World Journal of Organic Chemistry, 2013, Vol. 1, No. 1, 1-5 
Available online at http://pubs.sciepub.com/wjoc/1/1/1 
© Science and Education Publishing 
DOI:10.12691/wjoc-1-1-1 
Toxicity of Individual and Blends of Pure 
Phytoecdysteroids Isolated from Vitex Schiliebenii and 
Vitex Payos against Anopheles Gambiae S.S. Larvae  
Mokua Gladys Nyamoita* 
Department of Pharmacy and Complementary/Alternative Medicine, Kenyatta University, Nairobi, Kenya 
*Corresponding author: mokuag@yahoo.com 
Received December 31, 2012; Revised February 23, 2013; Accepted March 12, 2013 
Abstract  Four phytoecdysteroids: (20-hydroxyecdysone-20, 22-monacetonide (1), 20-hydroxyecdysone (2), 
stigmasterol (3), gamma-sitosterol (4), were investigated for toxic effect against 3rd /4th instar larvae of Anopheles 
gambiae under laboratory conditions as individual compounds and in blends. The test larvae were treated with 
solutions containing the phytoecdysteroids of concentrations 1, 5 and 10ppm. The blends were prepared in the ratio 
of 1:1. Compounds 1 and 2, isolated from acetone extracts of Vitex payos caused 100% mortality at 10ppm. 
Compound 3 isolated from acetone leaves of V. schiliebenii and compound 4 isolated from acetone stem bark of V. 
schilebenii also showed potent activity against the larvae at 10ppm. At the lower concentrations, abnormal mobility 
and impaired development was observed. Phytoecdysteroids (20-hydroxyecdysone-20, 22-monacetonide (1) and 20-
hydroxyecdysone (2) are larvicidal against An. gambiae. stigmasterol (3), gamma-sitosterol (4) also show potent 
IGR activities against An. gambiae. Also addition of compounds 1 and 2 to stigmasterol (3) and gamma-sitosterol (4) 
seperately improved the activity of the two compounds. 
Keywords: anopheles gambiae, phytoecdysteroids vitex schiliebenii, V. payos 
1. Introduction 
Phytoecdysteroids are plant analogues of insect growth 
hormones whose role in insect molting is understood, but 
their function in plants is uncertain [1]. However, it has 
been suggested that these chemicals are synthesized by the 
plants for their defense against phytophagous insects [1]. 
It is therefore expected that their production will be 
enhanced by insect attack. In the search for bioactive 
secondary metabolites with potential in the control of 
disease vectors and/or the diseases they transmit, 
detrimental effects including reduced weight, molting 
disruption and/or mortality have been reported in insects 
which ingest phytoecdysteroids [2]. These structurally 
diverse compounds have also been reported to affect 
protozoa and mollusks by impairing the digestion of 
protein and uptake of vitamins and minerals in their gut 
[2,3]. 
One of the main benefits of phytoecdysteroids is their 
therapeutic effects in mammals including humans. Their 
claimed medical properties include adaptogenic [4], 
anabolic [3], hypoglycemic [5], hepatoprotective [3], 
immunoprotective, wound-healing and anti-tumor. Other 
pharmacological properties associated with 
phytoecdysteroids include anti-proliferative, anti-
microbial and anti-oxidant activities [6]. Ecdysteroids are 
also considered as nutraceutical additives to food products 
[7]. 
Phytoecdysteroids are found in a wide range of species 
in the genus Vitex and may be used as taxonomic markers. 
An extensive literature search on the genus Vitex revealed 
the presence of ecdysteroids in a number of Vitex species 
[8] found in tropical and subtropical regions [9]. They 
affect a wide range of insects at low concentrations and 
are not harmful to human and animal cells [10]. Literature 
reports indicate that ingested phytoecdysteroids affect 
several insect species for example Spodoptera frugiperda 
[11], Bombyx mori [12,13], Lobesia botrana [14], Inachis 
io, Alglass urticae [15] and Bradysia impatiens [16], 
resulting in significant growth and developmental 
disruption. However, some insect species such as 
Heliothis virescens [17], H. armigera [18], S. litturalis 
[19], Locusta oleracea, Ostrinia nubilalis [20], and 
Lacanobia oleracea [21] were reported not to be affected 
after phytoecdysteroid ingestion by developing a 
detoxifying mechanism [22]. 
 
In this study, the author reports the effects of four 
phytoecdysteroids namely (20-hydroxyecdysone-20,22-
monacetonide (1), 20-hydroxyecdysone (2), Stigmasterol 
(3), Gamma-sitosterol (4) on 3rd and 4th instar larvae of An. 
gambiae under laboratory conditions. The compounds 
were isolated from two Vitex species namely, V. 
 World Journal of Organic Chemistry 2 
schiliebenii and V. payos collected from the Kenyan 
coastal region. 
2. Materials and Methods 
2.1. Plant Materials 
Leaves and stem bark of V. schiliebenii and root bark of 
V. payos used in this study were collected from the 
Kenyan coastal region in 2009. The plants were 
authenticated at the field by a botanist from the National 
Museum of Kenya (NMK), who preserved a voucher 
specimen (GMN/22) at the museum. The materials were 
air-dried at room temperature under the shade for three 
weeks and ground into powder in an electric miller.  
2.2. Extraction of Plant Materials 
Each powdered material was extracted three times 
using acetone (5-fold volume) for 24h with occasional 
stirring at room temperature. The extracts were filtered 
and concentrated to dryness using a rotary evaporator at 
40°C. The extraction process was repeated three times and 
the combined extracts were stored at 4°C. This procedure 
was repeated with methanol in the same proportions and 
for the same periods of time.  
2.3. Isolation of Phytoecdysteroids 
2.3.1. From Acetone Extract of V. payos Root Bark 
Powdered root bark (30g) of V. payos was extracted 
using acetone and the extract (8.0g) was subjected to 
column chromatography on silica gel (105g) eluting with 
100% dichloromethane and gradually increasing acetone 
to 100% then methanol to 30%. The 60% acetone eluent 
gave a mixture of two compounds, which were separated 
by repeated preparative Thin Layer Chromatography 
(PTLC) on silica gel (eluting with dichloromethane-
acetone, 1:1) to give 20-hydroxyecdysone-20, 22-
monacetonide (1) (16mg of a white amorphous powder 
which was soluble in methanol, with melting point 257-
259oC; lit. 256°C, [23] ) and impure 20-hydroxyecdysone 
(2). This was further subjected to repeated PTLC (eluting 
with dichloromethane-acetone, 4:1) followed by sephadex 
LH20 (DCM: MeOH 1:1). Ten milligrams of need-like 
crystals of melting point 234-236°C (lit. 230-233°C, [24] 
were obtained which were soluble in methanol. 
2.3.2. Acetone Extract of V. schiliebenii Leaves 
The acetone extract (10g) was subjected to column 
chromatography on silica gel (eluting with 100% 
dichloromethane and gradually increasing acetone to 
100%). The 40% acetone eluent gave a mixture of two 
compounds, which were subjected to repeated column 
chromatography using DCM: MeOH to yield gamma 
sitosterol (4) (6mg with a melting point of 142-144°C) 
which was then re-crystallized using the same solvent into 
a white star shaped crystal soluble in DCM. The other 
compound was too little to be analyzed. 
2.3.3. Acetone Extract of V. schiliebenii Stem Bark 
Sixteen grams (16g) of the extract was subjected to 
column chromatography on silica gel with 
Dichloromethane: Acetone gradient (100:0 - 0:100). The 
50% acetone eluent gave a mixture of two compounds 
(47mg), which were separated by repeated column 
chromatography followed by PTLC. The fraction yielded 
two compounds 20-hydroxyecdysone (2) (16mg) isolated 
as a crystalline solid and stigmasterol (3) (25mg of white 
crystals with a melting point of 165-7°C) lit. 163-6°C, 
[25]. 
2.4. Liebermann-Burchard Test for Steroids 
The isolated compounds were examined for the 
presence of steroids using Liebermann-Burchard test. 
Acetic anhydride (2ml) was added to the compounds (2mg) 
and the mixture was thoroughly heated and stirred for 2 
minutes on a water bath and allowed to stand at room 
temperature. Sulphuric acid (2ml) was gently added to 
1ml acetic acid layer. The blue to green color of the upper 
layer suggested the presence of phytosterols. 
2.5. Mosquito 
Larvae of An. gambiae Giles s.s. used in bioassays were 
obtained from a colony maintained at the International 
Centre of Insect Physiology and Ecology (ICIPE) Insect 
Mass Rearing Unit. This strain of mosquitoes originated 
from ICIPE’s Thomas Odhiambo Campus (Mbita Point) 
near Lake Victoria in 2003. Larvae were allowed to 
emerge from eggs in plastic containers filled with distilled 
water and were transferred to larger pans (37 × 31 × 6) at 
densities of 200-300 at 2nd instar stage. They were fed on 
Tetramin® fish food (Terta GmbH, Germany) and the 
water temperature was maintained at 28±2°C throughout 
larval development. 
2.6. Larvicidal Assays 
Larvicidal and insect growth regulatory (IGR) activities 
of the individual and blends of the four phytoecdysteroids 
(20-hydroxyecdysone-20, 22-monacetonide (1), 20-
hydroxyecdysone (2), stigmasterol (3) and gamma-
sitosterol (4) were conducted in accordance to the World 
Health Organization method [26]. Batches of twenty 
freshly moulted late 3rd and early 4th instar larvae of An. 
gambiae s.s. were transferred by means of dropper to glass 
beakers containing 100ml of tap water. Appropriate 
volume of stock solution where the pure compounds or 
blends were dissolved in 5% dimethylsuphoxide (DMSO) 
was added to 100ml water in the glass beakers to obtain 1, 
5, 10ppm dose levels. The blends were mixed in the ratio 
of 1:1. Three replicates were set up for each concentration 
and two negative controls (treated with DMSO-distilled 
water) were set up simultaneously. Larval mortality, 
abnormal behavior and/or morphological deformations 
were recorded at 24h intervals until the death of the last 
larva or emergence to adult. The bioassay room was kept 
at a temperature of 30°C, an average humidity of 78 % 
and a photo period of 12 hours of light and 12 hours of 
darkness. The larvae were fed on Tetramin® fish food 
(Terta GmbH, Germany) at about 1mg per beaker every 
24h. 
2.7. Calculation of Larval Mortality 
The average number of larvae or pupae collected for 
each replicate of each treatment and the control were 
3 World Journal of Organic Chemistry  
recorded after 24h. Percentage larval mortality was 
estimated for each treatment according to the formula:  
  100 26% Mortality Y Z

 
Where: Z=Initial number of larvae introduced into each 
test beaker and Y=Mean death defined by the difference 
between the mean test deaths and the mean control deaths. 
3. Results 
Chromatographic separation of the acetone extracts of 
V. payos root bark, V. schiliebenii leaves and V. 
schiliebenii stem bark yielded four known 
phytoecdysteroids [(20-hydroxyecdysone-20, 22-
monacetonide (1), 20-hydroxyecdysone (2), stigmasterol 
(3), gamma-sitosterol and (4)]. The identification was 
done by physical, spectroscopic and chemical analysis as 
well as literature data comparisons [8,27,28] (Table 1). 
These compounds were tested for larvicidal and/or IGR 
activities and the results revealed that they were toxic to 
An. gambiae larvae. Compounds 20-hydroxyecdysone-20, 
22-monacetonide (1) and 20-hydroxyecdysone (2) caused 
100% mortality at 10ppm (Table 2). Similarly, high 
mortality was obtained at 1 and 5 ppm (≥ 80%) with about 
15-18 % showing impaired development. Stigmasterol (3) 
and gamma-sitosterol (4) caused 55±2.5 and 65±2.4 % 
mortality respectively at 10ppm (Table 2). A blend of 20-
hydroxyecdysone-20, 22- monacetonide (1) and 20-
hydroxyecdysone (2) was moderately active (65±2.1%) at 
1ppm but the activity was high at 5 and 10 ppm (85±2.9 
and 90±2.5) respectively. These results therefore indicated 
a slight drop in the activity of the resulting blend. On the 
other hand, a combination of stigmasterol (3) and gamma-
sitosterol (4) which were less active improved the activity 
of the individual compounds. Addition of 20-
hydroxyecdysone-20, 22-monacetonide (1) to stigmasterol 
(3) and gamma-sitosterol (4) improved the activity of the 
two compounds to 90 and 100% at 1 and 10 ppm while 
individually each caused 25±2.4, 55±2.5 and 35±2.5 
65±2.4% mortality, respectively. It was also interesting to 
note that addition of 20-hydroxyecdysone (2) to 
stigmasterol (3) and gamma-sitosterol (4) also improved 
their activity as shown in (Table 2). 
Table 1. 13CNMR spectral data for compounds 1, 2, 3 and 4 [8,27,28] 
Compounds 1  2  3  4  
Position  (obs.)  (lit.)  (obs.)  (lit.)  (obs.)  (lit)  (obs.)  (lit.) 
1 36.0 38.0 36.0 37.3 37.3 37.2 37.3 37.0 
2 67.3 68.1 67.3 68.6 31.9 31.8 29.4 29.5 
3 67.1 68.0 67.1 68.5 71.8 71.5 71.8 71.8 
4 31.5 31.7 31.5 32.7 42.3 42.2 42.3 42.3 
5 50.4 51.3 50.4 51.7 140.8 140.7 140.8 140.8 
6 205.1 203.5 205.1 206.6 121.7 121.6 121.7 121.7 
7 120.7 121.8 120.7 122.1 33.9 33.6 31.7 31.9 
8 165.3 165.4 166.5 168.1 29.7 29.6 29.2 29.2 
9 33.7 34.4 33.7 35.0 50.1 50.1 50.2 50.2 
10 37.8 38.6 37.9 39.3 36.5 36.4 36.5 36.5 
11 21.0 21.0 20.1 21.5 21.1 21.1 21.1 21.1 
12 30.9 32.4 30.4 32.4 39.7 39.7 26.1 26.1 
13 48.6 47.8 47.4 48.6 42.2 42.2 45.9 45.9 
14 84.5 84.1 83.4 84.2 56.8 56.1 56.8 56.7 
15 30.2 31.6 31.1 31.7 24.3 24.1 24.3 24.1 
16 20.1 22.1 20.1 21.5 28.4 28.3 39.8 39.8 
17 49.1 50.0 49.1 50.5 56.7 56.0 56.1 56.1 
18 16.3 17.2 16.7 18.1 12.0 12.1 11.9 12.2 
19 23.1 24.4 23.0 24.4 19.4 19.4 18.8 18.8 
20 83.9 82.1 76.5 78.0 40.5 40.3 34.0 34.0 
21 21.2 22.4 19.7 21.1 19.8 20.5 19.1 19.1 
22 81.9 85.5 77.0 78.4 138.3 138.5 37.3 37.3 
23 23.3 24.3 25.9 27.3 129.3 129.4 26.2 26.6 
24 40.8 42.1 41.0 42.3 51.2 51.2 51.6 50.1 
25 69.7 69.2 69.9 71.4 31.7 31.9 28.2 28.3 
26 28.1* 30.0 28.3 29.1 21.1 21.2 19.4 19.4 
27 
28 
29 
O-C-O 
Me 
Me 
27.9 * 
 
 
106.6 
27.6 
29.8 
29.8 
 
 
106.9 
27.1 
29.4 
27.6 29.7 19.0 
26.1 
11.9 
19.8 
25.4 
11.9 
19.8 
23.3 
11.8 
19.8 
23.3 
12.0 
  
  
  
      
  
*- signals may be interchanged 
Compounds 1 and 2: (500 MHz, MeOD); Compound 3: (300 MHz, CDCl3); Compound 4: (400 MHz, CDCl3) 
 World Journal of Organic Chemistry 4 
Table 2. Percentage mortality of An. gambiae larvae exposed to pure compounds isolated from V. payos and V. schiliebenii individually and in 
blends at 1, 5, and 10ppm 
S/No. Compound(s) 
Mean % mortality/Concentration (ppm) 
1ppm 5ppm 10ppm 
1 20-hydroxyecdysone-20,22-monacetonide (1) 90±2.1 95±2.2 100±0.0 
2 20-hydroxyecdysone (2) 80±2.4 90±2.0 100±0.0 
3 Stigmasterol (3) 25±2.4 40±2.1 55±2.5 
4 Gamma-sitosterol (4) 35±2.5 45±1.5 65±2.4 
5 1 + 2 65±2.1 85±2.9 90±2.5 
6 1 + 3 90±3.3 90±2.1 100±0.0 
7 1 + 4 90±2.0 90±2.2 100±0.0 
8 2 + 3 80±2.1 85±2.0 100±0.0 
9 2 + 4 65±2.1 80±2.9 90±2.5 
10 3 + 4 50±2.4 70±2.0 85±2.4 
11 Control 0±0.0 0±0.0 0±0.0 
4. Discussion 
In the present study, 20-hydroxyecdsone (2) exhibited 
larvicidal activity against An. gambiae larvae. This 
observation compares with previous studies where 20-
hydroxyecdysteroid (2) was used as the sole or major 
component in bioassays. Results indicated a range of 
detrimental effects on development and survival of several 
insect species including Bombyx mori [11], Pectinophora 
gossypiella [11,29], Spodoptera frugiperda [30], 
Acrolepiopsis assectella [29,30] and Agrius convolvulus 
[31]. The blend effect observed in the current study 
indicated that the activity of stigmasterol (3) and gamma-
sitosterol (4) can be improved by preparing a formulation 
of the two compounds containing either 20-
hydroxyecdysone-20, 22-monacetonide (1), or 20-
hydroxyecdysone (2). In addition, the synergism observed 
in the blend of compounds 3 and 4 also indicated that a 
better formulation can be prepared by using the two 
compounds as a blend instead of using them as seperate 
compounds. Reported experiments [32,33,34,35,36] 
working on some plant extracts having potential larvicides 
also note that botanical blends provide better effect in 
reducing vector population. This is attributed to the 
adaptive value of phytochemical diversity in ecological 
interactions among plants and their associated herbivores 
and pathogens.  
The purpose of this study was to elucidate the role and 
relative importance of steroids in Vitex species in 
controlling An. gambiae larvae and to use this information 
in guiding effective development of formulations to be 
used in integrated pest management programmes. Three 
variants of blend effects were noted from these results. 
First, production of a less active blend from active 
constituents; secondly, enhancement of the activity of a 
moderately active compound by an active constituent and; 
thirdly, synergism between moderately active compounds 
to give a blend that was more active than the individual 
constituents. The first variant was illustrated by the high 
lethal activity of compounds 1 and 2 while the second was 
illustrated by the enhancement of the activity of 
compounds 3 and 4 in blends with 1 and 2. The third 
variant was illustrated by the combination of compounds 3 
and 4. 
5. Conclusion 
It can be concluded that phytoecdysteroids (20-
hydroxyecdysone-20, 22-monacetonide (1) and 20-
hydroxyecdysone (2) possess high larvicidal activity 
against An. gambiae. Stigmasterol (3) and gamma-
sitosterol (4) also show potent insect growth regulatory 
(IGR) activities against An. gambiae. Consequently, V. 
payos and V. schiliebeinii have important practical 
implications in the search for and use of plants and their 
phytochemicals for mosquito larvae control. 
Acknowledgements 
The author is grateful to the International Centre of 
Insect Physiology and Ecology (ICIPE-Kenya) for 
providing the necessary bioassay requirements. Muhimbili 
University of Health and Allied Sciences is also 
acknowledged for providing the necessary 
chromatographic equipment for fractionation and 
purification of the crude plant materials. The author also 
acknowledges DAAD-NAPRECA for funding the work 
reported in this paper. 
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