Summary
Cassava is uniquely suited for food security and economic development in unfavored areas of the tropics. Development research for cassava is an urgent need. In 1998, the Cassava Biotechnology Network (CBN) convened a workshop of cassava stakeholder groups in Latin America. After hearing an opening statement from representatives of small-scale cassava producers and processors, stakeholders formulated a consensus set of research and development (R&D) priorities. An adequate supply of good-quality planting material of desired varieties was clearly the most urgent, followed by R&D on market-value traits; yield losses due to pests, diseases, and drought; and cropping system flexibility.
Two new projects are using in vitro techniques to address priorities of small-scale cassava farmers in Latin America. One project in Colombia combines a nongovernmental organization, a local farmers’ association, and the international research center, CIAT, to explore affordable micropropagation. Findings to date show that most culture medium components can be replaced with local products, and a rustic growth room permits good culture growth without electricity or air conditioning. Low-costs system(s) developed will be assessed as a local microenterprise.
A second project, in Ecuador, couples local cassava germplasm (with oral histories and an in vitro back-up collection) and elite clones (introduced in vitro) with new concepts in agribusiness development, to restart local farmers’ cooperatives after the disastrous 1998–99 el Niño floods. The project was developed through group planning by the cooperatives, the local technical university, the national agricultural research program, and CIAT.
Research to improve in vitro tools focuses on safe and stable conservation and exchange of cassava genetic resources, long-term, less expensive conservation, rapid clonal propagation, and ultimately, genetic transformation technologies to add desired traits to useful cassava varieties.
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References
Akano, A. O.; Asiedu, R.; Ng, S. Y. C.; Atiri, G. I. Effect of African cassava mosaic disease on growth and yield components of virus-tested cassava genotypes derived from meristem culture in early and late planting periods in three agroecologies of Nigeria. Proceedings of the Third International Scientific Meeting, Cassava Biotechnology Network, Kampala, Uganda, Aug. 1996. African J. Trop. Root Crops 26–30 2:44–48; 1997.
Angel, F.; Barney, V. E.; Tohme, J.; Roca, W. M. Stability of cassava plants at the DNA level after retrieval from 10 years of in-vitro storage. Euphytica 90:307–313; 1996.
Arias, D. I.; Sayre, R. T. Genetic engineering approaches to reducing cyanide toxicity in cassava (Manihot esculenta Crantz) Abstract. Brazilian Cassava Journal (Supplement): Vol. 17:29; 1998.
Cock, J. H.; Franklin, D.; Sandoval, G.; Juri, P. The ideal cassava plant for maximum yield. Crop Sci. 19:271–279; 1979.
Delgado, G. E.; Rojas, C. Cassava “seed” production program by meristem culture in UNPRG, Lambayeque, Peru. In: Thro, A. M.; Roca, W., ed. Proceedings of the First International Scientific Meeting, Cassava Biotechnology Network, Cartagena, Colombia, 25–28 August 1992. CIAT Working Doc. No. 123:146–148; 1993.
Escobar, R. H.; Mafla, G.; Roca, W. M. Cryopreservation for long-term conservation of cassava genetic resources. In: Proceedings of the Second International Scientific Meeting, Cassava Biotechnology Network, Bogor, Indonesia, 25–28 August 1994. CIAT Working Doc. No. 150:190–193; 1995.
Epperson, J. E.; Pachico, D. H.; Guevara, C. L. The costs of maintaining genetic resources for cassava, Manihot esculenta Crantz. Acta Hortic. 429:409–413; 1996.
Garcia, G. M.; Vega, V. M.; Rodriguez, M. S. Effect of meristem culture on vigour and yield of the cassava clone “Senorita”. In: Thro, A. M.; Roca, W., ed. Proceedings of the First International Scientific Meeting, Cassava Biotechnology Network, Cartagena, Colombia, 25–28 August 1992. CIAT Working Doc. No. 123:149–153; 1993.
Gonzalez, A. E.; Schopke, C.; Taylor, N. J.; Beachy, R. N.; Fauquet, C. M. Regeneration of transgenic cassava plants (Manihot esculenta Crantz) through Agrobacterium-mediated transformation of embryogenic suspension cultures. Plant Cell Rep. 17:827–831; 1998.
Guo, J. Y.; Liu, Y. Q. Rapid propagation of cassava by tissue culture and its application in rural districts in China. In: Proceedings of the Second International Scientific Meeting, Cassava Biotechnology Network, Bogor, Indonesia, 25–28 August 1994. CIAT Working Doc. No. 150:183–189; 1995.
Henry, G.; Howeler, R. Cassava in China in an era of change. A CBN case study in Southeastern China, August 1994. CIAT Working Doc. No. 155; 1995.
Henry, G.; Iglesias, C. Problems and opportunity in cassava biotechnology. In: Thro, A. M.; Roca, W., ed. Proceedings of the First International Scientific Meeting, Cassava Biotechnology Network, Cartagena, Colombia, 25–28 August 1992. CIAT Working Doc. No. 123:432–461; 1993.
IPGRI/CIAT. Establishment and operation of a pilot in vitro active genebank. Report of a CIAT-IBPGR Collaborative Project using cassava (Manihot esculenta Crantz) as a model. A joint publication of IPBRI, Rome, and CIAT, Cali, Colombia; 1994; 59p.
Li, H. Q.; Sautter, C.; Potrykus, I.; Pounti-Kaerlas, J. Genetic transformation of cassava (Manihot esculenta Crantz) Nat. Biotechnol. 14:736–740; 1996.
Mabanza, J.; Rodriguez-Andriyamasi, A. F.; Mahouka, J.; Boumba, B. Evaluation of cleaned cassava varieties in Congo. In: Proceedings of the Second International Scientific Meeting, Cassava Biotechnology Network, Bogor, Indonesia, 25–28 August 1994. CIAT Working Doc. No. 150:194–201; 1995.
Ng, S. Y. C.; Ilona, P.; Adeniyi, O. J. Post-flask management of cassava and yam. Trop. Root Tuber Crops Bull. 8:6–7; 1994.
PROFISMA. Ecologically sustainable cassava plant protection in South America and Africa: an environmentally sound approach. Protecao Fitosanitária Sustentável da Mandioca na America Latina e Africa (PROFISMA). Annual Report 1997:68–196.
Raemakers, C. J. M.; Sofiari, E.; Taylor, N. J.; Henshaw, G. G.; Jacobsen, E.; Visser, R. G. F. Production of transgenic cassava (Manihot esculenta Crantz) plants by particle bombardment using luciferase activity as selection marker. Mol. Breed. 2:339–349; 1996.
Roca, W. M. Cassava. In: Sharp, W.; Evans, D.; Ammirato, P.; Yamada, Y., ed. Handbook of plant cell culture. Vol. 2. Crop species. New York: Macmillan; 1984:269–301.
Roca, W. M.; Nolt, B.; Mafla, G.; Roa, J.; Reyes, R. Eliminación de virus y propagación de clones en la yuca (Manihot esculenta Crantz). In: Roca, W. M.; Mroginski, L. A., ed. Cultivo de tejidos en la agricultura: fundamentos y aplicaciones. CIAT, Colombia; 1991:403–420.
Roca, W.; Henry, G.; Angel, F.; Sarria, R. Biotechnology research applied to cassava improvement at the International Center of Tropical Agriculture (CIAT). Agric. Biotechnol. News Inf. C. A. B. Int. 4:303–308; 1992.
Roca, W. M.; Chavez, R.; Marin, M. L.; Arias, D. I.; Mafla, G.; Reyes, R. In vitro methods of germ-plasm conservation. Genome 31:813–817; 1989.
Sarria, R.; Torres, E.; Angel, F.; Chavarriaga, P.; Roca, W. M. Ppt-Resistant cassavao obtained through Agrobacterium-mediated transformation. Plant Cell Rep. In press.
Sarria, R.; Torres, E.; Balcazar, N.; Destefano, L; Roca, W. M. Progress in Agrobacterium-mediated transformation of cassava (Manihot esculenta Crantz). In: Proceedings of the Second International Scientific Meeting, Cassava Biotechnology Network, Bogor, Indonesia, 24–28 August 1994. CIAT Working Doc. No. 150:241–244; 1995.
Schopke, C.; Taylor, N. J.; Cárcano, R.; Konan, N. K.; Marmey, P.; Henshaw, G. G.; Beachy, R. N.; Fauquet, C. M. Regeneration of cassava plants (Manihot esculenta Crantz) for microbombarded embryogenic suspension cultures. Nat. Biotechnol. 14:731–735; 1996.
Stamp, J. A.; Henshaw, G. G. Secondary somatic embryogenesis and plant regeneration in cassava. Plant Cell Tissue Organ Cult. 10:227–233; 1987.
Taylor, N. J.; Edwards, M.; Kiernan, R.; Davey, C. D. M.; Blakesley, D.; Henshaw, G. G. Development of friable embryogenic callus and embryogenic suspension culture systems in cassava (Manihot esculenta Crantz). Nat. Biotech. 14:126–130; 1996.
Thresh, J. M.; Otim-Nape, G. W.; Fargette, D. African cassava mosaic disease: an overall perspective. In: Thro, A. M.; Akoroda, M. O. Proceedings of the Third International Scientific Meeting, Cassava Biotechnology Network, Kampala, Uganda, 26–30 August 1996. African J. of Trop. Root Crops 2:13–18; 1997.
Thro, A. M.; Msabaha, M.; Kulembeka, H.; Shengero, W.; Kapande, A.; Mlingi, N.; Hemed, L.; Digges, P.; Cropley, J. Village perspectives on cassava production, processing, and use. A CBN Case Study in the Lake Zone of Northern Tanzania, October 1993. CIAT Working Doc. No. 154; 1994:82 p.
Thro, A. M.; Herazo, L. E.; Lenis, J. I. Flor de Yuca—Que florece un región. Que puede hacer la biotecnología para ayudar el pequeño productor de yuca en la Costa Norte de Colombia? (“What can biotechnology do to help the small farmer in the North Coast region of Colombia?”; also available in English). CIAT Working Doc. No. 164; 1997:15 p.
Uyen, N. V.; Vander Zaag, P. Vietnamese farmers use tissue culture for commercial potato production. Am. Potato J. 60:873–879; 1983.
Visser, R. G. R.; Jacobsen, E. Towards modifying plants for altered starch content and composition. Trends Biotechnol. 11:63–68; 1993.
Zok, S. Rapid seed stock multiplication of improved clones of cassava through shoot tip culture in Cameroon. In: Thro, A. M.; Roca, W., ed. Proceedings of the First International Scientific Meeting, Cassava Biotechnology Network, Cartagena, Colombia, 25–28 August 1992. CIAT Working Doc. No. 123:96–104; 1993.
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Thro, A.M., Roca, W.M., Restrepo, J. et al. Can in vitro biology have farm-level impact for small-scale cassava farmers in Latin America?. In Vitro Cell.Dev.Biol.-Plant 35, 382–387 (1999). https://doi.org/10.1007/s11627-999-0051-8
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DOI: https://doi.org/10.1007/s11627-999-0051-8