Keywords

Insecticidal activities, Anopheles, Chromolaena odorata, Vernonia amygdalina, Malaria

Introduction

Several diseases are transmitted by arthropod vectors [1] of which mosquito is one of them. Mosquitoes are responsible for the transmission of diseases such as malaria, lymphatic filariasis, and dengue fever among others [2] most especially in the tropical regions of the world. Out of these diseases transmitted by mosquitoes, malaria is the most devastating in terms of the number of incidence, prevalence, morbidity and mortality [2]. It is transmitted by the mosquitoes of the genus Anopheles and it is caused by the protozoa of the Plasmodium genus [3]. Examples of Anopheles species include Anopheles gambiae, Anopheles culicifacies, Anopheles stephensi, Anopheles fluviatilis, Anopheles minimus, Anopheles dirus and Anopheles sundaicus among others with Anopheles gambiae being the prominent one among them all [4,5]. Five species of Plasmodium namely Plasmodium falciparum, Plasmodium vivax, Plasmodium malariae, Plasmodium ovale and Plasmodium knowlesi are responsible for human malaria [6] but P. falciparum and P. vivax are most notorious in terms of the number of cases they are responsible for [3].

They were an estimated 219 million cases of malaria with 435,000 of them resulting in death in 2017 [3]. In order to stop or reduce the transmission of malaria parasites, there is need to control the vector population. Several methods such as habitat modification [7], the use of synthetic chemical insecticides [4] and the use of biological means such as employing natural predators, parasites and parasitoids to control the populations of mosquitoes [8,9]. The major method that have been employed in the control of mosquitoes is the use of synthethic insecticides such as chlorodane, aldrin, Dieldrin, dichlorodiphenyl trichoroethane (DDT) among others [4].

However, these chemical have been shown to have negative effect in the dynamics of the earth's ecosystem resulting in resistance of mosquito species to the chemicals, environmental pollution and toxicity to human and other non-targeted organisms [10]. Hence, there have been clamor by various quarters to develop a safe means to combat the proliferation of insect vector species [11]. This has led to the focus on developing insecticides from botanical sources that are safe to use in the environment due to the fact that they are easily degradable and less toxic to humans and non-targeted organisms [12,13].

Several plant materials such as Alstonia boonei, Curuma longa, Cymbopogon winterianus, Ocimum americanum, Nepeta cataria, Viola odorata, Melaleuca quinquenervia, Azadirachta indica, Citrus medica, Nicotiana tabacum, Anacardium occidentale, Aframomum melegueta, Garcinia kola, Citrus sinensis and Murraya koenigii have been used to control mosquitoes [14-22].

Chromolaena odorata is a fast-growing perennial herb which belongs to the family Asteraceae [23]. The plants are known for its medicinal value in many areas as well as pests control purposes [23]. Chromolaena odorata contains carcinogenic pyrrolizidine alkaloids [24]. It is not habitat specific and nature of soil, it grows generally in the wild (abandoned land) [25]. The plantis acknowledged for its high proliferation and one of the world worst tropical weeds [26].

Vernonia amygdalina belong to the family Asteraceae and grows in the tropical regions of Africa [23]. The plant is a shrub, evergreen in colour and can grow between 2-5 m in height with petiolate leaf of about 6 mm in diameter [27]. The plant is bitter due to the characteristic odour and bitter taste of the leaves owing to the presence of anti-nutritional factors such as alkaloids, saponins, tannins and glycosides [28,29].The aim of this research study isto investigate the anti-mosquito activities of C. odorata and V. amygdalina leaf extracts on the larvae, pupae and adults of malaria vector, An. gambiae.

Materials and Methods

Place and duration of study

The research was conducted at the Storage Entomology Postgraduate Research Laboratory, Department of Biology, Federal University of Technology, Akure, Nigeria between August and November, 2018.

Collection and rearing of larva, pupa and adult mosquito

Mosquito bait was established under a partial shade in an open field by filling a white bucket with rain water. Yeast was sprinkled on the surface of the water to serves as source of foods for the nourishment of larvae. Wild mosquitoes were allowed to freely visit the baits and to lay eggs. This was monitored for 4-6 days for the development of eggs and first instar larvae. Subsequently, the larvae were harvested and taken into the laboratory for identification into species levels [30]. Anopheles gambiae larvae were transferred into another plastic container containing rain water. Some of the larvae were used for the larvicidal tests while the remaining larvae nurtured to pupae for 4-6 days for pupicidal tests. Adult mosquito that emerged from pupae cultured were fed with sucrose solution [31].

Collection of plant materials

Chromolaena odorata and V. amygdalina leaves that have not be sprayed with chemical insecticides (based on the information obtained from the farmer) were obtained in fresh form a farm at Ogbese, Ondo State, Nigeria. They were taken to the Biology Department, Federal University of Technology, Akure, Ondo State for authentication.

Extraction of plant materials

Chromolaena odorata and V. amygdalina leaves were washed separately with distilled water, shade dried, cut into small pieces and air dried for 14 days in the laboratory before pulverized into fine powders using an industrial electric pulverizing machine at the Department of Animal Production and Health Laboratory, Federal University of Technology, Akure. The powders were further sieved to pass through mm² perforations and kept in an air-tight plastic containers for storage before use at ambient temperature (28 ± 2) °C.

About 300 g of C. odorata and V. amygdalina powders were soaked separately in an extraction bottle containing 500 ml of absolute methanol for 72 hours. The mixture was stirred occasionally with a glass rod and extraction was terminated after three days. Filtration was carried out using a double layer of Whatman No. 1 filter papers and solvent evaporated using a rotary evaporator at 30 to 40 °C with rotary speed of three to six rpm for eight hours [32]. The resulting extracts were air dried in order to remove traces of methanol. The extracts were kept in labeled plastic bottles till when needed.

Standard stock solutions were prepared by dissolving 3 g of the crude extracts in 1 Litre of water. From these stock solutions, different concentrations of 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L were prepared and these aqueous solutions were used for the various experiments.

Anti-larval activity of C. odorata and V. amygdalina extracts

Twenty (20) 3^rd/4^th larval instar of An. gambiae were introduced into C. odorata and V. amygdalina extracts separately at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L with a set of control containing rain water. All tested concentrations were replicated four times. The number of dead larvae were counted and recorded accordingly after 24 hours of exposure. Dead larvae were those unable of rising to the surface or without the characteristic diving reaction when the water was disturbed [33].

$$\%\text{ Larval Mortality = }\frac{\text{Number of dead larvae}}{\text{Number of larvae introduced }}\text{ X }\frac{100}{1}$$

Percentage larvae mortality was corrected using Abbott [25] formula thus:

$$P_T=\frac{P_o-P_c}{100-P_o}\text{ x }\frac{100}{1}$$

Where P_T = corrected mortality (%)

P_O = observed mortality (%)

P_C = control mortality (%)

Anti-pupal activity of C. odorata and V. amygdalina extracts

Twenty-two days old pupae of An. gambiae were introduced into C. odorata and V. amygdalina extracts separately at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L with a set of controls containing rain water. All tested concentrations were replicated four times. The number of dead pupae were counted and recorded accordingly after 24 hours of treatment. Percentage pupal mortality were calculated using standard method and % pupae mortality was corrected using Abbott formula [34].

Anti-adult fumigant efficacy of C. odorata and V. amygdalina extracts

Twenty adults were introduced into a test-tube covered with cotton wool [9]. Strips of Whatman's No.1 filter papers soaked with 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L of C. odorata and V. amygdalina extracts were suspended in the test tube separately in four replicates. Mortality of adult insect was evaluated after 24 hours of treatment using standard method. Percentage adult mortality was corrected using Abbott formula as illustrated above.

Statistical analysis of data

Data were subjected to analysis of variance and means were separated using the new Duncan's multiple range test. The log-Probit model analysis was carried out on larvicidal, pupicidal and adulticidal bioassay results to assess the 50% lethal concentration (LC₅₀) and 90% lethal concentration (LC₉₀).

Result

Anti-larval activity of C. odorata and V. amygdalina extracts on An. gambiae larvae

There was a significant difference (P < 0.05) in toxicity level of C. odorata and V. amygdalina extracts on An. gambiae larvae at all tested concentrations (Table 1). Vernonia amygdalina extract was the most toxic to An. gambiae at all tested concentrations of 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L which evoked 47.5%, 82.5%, 100%, 100% and 100% mortality after 24 hours of treatment, respectively. Chromolaena odorata extract caused 32.5%, 60%, 82.5%, 92.5% and 100% mortality of An. gambiae larvae after 24 hours of treatment at rates 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L, respectively.

Anti-pupal activity of C. odorata and V. amygdalina extracts on An. gambiae pupae

Anti-pupal activity of C. odorata and V. amygdalina extracts on percentage mortality of An. gambiae larvae is presented in Table 2. Generally, pupae mortality occurred in a dosage-dependent manner. There was a significant difference (P < 0.05) in toxicity level of the two plant extracts on An. gambiae pupae at concentrations. Vernonia amygdalina extract was the most lethal to An. gambiae pupae which evoked 32.5%, 50%, 77.5%, 100% and 100% mortality after 24 hours of treatment at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L, respectively. Chromolaena odorata extract caused 20%, 37.5%, 50%, 77.5% and 100% mortality of An. gambiae larvae after 24 hours of treatment at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L, respectively. The higher the concentration, the more the mortality rate of pupae mosquito.

Anti-adult fumigant efficacy of C. odorata and V. amygdalina leaves extracts on An. gambiae adults

Fumigant toxicity of C. odorata and V. amygdalina extracts on percentage mortality of An. gambiae adults is presented in Table 3. Adult mortality occurred in a dosage-dependent manner. There was a significant difference (P < 0.05) in toxicity level of the two plant extracts on An. gambiae adults at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L. Vernonia amygdalina caused 17.5%, 27.5%, 37.5%, 42.5% and 55% mortality of adult An. gambiae after 24 hours of treatment at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L, respectively. Chromolaena odorata extract caused 7.5%, 15%, 20%, 30% and 40% mortality of An. gambiae larvae after 24 hours of treatment at concentrations 20 mg/L, 40 mg/L, 80 mg/L, 120 mg/L and 160 mg/L, respectively. The higher the concentration, the more the mortality rate of adult An. gambiae.

LC₅₀ and LC₉₀ values calculated for C. odorata and V. amygdalina leaves extracts on An. gambiae larvae, pupae and adults based on the log-probit regression analysis

The 50% lethal concentration of C. odorata extract was 31.33 mg/L while V. amygdalina extract was 21.42 mg/L for An. gambiae larvae. The concentration of C. odorata and V. amygdalina leaf extracts to cause 90% death of An. gambiae larvae were 95.73 mg/L and 44.56 mg/L respectively (Table 4). Chromolaena odorata extract required more concentration than V. amygdalina leaf extracts to cause 50% and 90% death of An. gambiae larvae. The concentration of C. odorata and V. amygdalina leaf extracts to cause 50% death of mosquito pupae were 53.61 mg/L and 33.93 mg/L respectively. The concentration of C. odorata and V. amygdalina leaf extracts to cause 90% death of An. gambiae pupae were 117.66 mg/L and 92.29 mg/L respectively. Vernonia amygdalina extract required less concentration than C. odorata leaves extracts to cause 50% and 90% death of An. gambiae pupae. The concentration of C. odorata and V. amygdalina leaves extracts required to evoke 50% death of An. gambiae adult were 296.20 mg/L and 147.98 mg/L respectively. The LC₉₀ of C. odorata extract was 3107.55 mg/L while V. amygdalina extract was 2221.05 mg/L for mosquito adults. The plant extracts were not as effective against adults compared to larva and pupa of An. gambiae.

Discussion

The use of plants as mosquitocides in lieu of synthetic chemical insecticides for the management of malaria vectors is gaining attention in developing nations such as Nigeria [17,20]. Utilization of C. odorata and V. amygdalina in the biocontrol of insect pest of cereals, legumes and vectors of malaria have been previously reported [35-42].

The result obtained in this study showed that C. odorata and V. amygdalina leaves extracts were effective in the control of larva, pupa and adult stages of An. gambiae. The larvicidal, pupicidal and adulticidal potentials of C. odorata and V. amygdalina extracts were concentration dependent. The higher the concentration, the higher the mortality rate of larva, pupa and adult mosquito. Larvae were more susceptible to C. odorata and V. amygdalina extracts than pupa and adults stages. This may be due to the swimming ability of the pupae, picking the lethal dose in the process of searching for food [18,21,43]. The extract also reduces dissolved oxygen which could have caused their death [18,43].

Vernonia amygdalina leaf extract was the most toxic to all stages of An. Gambiae in this study. The biocontrol of V. amygdalina against stored product pest have been reported [35-39,42]. Adedire and Lajide [35] reported 100% mortality of maize weevil, Sitophilus zeamais when treated with V. amygdalina Musa, et al. [36] also reported the efficacy of V. amygdalina in the management of cowpea beetle, Callosobruchus maculatus. Moses and Dorathy [37] reported that bitter leaf gave the best protection against cowpea weevil when compared with garlic and ginger. Akunne, et al. [39] reported on efficacy of mixed application of leaf powders of V. amygdalina and Azadirachta indica against adult C. maculatus. Ileke [42] reported on entomotoxicant potential of bitter leaf, V. amygdalina powder in the control of Cowpea bruchid, C. maculatus infesting stored cow peaseeds. The larvicidal and pupicidal bioefficacies of V. amygdalina extract on the malaria vector developmental stages could be linked to the presence of some chemical compounds like sesquiterpene lactones containing vernodalin, vernodalol and 11, 13-dihydrovernodalin which act as insect feeding deterrent [44].

Chromolaena odorata extract also effectively control larva and pupa stages of malaria vector. This agreed with many earlier researchers on the use of botanicals against suppression of vectors malaria [38,39]. Ahiati, et al. [38] reported on the insecticidal effects of C. Odorata Oil extracts on the Larvae and adults of mosquitoes (Family Culicidae). Jagruti, et al. [39] reported on the larvicidal activity of methanolic leaf extracts of plant, C. odorata L. (Asteraceae) against vector mosquito. Chromolaena odorata extract had been utilized against a household pests such as cockroaches. Udebuani, et al. [41] reported on the effectiveness of C. odorata against adult stage of American cockroach, Periplaneta americana. Insecticidal property of C. odorata could be linked to it chemical constituents such as tannin, saponin, flavonoid and alkaloids. The presence of these phytochemical alters some biochemical functions of organisms. Man [45] reported that increase mortality of An. gambiae rate which was reported in thin study could be attributed to phytochemical content of the leaf extract. Studies have shown that high dose of flavonoid alters the normal body functioning of insects [46,47]. Kelm and Nair [48] also reported the presence of flavonoid, tannin, saponin in leaf extract of C. odorata. Saponin are a class of steroidal or triterpenoid secondary plant metabolite with diverse biological properties, such as antifeeding [47,49] and growth inhibitory activities [47, 50]. Chromolaena odorata and V. amygdalina leaves were less toxic to the adult mosquito compared with larvae and pupae of An. gambiae. The major limitation of this study is that we did not identify the active ingredients in the leaf extracts. However, we propose, in the future, to characterize active ingredients in the C. odorata and V. amygdalina leaf extracts with a view to developing a potent insecticide against all the life stages of An. gambiae.

Conclusion

Anopheles gambiae larvae were more susceptible to leaf extracts tested than their pupae and adults at all tested concentrations. In addition, V. amygdalina extracts required less concentration than C. odorata to cause 50% and 90% death of malaria vector, An. gambiae larvae, pupae and adults. The test plants can be incorporated into a control strategy or intervention programmes on the management of malaria vector, An. gambiae.

Acknowledgments

We appreciate Dr. Foluso Akindele Ologundudu, (Plant Physiologist/Taxonomist) of the Department of Biology, Federal University of Technology, Akure, Nigeria who assisted in the authentication of two plants assessed in this study.

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