Anti-plasmodial activity of Dicoma tomentosa (Asteraceae) and identification of urospermal A-15-O-acetate as the main active compound

Eight crude extracts were prepared using eight different solvents: petroleum ether, hexane, dichloromethane, diethylether, ethylacetate, methanol, ethanol/water (50%, v/v) and hot water. For each solvent, 5 g of dried plant powder were macerated with 50 ml of solvent, while being shaken for 30 minutes with a magnetic stirrer. This step was repeated twice. The preparations were filtered and evaporated under reduced pressure.

For the aqueous crude extract, we prepared a decoction of 5 g dried plant powder in 150 ml distilled water for 90 min in order to approximate the traditional preparation method. The preparation was then filtered and freeze dried.

Haemolysis assays were conducted with the eight crude extracts and isolated pure compound, according to a previously described procedure [36]. Briefly, red blood cells suspensions (10% in PBS (v/v)) were incubated under agitation at room temperature for one hour with extract or pure compound solutions (final concentration = 100 μg/ml and DMSO <1%). The mixtures were then centrifuged at room temperature for 5 min at 10,000 × g and the absorbance (OD) of the supernatants was measured at 550 nm with a microplate reader (Stat Fax 2100, Awareness Technology Inc). The crude extracts/pure compound were tested in triplicate at a final concentration of 100 μg/ml. Triton X-100 1% (v/v) was used as a positive control (100% red blood cell lysis) and PBS as a negative control (0% red blood cell lysis). The red blood cell lysis percentage (H) was determined as follows: H = (OD550nm sample − OD550nm PBS)/(OD550nm Triton X-100 1% − OD550nm PBS). The results were expressed as means ± SD with n = 3.

The present study was approved by the Ethical Committee for the use of laboratory animals at the University of Liège (no. 721) and was designed according to the internationally recognized guidelines. Methanol, hydroethanolic and aqueous extracts of D. tomentosa were tested using a test protocol based on the four-day suppressive test of Peters [35]. Female Swiss mice (10 weeks of age, 25 ± 2 g), obtained from Charles River Laboratories (Brussels), were infected by the rodent parasite Plasmodium berghei NK173, following the protocol described in Frederich et al.[37]. Groups of five mice were formed randomly. The treatment doses (100 mg/kg ip or 300 mg/kg po, dissolved in 7% Tween 80 and 3% ethanol) were given intraperitoneally (methanol and hydroethanolic extracts) or orally (hydroethanolic and aqueous extracts), four hours after infection (day 0). The treatment was repeated once daily for the next three days (on days 1, 2 and 3 post-infection). On day 4 and day 7, thin blood smears were made from mouse-tail blood and were stained with Giemsa. Slides were inspected under the microscope and parasitaemia was determined by counting at least 500 erythrocytes. Mice were controlled for their mortality for two weeks. Chloroquine diphosphate salt at 4 mg/kg (ip) was used as positive control and a methanol extract of the bark of Cinchona succirubra at 200 mg/kg (ip) was used as “positive plant extract control” due to the known presence of quinine in this Cinchona bark extract. This was used as a supplemental positive control to observe the profile of inhibition with a plant extract containing a known active ingredient. The vehicle solution (7% Tween 80 and 3% ethanol) was used as a negative control.

All eight tested extracts were found to be active against both chloroquine-sensitive 3D7 and -resistant W2 strains of P. falciparum (IC₅₀ < 50 μg/ml). IC₅₀ values obtained with crude extracts are detailed in Table 1, as well as extraction yields from plants (w/w). Dichloromethane, diethylether, ethylacetate, and methanol extracts were found to be highly active with IC₅₀ ≤ 5 μg/ml, while hydroethanolic and hot water extracts displayed a promising activity (IC₅₀ ≤ 15 μg/ml). Petroleum ether and hexane extracts showed a lower level of activity.

The levels of activity observed with the dichloromethane, methanol and hot water extracts were about twice as high as the anti-plasmodial IC₅₀ values obtained for the same extracts in the previous study. That previous study was conducted with a batch of D. tomentosa also collected in Burkina Faso, at the same time of year but in 2007 and in a different area (and with samples from stock maintained in less adequate storage conditions) [20]. The anti-plasmodial activity obtained with this new batch was found to be in the same range as can be observed with Artemisia annua extracts [38]. The anti-plasmodial activity of the hot water extract supports the traditional use of this plant to treat malaria and is an interesting result when considering further prospects for its local valorization.

In vivo experiments with methanol, hydroethanolic and aqueous extracts of D. tomentosa whole plant confirmed the anti-plasmodial activity of this Asteraceae. Both treatments given intraperitoneally (methanol and hydroethanolic extracts, 100 mg/kg) displayed an inhibition of parasitaemia in the range of 40-60% at days 4 and 7. Unfortunately, both extracts were found to be toxic when the dose was increased to 200 mg/kg/day, i.p. (all the mice died before day 4). Both treatments given by oral route (hydroethanolic and hot water extracts, 300 mg/kg) showed a much lower activity at day 4, but at day 7 the inhibition of Plasmodium growth was in the same range as for the extracts given intraperitoneally. Detailed results are presented in Figure 1.

Additional in vitro studies concerning the haemolytic potential and the cytotoxic activity on normal human fibroblasts were also carried out in order to check the anti-plasmodial selectivity of D. tomentosa. Results are detailed in Table 1.

No extract was found to exhibit significant red blood cells lysis activity with a percentage of haemolysis <1% for all tested extracts (conc = 100 μg/ml). This indicates that anti-plasmodial activity is not correlated with haemolysis of red blood cells but with a real action against the parasite.

However, all eight extracts were found to be quite cytotoxic on WI38 cells (IC₅₀ values from 5.9 to 47.2 μg/ml) and showed a low to moderate selectivity (SI from 0.9 to 7.0, depending on the extract and the plasmodial strain).

A bioguided fractionation was carried out in order to identify the compound(s) responsible for the anti-plasmodial activity.

Preliminary TLC analysis of the CH₂Cl₂ crude extract revealed the presence of some major terpenic compounds in the plant, especially one grey spot (Rf ~0.65), using the sulphuric vanillin reagent. The intensity of this grey spot, named “compound 1”, seemed to be correlated with the in vitro anti-plasmodial activity of the different tested extracts (Additional file 2).

For the bioguided fractionation and depending on the results obtained with the eight crude extracts, powdered plant was first extracted by hexane (E1), followed by dichloromethane (E2 = “defatted extract” – yield = 3.1%).

E2 was submitted to preparative reversed-phase HPLC to give 16 fractions (F1-F16). The activity of the extracts and fractions was evaluated against P. falciparum 3D7 strain. IC₅₀ values of E1 and E2 were 36.9 and 2.0 μg/ml, respectively. E2 containing compound 1 as the major compound was found to be even more active than the crude dichloromethane extract, while E1, found to contain the other major terpenes in TLC analysis, was much less active.

All tested fractions obtained from E2 were found to possess high or promising anti-plasmodial activity, with IC₅₀ values ranging from 0.95 μg/ml (F4 and F5) to 6.9 μg/ml (F16).

The significant activity detected in several fractions with different TLC profiles means that several compounds can be said to contribute to the overall in vitro anti-plasmodial properties of D. tomentosa dichloromethane extract. However, major compound 1 - the grey spot - was the main constituent of the two most active fractions F4 and F5 (respectively 10.2 mg and 67.3 mg = 25.84% E2 (w/w)) and this compound could therefore be considered as the major active compound in the plant.

Compound 1, a terpene, was finally isolated as a pure compound after an additional preparative TLC step on F4 and F5 and was submitted to UV, MS/MS and NMR analysis. Compound 1 was identified as urospermal A-15-O-acetate, a melampolide-type sesquiterpene lactone (Figure 2). Its identity was confirmed by comparison of its spectral profile with spectral data available for known compounds in D. tomentosa[22]. Melampolides are 10-membered ring sesquiterpene lactones. They can be considered a subgroup of germacranolides but with a 1,10 cis-double bond configuration.

Yield of urospermal A-15-O-acetate was estimated to 20.7% (w/w) of the dichloromethane extract (E2), corresponding to 0.64% (w/w) of the dried plant.

Purified compound 1 was also tested for its anti-plasmodial, cytotoxic and haemolytic properties. Results are presented in Table 1. Urospermal A-15-O-acetate was found to display a very strong anti-plasmodial activity with IC₅₀ <1 μg/ml against both chloroquine-sensitive and -resistant P. falciparum strains. The contribution of this active compound to the activity of the dichloromethane extract (E2) can be estimated to 62.1%, according to the method described by Deharo and Ginsburg [15]. This confirmed that urospermal A-15-O-acetate could be considered as the main active compound of the plant. It is likely that other minor closely related sesquiterpene lactones – such as the other germacranolides and melampolides already described in the plant [22, 23] – also displayed additive/synergistic anti-plasmodial activity, as attested by the significant activity detected in almost all the fractions. Products from other phytochemical classes, such as flavonoids (already described in the plant [27‐30]) could also play some role in the overall anti-plasmodial effect by several mechanisms, as widely described for A. annua[38, 39].

No significant haemolytic activity was detected for 1. However, this sesquiterpene lactone appeared to be cytotoxic with IC₅₀ = 3.0 μg/ml on WI38 human fibroblasts. The selectivity index (SI = 3.3) was the same as those obtained with the crude CH₂Cl₂ extract, which suggests that this major anti-plasmodial compound is the main cytotoxic product in the plant.

Urospermal A-15-O-acetate has already been described as a major compound of D. tomentosa by Bolhmann et al.[22] for a batch collected in South Africa. The present study is, however, the first report of the compound’s anti-plasmodial and cytotoxic properties. Moreover, this compound has never been described in any other plant.

Recently, another plant from the same genus, Dicoma anomala ssp gerrardii was described for its anti-plasmodial activity [40]. The main active compound in that plant was also a sesquiterpene lactone but of the eudesmanolide-type and represented 0.0013% (w:w) of the dried plant powder. Cytotoxic activity was also detected for this compound in that study.

Many sesquiterpene lactones isolated from Asteraceae have already been described as anti-plasmodial and cytotoxic in the literature, such as (pseudo)guaianolides, eudesmanolides and also germacranolides/melampolides (e g, tagitinin C from Tithonia diversifolia[41] and recently acanthospermolide derivatives from Acanthospermum hispidum[42]). Structure–activity relationship studies have shown that the α-methylene-γ-lactone moeity (or more widely, at least one potentially reactive α,β-unsaturated bond) is the main element needed for anti-plasmodial or cytotoxic activity of such compounds, and that antiprotozoal activity is significantly correlated with cytotoxicity [43, 44]. The low selectivity of such compounds can be explained by the chemical reactivity of the α,β-unsaturated bond, especially towards free thiol groups (e g, cysteine residues in enzymes and transcription factors).