Cacao swollen-shoot virus
|Cacao swollen-shoot virus (CSSV)|
|Group:||VII: DNA Reverse Transcribing Viruses|
|Species:||Cacao swollen-shoot virus|
theobroma virus 1
Cacao swollen-shoot virus (CSSV) is a plant pathogenic virus of the family Caulimoviridae that primarily infects cacao trees. It decreases cacao yield within the first year of infection, and usually kills the tree within a few years. Symptoms vary by strain, but leaf discoloration, stem/root swelling, and die-back generally occur. The virus is transmitted from tree to tree by mealybug vectors. It was first discovered in Ghana in 1936, and is currently endemic in Togo, Ghana and Nigeria. Over 200 million trees have already been claimed by this disease, which has prompted Ghana to launch the most ambitious and costly eradication effort of any country in the world against a viral plant disease.
Hosts and symptoms
Cacao swollen-shoot virus (CSSV) principally infects Theobroma cacao (cacao tree) and has a major effect on crop yields. Within one year of infection yields decrease by 25%, and within two years by 50%. The trees are usually killed within 3 to 4 years. Symptoms vary depending on the strain of virus. Main symptoms include: leaf chlorosis (interveinal), root necrosis, red vein banding in young leaves, small mottled pods, and stem/root swelling followed by die-back. CSSV has also been isolated from alternative hosts Cola chlamydanta, Ceiba pentandra, Adansonia digitata, Cola gigantean and Sterculia tragacantha. These alternate hosts display the same symptoms as infected cacao trees, but with less severity. Symptoms also vary with environmental conditions. Neither nutrition nor temperature changes have a perceivable effect on symptoms, but increased light intensity inhibits the development of root/stem swellings in infected plants. Shaded cacao trees exhibit decreased growth and slightly more severe symptoms.
Cacao swollen-shoot virus has a double stranded circular DNA genome that is 7.4 kb in size and bacilliform in structure. It is transmitted primarily through mealybug (Pseudococcidae) vectors. Once within the host, the virus uses the host to replicate. The virus codes for RNA silencing genes, which turn off the host plant's defenses. Its genome also codes for a movement protein, which allows the virus to move throughout the plant using the plasmodesmata. Of the many identified strains, the most studied and severe is the New Juaben strain, which is widespread in eastern Ghana. There is some spread of the virus at all times of year, but seasonally, spread depends on the size and activity of the mealybug population. It is hard to see this correlation within the cacao population because symptoms start to show at times of new growth.
CSSV is primarily transmitted by mealybugs. These mealybugs have a mutualistic relationship with ants which provide protection in return for sugar exudates. Fourteen species of mealybugs within the family Pseudoccidae act as vectors for CSSV, but Planococcoides njalensis and Planococcus citri are the most important mealybug vectors. Transmission is semi-persistent, meaning that the virus is taken up into the vector's circulatory system, but does not replicate within it. The feeding period required for acquisition of the virus is, at minimum, 20 minutes, but optimally 2–4 days. Once acquired, the virus can be transmitted within 15 minutes, but optimal transmission occurs 2–10 hours after acquisition. No transmission of the virus occurs through the mealybug eggs.
Light intensity has the effect of reducing swelling in shoots while plants in the shade show more severe symptoms. Temperature and nutrition have no significant effect. Since mealy bugs are the vectors of the virus, environmental conditions favorable to mealy bugs could increase the spread of the virus. Planococcus njalensis population density is closely correlated with density of ants in the Crematogaster genus, which build protective carton tents over the mealy bug colonies. High-density planting can facilitate the spread of the virus when mealy bugs are able to go from plant to plant through the interlocked canopy. Aside from crawling from plant to plant, mealy bugs can be dispersed by wind as well. In controlled trials, 340 feet was the maximum distance a mealy bug could be spread from an infected plant to a cacao seedling by wind dispersal. In dry conditions, aerial dispersal is increased.
Only occurs in West Africa. Major problem in Togo, Ghana, Cote d'Ivorie and Nigeria; transmitted by mealybugs. The Swollen Shoot Virus is not native to cocoa but jumped into the cocoa from trees that grew in the rain forests of W. Africa (e.g. Cola chlamydanta, Ceiba pentandra, Adansonia digitata, Cola gigantean and Sterculia tragacantha). The virus is a badnavirus within the family Caulimoviridae. Eradication of infected trees has been the most widely used means of control. In Ghana, between 2006 and 2010, over 28 million trees were removed for being visibly infected or for being in contact with infected trees. This serves to remove the source of inoculum to prevent spread of the virus; however the method has not succeeded to significantly control the disease. Since there are alternative host species that could also serve as inoculum, their removal has been advised too. Although it has been suggested the importance of alternative hosts in cacao re-infection is not that great compared to cacao-cacao infection, it is still advised by Dzahini-Obiatey et al. that alternative hosts, such as Cola gigantea, be removed from newly planted fields.
Before planting any new plantation, it is advised that all obviously infected trees in the surrounding plantations be removed beforehand. Also, a cordon, or gap, should be left around the entire plantation, putting the new plants a recommended 10 meters away from any old plantations that could contain infected trees. It is also recommended that the cordon be planted with a CSSV-resistant crop to provide a physical barrier to the mealy bug vectors.
This is viewed as a waste of land, however, by farmers in Ghana who are set on growing only the valuable cacao plant, so they are resistant to the idea. This issue is being addressed by suggesting alternative money-making crops such as citrus and oil palm, which have promise as barriers that prevent the spread of CSSV. Farmers are also occasionally resistant to the idea of killing infected plants if they feel they can still get some harvest from them. In both cases, education through extension practices has been suggested as a means of convincing farmers to participate in these control measures, as well as more rigid implementation of these recommendations.
If only a single seedling is infected in a new plantation, it may seem insignificant at first.[according to whom?] However, once the canopy starts to grow together with interlocking branches, mealy bug movement is facilitated and the virus can quickly spread to the whole plantation. Since the virus is transmitted readily through seed, only seed that is known to be free of the virus should be planted.
Planococcus njalensis population density is closely correlated with density of ants in the Crematogaster genus, which build protective carton tents over the mealy bug colonies. Crematogaster populations however are negatively correlated with populations of ants of the Oecophylla genus. This could be a natural biological control that is worth considering if agents to control the Crematogaster ants are developed, since they should not target Oecophylla ants as well.
Cacao swollen shoot virus has had a major impact on cocoa production in Africa. Since its discovery in 1936, it has not been effectively contained, despite costly eradication efforts, especially in Ghana. With yield losses of 25% and 50% the first and second years, respectively, and eventual death of the plant, this has been a persistent issue affecting the livelihoods of cocoa farmers. The partially effective methods of management mentioned above were not realized until the late 1960s and 1970s. Between 1936 and that time the cocoa industry of Ghana almost completely broke down, causing much rural discontent and political uproar. Today CSSV is responsible for 15% of total cocoa crop loss in the world.
- Dzahini-Obiatey, H., O. Domfeh, and F. M. Amoah. 2010. Over seventy years of a viral disease of cocoa in Ghana: From researchers' perspective. Afr. J. Agric. Res. 5:476-485.
- Crowdy, S. H., and A. F. Posnette. 1947. Virus diseases of cacao in West Africa. II Cross-immunity experiments with viruses 1A, 1B, 1C. Ann. Appl. Biol. 34:403-411.
- Dongo, L. N., and S. B. Orisajo. 2007. Status of cocoa swollen shoot virus disease in Nigeria. Afr. J. Biotechnol. 6:2054-2061.
- Legg, J., and J. Bonney. 1967. Host Range and Vector Species of Viruses from Cola Chlamydantha K Schum Adansonia Digitata L and Theobroma Cacao L. Ann. Appl. Biol. 60:399-403.
- Asomaning, E. J. A., and R. G. Lockard. 1964. Studies on the physiology of cocoa (Theobroma cacao L.). I Suppression of swollen-shoot virus symptoms by light. Ann. Appl. Biol. 54: 193-198.
- Thresh, J. 1974. Temporal Patterns of Virus Spread. Annu. Rev. Phytopathol. 12:111-128.
- Posnette, A. F., and N. F. Robertson. 1950. Virus diseases of cacao in West Africa. VI. Vector investigations. Ann. Appl. Biol. 37:363-377.
- Quainoo, A. K., A. C. Wetten, and J. Allainguillaume. 2008. Transmission of cocoa swollen shoot virus by seeds. J. Virol. Methods. 150:45-49.
- Strickland, A.H. (1951). "The Entomology of Swollen Shoot of Cacao. II.—The Bionomics and Ecology of the Species involved". Bulletin of Entomological Research. 42: 65–103. doi:10.1017/s0007485300025177.
- Strickland, A.H. (1951). "The entomology of swollen shoot of cacao. 1. The insect species involved with notes on their biology". Bull. Entomol. Res. 41: 725–748.
- Cornwell, P.B. (1960). "Movement of vectors of virus disease of cacao in Ghana. II. Wind movement and aerial dispersal". Bull. Entomol. Res. 51: 175–201. doi:10.1017/s0007485300055048.
- O. Domfeh, O.; H. Dzahini-Obiatey; G. A. Ameyaw; K. Abaka-Ewusie; G. Opoku (12 October 2011). "Cocoa swollen shoot virus disease situation in Ghana: A review of current trends". African Journal of Agricultural Research. 6 (22): 5033–5039.
- Posnette, A.F. (1981). "The role of wild hosts in cocoa swollen shoot disease". Thresh, J.M. (Ed.), Pest, Pathogens and Vegetation. Pitman, London: 71–78.
- Dzahini-Obiatey, H.; G. Akumfi Ameyaw; L.A. Ollennu (2006). "Control of cocoa swollen shoot disease by eradicating infected trees in Ghana: A survey of treated and replanted areas". Crop Protection. 25: 647–652. doi:10.1016/j.cropro.2005.09.004.
- Are, L.A. (1969). "Rehabilitation of cocoa farms". Cocoa Growers Bull. 13: 11–13.
- Ollennu, L.A.; Osei-Bonsu, K.; Acheampong, K.; Aneani, F. (2001–2002). "Barrier Cropping Trial". Annual Report of The Cocoa Research Institute of Ghana. in press.
- Kokutse, Francis (2008). "Swollen Shoot Disease Devastating Cocoa Trees". Inter Press Service News Agency. Retrieved 26 October 2011.
- Danquah, Francis K. (2003). "Sustaining a West African Cocoa Economy: Agricultural Science and the Swollen Shoot Contagion in Ghana, 1936-1965". African Economic History. 31: 43–74.