/s present in this fraction.
Discussion
Despite intense research, the chemotherapeutic armamentarium for the treatment of malignant melanoma, one of the most aggressive forms of human cancer, remains limited19. The present study introduces DW-F5, a semi purified fraction isolated from the leaves of an indigenous plant, Wrightia tinctoria, as a potential formulation against melanoma. To the best of our knowledge, no information regarding the anti-tumour activity of this plant subsists in literature, except a report on the anti-inflammatory activity of its leaf extract20.
The efficacy of DW-F5 as an apoptosis inducer deserves prime mentioning in this context. Apoptosis is an energy-dependent cascade of molecular events characterized by membrane flip flop, caspase activation and subsequent cleavage of functional enzymes such as PARP leading to the systematic dismantling of cells21. In concordance with the currently acceptable dogma of apoptosis, DWF-5 induces such signature molecular events of apoptosis in melanoma cells demonstrating its chemotherapeutic potential.
From the experimental results, it is quite logical to presume that the reason behind the efficacy of DW-F5 to inhibit melanoma cells, resides in its ability to down-regulate the expression of some of the key molecules involved in melanoma progression. The pronounced ability of DW-F5 to inhibit MITF-M is a case in point. MITF-M is a transcription factor, which is considered as a melanoma oncogene and the master regulator of melanocyte development22. It is known that the ectopic co-expression of MITF and mutant BRAF leads to transformation of primary melanocytes23 while the abrogation of MITF-M activity in BRAF V600E MITF-M melanoma leads to dramatic tumour regression24. Besides this, disruption of the canonical Wnt pathway also abrogates growth of melanoma cells25 and constitutive over-expression of MITF-M rescues the growth suppression, which establishes the critical role of both β-catenin and MITF-M in melanoma development15. Phosphorylation status of ERK 1/2 has strong correlation to the malignant potential and progression of melanoma26. It has been shown that oncogenic BRAF induces phosphorylation of ERK 1/227 leading to up-regulation of the transcription factor, Brn-2 and subsequently the up-regulation of MITF-M22. Up-regulation of β-catenin too induces Brn-228 and hence leads to up-regulation of MITF-M22.
However, our data regarding the regulatory effect of MITF-M in DW-F5-induced cytotoxicity in multiple skin cancer cell lines indicate that the complete abolition of MITF expression, but not the blockage of Brn-2 expression, is the crucial factor for DW- F5-induced cell death. While a moderate reduction of MITF-M and a complete abolition of Brn-2 by 10 μg/ml of DW-F5 are not enough to induce 50% cytotoxicity in SK-MEL-2 cell line (IC50- 24.02 μg/ml), the same concentration, which caused complete abolition of MITF-M and Brn-2 expression induced more than 50% cytotoxicity in A375 (IC50- 9.8 μg/ml) indicating that MITF-M has an upper hand over Brn-2 in regulating DW-F5-induced cytotoxicity. Curiously enough, we could find that A431 (a non melanoma cell line) having comparatively low or nil expression of Brn-2 and MITF and perhaps not depending on these molecules for its survival, was relatively non-sensitive to DW-F5 (IC50- 47.1 μg/ml).
About 50% of melanoma cells harbour mutation in BRAF kinase protein, which will lead to the deregulated activation of its downstream ERK/ MEK effectors. Given the significance of BRAF activation in melanoma cells, the down-regulation of BRAF in the DW-F5-treated cells and xenograft tissues assumes importance. Melanoma cells with BRAF mutation, through their elevated ERK1/2 signaling, activate NF-κB29, which in turn may lead to the transcription of proteins regulating melanoma progression and metastasis. Consideration of COX-2, a molecule downstream of NF-κB30, as an attractive target for melanoma treatment underscores the importance of NF-κB signaling axis in melanoma cells. An elevated Akt activation, which is reported in ~77% of melanomas31 could also be a factor contributing to the elevated NF-κB signaling32,29. Interestingly, there are reports placing MITF-M and one of its direct targets, Bcl-233,34, downstream of Akt- NF-κB signaling axis in melanoma cells35. The efficacy of DW-F5 to disarray the above-mentioned signaling axis operating in melanoma cells is demonstrated in its ability to down-regulate constitutive as well as induced activation of ERK1/2, Akt, NF-κB, COX-2 and Bcl-2.
The histopathology results of the liver cryosections and the normal range of the serum biochemistry profile of the animals administered with DW-F5, obtained from the toxicity studies confirms its pharmacological safety. Moreover, the non-toxic nature and the medicinal property of the leaves of Wrightia tinctoria is already established as its decoction is being used orally against jaundice, fever and tooth ache and also applied as poultice against psoriasis, mumps and herpes1.
Taken together, we observed that DW-F5 is inhibiting the expression of molecules such as BRAF, β-catenin, Akt and NF-κB, all of which are known to mediate signals converging in MITF-M, the master regulator of melanomagenesis. Hence the probable mechanism of the anti-tumour efficacy of DW-F5 is the down-regulation of BRAF, which leads to dephosphorylation of ERK1/2, along with the inhibition of β-catenin and Akt-NF-κB, together contributing to the inhibition of MITF-M, which in turn inhibits the anti-apoptotic molecule Bcl-2, ultimately leading to cell annihilation. However, more studies are needed to validate and confirm this assumption.
A considerable reduction in the vasculature in and around the treated tumour mass and the substantial down-regulation of VEGF expression in both in vitro and IHC results, illustrates the anti-angiogenic potential of DW-F5, an important event involved in the progression and spread of tumour. In harmony with the in vitro results, the substantial decrease observed in the expression of MMP-9, a major metastatic marker protein, in tissue sections of DW-F5 treated mice, confirms and attests the anti-metastatic potential of the fraction.
Spectral analyses indicates that DW-F5 is composed of an aromatic compound, tryptanthrin and an uncharacterized aliphatic fraction, both of which are cytotoxic to melanoma cells. Even though no study has been conducted on the anticancer effect of tryptanthrin against malignant melanoma, there are reports indicating its efficacy against multi drug resistant breast cancer cells36, colorectal adenocarcinoma37 and leukemia38,39. The cancer chemopreventive property of tryptanthrin has also been reported40 against intestinal tumours. Further studies are in progress to identify the aliphatic component of DW-F5. Investigation is also going on to identify the multiple molecular pathways regulating the anticancer activity of DW-F5, which may help to bring up the formulation as a potential drug for treating melanoma.
Methods
Plant materials
Wrightia tinctoria leaves were collected from Sanjeevani Naturopathic Centre and authenticated by Dr. Reni Muringatheri (SI).
Extraction, isolation and characterization of DW-F5
Successive extraction was done using solvents of ascending polarity and concentrated using a rotary evaporator (SI Methods). The DCM extract was subjected to silica gel column chromatography to isolate the semi purified fraction DW-F5 (SI Methods). The IR and 1H NMR spectra of the fraction were recorded for its characterization.
Cell lines
FS was a gift from Dr. Bharat B. Agarwal. HEMa-LP was purchased from Gibco. All the other cell lines were procured from NCCS (SI).
Antibodies and reagents
Antibodies against Caspases, p-ERK1/2, cleaved PARP and p-Akt were obtained from Cell Signaling (Beverly, MA, USA); those against Brn-2 and MITF-M were purchased from Abcam (Cambridge, UK). Antibodies against β-catenin, p-p65, Bcl-2, COX-2, PARP, VEGF and BRAF were purchased from Santa Cruz Biotechnology (Santa Cruz, CA, USA). Chemicals for purification were obtained from Merck and other chemicals were purchased from Sigma (SI).
MTT assay
The cytotoxic effect of the extracts and fractions were determined by MTT assay as described earlier41 (SI Methods).
Annexin V-Propidium Iodide staining and FACS analysis
The cells were treated with DW-F5 for 24 h, stained with annexin and PI and documented in a confocal microscope. The cells were treated with DW-F5 for 48 h, stained with annexin and PI and analysed using flow cytometry [SI Methods].
Clonogenic assay
Clonogenic assay was performed in melanoma cells treated with or without DW-F5 as described previously42 (SI Methods).
Western blot analysis
Total protein isolated from cells after indicated treatments were subjected to Western blotting as described earlier41 (SI Methods).
DNA Fragmentation Assay
DNA Fragmentation Assay was done as described in SI Methods.
Preparation of nuclear extracts and EMSA
EMSA was performed to evaluate DNA-binding activity of NF-κB as described earlier42 (SI Methods).
Plasmid
The renilla luciferase expression plasmid, pKT2/mCa-Rluc-IRES-Puro was constructed as described earlier43 (SI Methods).
Transfection
A375-Ren-Luc cells were generated by stably transfecting A375 cells with pKT2/mCa-Rluc-IRES-Puro vector using Lipofectamine 2000 (Invitrogen), according to manufactures protocol (SI Methods).
Luciferase assay
The luminescence of A375-Ren-Luc cells in different tissues of NOD-SCID mice were analysed using the Dual-Luciferase Reporter Assay System (Promega) according to manufacturer’s protocol (SI Methods).
In vivo studies
Animal studies were performed in accordance with the approved guidelines of Institute Animal Ethics Committee [IAEC] of Rajiv Gandhi Centre for Biotechnology, Thiruvananthapuram, Kerala, India. The anticancer, anti-metastatic and anti-angiogenic properties were evaluated using orthotopic model in NOD-SCID mice (SI Methods). The toxicological analyses was performed in Swiss albino mice. DW-F5 was administered in liposome-encapsulated form44 (SI Methods).
Orthotopic model
Mice were injected with A375-Ren-Luc cells intradermally. DW-F5 was administered twice weekly for four weeks adopting two different types of drug treatment strategies and routes of administration (SI Methods).
Metastasis model
Mice were injected with A375-Ren-Luc cells as described in the orthotopic model. Drug was administered twice weekly for eight weeks. The liver and lung tissues were analysed for metastatic spread using in vitro luciferase assay (SI Methods).
Angiogenesis experiment
The anti-angiogenic potential was assessed by Western blot in melanoma cells and by observing the vascularisation on and around the tumour and the expression of VEGF in the tumour cryosections by using immunohistochemistry (IHC) analysis.
Toxicological analyses
Acute toxicity
Doses of 0, 120 and 600 mg/Kg of DW-F5 were given to groups of six mice each9. Animals were euthanized on day 8. The liver tissue was analysed by histopathology using H&E staining45 and the serum was used to perform Liver Function Test (LFT) (SI Methods).
Chronic Toxicity
Doses of 0 and 120 mg/Kg of DW-F5 were given to groups of six mice each9. Animals were euthanized after 90 days and toxicity was measured as described above.
Histology and Immunohistochemistry
The tumour tissues from mice were fixed and cryosectioned (SI Methods). Expression of different proteins in the tissue sections was assessed using Super Sensitive Polymer-HRP IHC Detection System (Biogenex, USA) (SI Methods).
Isolation of tryptanthrin and aliphatic fraction form DW-F5
DW-F5 was subjected to silica gel column chromatography to isolate tryptanthrin and the aliphatic fraction (SI methods).
Structure elucidation of bioactive compound
The pure compound was characterized by its 1H NMR, 13C NMR, ESI-MS spectra and melting point analyses (SI Methods).
Spectral data
Indolo[2,1-b]quinazoline-6,12-dione (Tryptanthrin): Yellow solid; mp 259–260 °C (Lit. mp 258–260 °C, 18; 1H NMR (CDCl3, 500 MHz) δ 7. 34 (d, J = 7.9 Hz, 1H), 7.69 (dt, J = 7.9 and 2.1 Hz, 1H), 7.72 (dt, J = 7.9 and 2.1 Hz, 1H), 7.78 (dt, J = 7.9 and 2.1 Hz, 1H), 7.83 (d, J = 7.9 Hz, 1H), 7.95 (d, J = 7.9 Hz, 1H), 8.36 (dd, J = 7.9 and 2.1 Hz, 1H), 8.55 (d, J = 7.9 Hz, 1H); 13C NMR (CDCl3, 100 MHz) δ 117.9, 121.9, 123.7, 125.3, 127.1, 127.5, 130.2, 130.7, 135.1, 138.2, 144.3, 146.3, 146.6, 158.1, 177.8, 182.5; ESIMS (m/z) 249 [M+H]+.
Statistics
The error bars represent ± S.D., taken from three independent experiments. Statistical significance was analysed by Student’s two-tailed, unpaired t test or two-way ANOVA followed by Tukey’s post test. Significance level was set at P < 0.05.
Additional Information
How to cite this article: Antony, J. et al. DW-F5: A novel formulation against malignant melanoma from Wrightia tinctoria. Sci. Rep. 5, 11107; doi: 10.1038/srep11107 (2015).
Change history
03 August 2015
A correction has been published and is appended to both the HTML and PDF versions of this paper. The error has not been fixed in the paper.
03 August 2015
Wrightia tinctoria is a constituent of several ayurvedic preparations against skin disorders including psoriasis and herpes, though not yet has been explored for anticancer potential. Herein, for the first time, we report the significant anticancer properties of a semi-purified fraction, DW-F5, from the dichloromethane extract of W. tinctoria leaves against malignant melanoma. DW-F5 exhibited anti-melanoma activities, preventing metastasis and angiogenesis in NOD-SCID mice, while being non-toxic in vivo. The major pathways in melanoma signaling mediated through BRAF, WNT/β-catenin and Akt-NF-κB converging in MITF-M, the master regulator of melanomagenesis, were inhibited by DW-F5, leading to complete abolition of MITF-M. Purification of DW-F5 led to the isolation of two cytotoxic components, one being tryptanthrin and the other being an unidentified aliphatic fraction. The overall study predicts Wrightia tinctoria as a candidate plant to be further explored for anticancer properties and DW-F5 as a forthcoming drug formulation to be evaluated as a chemotherapeutic agent against malignant melanoma.
References
Chandrashekar, R., Adake, P., Rao, S. & Santanusaha, S. WRIGHTIA TINCTORIA: AN OVERVIEW. J. Drug Deliv. 3, 196–198 (2013).
Mitra, S., Seshadri, S., Venkataranganna, M. & Gopumadhavan, S. Reversal Of Parakeratosis, A Feature Of Psoriasis By Wrightia tinctoria (In Emulsion)-Histological Evaluation Based On Mouse Tail Test. Ind. J. Dermatol. 43, 102–104 (1998).
Krishnamoorthy, J., Ranganathan, S., Shankar, S. G. & Ranjith, M. Dano: A herbal solution for dandruff. Afr. J. Biotechnol. 5, 960–962 (2006).
Lakshman, D. K., Rao, K., Madhavi, B., Kumar, D. S. & Banji, D. Anti oxidation activity of Wrightia tinctoria Roxb bark and Schrebera swietenoides Roxb bark extract. J. Pharm. Res. 4, 396 (2011).
Sathyanarayanan, S. et al. Preliminary phytochemical screening and study of antiviral activity and cytotoxicity of Wrightia tinctoria. Int. J. Chem. Sci. 7, 1–5 (2009).
Divakar, M. C. & Lakshmi, S. D. Antiulcer activity of Wrightia tinctoria (Roxb.) R. Br. Der. Pharmacia Sinica 2, 355–360 (2011).
Veerapur, V. et al. The effect of ethanol extract of Wrightia tinctoria bark on wound healing in rats. J. Nat. Remedies. 4, 155–159 (2004).
Oudhia, P., Traditional Medicinal Knowledge about Herbs used in Treatment of Cancer in Chhattisgarh, India. 80. Uses of Dudhi (Wrightia tinctoria)., (2006-2007) (Date of access: 28/04/2015)
Patra, C. R. et al. In vivo toxicity studies of europium hydroxide nanorods in mice. Toxicol. Appl. Pharmacol. 240, 88–98, 10.1016/j.taap.2009.07.009 (2009).
Hoeflich, K. P. et al. Oncogenic BRAF is required for tumor growth and maintenance in melanoma models. Cancer Res. 66, 999–1006 (2006).
Flaherty, K. T. et al. Inhibition of mutated, activated BRAF in metastatic melanoma. N. Engl. J. Med. 363, 809–819 (2010).
Sumimoto, H., Imabayashi, F., Iwata, T. & Kawakami, Y. The BRAF–MAPK signaling pathway is essential for cancer-immune evasion in human melanoma cells. J. Exp. Med. 203, 1651–1656 (2006).
Mirmohammadsadegh, A. et al. ERK1/2 is highly phosphorylated in melanoma metastases and protects melanoma cells from cisplatin-mediated apoptosis. J. Invest. Dermatol. 127, 2207–2215 (2007).
Goodall, J. et al. The Brn-2 transcription factor links activated BRAF to melanoma proliferation. Mol. Cell. Biol. 24, 2923–2931 (2004).
Widlund, H. R. et al. β-Catenin–induced melanoma growth requires the downstream target Microphthalmia-associated transcription factor. J. Cell Biol. 158, 1079–1087 (2002).
Feng, Y. et al. Effective inhibition of melanoma by BI‐69A11 is mediated by dual targeting of the AKT and NF‐κB pathways. Pigment Cell Melanoma Res. 24, 703–713 (2011).
Bava, S. V. et al. Akt is upstream and MAPKs are downstream of NF-kappaB in paclitaxel-induced survival signaling events, which are down-regulated by curcumin contributing to their synergism. Int. J. Biochem. Cell Biol. 43, 331–341, 10.1016/j.biocel.2010.09.011S1357-2725(10)00330-4(2011).
Vaidya, S. D. & Argade, N. P. Aryne insertion reactions leading to bioactive fused quinazolinones: diastereoselective total synthesis of cruciferane, Org. Lett. 15 4006–4009 (2013).
Keith, T. F. Chemotherapy and Targeted Therapy Combinations in AdvancedMelanoma. Clin. Cancer Res. 12, 2366s–2370s, 10.1158/1078-0432.CCR-05-2505 (2006).
Aleykutty, N., Bindu, A., Sangeetha, S. & Jiljit, G. Evaluation of Anti-inflammatory and Analgesic Activity of Wrightia tinctoria Leaves. J. Biol. Active Prod. Nat. 1, 33–41 (2011).
Elmore, S. Apoptosis: a review of programmed cell death. Toxicol. Pathol. 35, 495–516 (2007).
Wellbrock, C. et al. Oncogenic BRAF regulates melanoma proliferation through the lineage specific factor MITF. PLoS One. 3, e2734 (2008).
Garraway, L. A. et al. Integrative genomic analyses identify MITF as a lineage survival oncogene amplified in malignant melanoma. Nature 436, 117–122 (2005).
Lister, J. A. et al. A Conditional Zebrafish MITF Mutation Reveals MITF Levels Are Critical for Melanoma Promotion vs. Regression In Vivo. J. Invest. Dermatol. 134,133–140 (2013).
Damsky, W. E. et al. β-catenin signaling controls metastasis in Braf-activated Pten-deficient melanomas. Cancer cell. 20, 741–754 (2011).
Zhuang, L. et al. Activation of the extracellular signal regulated kinase (ERK) pathway in human melanoma. J. Clin. Pathol. 58, 1163–1169, 58/11/1163 10.1136/jcp.2005.025957 (2005).
Smalley, K. S. A pivotal role for ERK in the oncogenic behaviour of malignant melanoma? Int. J. Cancer. 104, 527–532, 10.1002/ijc.10978 (2003).
Goodall, J. et al. Brn-2 expression controls melanoma proliferation and is directly regulated by β-catenin. Mol.Cell. Biol. 24, 2915–2922 (2004).
Madonna, G., Ullman, C. D., Gentilcore, G., Palmieri, G. & Ascierto, P. A. NF-kB as potential target in the treatment of melanoma. J. Transl. Med. 10, 53, 10.1186/1479-5876-10.53 (2012).
Becker, M. R., Siegelin, M. D., Rompel, R., Enk, A. H. & Gaiser, T. COX-2 expression in malignant melanoma: a novel prognostic marker? Melanoma. Res. 19, 8–16 (2009).
Madhunapantula, S., Mosca, P. J. & Robertson, G. P. The Akt signaling pathway: an emerging therapeutic target in malignant melanoma. Cancer. Biol. Ther. 12, 1032–1049 (2011).
Dhawan, P., Singh, A. B., Ellis, D. L. & Richmond, A. Constitutive activation of Akt/protein kinase B in melanoma leads to up-regulation of nuclear factor-κB and tumor progression. Cancer. Res. 62, 7335–7342 (2002).
Levy, C., Khaled, M. & Fisher, D. E. MITF: master regulator of melanocyte development and melanoma oncogene. Trends. Mol. Med. 12, 406–414 (2006).
McGill, G. G. et al. Bcl2 regulation by the melanocyte master regulator Mitf modulates lineage survival and melanoma cell viability. Cell 109, 707–718 (2002).
Bedogni, B. & Powell, M. B. Hypoxia, melanocytes and melanoma–survival and tumor development in the permissive microenvironment of the skin. Pigment Cell Melanoma Res. 22, 166–174 (2009).
Yu, S.-T., Chen, T.-M., Tseng, S.-Y. & Chen, Y.-H. Tryptanthrin inhibits MDR1and reverses doxorubicin resistance in breast cancer cells. Biochem. Biophys. Res. Commun. 358, 79–84 (2007).
Zhu, X. et al. Transport characteristics of tryptanthrin and its inhibitory effect on P-gp and MRP2 in Caco-2 cells. J. Phar. Pharm. Sci. 14, 325–335 (2011).
Chan, H.-L., Yip, H.-Y., Mak, N.-K. & Leung, K.-N. Modulatory effects and action mechanisms of tryptanthrin on murine myeloid leukemia cells. Cell. Mol. Immunol. 6 335–342 (2009).
Miao, S. et al. Proliferation-attenuating and apoptosis-inducing effects of tryptanthrin on human chronic myeloid leukemia k562 cell line in vitro. Int. J. Mol. Sci. 12, 3831–3845 (2011).
Motoki, T. et al. Inhibition of hepatocyte growth factor induction in human dermal fibroblasts by tryptanthrin. Biol. Pharm. Bull. 28, 260–266 (2005).
Bava, S. V. et al. Sensitization of taxol-induced apoptosis by curcumin involves down-regulation of nuclear factor-kappaB and the serine/threonine kinase Akt and is independent of tubulin polymerization. J. Biol. Chem. 280, 6301–6308, M410647200 10.1074/jbc.M410647200 (2005).
Puliyappadamba, V. T. et al. Nicotine-induced survival signaling in lung cancer cells is dependent on their p53 status while its down-regulation by curcumin is independent. Mol. Cancer. 9, 220, 10.1186/1476-4598-9-2201476-4598-9-220 (2010).
Volk-Draper, L. D., Rajput, S., Hall, K. L., Wilber, A. & Rana, S. Novel Model for Basaloid Triple-negative Breast Cancer: Behavior In Vivo and Response to Therapy. Neoplasia 14, 926–942 (2012).
Ruby, A., Kuttan, G., Dinesh Babu, K., Rajasekharan, K. & Kuttan, R. Anti-tumour and antioxidant activity of natural curcuminoids. Cancer.Lett. 94, 79–83 (1995).
Prasad, S. B. & Giri, A. Antitumor effect of cisplatin against murine ascites Dalton’s lymphoma. Indian J. Exp. Biol. 32, 155–162 (1994).
Acknowledgements
This work was supported by CSIR, Government of India. We thank Dr. Y. Venkateswarlu for helping in purification and Dr. Rajagopal and Dr. Santhosh Sankaran for in vivo studies and Arun Kumar T.T., Haritha H. Nair, Sai Shyam Narayanan, Mohan Sankar, Anurup K.G. and Abdul Rasheed V.T. for their technical help. JA thanks UGC and MS thanks DST for fellowship.
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J.A. and M.S. contributed equally to the work, J.A. performed in vitro and in vivo experiments, M.S. performed in vivo experiments, V.V. and S.A. performed western blotting, H&E. and I.H.C. analyses, A.P., H.C., S.M.J., L.R.N., N.K.S., E.J.P., S.I.V., S.I.V. and E.R. performed purification experiments. M.R.K. and M.S.R.M. did spectroscopic analysis, S.R. constructed Luciferase plasmid, S.S. verified histopathology, R.J.A. designed research and wrote the paper.
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Antony, J., Saikia, M., V, V. et al. DW-F5: A novel formulation against malignant melanoma from Wrightia tinctoria. Sci Rep 5, 11107 (2015). https://doi.org/10.1038/srep11107
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DOI: https://doi.org/10.1038/srep11107
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