,
Habte Nida,
Derara Sori,
Temesgen Begna,
Temesgen Teressa,
Hailu Gichile,
Ashenafi Getahun,
Muktar Mohammed
Sorghum is a vital crop for food security in Ethiopia. Sorghum landraces are particularly crucial in crop-livestock mixed farming, however, the extended growing periods (6-8 months) required for these landraces make the crop vulnerable to recurrent drought events associated with delayed rain, dry spells, and drought during critical stages. The landraces are usually planted in March or April depending on the onset of rainfall and harvested around November but often fail due to drought. In such situations, early-maturing improved varieties are an option for farmers but access to seeds of these improved varieties is a challenge. Unlike the landraces, the improved early maturing varieties are planted around the first weeks of July and harvested in November. The formal seed system multiplies only a limited amount of improved sorghum seed, which is rarely available to smallholder sorghum growers, mostly as part of a government package for targeted programs. Therefore, a community-based seed multiplication (CBSM) scheme was introduced to address seed shortages among smallholder sorghum farmers. After a successful experiment in 2015 aimed at enhancing seed multiplication by smallholder sorghum farmers, the process was further implemented on a larger scale using the CBSM scheme. Between 2016 and 2017, three CBSM farmer groups consisting of a total of 56 participants were established in three districts of West Hararghe, Ethiopia. Seeds of two early-maturing and drought-tolerant improved sorghum varieties (Dekeba and Melkam) were multiplied on a total area of 49.58 hectares, resulting in 215.6 tons of certified seeds. The study's findings indicate that the CBSM scheme enhanced smallholder farmers' sorghum yields, incomes, and climate resilience by providing high-quality seeds, expanding access to improved seeds, improving crop quality, and empowering communities to manage seed distribution. Partnerships with local organizations and government agencies were vital for success, allowing the scheme to reach more farmers in different regions. The scheme proved successful for smallholder sorghum growers in Ethiopia's dry lowlands, offering lessons applicable to similar challenges elsewhere, and promoting sustainable solutions for smallholder farmers.
| Published in | Agriculture, Forestry and Fisheries (Volume 13, Issue 4) |
| DOI | 10.11648/j.aff.20241304.13 |
| Page(s) | 116-125 |
| Creative Commons |
This is an Open Access article, distributed under the terms of the Creative Commons Attribution 4.0 International License (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted use, distribution and reproduction in any medium or format, provided the original work is properly cited. |
| Copyright |
Copyright © The Author(s), 2024. Published by Science Publishing Group |
Improved Sorghum Seed, Seed Security, Drought-Tolerant, Climate Resilience, Sustainable Agriculture, West-Hararghe, Ethiopia
| [1] | CSA. Report on Area and Production of Major Crops (Private Peasant Holdings, Meher Season), in Agricultural Sample Survey 2017/18 (2010 E. C.), The Federal Democratic Republic of Ethiopia, Central Statistical Agency. 2018: Addis Ababa, Ethiopia. |
| [2] | Wanous, M. K., Miller, F. R. and Rosenow, D. T. Evaluation of visual rating scales for green leaf retention in sorghum. Crop science, 1991. 31(6): p. 1691-1694 |
| [3] | Dykes, L. Sorghum phytochemicals and their potential impact on human health. Sorghum: Methods and Protocols, 2019: p. 121-140 |
| [4] | Queiroz, M. S., Oliveira, C. E., Steiner, F., Zuffo, A. M., Zoz, T., Vendruscolo, E. P., Silva, M. V., Mello, B. F., Cabral, R. C. and Menis, F. T. Drought stresses on seed germination and early growth of maize and sorghum. Journal of Agricultural Science, 2019. 11(2): p. 310 |
| [5] | Abreha, K. B., Enyew, M., Carlsson, A. S., Vetukuri, R. R., Feyissa, T., Motlhaodi, T., Ng’uni, D. and Geleta, M. Sorghum in dryland: morphological, physiological, and molecular responses of sorghum under drought stress. Planta, 2022. 255: p. 1-23 |
| [6] | Bobade, P., Amarshettiwar, S., Rathod, T., Ghorade, R., Kayande, N. and Yadav, Y. Effect of polyethylene glycol induced water stress on germination and seedling development of rabi sorghum genotypes. Journal of Pharmacognosy and Phytochemistry, 2019. 8(5): p. 852-856. |
| [7] | Geremew, G., Adugna, A., Taye, T., Tesfaye, T., Ketema, B. and Michael, H. Development of sorghum varieties and hybrids for dryland areas of Ethiopia. Uganda Journal of Agricultural Sciences, 2004. 9(1): p. 594-605. |
| [8] | Assefa, Y., Staggenborg, S. A. and Prasad, V. P. Grain sorghum water requirement and responses to drought stress: A review. Crop Management, 2010. 9(1): p. 1-11 |
| [9] | Enyew, M., Carlsson, A. S., Geleta, M., Tesfaye, K., Hammenhag, C., Seyoum, A. and Feyissa, T. Novel sources of drought tolerance in sorghum landraces revealed via the analyses of genotype-by-environment interactions. Frontiers in Plant Science, 2022. 13 |
| [10] | Tirfessa, A., Getachew, F., McLean, G., van Oosterom, E., Jordan, D. and Hammer, G. Modeling adaptation of sorghum in Ethiopia with APSIM—opportunities with G×E×M. Agronomy for Sustainable Development, 2023. 43(1): p. 15 |
| [11] | Sirany, T., Tadele, E., Aregahegn, H. and Wale, D. Economic Potentials and Use Dynamics of Sorghum Food System in Ethiopia: Its Implications to Resolve Food Deficit. Advances in Agriculture, 2022. 2022: p. 4580643 |
| [12] | Mulesa, T. Politics of Seed in Ethiopia's Agricultural Transformation: Pathways to Seed System Development. Frontiers in Sustainable Food Systems, 2021. 5: p. 742001 |
| [13] | Zerssa, G., Feyssa, D., Kim, D. G. and Eichler-Lobermann, B. Challenges of Smallholder Farming in Ethiopia and Opportunities by Adopting Climate-Smart Agriculture. Agriculture, 2021. 11: p. 192 |
| [14] | Thijssen, M. H., Bishaw, Z., Beshir, A. and Boef, W. S. d. Farmers, seeds and varieties: supporting informal seed supply in Ethiopia. 2008, Wageningen: Wageningen International. 348-348. |
| [15] | Alemu, D. Farmer-based seed multiplication in the Ethiopian seed system: Approaches, priorities and performance, in AFC Working Paper 036. 2011, Future Agricultures Consortium: Brighton. p. 13-13. |
| [16] | Sisay, D. T., Verhees, F. J. H. M. and van Trijp, H. C. M. Seed producer cooperatives in the Ethiopian seed sector and their role in seed supply improvement: A review. Journal of Crop Improvement, 2017. 31(3): p. 323-355 |
| [17] | Bishaw, Z. and Louwaars, N. Evolution of seed policy and strategies and implications for Ethiopian seed systems development, A. T. Wold, et al., Editors. 2012, Ethiopian Institute of Agricultural Research: Addis Ababa, Ethiopia. p. 31-60. |
| [18] | Mekbib, F. Farmers’ Seed System of Sorghum (Sorghum bicolor (L.) Moench) in the Center of Diversity: I. Seed Sources, Distribution, and Networking. Journal of New Seeds, 2007. 8(3): p. 23 |
| [19] | Seboka, B. and Deressa, A. Validating farmers' indigenous social networks for local seed supply in central rift valley of Ethiopia. The Journal of Agricultural Education and Extension, 1999. 6(4): p. 245-254 |
| [20] | Atilaw, A. and Korbu, L. Recent development in seed systems of Ethiopia. in Empowering Farmers' Innovation - Improving Farmers' Access to Seed. 2011. Addis Ababa, Ethiopia.: Ethiopian Institute of Agricultural Research. |
| [21] | Abebaw, A., Adane, M., Birhanu, A., Dessalegn, T. and Mazengia, Y. Assessment of Seed Systems in North Western Ethiopia; with Special Emphasis on Community Based Seed Multiplication Scheme. World Scientific News, 2015. 12: p. 100-110. |
| [22] | Tufa, A., Meuwissen, M., Lommen, W. J. M., Oude Lansink, A., Tsegaye, A. and Struik, P. Improving seed potato quality in Ethiopia: a value chain perspective. 2016. p. 101-118 |
| [23] | FarmAfrica. Cooperative Based Seed Multiplication Systems. 2020. |
| [24] |
McGuire, S. J. Vulnerability in Farmer Seed Systems: Farmer Practices for Coping with Seed Insecurity for Sorghum in Eastern Ethiopia. Economic Botany, 2007. 61(3): p. 211-222
https://doi.org/10.1663/0013-0001(2007)61[211:VIFSSF]2.0.CO;2 |
| [25] | McGuire, S. J. Getting Genes: Rethinking seed system analysis and reform for sorghum in Ethiopia. 2005. |
| [26] | Tebeka, Y. A., Katungi, E., Rubyogo, J., Sserunkuuma, D. and Kidane, T. Economic performance of community based bean seed production and marketing in the central rift valley of Ethiopia. African Crop Science Journal, 2017. 25: p. 189 |
| [27] | Nateebwa, M., Okiror, J. and Mangheni, M. Effectiveness of community based seed multiplication in enhancing farmers’ knowledge and access to improved bean seeds in western Uganda. African Crop Science Journal, 2017. 25: p. 321 |
| [28] | Walsh, S., Remington, T., Kugbei, S. and Ojiewo, C. O. Review of community seed production practices in Africa Part 1: Implementation strategies and models. 2015. |
| [29] | Kassa, Y., Beyene, F., Haji, J. and Legesse, B. Impact of Integrated Soil and Water Conservation Program on Crop Production and Income in West Harerghe Zone, Ethiopia. International Journal of Environmental Monitoring and Analysis, 2013. 1(4): p. 111 |
| [30] | CSA. Report on Area and Production of Major Crops (Private Peasant Holdings, Meher Season), in Agricultural Sample Survey 2014 / 2015 (2007 E.C.), The Federal Democratic Republic of Ethiopia, Central Statistical Agency. 2015: Addis Ababa, Ethiopia. |
| [31] | ExpoGroup. Ethiopia: Improved sorghum varieties a solution to persistent drought. 2017. |
| [32] | EIAR. Ethiopian Strategy for Sorghum. 2014: Addis Ababa, Ethiopia. p. 28-28. |
| [33] | Shako, M., Dinku, A. and Mosisa, W. Constraints of Adoption of Agricultural Extension Package Technologies on Sorghum Crop Production at Smallholder Farm Household Level: Evidence from West Hararghe Zone, Oromia, Ethiopia. Advances in Agriculture, 2021. 2021: p. 6674606 |
| [34] | Kassa, B. and Alemu, D. Agricultural Research and Extension Linkages: Challenges and Intervention Options. Ethiopian Journal of Agricultural Science, 2017. 27(1): p. 21. |
| [35] | MoANR. Ethiopia’s Agricultural Extension Strategy: Vision, Systemic Bottlenecks and Priority Interventions. 2017, Ministry of Agriculture and Natural Resources (MoANR): Addis Ababa, Ethiopia. p. 52. |
| [36] | Tiwari, T. P., Virk, D. S. and Sinclair, F. L. Rapid Gains in Yield and Adoption of New Maize Varieties for Complex Hillside Environments through Farmer Participation: Part I, Improving Options through Participatory Varietal Selection (PVS). Field Crops Research, 2009. 111(1-2): p. 6 |
| [37] | Tirtha Bdr, K., Wangchuk, D., Namgay, W., Rinzin, C. and Lhap, D. Community Based Seed Production—A Sustainable Seed Production Model for Subsistence of Bhutanese Maize Farmers. Journal of Food Science and Engineering, 2015. 5(2): p. 76-84 |
| [38] | Sarah Haaij, Marianne Heselmans, Ellen Mangnus, Manon Stravens and Tielens, J. Farmers gain access to and control over seeds, in Seed Special Winter 2017, E. Mangnus and J. Tielens, Editors. 2017, Stichting Vice Versa: Mauritskade 63, 1092 AD Amsterdam, Netherlands. |
| [39] | Hirpa, A., Meuwissen, M. P., Tesfaye, A., Lommen, W. J., Lansink, A. O., Tsegaye, A. and Struik, P. C. Analysis of seed potato systems in Ethiopia. American journal of potato research, 2010. 87(6): p. 537-552 |
| [40] | Argaye, S. The Role of Formal, Informal and Intermediary Seed System for Food Security in Ethiopia. International Journal of Novel Research in Life Sciences, 2019. 6(5): p. 57-65. |
| [41] | Donovan, J., Rutsaert, P., Spielman, D., Shikuku, K. M. and Demont, M. Seed value chain development in the Global South: Key issues and new directions for public breeding programs. Outlook on Agriculture, 2021. 50(4): p. 366-377 |
| [42] | Bula, H., Soboka, D. and Ahmed, K. Prospects and Challenges in Seed Sector Development: Lessons from Eastern Ethiopia. European Business & Management, 2019. 5: p. 51 |
| [43] | Almekinders, C. J. M. and Louwaars, N. P. The Importance of the Farmers' Seed Systems in a Functional National Seed Sector. Journal of New Seeds, 2002. 4(1-2): p. 15-33 |
APA Style
Altaye, S. Z., Nida, H., Sori, D., Begna, T., Teressa, T., et al. (2024). Empowering Smallholder Sorghum Farmers for Resilience: Lessons from a Community-Based Seed Multiplication Scheme in West Hararghe, Ethiopia. Agriculture, Forestry and Fisheries, 13(4), 116-125. https://doi.org/10.11648/j.aff.20241304.13
ACS Style
Altaye, S. Z.; Nida, H.; Sori, D.; Begna, T.; Teressa, T., et al. Empowering Smallholder Sorghum Farmers for Resilience: Lessons from a Community-Based Seed Multiplication Scheme in West Hararghe, Ethiopia. Agric. For. Fish. 2024, 13(4), 116-125. doi: 10.11648/j.aff.20241304.13
AMA Style
Altaye SZ, Nida H, Sori D, Begna T, Teressa T, et al. Empowering Smallholder Sorghum Farmers for Resilience: Lessons from a Community-Based Seed Multiplication Scheme in West Hararghe, Ethiopia. Agric For Fish. 2024;13(4):116-125. doi: 10.11648/j.aff.20241304.13
Share This Article
Twitter
Linked In
Facebook
Copy
Download@article{10.11648/j.aff.20241304.13,
author = {Solomon Zewdu Altaye and Habte Nida and Derara Sori and Temesgen Begna and Temesgen Teressa and Hailu Gichile and Ashenafi Getahun and Muktar Mohammed},
title = {Empowering Smallholder Sorghum Farmers for Resilience: Lessons from a Community-Based Seed Multiplication Scheme in West Hararghe, Ethiopia
},
journal = {Agriculture, Forestry and Fisheries},
volume = {13},
number = {4},
pages = {116-125},
doi = {10.11648/j.aff.20241304.13},
url = {https://doi.org/10.11648/j.aff.20241304.13},
eprint = {https://article.sciencepublishinggroup.com/pdf/10.11648.j.aff.20241304.13},
abstract = {Sorghum is a vital crop for food security in Ethiopia. Sorghum landraces are particularly crucial in crop-livestock mixed farming, however, the extended growing periods (6-8 months) required for these landraces make the crop vulnerable to recurrent drought events associated with delayed rain, dry spells, and drought during critical stages. The landraces are usually planted in March or April depending on the onset of rainfall and harvested around November but often fail due to drought. In such situations, early-maturing improved varieties are an option for farmers but access to seeds of these improved varieties is a challenge. Unlike the landraces, the improved early maturing varieties are planted around the first weeks of July and harvested in November. The formal seed system multiplies only a limited amount of improved sorghum seed, which is rarely available to smallholder sorghum growers, mostly as part of a government package for targeted programs. Therefore, a community-based seed multiplication (CBSM) scheme was introduced to address seed shortages among smallholder sorghum farmers. After a successful experiment in 2015 aimed at enhancing seed multiplication by smallholder sorghum farmers, the process was further implemented on a larger scale using the CBSM scheme. Between 2016 and 2017, three CBSM farmer groups consisting of a total of 56 participants were established in three districts of West Hararghe, Ethiopia. Seeds of two early-maturing and drought-tolerant improved sorghum varieties (Dekeba and Melkam) were multiplied on a total area of 49.58 hectares, resulting in 215.6 tons of certified seeds. The study's findings indicate that the CBSM scheme enhanced smallholder farmers' sorghum yields, incomes, and climate resilience by providing high-quality seeds, expanding access to improved seeds, improving crop quality, and empowering communities to manage seed distribution. Partnerships with local organizations and government agencies were vital for success, allowing the scheme to reach more farmers in different regions. The scheme proved successful for smallholder sorghum growers in Ethiopia's dry lowlands, offering lessons applicable to similar challenges elsewhere, and promoting sustainable solutions for smallholder farmers.
},
year = {2024}
}
TY - JOUR T1 - Empowering Smallholder Sorghum Farmers for Resilience: Lessons from a Community-Based Seed Multiplication Scheme in West Hararghe, Ethiopia AU - Solomon Zewdu Altaye AU - Habte Nida AU - Derara Sori AU - Temesgen Begna AU - Temesgen Teressa AU - Hailu Gichile AU - Ashenafi Getahun AU - Muktar Mohammed Y1 - 2024/07/15 PY - 2024 N1 - https://doi.org/10.11648/j.aff.20241304.13 DO - 10.11648/j.aff.20241304.13 T2 - Agriculture, Forestry and Fisheries JF - Agriculture, Forestry and Fisheries JO - Agriculture, Forestry and Fisheries SP - 116 EP - 125 PB - Science Publishing Group SN - 2328-5648 UR - https://doi.org/10.11648/j.aff.20241304.13 AB - Sorghum is a vital crop for food security in Ethiopia. Sorghum landraces are particularly crucial in crop-livestock mixed farming, however, the extended growing periods (6-8 months) required for these landraces make the crop vulnerable to recurrent drought events associated with delayed rain, dry spells, and drought during critical stages. The landraces are usually planted in March or April depending on the onset of rainfall and harvested around November but often fail due to drought. In such situations, early-maturing improved varieties are an option for farmers but access to seeds of these improved varieties is a challenge. Unlike the landraces, the improved early maturing varieties are planted around the first weeks of July and harvested in November. The formal seed system multiplies only a limited amount of improved sorghum seed, which is rarely available to smallholder sorghum growers, mostly as part of a government package for targeted programs. Therefore, a community-based seed multiplication (CBSM) scheme was introduced to address seed shortages among smallholder sorghum farmers. After a successful experiment in 2015 aimed at enhancing seed multiplication by smallholder sorghum farmers, the process was further implemented on a larger scale using the CBSM scheme. Between 2016 and 2017, three CBSM farmer groups consisting of a total of 56 participants were established in three districts of West Hararghe, Ethiopia. Seeds of two early-maturing and drought-tolerant improved sorghum varieties (Dekeba and Melkam) were multiplied on a total area of 49.58 hectares, resulting in 215.6 tons of certified seeds. The study's findings indicate that the CBSM scheme enhanced smallholder farmers' sorghum yields, incomes, and climate resilience by providing high-quality seeds, expanding access to improved seeds, improving crop quality, and empowering communities to manage seed distribution. Partnerships with local organizations and government agencies were vital for success, allowing the scheme to reach more farmers in different regions. The scheme proved successful for smallholder sorghum growers in Ethiopia's dry lowlands, offering lessons applicable to similar challenges elsewhere, and promoting sustainable solutions for smallholder farmers. VL - 13 IS - 4 ER -
Chiro National Sorghum Research and Training Center, Ethiopian Institute of Agricultural Research, Chiro, Ethiopia
Melkassa Agricultural Research Center, Ethiopian Institute of Agricultural Research, Adama, Ethiopia
Melkassa Agricultural Research Center, Ethiopian Institute of Agricultural Research, Adama, Ethiopia
Chiro National Sorghum Research and Training Center, Ethiopian Institute of Agricultural Research, Chiro, Ethiopia
Chiro National Sorghum Research and Training Center, Ethiopian Institute of Agricultural Research, Chiro, Ethiopia
Chiro National Sorghum Research and Training Center, Ethiopian Institute of Agricultural Research, Chiro, Ethiopia
Chiro National Sorghum Research and Training Center, Ethiopian Institute of Agricultural Research, Chiro, Ethiopia
Faculty of Agriculture and Forestry, Oda-Bultum University, Chiro, Ethiopia
