Subscribe Now Subscribe Today
Research Article
 

Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae)



Culver Mvumi
 
Facebook Twitter Digg Reddit Linkedin StumbleUpon E-mail
ABSTRACT

Background and Objectives: Southern Africa needs plant pesticidal technologies to control aphids (Brevicoryne brassicae) as alternatives to synthetic chemicals. This study sought to determine the efficacy of Bitter Apple (BA) (Citrullus colosynthis) fruit solution to control cabbage aphids by considering aphid mortality in case of varied BA contact time. Materials and Methods: Treatments were prepared by pounding ripe BA fruits to form a paste, then mixed with distilled water to obtain BA fruit concentrations (30, 60 and 90 mL L1). The treatments were mixed with 3, 6 and 12 g of sugar, respectively. Negative and positive controls were no BA (distilled water only) and dimethoate 40% EC, respectively. Efficacy of each concentration of BA was evaluated at 6, 24 and 48 h after application. Results: Bitter apple was significantly (p<0.001) efficacious to cabbage aphid. All BA concentrations increased aphid mortality at all the contact times as the contact time increased. At a concentration of 90 mL L1, the highest mortality (13.00) was at 6 h and was significantly different from the negative control. The lowest concentration (30 mL L1) was significantly different from the negative control at 24 and 48 h. Conclusion: This study concluded that bitter apple fruit extract should be used at a concentration of 90 mL L1 at 48 h of contact time to obtain highly significant cabbage aphid mortality.

Services
Related Articles in ASCI
Search in Google Scholar
View Citation
Report Citation

 
  How to cite this article:

Culver Mvumi , 2019. Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae). Asian Journal of Crop Science, 11: 71-76.

DOI: 10.3923/ajcs.2019.71.76

URL: https://scialert.net/abstract/?doi=ajcs.2019.71.76
 
Received: February 28, 2019; Accepted: April 26, 2019; Published: July 23, 2019


Copyright: © 2019. This is an open access article distributed under the terms of the creative commons attribution License, which permits unrestricted use, distribution and reproduction in any medium, provided the original author and source are credited.

INTRODUCTION

Cabbage (Brassica oleracea) is a popular vegetable grown in southern Africa, for its economic and nutritive values, especially in the rural areas. Due to its better resilience than rape in dry regions, cabbage is preferred by most rural people to all the other Brassica spp. because it meets the economic and nutritive values they crave for. Cabbage is rich in vitamin A and C and also contains minerals like phosphorus, potassium, calcium, sodium and iron1. However, like rape (Brassica napus), cabbage is heavily attacked by aphid (Brevicoryne brassicae), which is one of the most destructive pests widely distributed in warm and even temperate regions around the world2. The aphid attack on cabbage in such conditions leads to low head yield3,4. The yield loss may rise up5 to 70% and in very favorable conditions, aphids can cause total crop loss on brassica leafy vegetables6. The status of the cabbage aphid is enhanced by its high reproductive capacity7. One mature aphid can give birth to 2-5 live young ones per day which mature in 5-7 days after birth7. Aphids feed by sucking the sap from the plants and if in large numbers, remove sufficient sap to cause leaves to wrap or curl inwards8.

Some smallholder cabbage farmers pre-dominantly use synthetic pesticides to control aphids4,9,10. The most widely used chemical to control cabbage aphids in Zimbabwe is dimethoate 40% EC. Smallholder farmers cannot afford the commercial chemicals due to their high costs. They also have no easy access to the synthetic chemical due to its unavailability in local shops. Synthetic pesticides destroy the non-target insects, even though they may be very effective11. Synthetic chemicals have been reported to cause environmental hazards12,10.

Medicinal plants are usually locally available. They are less expensive, easy to use and are environmental friendly13. They have little impact on natural enemies of pests14, which means they can also be pest-specific. Indeed, locally available pesticidal plant products are great technologies. Botanical pesticides can be easily managed, are environmentally benign, for example, the poorest farmers following a demonstrative research can safely use them15,16. A study on the efficacy of lantana (Lantana camara) against aphids in rape (Brassica nupas) over varied periods of time (contact time) was carried out17. Contact time is critical in determining the efficacy of a biopesticide as it is the basis of how long a plant is safe from a particular pest attack. Interestingly, the efficacy of organic pesticides and contact time taken vary with the pesticidal plant used and the type or species of pest to control17,18.

The efficacy of Bitter Apple (BA) fruits against aphids has not been fully researched. Additionally, insufficient studies have been done to show the effect of contact time on the efficacy of organic pesticides. The current study investigated the efficacy of BA on the control of the cabbage aphid considering the length of contact time taken after application.

MATERIALS AND METHODS

The efficacy of BA in relation to contact time in controlling cabbage aphids was evaluated in the field in 2017.

Site: The trial was carried out in Biriiri, Chimanimani district (coordinates 19°48' 0.00"S, 32°51' 36.00"E), Zimbabwe. The area receives an average annual rainfall of 350-400 mm which is erratic. Biriiri experiences an annual temperature range of 24-32°C in summer (August-March), but can drop to 12°C in winter (April-July). The soil is acid (Table 1) and is shallow sandy to sandy loam, with stony patches which pose difficulties during cultivation.

Biological materials: Certified cabbage (Brassica oleracea var. capitata) seed was obtained from farm and city in Mutare. Cabbage seeds were sown on 23 July, 2017 and seedlings were raised on a nursery bed. Ripe freshly harvested bitter apple fruits were collected from Biriiri fields in Chimanimani district. Aphids were taken from the host cabbage crop in a nearby cabbage field. Only the ones identified as adults were selected. After a thorough check of the experimental plants that they were clean of aphid infestation, 20 adult aphids were immediately introduced on each plant, 6 weeks after transplanting; the introduction of the aphids was done following the protocol of Mvumi and Maunga17, with slight modifications. The aphids were introduced on the same day and about the same time, 6 weeks after transplanting. The aphids were physically checked that they were healthy and active as these were the fundamental characteristics of the aphids’ ability to infest the plants. The infestation period was 15 min after introducing the adult aphids to the plants, before application of treatments.

Table 1:
Chemical characteristics of the soil used in Biriiri during the 2017-2018 cropping period
Image for - Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae)

The shortness of time (15 min) which was allowed for infestation period was for ensuring that the number of aphids (20 aphids per plant) would not change before the BA treatments were applied. To ensure no aphids could have escaped, physical re-examination to determine the consistence of the number of adult aphids (20) previously introduced per plant19 was done.

Bitter apple extract preparation: The fresh BA fruits were pounded in a mortar to paste. The paste was then thoroughly compressed in a perforated net cloth to extract the concentrated fruit pulp. After the filtering process, each concentration (obtained from 1 L1 distilled water which had been mixed with each of the pounded amounts of Moringa leaves (3, 2 and 1 kg) was then mixed with 5 g of sugar and stored in air tight glass bottles at 4°C before it was used. Sugar was integrated with all treatments to act as a sticking agent and as an attractant. Sugar is used in similar processes in horticultural agronomy20. Sugar has sweetness characteristic which attracts pests to a host or retains a pest on a host, implying that it has a strong impact on aphid-host choice21. The mixture was left for 24 h at a temperature of 5°C before use.

Treatments and experimental design: Treatments were prepared by mixing BA extract with distilled water to obtain BA fruit concentrations (30, 60 and 90 mL L1) were then mixed with sugar20,17 (3, 6 and 12 g of sugar, respectively) and stored in air tight glass bottles at 4°C before the treatments were used. Dimethoate 40% EC5l5l1 of distilled water (v/v) was the positive control, while no BA extract (distilled water only) was the negative control. The treatments were replicated four times and arranged in a randomized complete block (RCBD). The experiment was repeated twice.

Planting: The seedlings were transplanted to the field at 4 weeks after seed emergence. Soil was pressed around the plant to close air pockets and light irrigation was done. The amounts of fertilizer used were 80 kg N ha1, 170 kg P2O5 ha1 and 110 kg K2O ha1. AN = 34.5% N, SSP = 18% P2O5, sulphate of potash = 50% K2O5. The plant spacing used was 90 cm inter-row×30 cm in-row.

Treatment application: Spraying was done 2 h after the introduction of cabbage aphids. The control treatment was covered using plastic spray-shields to prevent movement of aphids to other treatments and to prevent chemical drifts22. The other 4 treatments were applied at the same time, each having their own applicator. One spray was done followed by 3 recordings which were taken at 6, 24 and 48 h after spraying. An amount of 34.5 kg N ha1 was applied as top dressing fertilizer, 2 times at 3 week interval, starting from 2 weeks after transplanting.

A knapsack was used to apply the treatments19,22 at a rate of 115 m2. At contact times of 6, 24 and 48 h after BA extract applications; physical counting of dead aphids was done on each plant sample. White papers were strategically placed underneath the plants for easy identification of the dead aphids; paper-position and mortality were strictly monitored. To check the lethality of the BA, the number of dead aphids was checked after every 1 h and recorded; the numbers were then added up to get the total for each of the periods (6, 24 and 48 h) earmarked as the contact times.

Statistical analysis: One-way analysis of variance (ANOVA) was carried out by using GenStat 14th Edition (VSN International, Hemel Hempstead, UK) to detect significant differences between treatments means. Separation of treatment means all treatments (including positive and negative controls) were then employed using the Turkey’s HSD test (p<0.05).

RESULTS

Aphid mortality response to bitter apple treatment at 6 h: The BA treatment significantly (p<0.001) increased the number of dead aphids. At the highest concentration (90 mL L1), the highest number of dead aphids (13.00) was at 6 h (Table 2). However, the lowest BA concentration (30 mL L1) was not significantly (p>0.05) different from the negative control (no BA). The positive control (dimethoate 40% EC) showed higher aphid mortality (18.00) than the BA concentration (90 mL L1).

Table 2:
Deleterious effect of the different treatment concentrations on cabbage aphid at 6 h
Image for - Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae)
Means within a column are compared and separated using Tukey’s HSD test (p<0.05) and different alphabetic letters within a column indicate significant differences

Table 3:
Deleterious effect of the different treatment concentrations on cabbage aphid at 24 h
Image for - Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae)
Means within a column are compared and separated using Tukey’s HSD test (p<0.05) and different alphabetic letters within a column indicate significant differences

Table 4:Deleterious effect of the different treatment concentrations on cabbage aphid at 48 h
Image for - Efficacy of Bitter Apple (Solanum incanum) in Relation to Contact Time for Controlling Cabbage Aphids (Brevicoryne brassicae)
Means within a column are compared and separated using Tukey’s HSD test (p<0.05) and different alphabetic letters within a column indicate significant differences

Aphid mortality response to bitter apple treatment at 24 h: The BA treatment significantly (p<0.001) increased aphid mortality. Of all the BA treatments, 90 mL L1 gave the highest number (18.50) of dead aphids which was not significantly different from the positive control. The highest BA concentration at 24 h had comparably higher aphid mortality than at 6 h (Table 3). The lowest BA concentration (30 mL L1) gave significantly (p<0.05) higher aphid death than the negative control.

Aphid mortality response to bitter apple treatment at 48 h: The BA treatment significantly (p<0.001) increased aphid mortality. The extract showed its highly efficacious effect by having even the lowest concentration (30 mL L1) having significantly (p<0.05) higher aphid death than the negative control where no BA was applied. This highest BA concentration had the highest number of dead aphids of all the other BA treatments at 48 h. There was no significant (p>0.05) difference between 90 mL L1 treatment and the positive control (Table 4).

Means within a column are compared and separated using Tukey’s HSD test (p<0.05) and different alphabetic letters within a column indicated significant differences.

DISCUSSION

The lowest concentration (30 mL L1) showed a slight repellent effect. This phenomenon happened might be because of the low concentration and the shortness of time aphids were exposed to BA. Higher concentrations were effective. Other workers have found these results in neem (Azandirachta indica) oil and nicotine19. The performance of neem oil as seed treatment against aphid (Aphis gossypii) on okra (Abelmoschus esculentus) crop and was tested by Gandhi et al.23 who found excellent results. No environmental hazards after applying the biopesticides were reported. Studies showed that the biopesticides can be used in control of aphids as they are environmentally safe and have low toxicity to animals (including humans), fish and pollinators24,25. Studies done by Abdel-Rahman et al.26 also confirmed these findings. The synthetic pesticide (dimethoate 40% EC) showed higher aphid mortality than the highest BA concentration’s mortality12. This was also observed by Shiberu and Negeri27, when neem seed, hop bush (Dodonaea viscosa) fresh leaf and lemon grass (Cymbopogon citrates) showed less effective control on cabbage aphid as compared to tested insecticides.

A high toxicity of hexane, diethyl ether, ethyl acetate, acetone and ethanol extracts of BA against adults of the cotton aphid was reported28. This clearly reflects that BA is highly efficacious in aphid control, although the synthetic chemical kills more aphids within a relatively shorter time in comparison to plant extracts applied at the same time length3,17. At 48 h after treatment, aphid mortality (at a treatment of 90 mL L1) was the highest of all the other treatments. In a different study, an overall performance of two consecutive sprays in two different locations against the population of cabbage aphid by insecticides gave as an average effect after a 3rd day of application27. However, the current work further showed that there was relationship between the efficacy of BA concentration and its contact time. Similar results were obtained by Mvumi and Maunga17, who investigated the efficacy of lantana extract against aphids in rape (Brassica nupas) over varied periods of time and found that the extract was most efficacious at the longest contact time. This also agreed with the study on the efficacy of BA on bird cherry-oat aphid Rhopalosiphum padi done by other researchers29. Based on these results, it can be acknowledged that BA is lethal to cabbage aphid. Therefore, for BA, farmers should use 90 ml L1 for 48 h-contact time in order to achieve the highest aphid mortality.

CONCLUSION

Considering the fruit concentrations tests of efficacy at 6, 24 and 48 h contact times, the fruit concentrations revealed highly significant cabbage aphid mortality at the longest contact time (48 h). Therefore, this can be considered the best contact time to control cabbage aphid when using BA fruit extract.

SIGNIFICANCE STATEMENT

This study discovered the biopesticide (bitter apple) extract that can be beneficial for aphid control in cabbage whereby, among the three different bitter apple fruit solution concentrations used, the 90 mL L1 at 48 h proved to be highly effective against the aphids, in comparison to the other shorter times (6; 24 h). This study will help the researchers to uncover the critical areas concerning plants which are pesticidal and the length of contact time to cause lethality. Flora distribution is biome-specific, such that; many researchers were not able to explore the pesticidal potential of bitter apple. Thus a new theory on research-based identifications of local plants being potentially pesticidal to common pests in the area may be arrived at.

REFERENCES

1:  Tyagi, S.K. and A.R. Khire, 2018. Vegetable Crops at a Glance. Scientific Publisher, Jodhpur, India, ISBN: 9789386652478, pp: 19-28

2:  CABI., 2013. Crop Protection Compendium. Centre for Agriculture and Bioscience International, UK

3:  Kopondo, F.B.O., 2004. Notes on African indigenous vegetables and edible mushrooms for tertiary level institute. Moi University, Nairobi, Kenya

4:  Turner, A. and O. Chivinge, 1999. Production and Marketing of Horticultural Crops in Zimbabwe: A Survey of Smallholder Farmers in the Mashonaland East Province. CIIFAD., Ithaca, New York, Pages: 74

5:  Bhatti, M.A., M. Saeed, N. Chattan and S. Iqbal, 1976. Host-plant resistance and importance to insect population suppression in cotton crop. Proceedings of the Cotton Producation Seminar, April 29-30, 1976, ESSO, Pak. Fertilizer Co. Ltd., pp: 132-142

6:  Swiader, J.M., G.W. Ware and J.P. McCollum, 1992. Producing Vegetable Crops. Interstate Publishers Inc., Danville, Ill, ISBN-13: 9780813429038, Pages: 602

7:  Munthali, D.C. and A.B. Tshegofatso, 2014. Factors affecting abundance and damage caused by cabbage aphid, Brevicoryne brassicae on four brassica leafy vegetables: Brassica oleracea var. Acephala, B. chinense, B. napus and B. carinata. Entomol. J., 8: 1-9.
CrossRef  |  Direct Link  |  

8:  Tibugari, H., P. Jowah, R. Mandumbu and C. Karavina, 2012. Tackling diamondback moth Plutella xylostella (L.) resistance: A review on the current research on vegetable integrated pest management in Zimbabwe. Arch. Phytopathol. Plant Prot., 45: 2445-2453.
CrossRef  |  Direct Link  |  

9:  Sibanda, T., H.M. Dobson, J.F. Cooper, W. Manyangarirwa and W. Chiimba, 2000. Pest management challenges for smallholder vegetable farmers in Zimbabwe. Crop Prot., 19: 807-815.
CrossRef  |  Direct Link  |  

10:  Obopile, M., D. Munthali and B. Matilo, 2008. Farmers’ knowledge, perceptions and management of vegetable pests and diseases in Botswana. Crop Prot., 27: 1220-1224.
CrossRef  |  Direct Link  |  

11:  Williamson, S., A. Ball and P. Jules, 2008. Trends in pesticide use and drivers for safer pest management in four African countries. Crop Prot., 27: 1327-1334.
CrossRef  |  Direct Link  |  

12:  Yi, Y.J., R.S. Liu, H.Q. Yin, K. Luo, E.M. Liu and X.D. Liu, 2007. Isolation, identification and field control efficacy of an endophytic strain against tobacco bacterial wilt (Ralstonia solanacarum). Chin. J. Applied Ecol., 18: 554-558, (In Chinese).
PubMed  |  Direct Link  |  

13:  Mvumi, C., E. Ngadze, D. Marais, E.S. du Toit and B.M. Mvumi, 2017. Moringa (Moringa oleifera) leaf extracts inhibit spore germination of Alternaria solani, causal agent of early blight disease of tomato (Solanum lycopersicum). S. Afr. J. Plant Soil, 34: 161-165.
CrossRef  |  Direct Link  |  

14:  Shmutterer, H., 1997. Side-effects of neem (Azadirachta indica) products on insect pathogens and natural enemies of spider mites and insects. J. Applied Entomol., 12: 121-128.
CrossRef  |  Direct Link  |  

15:  Stevenson, P.C., S.P. Nyirenda, B.M. Mvumi, P. Sola, J.F. Kamanula, G.W. Sileshi and S.R. Belmain, 2012. Pesticidal Plants: A Viable Alternative Insect Pest Management Approach for Resource-Poor Farming in Africa. In: Botanicals in Environment and Food Security, Koul, O., G.S. Dhaliwal, S. Khokhar and R. Singh (Eds.), Scientific Publishers, Jodhpur, ISBN 9788172337971, pp: 212-238

16:  Mkenda, P., R. Mwanauta, P.C. Stevenson, P. Ndakidemi, K. Mtei and S.R. Belmain, 2015. Extracts from field margin weeds provide economically viable and environmentally benign pest control compared to synthetic pesticides. PLoS One, Vol. 10, No. 11.
CrossRef  |  Direct Link  |  

17:  Mvumi, C. and P.R. Maunga, 2018. Efficacy of lantana (Lantana camara) extract application against aphids (Brevicoryne brassicae) in rape (Brassica napus) over varied periods of time. Afr. J. Biotechnol., 17: 249-254.
CrossRef  |  Direct Link  |  

18:  Ogendo, J.O., S.R. Belmain, A.L. Deng and D.J. Walker, 2003. Comparison of toxic and repellent effects of Lantana camara L. with Tephrosia vogelii hook and a synthetic pesticide against Sitophilus zeamais Motschulsky (Coleoptera: Curculionidae) in stored maize grain. Int. J. Trop. Insect Sci., 23: 127-135.
CrossRef  |  Direct Link  |  

19:  Muzemu, S., B.M. Mvumi, S.P.M. Nyirenda, G.W. Sileshi and P. Sola et al., 2011. Pesticidal effects of indigenous plants extracts against rape aphids and tomato red spider mites. Afr. Crop Sci. Conf. Proc., 10: 169-171.
Direct Link  |  

20:  Cao, H.H., H.R. Liu, Z.F. Zhang and T.X. Liu, 2016. The green peach aphid Myzus persicae perform better on pre-infested Chinese cabbage Brassica pekinensis by enhancing host plant nutritional quality. Sci. Rep., Vol. 6
CrossRef  |  Direct Link  |  

21:  Powell, G., C.R. Tosh and J. Hardie, 2006. Host plant selection by aphids: Behavioral, evolutionary and applied perspectives. Annu. Rev. Entomol., 51: 309-330.
CrossRef  |  Direct Link  |  

22:  Pahla, I., M. Moyo, S. Muzemu and T. Muziri, 2014. Evaluating the effectiveness of botanical sprays in controlling aphids (Brevicoryne brassicae) on rape (Brassica napus L.). Int. J. Agron. Agric. Res., 5: 1-6.
Direct Link  |  

23:  Gandhi, P.I., K. Gunasekaran and T. Sa, 2006. Neem oil as a potential seed dresser for managing Homopterous sucking pests of Okra (Abelmoschus esculentus (L.) Moench). J. Pest. Sci., 79: 103-111.
CrossRef  |  Direct Link  |  

24:  Peris, N.W. and J.J. Kiptoo, 2017. Potential of botanical extracts in the control of kale aphids (Brevicoryne brassicaea) and their effect on the parasitic wasp (Aphidius ervi). Asian Res. J. Agric., 4: 1-6.
CrossRef  |  Direct Link  |  

25:  Alghamdi, A.S., 2018. Insecticidal effect of four plant essential oils against two aphid species under laboratory conditions. J. Applied Biol. Biotechnol., 6: 27-30.
CrossRef  |  Direct Link  |  

26:  Abdel-Rahman, R.S., I.A. Ismail, T.A. Mohamed, M.E.F. Hegazy and K.A. Abdelshafeek, 2019. Laboratory and field evaluation of certain wild plant extracts against Aphis fabae Scop. (Homoptera: Aphididae) and its predators. Bull. National Res. Centre, Vol. 43
CrossRef  |  Direct Link  |  

27:  Shiberu, T. and M. Negeri, 2016. Effects of synthetic insecticides and crude botanicals extracts on cabbage aphid, Brevicoryne brassicae (L.) (Hemiptera: Aphididae) on Cabbage. J. Fertil. Pestic., Vol. 7.
CrossRef  |  Direct Link  |  

28:  Soliman, M.M.M., A.A. Hassanein and H. Abou-Yousef, 2005. Efficiency of various wild plant extracts against the cotton aphid, Aphis gossypii Glov. (Aphididae: Homoptera). Acta Phytopathol. Entomol. Hungar., 40: 185-196.
CrossRef  |  Direct Link  |  

29:  Asiry, K.A., 2015. Aphidicidal activity of different aqueous extracts of bitter apple Citrullus colocynthis (L.) against the bird cherry-oat aphid, Rhopalosiphum padi (L.) (Homoptera: Aphididae) under laboratory conditions. J. Anim. Plant Sci., 25: 456-462.
Direct Link  |  

©  2021 Science Alert. All Rights Reserved